/* WiFiSTA.cpp - WiFi library for esp32 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" #include "WiFiSTA.h" extern "C" { #include #include #include #include #include #include #include #include #include #include #include #include "lwip/err.h" #include "lwip/dns.h" #include #include } // ----------------------------------------------------------------------------------------------------------------------- // ---------------------------------------------------- Private functions ------------------------------------------------ // ----------------------------------------------------------------------------------------------------------------------- esp_netif_t* get_esp_interface_netif(esp_interface_t interface); esp_err_t set_esp_interface_dns(esp_interface_t interface, IPAddress main_dns=IPAddress(), IPAddress backup_dns=IPAddress(), IPAddress fallback_dns=IPAddress()); esp_err_t set_esp_interface_ip(esp_interface_t interface, IPAddress local_ip=IPAddress(), IPAddress gateway=IPAddress(), IPAddress subnet=IPAddress()); static bool sta_config_equal(const wifi_config_t& lhs, const wifi_config_t& rhs); /** * compare two STA configurations * @param lhs station_config * @param rhs station_config * @return equal */ static bool sta_config_equal(const wifi_config_t& lhs, const wifi_config_t& rhs) { if(memcmp(&lhs, &rhs, sizeof(wifi_config_t)) != 0) { return false; } return true; } static void wifi_sta_config(wifi_config_t * wifi_config, const char * ssid=NULL, const char * password=NULL, const uint8_t * bssid=NULL, uint8_t channel=0, wifi_scan_method_t scan_method=WIFI_ALL_CHANNEL_SCAN, wifi_sort_method_t sort_method=WIFI_CONNECT_AP_BY_SIGNAL, uint16_t listen_interval=0, bool pmf_required=false){ wifi_config->sta.channel = channel; wifi_config->sta.listen_interval = listen_interval; wifi_config->sta.scan_method = scan_method;//WIFI_ALL_CHANNEL_SCAN or WIFI_FAST_SCAN wifi_config->sta.sort_method = sort_method;//WIFI_CONNECT_AP_BY_SIGNAL or WIFI_CONNECT_AP_BY_SECURITY wifi_config->sta.threshold.rssi = -75; wifi_config->sta.pmf_cfg.capable = true; wifi_config->sta.pmf_cfg.required = pmf_required; wifi_config->sta.bssid_set = 0; memset(wifi_config->sta.bssid, 0, 6); wifi_config->sta.threshold.authmode = WIFI_AUTH_OPEN; wifi_config->sta.ssid[0] = 0; wifi_config->sta.password[0] = 0; if(ssid != NULL && ssid[0] != 0){ snprintf((char*)wifi_config->sta.ssid, 32, ssid); if(password != NULL && password[0] != 0){ wifi_config->sta.threshold.authmode = WIFI_AUTH_WEP; if(strlen(password) == 64){ memcpy((char*)wifi_config->sta.password, password, 64); } else { snprintf((char*)wifi_config->sta.password, 64, password); } } if(bssid != NULL){ wifi_config->sta.bssid_set = 1; memcpy(wifi_config->sta.bssid, bssid, 6); } } } // ----------------------------------------------------------------------------------------------------------------------- // ---------------------------------------------------- STA function ----------------------------------------------------- // ----------------------------------------------------------------------------------------------------------------------- bool WiFiSTAClass::_autoReconnect = true; bool WiFiSTAClass::_useStaticIp = false; static wl_status_t _sta_status = WL_NO_SHIELD; static EventGroupHandle_t _sta_status_group = NULL; void WiFiSTAClass::_setStatus(wl_status_t status) { if(!_sta_status_group){ _sta_status_group = xEventGroupCreate(); if(!_sta_status_group){ log_e("STA Status Group Create Failed!"); _sta_status = status; return; } } xEventGroupClearBits(_sta_status_group, 0x00FFFFFF); xEventGroupSetBits(_sta_status_group, status); } /** * Return Connection status. * @return one of the value defined in wl_status_t * */ wl_status_t WiFiSTAClass::status() { if(!_sta_status_group){ return _sta_status; } return (wl_status_t)xEventGroupClearBits(_sta_status_group, 0); } /** * Start Wifi connection * if passphrase is set the most secure supported mode will be automatically selected * @param ssid const char* Pointer to the SSID string. * @param passphrase const char * Optional. Passphrase. Valid characters in a passphrase must be between ASCII 32-126 (decimal). * @param bssid uint8_t[6] Optional. BSSID / MAC of AP * @param channel Optional. Channel of AP * @param connect Optional. call connect * @return */ wl_status_t WiFiSTAClass::begin(const char* ssid, const char *passphrase, int32_t channel, const uint8_t* bssid, bool connect) { if(!WiFi.enableSTA(true)) { log_e("STA enable failed!"); return WL_CONNECT_FAILED; } if(!ssid || *ssid == 0x00 || strlen(ssid) > 32) { log_e("SSID too long or missing!"); return WL_CONNECT_FAILED; } if(passphrase && strlen(passphrase) > 64) { log_e("passphrase too long!"); return WL_CONNECT_FAILED; } wifi_config_t conf; memset(&conf, 0, sizeof(wifi_config_t)); strcpy(reinterpret_cast(conf.sta.ssid), ssid); conf.sta.scan_method = WIFI_ALL_CHANNEL_SCAN; //force full scan to be able to choose the nearest / strongest AP if(passphrase) { if (strlen(passphrase) == 64){ // it's not a passphrase, is the PSK memcpy(reinterpret_cast(conf.sta.password), passphrase, 64); } else { strcpy(reinterpret_cast(conf.sta.password), passphrase); } } wifi_config_t current_conf; wifi_sta_config(&conf, ssid, passphrase, bssid, channel); if(esp_wifi_get_config((wifi_interface_t)ESP_IF_WIFI_STA, ¤t_conf) != ESP_OK){ log_e("get current config failed!"); return WL_CONNECT_FAILED; } if(!sta_config_equal(current_conf, conf)) { if(esp_wifi_disconnect()){ log_e("disconnect failed!"); return WL_CONNECT_FAILED; } if(esp_wifi_set_config((wifi_interface_t)ESP_IF_WIFI_STA, &conf) != ESP_OK){ log_e("set config failed!"); return WL_CONNECT_FAILED; } } else if(status() == WL_CONNECTED){ return WL_CONNECTED; } else { if(esp_wifi_set_config((wifi_interface_t)ESP_IF_WIFI_STA, &conf) != ESP_OK){ log_e("set config failed!"); return WL_CONNECT_FAILED; } } if(!_useStaticIp){ if(set_esp_interface_ip(ESP_IF_WIFI_STA) != ESP_OK) { return WL_CONNECT_FAILED; } } if(connect){ if(esp_wifi_connect() != ESP_OK) { log_e("connect failed!"); return WL_CONNECT_FAILED; } } return status(); } wl_status_t WiFiSTAClass::begin(char* ssid, char *passphrase, int32_t channel, const uint8_t* bssid, bool connect) { return begin((const char*) ssid, (const char*) passphrase, channel, bssid, connect); } /** * Use to connect to SDK config. * @return wl_status_t */ wl_status_t WiFiSTAClass::begin() { if(!WiFi.enableSTA(true)) { log_e("STA enable failed!"); return WL_CONNECT_FAILED; } wifi_config_t current_conf; if(esp_wifi_get_config((wifi_interface_t)ESP_IF_WIFI_STA, ¤t_conf) != ESP_OK || esp_wifi_set_config((wifi_interface_t)ESP_IF_WIFI_STA, ¤t_conf) != ESP_OK) { log_e("config failed"); return WL_CONNECT_FAILED; } if(!_useStaticIp && set_esp_interface_ip(ESP_IF_WIFI_STA) != ESP_OK) { log_e("set ip failed!"); return WL_CONNECT_FAILED; } if(status() != WL_CONNECTED){ esp_err_t err = esp_wifi_connect(); if(err){ log_e("connect failed! 0x%x", err); return WL_CONNECT_FAILED; } } return status(); } /** * will force a disconnect and then start reconnecting to AP * @return true when successful */ bool WiFiSTAClass::reconnect() { if(WiFi.getMode() & WIFI_MODE_STA) { if(esp_wifi_disconnect() == ESP_OK) { return esp_wifi_connect() == ESP_OK; } } return false; } /** * Disconnect from the network * @param wifioff * @return one value of wl_status_t enum */ bool WiFiSTAClass::disconnect(bool wifioff, bool eraseap) { wifi_config_t conf; wifi_sta_config(&conf); if(WiFi.getMode() & WIFI_MODE_STA){ if(eraseap){ if(esp_wifi_set_config((wifi_interface_t)ESP_IF_WIFI_STA, &conf)){ log_e("clear config failed!"); } } if(esp_wifi_disconnect()){ log_e("disconnect failed!"); return false; } if(wifioff) { return WiFi.enableSTA(false); } return true; } return false; } /** * Change IP configuration settings disabling the dhcp client * @param local_ip Static ip configuration * @param gateway Static gateway configuration * @param subnet Static Subnet mask * @param dns1 Static DNS server 1 * @param dns2 Static DNS server 2 */ bool WiFiSTAClass::config(IPAddress local_ip, IPAddress gateway, IPAddress subnet, IPAddress dns1, IPAddress dns2) { esp_err_t err = ESP_OK; if(!WiFi.enableSTA(true)) { return false; } err = set_esp_interface_ip(ESP_IF_WIFI_STA, local_ip, gateway, subnet); if(err == ESP_OK){ err = set_esp_interface_dns(ESP_IF_WIFI_STA, dns1, dns2); } _useStaticIp = err == ESP_OK; return err == ESP_OK; } /** * is STA interface connected? * @return true if STA is connected to an AP */ bool WiFiSTAClass::isConnected() { return (status() == WL_CONNECTED); } /** * Setting the ESP32 station to connect to the AP (which is recorded) * automatically or not when powered on. Enable auto-connect by default. * @param autoConnect bool * @return if saved */ bool WiFiSTAClass::setAutoConnect(bool autoConnect) { return false;//now deprecated } /** * Checks if ESP32 station mode will connect to AP * automatically or not when it is powered on. * @return auto connect */ bool WiFiSTAClass::getAutoConnect() { return false;//now deprecated } bool WiFiSTAClass::setAutoReconnect(bool autoReconnect) { _autoReconnect = autoReconnect; return true; } bool WiFiSTAClass::getAutoReconnect() { return _autoReconnect; } /** * Wait for WiFi connection to reach a result * returns the status reached or disconnect if STA is off * @return wl_status_t */ uint8_t WiFiSTAClass::waitForConnectResult() { //1 and 3 have STA enabled if((WiFiGenericClass::getMode() & WIFI_MODE_STA) == 0) { return WL_DISCONNECTED; } int i = 0; while((!status() || status() >= WL_DISCONNECTED) && i++ < 100) { delay(100); } return status(); } /** * Get the station interface IP address. * @return IPAddress station IP */ IPAddress WiFiSTAClass::localIP() { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return IPAddress(); } esp_netif_ip_info_t ip; if(esp_netif_get_ip_info(get_esp_interface_netif(ESP_IF_WIFI_STA), &ip) != ESP_OK){ log_e("Netif Get IP Failed!"); return IPAddress(); } return IPAddress(ip.ip.addr); } /** * Get the station interface MAC address. * @param mac pointer to uint8_t array with length WL_MAC_ADDR_LENGTH * @return pointer to uint8_t * */ uint8_t* WiFiSTAClass::macAddress(uint8_t* mac) { if(WiFiGenericClass::getMode() != WIFI_MODE_NULL){ esp_wifi_get_mac((wifi_interface_t)ESP_IF_WIFI_STA, mac); } else{ esp_read_mac(mac, ESP_MAC_WIFI_STA); } return mac; } /** * Get the station interface MAC address. * @return String mac */ String WiFiSTAClass::macAddress(void) { uint8_t mac[6]; char macStr[18] = { 0 }; if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ esp_read_mac(mac, ESP_MAC_WIFI_STA); } else{ esp_wifi_get_mac((wifi_interface_t)ESP_IF_WIFI_STA, mac); } sprintf(macStr, "%02X:%02X:%02X:%02X:%02X:%02X", mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]); return String(macStr); } /** * Get the interface subnet mask address. * @return IPAddress subnetMask */ IPAddress WiFiSTAClass::subnetMask() { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return IPAddress(); } esp_netif_ip_info_t ip; if(esp_netif_get_ip_info(get_esp_interface_netif(ESP_IF_WIFI_STA), &ip) != ESP_OK){ log_e("Netif Get IP Failed!"); return IPAddress(); } return IPAddress(ip.netmask.addr); } /** * Get the gateway ip address. * @return IPAddress gatewayIP */ IPAddress WiFiSTAClass::gatewayIP() { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return IPAddress(); } esp_netif_ip_info_t ip; if(esp_netif_get_ip_info(get_esp_interface_netif(ESP_IF_WIFI_STA), &ip) != ESP_OK){ log_e("Netif Get IP Failed!"); return IPAddress(); } return IPAddress(ip.gw.addr); } /** * Get the DNS ip address. * @param dns_no * @return IPAddress DNS Server IP */ IPAddress WiFiSTAClass::dnsIP(uint8_t dns_no) { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return IPAddress(); } const ip_addr_t * dns_ip = dns_getserver(dns_no); return IPAddress(dns_ip->u_addr.ip4.addr); } /** * Get the broadcast ip address. * @return IPAddress broadcastIP */ IPAddress WiFiSTAClass::broadcastIP() { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return IPAddress(); } esp_netif_ip_info_t ip; if(esp_netif_get_ip_info(get_esp_interface_netif(ESP_IF_WIFI_STA), &ip) != ESP_OK){ log_e("Netif Get IP Failed!"); return IPAddress(); } return WiFiGenericClass::calculateBroadcast(IPAddress(ip.gw.addr), IPAddress(ip.netmask.addr)); } /** * Get the network id. * @return IPAddress networkID */ IPAddress WiFiSTAClass::networkID() { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return IPAddress(); } esp_netif_ip_info_t ip; if(esp_netif_get_ip_info(get_esp_interface_netif(ESP_IF_WIFI_STA), &ip) != ESP_OK){ log_e("Netif Get IP Failed!"); return IPAddress(); } return WiFiGenericClass::calculateNetworkID(IPAddress(ip.gw.addr), IPAddress(ip.netmask.addr)); } /** * Get the subnet CIDR. * @return uint8_t subnetCIDR */ uint8_t WiFiSTAClass::subnetCIDR() { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return (uint8_t)0; } esp_netif_ip_info_t ip; if(esp_netif_get_ip_info(get_esp_interface_netif(ESP_IF_WIFI_STA), &ip) != ESP_OK){ log_e("Netif Get IP Failed!"); return IPAddress(); } return WiFiGenericClass::calculateSubnetCIDR(IPAddress(ip.netmask.addr)); } /** * Return the current SSID associated with the network * @return SSID */ String WiFiSTAClass::SSID() const { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return String(); } wifi_ap_record_t info; if(!esp_wifi_sta_get_ap_info(&info)) { return String(reinterpret_cast(info.ssid)); } return String(); } /** * Return the current pre shared key associated with the network * @return psk string */ String WiFiSTAClass::psk() const { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return String(); } wifi_config_t conf; esp_wifi_get_config((wifi_interface_t)ESP_IF_WIFI_STA, &conf); return String(reinterpret_cast(conf.sta.password)); } /** * Return the current bssid / mac associated with the network if configured * @return bssid uint8_t * */ uint8_t* WiFiSTAClass::BSSID(void) { static uint8_t bssid[6]; wifi_ap_record_t info; if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return NULL; } if(!esp_wifi_sta_get_ap_info(&info)) { memcpy(bssid, info.bssid, 6); return reinterpret_cast(bssid); } return NULL; } /** * Return the current bssid / mac associated with the network if configured * @return String bssid mac */ String WiFiSTAClass::BSSIDstr(void) { uint8_t* bssid = BSSID(); if(!bssid){ return String(); } char mac[18] = { 0 }; sprintf(mac, "%02X:%02X:%02X:%02X:%02X:%02X", bssid[0], bssid[1], bssid[2], bssid[3], bssid[4], bssid[5]); return String(mac); } /** * Return the current network RSSI. * @return RSSI value */ int8_t WiFiSTAClass::RSSI(void) { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return 0; } wifi_ap_record_t info; if(!esp_wifi_sta_get_ap_info(&info)) { return info.rssi; } return 0; } /** * Enable IPv6 on the station interface. * @return true on success */ bool WiFiSTAClass::enableIpV6() { if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return false; } return esp_netif_create_ip6_linklocal(get_esp_interface_netif(ESP_IF_WIFI_STA)) == ESP_OK; } /** * Get the station interface IPv6 address. * @return IPv6Address */ IPv6Address WiFiSTAClass::localIPv6() { esp_ip6_addr_t addr; if(WiFiGenericClass::getMode() == WIFI_MODE_NULL){ return IPv6Address(); } if(esp_netif_get_ip6_linklocal(get_esp_interface_netif(ESP_IF_WIFI_STA), &addr)) { return IPv6Address(); } return IPv6Address(addr.addr); } bool WiFiSTAClass::_smartConfigStarted = false; bool WiFiSTAClass::_smartConfigDone = false; bool WiFiSTAClass::beginSmartConfig() { esp_err_t err; if (_smartConfigStarted) { return false; } if (!WiFi.mode(WIFI_STA)) { return false; } esp_wifi_disconnect(); smartconfig_start_config_t conf = SMARTCONFIG_START_CONFIG_DEFAULT(); err = esp_smartconfig_set_type(SC_TYPE_ESPTOUCH); if (err != ESP_OK) { log_e("SmartConfig Set Type Failed!"); return false; } err = esp_smartconfig_start(&conf); if (err != ESP_OK) { log_e("SmartConfig Start Failed!"); return false; } _smartConfigStarted = true; _smartConfigDone = false; return true; } bool WiFiSTAClass::stopSmartConfig() { if (!_smartConfigStarted) { return true; } if (esp_smartconfig_stop() == ESP_OK) { _smartConfigStarted = false; return true; } return false; } bool WiFiSTAClass::smartConfigDone() { if (!_smartConfigStarted) { return false; } return _smartConfigDone; }