arduino-esp32/libraries/WiFi/src/WiFiGeneric.cpp

785 lines
24 KiB
C++

/*
ESP8266WiFiGeneric.cpp - WiFi library for esp8266
Copyright (c) 2014 Ivan Grokhotkov. All rights reserved.
This file is part of the esp8266 core for Arduino environment.
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
Reworked on 28 Dec 2015 by Markus Sattler
*/
#include "WiFi.h"
#include "WiFiGeneric.h"
extern "C" {
#include <stdint.h>
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#include <inttypes.h>
#include <string.h>
#include <esp_err.h>
#include <esp_wifi.h>
#include <esp_event_loop.h>
#include "lwip/ip_addr.h"
#include "lwip/opt.h"
#include "lwip/err.h"
#include "lwip/dns.h"
#include "esp_ipc.h"
} //extern "C"
#include "esp32-hal-log.h"
#include <vector>
#include "sdkconfig.h"
static xQueueHandle _network_event_queue;
static TaskHandle_t _network_event_task_handle = NULL;
static EventGroupHandle_t _network_event_group = NULL;
esp_err_t postToSysQueue(system_prov_event_t *data)
{
if (xQueueSend(_network_event_queue, &data, portMAX_DELAY) != pdPASS) {
log_w("Network Event Queue Send Failed!");
return ESP_FAIL;
}
return ESP_OK;
}
static void _network_event_task(void * arg){
system_prov_event_t *data;
for (;;) {
if(xQueueReceive(_network_event_queue, &data, portMAX_DELAY) == pdTRUE){
if(data->prov_event != NULL){
WiFiGenericClass::_eventCallback(arg, data->sys_event, data->prov_event);
free(data->sys_event);
free(data->prov_event);
} else {
WiFiGenericClass::_eventCallback(arg, data->sys_event, NULL);
}
free(data);
}
}
vTaskDelete(NULL);
_network_event_task_handle = NULL;
}
static esp_err_t _network_event_cb(void *arg, system_event_t *event){
system_prov_event_t *sys_prov_data = (system_prov_event_t *)malloc(sizeof(system_prov_event_t));
if(sys_prov_data == NULL) {
return ESP_FAIL;
}
sys_prov_data->sys_event = event;
sys_prov_data->prov_event = NULL;
if (postToSysQueue(sys_prov_data) != ESP_OK){
free(sys_prov_data);
return ESP_FAIL;
}
return ESP_OK;
}
static bool _start_network_event_task(){
if(!_network_event_group){
_network_event_group = xEventGroupCreate();
if(!_network_event_group){
log_e("Network Event Group Create Failed!");
return false;
}
xEventGroupSetBits(_network_event_group, WIFI_DNS_IDLE_BIT);
}
if(!_network_event_queue){
_network_event_queue = xQueueCreate(32, sizeof(system_prov_event_t));
if(!_network_event_queue){
log_e("Network Event Queue Create Failed!");
return false;
}
}
if(!_network_event_task_handle){
xTaskCreateUniversal(_network_event_task, "network_event", 4096, NULL, ESP_TASKD_EVENT_PRIO - 1, &_network_event_task_handle, CONFIG_ARDUINO_EVENT_RUNNING_CORE);
if(!_network_event_task_handle){
log_e("Network Event Task Start Failed!");
return false;
}
}
return esp_event_loop_init(&_network_event_cb, NULL) == ESP_OK;
}
void tcpipInit(){
static bool initialized = false;
if(!initialized && _start_network_event_task()){
initialized = true;
tcpip_adapter_init();
}
}
static bool lowLevelInitDone = false;
static bool wifiLowLevelInit(bool persistent){
if(!lowLevelInitDone){
tcpipInit();
wifi_init_config_t cfg = WIFI_INIT_CONFIG_DEFAULT();
esp_err_t err = esp_wifi_init(&cfg);
if(err){
log_e("esp_wifi_init %d", err);
return false;
}
if(!persistent){
esp_wifi_set_storage(WIFI_STORAGE_RAM);
}
lowLevelInitDone = true;
}
return true;
}
static bool wifiLowLevelDeinit(){
//deinit not working yet!
//esp_wifi_deinit();
return true;
}
static bool _esp_wifi_started = false;
static bool espWiFiStart(){
if(_esp_wifi_started){
return true;
}
esp_err_t err = esp_wifi_start();
if (err != ESP_OK) {
log_e("esp_wifi_start %d", err);
return false;
}
_esp_wifi_started = true;
system_event_t event;
event.event_id = SYSTEM_EVENT_WIFI_READY;
WiFiGenericClass::_eventCallback(nullptr, &event, NULL);
return true;
}
static bool espWiFiStop(){
esp_err_t err;
if(!_esp_wifi_started){
return true;
}
_esp_wifi_started = false;
err = esp_wifi_stop();
if(err){
log_e("Could not stop WiFi! %d", err);
_esp_wifi_started = true;
return false;
}
return wifiLowLevelDeinit();
}
// -----------------------------------------------------------------------------------------------------------------------
// ------------------------------------------------- Generic WiFi function -----------------------------------------------
// -----------------------------------------------------------------------------------------------------------------------
typedef struct WiFiEventCbList {
static wifi_event_id_t current_id;
wifi_event_id_t id;
WiFiEventCb cb;
WiFiEventFuncCb fcb;
WiFiEventSysCb scb;
WiFiProvEventCb provcb;
system_event_id_t event;
WiFiEventCbList() : id(current_id++), cb(NULL), fcb(NULL), scb(NULL), provcb(NULL), event(SYSTEM_EVENT_WIFI_READY) {}
} WiFiEventCbList_t;
wifi_event_id_t WiFiEventCbList::current_id = 1;
// arduino dont like std::vectors move static here
static std::vector<WiFiEventCbList_t> cbEventList;
bool WiFiGenericClass::_persistent = true;
bool WiFiGenericClass::_long_range = false;
wifi_mode_t WiFiGenericClass::_forceSleepLastMode = WIFI_MODE_NULL;
WiFiGenericClass::WiFiGenericClass()
{
}
int WiFiGenericClass::setStatusBits(int bits){
if(!_network_event_group){
return 0;
}
return xEventGroupSetBits(_network_event_group, bits);
}
int WiFiGenericClass::clearStatusBits(int bits){
if(!_network_event_group){
return 0;
}
return xEventGroupClearBits(_network_event_group, bits);
}
int WiFiGenericClass::getStatusBits(){
if(!_network_event_group){
return 0;
}
return xEventGroupGetBits(_network_event_group);
}
int WiFiGenericClass::waitStatusBits(int bits, uint32_t timeout_ms){
if(!_network_event_group){
return 0;
}
return xEventGroupWaitBits(
_network_event_group, // The event group being tested.
bits, // The bits within the event group to wait for.
pdFALSE, // BIT_0 and BIT_4 should be cleared before returning.
pdTRUE, // Don't wait for both bits, either bit will do.
timeout_ms / portTICK_PERIOD_MS ) & bits; // Wait a maximum of 100ms for either bit to be set.
}
/**
* set callback function
* @param cbEvent WiFiEventCb
* @param event optional filter (WIFI_EVENT_MAX is all events)
*/
wifi_event_id_t WiFiGenericClass::onEvent(WiFiProvEventCb cbEvent, system_event_id_t event)
{
if(!cbEvent){
return 0;
}
WiFiEventCbList_t newEventHandler;
newEventHandler.cb = NULL;
newEventHandler.fcb = NULL;
newEventHandler.scb = NULL;
newEventHandler.provcb = cbEvent;
newEventHandler.event = event;
cbEventList.push_back(newEventHandler);
return newEventHandler.id;
}
wifi_event_id_t WiFiGenericClass::onEvent(WiFiEventCb cbEvent, system_event_id_t event)
{
if(!cbEvent) {
return 0;
}
WiFiEventCbList_t newEventHandler;
newEventHandler.cb = cbEvent;
newEventHandler.fcb = NULL;
newEventHandler.scb = NULL;
newEventHandler.provcb = NULL;
newEventHandler.event = event;
cbEventList.push_back(newEventHandler);
return newEventHandler.id;
}
wifi_event_id_t WiFiGenericClass::onEvent(WiFiEventFuncCb cbEvent, system_event_id_t event)
{
if(!cbEvent) {
return 0;
}
WiFiEventCbList_t newEventHandler;
newEventHandler.cb = NULL;
newEventHandler.fcb = cbEvent;
newEventHandler.scb = NULL;
newEventHandler.provcb = NULL;
newEventHandler.event = event;
cbEventList.push_back(newEventHandler);
return newEventHandler.id;
}
wifi_event_id_t WiFiGenericClass::onEvent(WiFiEventSysCb cbEvent, system_event_id_t event)
{
if(!cbEvent) {
return 0;
}
WiFiEventCbList_t newEventHandler;
newEventHandler.cb = NULL;
newEventHandler.fcb = NULL;
newEventHandler.scb = cbEvent;
newEventHandler.provcb = NULL;
newEventHandler.event = event;
cbEventList.push_back(newEventHandler);
return newEventHandler.id;
}
/**
* removes a callback form event handler
* @param cbEvent WiFiEventCb
* @param event optional filter (WIFI_EVENT_MAX is all events)
*/
void WiFiGenericClass::removeEvent(WiFiEventCb cbEvent, system_event_id_t event)
{
if(!cbEvent) {
return;
}
for(uint32_t i = 0; i < cbEventList.size(); i++) {
WiFiEventCbList_t entry = cbEventList[i];
if(entry.cb == cbEvent && entry.event == event) {
cbEventList.erase(cbEventList.begin() + i);
}
}
}
void WiFiGenericClass::removeEvent(WiFiEventSysCb cbEvent, system_event_id_t event)
{
if(!cbEvent) {
return;
}
for(uint32_t i = 0; i < cbEventList.size(); i++) {
WiFiEventCbList_t entry = cbEventList[i];
if(entry.scb == cbEvent && entry.event == event) {
cbEventList.erase(cbEventList.begin() + i);
}
}
}
void WiFiGenericClass::removeEvent(wifi_event_id_t id)
{
for(uint32_t i = 0; i < cbEventList.size(); i++) {
WiFiEventCbList_t entry = cbEventList[i];
if(entry.id == id) {
cbEventList.erase(cbEventList.begin() + i);
}
}
}
/**
* callback for WiFi events
* @param arg
*/
#if ARDUHAL_LOG_LEVEL >= ARDUHAL_LOG_LEVEL_DEBUG
const char * system_event_names[] = { "WIFI_READY", "SCAN_DONE", "STA_START", "STA_STOP", "STA_CONNECTED", "STA_DISCONNECTED", "STA_AUTHMODE_CHANGE", "STA_GOT_IP", "STA_LOST_IP", "STA_WPS_ER_SUCCESS", "STA_WPS_ER_FAILED", "STA_WPS_ER_TIMEOUT", "STA_WPS_ER_PIN", "STA_WPS_ER_PBC_OVERLAP", "AP_START", "AP_STOP", "AP_STACONNECTED", "AP_STADISCONNECTED", "AP_STAIPASSIGNED", "AP_PROBEREQRECVED", "GOT_IP6", "ETH_START", "ETH_STOP", "ETH_CONNECTED", "ETH_DISCONNECTED", "ETH_GOT_IP", "MAX"};
#endif
#if ARDUHAL_LOG_LEVEL >= ARDUHAL_LOG_LEVEL_WARN
const char * system_event_reasons[] = { "UNSPECIFIED", "AUTH_EXPIRE", "AUTH_LEAVE", "ASSOC_EXPIRE", "ASSOC_TOOMANY", "NOT_AUTHED", "NOT_ASSOCED", "ASSOC_LEAVE", "ASSOC_NOT_AUTHED", "DISASSOC_PWRCAP_BAD", "DISASSOC_SUPCHAN_BAD", "UNSPECIFIED", "IE_INVALID", "MIC_FAILURE", "4WAY_HANDSHAKE_TIMEOUT", "GROUP_KEY_UPDATE_TIMEOUT", "IE_IN_4WAY_DIFFERS", "GROUP_CIPHER_INVALID", "PAIRWISE_CIPHER_INVALID", "AKMP_INVALID", "UNSUPP_RSN_IE_VERSION", "INVALID_RSN_IE_CAP", "802_1X_AUTH_FAILED", "CIPHER_SUITE_REJECTED", "BEACON_TIMEOUT", "NO_AP_FOUND", "AUTH_FAIL", "ASSOC_FAIL", "HANDSHAKE_TIMEOUT", "CONNECTION_FAIL" };
#define reason2str(r) ((r>176)?system_event_reasons[r-176]:system_event_reasons[r-1])
#endif
esp_err_t WiFiGenericClass::_eventCallback(void *arg, system_event_t *event, wifi_prov_event_t *prov_event)
{
if(WiFi.isProvEnabled()) {
wifi_prov_mgr_event_handler(arg,event);
}
if(event->event_id < 26) {
log_d("Event: %d - %s", event->event_id, system_event_names[event->event_id]);
}
if(event->event_id == SYSTEM_EVENT_SCAN_DONE) {
WiFiScanClass::_scanDone();
} else if(event->event_id == SYSTEM_EVENT_STA_START) {
WiFiSTAClass::_setStatus(WL_DISCONNECTED);
setStatusBits(STA_STARTED_BIT);
} else if(event->event_id == SYSTEM_EVENT_STA_STOP) {
WiFiSTAClass::_setStatus(WL_NO_SHIELD);
clearStatusBits(STA_STARTED_BIT | STA_CONNECTED_BIT | STA_HAS_IP_BIT | STA_HAS_IP6_BIT);
} else if(event->event_id == SYSTEM_EVENT_STA_CONNECTED) {
WiFiSTAClass::_setStatus(WL_IDLE_STATUS);
setStatusBits(STA_CONNECTED_BIT);
} else if(event->event_id == SYSTEM_EVENT_STA_DISCONNECTED) {
uint8_t reason = event->event_info.disconnected.reason;
log_w("Reason: %u - %s", reason, reason2str(reason));
if(reason == WIFI_REASON_NO_AP_FOUND) {
WiFiSTAClass::_setStatus(WL_NO_SSID_AVAIL);
} else if(reason == WIFI_REASON_AUTH_FAIL || reason == WIFI_REASON_ASSOC_FAIL) {
WiFiSTAClass::_setStatus(WL_CONNECT_FAILED);
} else if(reason == WIFI_REASON_BEACON_TIMEOUT || reason == WIFI_REASON_HANDSHAKE_TIMEOUT) {
WiFiSTAClass::_setStatus(WL_CONNECTION_LOST);
} else if(reason == WIFI_REASON_AUTH_EXPIRE) {
} else {
WiFiSTAClass::_setStatus(WL_DISCONNECTED);
}
clearStatusBits(STA_CONNECTED_BIT | STA_HAS_IP_BIT | STA_HAS_IP6_BIT);
if(((reason == WIFI_REASON_AUTH_EXPIRE) ||
(reason >= WIFI_REASON_BEACON_TIMEOUT && reason != WIFI_REASON_AUTH_FAIL)) &&
WiFi.getAutoReconnect())
{
WiFi.disconnect();
WiFi.begin();
}
} else if(event->event_id == SYSTEM_EVENT_STA_GOT_IP) {
#if ARDUHAL_LOG_LEVEL >= ARDUHAL_LOG_LEVEL_DEBUG
uint8_t * ip = (uint8_t *)&(event->event_info.got_ip.ip_info.ip.addr);
uint8_t * mask = (uint8_t *)&(event->event_info.got_ip.ip_info.netmask.addr);
uint8_t * gw = (uint8_t *)&(event->event_info.got_ip.ip_info.gw.addr);
log_d("STA IP: %u.%u.%u.%u, MASK: %u.%u.%u.%u, GW: %u.%u.%u.%u",
ip[0], ip[1], ip[2], ip[3],
mask[0], mask[1], mask[2], mask[3],
gw[0], gw[1], gw[2], gw[3]);
#endif
WiFiSTAClass::_setStatus(WL_CONNECTED);
setStatusBits(STA_HAS_IP_BIT | STA_CONNECTED_BIT);
} else if(event->event_id == SYSTEM_EVENT_STA_LOST_IP) {
WiFiSTAClass::_setStatus(WL_IDLE_STATUS);
clearStatusBits(STA_HAS_IP_BIT);
} else if(event->event_id == SYSTEM_EVENT_AP_START) {
setStatusBits(AP_STARTED_BIT);
} else if(event->event_id == SYSTEM_EVENT_AP_STOP) {
clearStatusBits(AP_STARTED_BIT | AP_HAS_CLIENT_BIT);
} else if(event->event_id == SYSTEM_EVENT_AP_STACONNECTED) {
setStatusBits(AP_HAS_CLIENT_BIT);
} else if(event->event_id == SYSTEM_EVENT_AP_STADISCONNECTED) {
wifi_sta_list_t clients;
if(esp_wifi_ap_get_sta_list(&clients) != ESP_OK || !clients.num){
clearStatusBits(AP_HAS_CLIENT_BIT);
}
} else if(event->event_id == SYSTEM_EVENT_ETH_START) {
setStatusBits(ETH_STARTED_BIT);
} else if(event->event_id == SYSTEM_EVENT_ETH_STOP) {
clearStatusBits(ETH_STARTED_BIT | ETH_CONNECTED_BIT | ETH_HAS_IP_BIT | ETH_HAS_IP6_BIT);
} else if(event->event_id == SYSTEM_EVENT_ETH_CONNECTED) {
setStatusBits(ETH_CONNECTED_BIT);
} else if(event->event_id == SYSTEM_EVENT_ETH_DISCONNECTED) {
clearStatusBits(ETH_CONNECTED_BIT | ETH_HAS_IP_BIT | ETH_HAS_IP6_BIT);
} else if(event->event_id == SYSTEM_EVENT_ETH_GOT_IP) {
#if ARDUHAL_LOG_LEVEL >= ARDUHAL_LOG_LEVEL_DEBUG
uint8_t * ip = (uint8_t *)&(event->event_info.got_ip.ip_info.ip.addr);
uint8_t * mask = (uint8_t *)&(event->event_info.got_ip.ip_info.netmask.addr);
uint8_t * gw = (uint8_t *)&(event->event_info.got_ip.ip_info.gw.addr);
log_d("ETH IP: %u.%u.%u.%u, MASK: %u.%u.%u.%u, GW: %u.%u.%u.%u",
ip[0], ip[1], ip[2], ip[3],
mask[0], mask[1], mask[2], mask[3],
gw[0], gw[1], gw[2], gw[3]);
#endif
setStatusBits(ETH_CONNECTED_BIT | ETH_HAS_IP_BIT);
} else if(event->event_id == SYSTEM_EVENT_GOT_IP6) {
if(event->event_info.got_ip6.if_index == TCPIP_ADAPTER_IF_AP){
setStatusBits(AP_HAS_IP6_BIT);
} else if(event->event_info.got_ip6.if_index == TCPIP_ADAPTER_IF_STA){
setStatusBits(STA_CONNECTED_BIT | STA_HAS_IP6_BIT);
} else if(event->event_info.got_ip6.if_index == TCPIP_ADAPTER_IF_ETH){
setStatusBits(ETH_CONNECTED_BIT | ETH_HAS_IP6_BIT);
}
}
for(uint32_t i = 0; i < cbEventList.size(); i++) {
WiFiEventCbList_t entry = cbEventList[i];
if(entry.cb || entry.fcb || entry.scb) {
if(entry.event == (system_event_id_t) event->event_id || entry.event == SYSTEM_EVENT_MAX) {
if(entry.cb) {
entry.cb((system_event_id_t) event->event_id);
} else if(entry.fcb) {
entry.fcb((system_event_id_t) event->event_id, (system_event_info_t) event->event_info);
} else {
entry.scb(event);
}
}
}
if(entry.provcb) {
entry.provcb(event,prov_event);
}
}
return ESP_OK;
}
/**
* Return the current channel associated with the network
* @return channel (1-13)
*/
int32_t WiFiGenericClass::channel(void)
{
uint8_t primaryChan = 0;
wifi_second_chan_t secondChan = WIFI_SECOND_CHAN_NONE;
if(!lowLevelInitDone){
return primaryChan;
}
esp_wifi_get_channel(&primaryChan, &secondChan);
return primaryChan;
}
/**
* store WiFi config in SDK flash area
* @param persistent
*/
void WiFiGenericClass::persistent(bool persistent)
{
_persistent = persistent;
}
/**
* enable WiFi long range mode
* @param enable
*/
void WiFiGenericClass::enableLongRange(bool enable)
{
_long_range = enable;
}
/**
* set new mode
* @param m WiFiMode_t
*/
bool WiFiGenericClass::mode(wifi_mode_t m)
{
wifi_mode_t cm = getMode();
if(cm == m) {
return true;
}
if(!cm && m){
if(!wifiLowLevelInit(_persistent)){
return false;
}
} else if(cm && !m){
return espWiFiStop();
}
esp_err_t err;
err = esp_wifi_set_mode(m);
if(err){
log_e("Could not set mode! %d", err);
return false;
}
if(_long_range){
if(m & WIFI_MODE_STA){
err = esp_wifi_set_protocol(WIFI_IF_STA, WIFI_PROTOCOL_LR);
if(err != ESP_OK){
log_e("Could not enable long range on STA! %d", err);
return false;
}
}
if(m & WIFI_MODE_AP){
err = esp_wifi_set_protocol(WIFI_IF_AP, WIFI_PROTOCOL_LR);
if(err != ESP_OK){
log_e("Could not enable long range on AP! %d", err);
return false;
}
}
}
if(!espWiFiStart()){
return false;
}
return true;
}
/**
* get WiFi mode
* @return WiFiMode
*/
wifi_mode_t WiFiGenericClass::getMode()
{
if(!lowLevelInitDone){
return WIFI_MODE_NULL;
}
wifi_mode_t mode;
if(esp_wifi_get_mode(&mode) == ESP_ERR_WIFI_NOT_INIT){
log_w("WiFi not started");
return WIFI_MODE_NULL;
}
return mode;
}
/**
* control STA mode
* @param enable bool
* @return ok
*/
bool WiFiGenericClass::enableSTA(bool enable)
{
wifi_mode_t currentMode = getMode();
bool isEnabled = ((currentMode & WIFI_MODE_STA) != 0);
if(isEnabled != enable) {
if(enable) {
return mode((wifi_mode_t)(currentMode | WIFI_MODE_STA));
}
return mode((wifi_mode_t)(currentMode & (~WIFI_MODE_STA)));
}
return true;
}
/**
* control AP mode
* @param enable bool
* @return ok
*/
bool WiFiGenericClass::enableAP(bool enable)
{
wifi_mode_t currentMode = getMode();
bool isEnabled = ((currentMode & WIFI_MODE_AP) != 0);
if(isEnabled != enable) {
if(enable) {
return mode((wifi_mode_t)(currentMode | WIFI_MODE_AP));
}
return mode((wifi_mode_t)(currentMode & (~WIFI_MODE_AP)));
}
return true;
}
/**
* control modem sleep when only in STA mode
* @param enable bool
* @return ok
*/
bool WiFiGenericClass::setSleep(bool enable)
{
if((getMode() & WIFI_MODE_STA) == 0){
log_w("STA has not been started");
return false;
}
return esp_wifi_set_ps(enable?WIFI_PS_MIN_MODEM:WIFI_PS_NONE) == ESP_OK;
}
/**
* control modem sleep when only in STA mode
* @param mode wifi_ps_type_t
* @return ok
*/
bool WiFiGenericClass::setSleep(wifi_ps_type_t mode)
{
if((getMode() & WIFI_MODE_STA) == 0){
log_w("STA has not been started");
return false;
}
return esp_wifi_set_ps(mode) == ESP_OK;
}
/**
* get modem sleep enabled
* @return true if modem sleep is enabled
*/
bool WiFiGenericClass::getSleep()
{
wifi_ps_type_t ps;
if((getMode() & WIFI_MODE_STA) == 0){
log_w("STA has not been started");
return false;
}
if(esp_wifi_get_ps(&ps) == ESP_OK){
return ps == WIFI_PS_MIN_MODEM;
}
return false;
}
/**
* control wifi tx power
* @param power enum maximum wifi tx power
* @return ok
*/
bool WiFiGenericClass::setTxPower(wifi_power_t power){
if((getStatusBits() & (STA_STARTED_BIT | AP_STARTED_BIT)) == 0){
log_w("Neither AP or STA has been started");
return false;
}
return esp_wifi_set_max_tx_power(power) == ESP_OK;
}
wifi_power_t WiFiGenericClass::getTxPower(){
int8_t power;
if((getStatusBits() & (STA_STARTED_BIT | AP_STARTED_BIT)) == 0){
log_w("Neither AP or STA has been started");
return WIFI_POWER_19_5dBm;
}
if(esp_wifi_get_max_tx_power(&power)){
return WIFI_POWER_19_5dBm;
}
return (wifi_power_t)power;
}
// -----------------------------------------------------------------------------------------------------------------------
// ------------------------------------------------ Generic Network function ---------------------------------------------
// -----------------------------------------------------------------------------------------------------------------------
/**
* DNS callback
* @param name
* @param ipaddr
* @param callback_arg
*/
static void wifi_dns_found_callback(const char *name, const ip_addr_t *ipaddr, void *callback_arg)
{
if(ipaddr) {
(*reinterpret_cast<IPAddress*>(callback_arg)) = ipaddr->u_addr.ip4.addr;
}
xEventGroupSetBits(_network_event_group, WIFI_DNS_DONE_BIT);
}
/**
* Resolve the given hostname to an IP address.
* @param aHostname Name to be resolved
* @param aResult IPAddress structure to store the returned IP address
* @return 1 if aIPAddrString was successfully converted to an IP address,
* else error code
*/
int WiFiGenericClass::hostByName(const char* aHostname, IPAddress& aResult)
{
ip_addr_t addr;
aResult = static_cast<uint32_t>(0);
waitStatusBits(WIFI_DNS_IDLE_BIT, 16000);
clearStatusBits(WIFI_DNS_IDLE_BIT | WIFI_DNS_DONE_BIT);
err_t err = dns_gethostbyname(aHostname, &addr, &wifi_dns_found_callback, &aResult);
if(err == ERR_OK && addr.u_addr.ip4.addr) {
aResult = addr.u_addr.ip4.addr;
} else if(err == ERR_INPROGRESS) {
waitStatusBits(WIFI_DNS_DONE_BIT, 15000); //real internal timeout in lwip library is 14[s]
clearStatusBits(WIFI_DNS_DONE_BIT);
}
setStatusBits(WIFI_DNS_IDLE_BIT);
if((uint32_t)aResult == 0){
log_e("DNS Failed for %s", aHostname);
}
return (uint32_t)aResult != 0;
}
IPAddress WiFiGenericClass::calculateNetworkID(IPAddress ip, IPAddress subnet) {
IPAddress networkID;
for (size_t i = 0; i < 4; i++)
networkID[i] = subnet[i] & ip[i];
return networkID;
}
IPAddress WiFiGenericClass::calculateBroadcast(IPAddress ip, IPAddress subnet) {
IPAddress broadcastIp;
for (int i = 0; i < 4; i++)
broadcastIp[i] = ~subnet[i] | ip[i];
return broadcastIp;
}
uint8_t WiFiGenericClass::calculateSubnetCIDR(IPAddress subnetMask) {
uint8_t CIDR = 0;
for (uint8_t i = 0; i < 4; i++) {
if (subnetMask[i] == 0x80) // 128
CIDR += 1;
else if (subnetMask[i] == 0xC0) // 192
CIDR += 2;
else if (subnetMask[i] == 0xE0) // 224
CIDR += 3;
else if (subnetMask[i] == 0xF0) // 242
CIDR += 4;
else if (subnetMask[i] == 0xF8) // 248
CIDR += 5;
else if (subnetMask[i] == 0xFC) // 252
CIDR += 6;
else if (subnetMask[i] == 0xFE) // 254
CIDR += 7;
else if (subnetMask[i] == 0xFF) // 255
CIDR += 8;
}
return CIDR;
}