/* © 2023 Paul M. Antoine © 2021 Harald Barth © 2023 Nathan Kellenicki This file is part of CommandStation-EX This is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. It 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 General Public License for more details. You should have received a copy of the GNU General Public License along with CommandStation. If not, see . */ #if defined(ARDUINO_ARCH_ESP32) #include #include "defines.h" #include "ESPmDNS.h" #include #include "esp_wifi.h" #include "WifiESP32.h" #include "DIAG.h" #include "RingStream.h" #include "CommandDistributor.h" #include "WiThrottle.h" /* #include "soc/rtc_wdt.h" #include "esp_task_wdt.h" */ #include "soc/timer_group_struct.h" #include "soc/timer_group_reg.h" void feedTheDog0(){ // feed dog 0 #ifdef ARDUINO_ESP32S3_DEV TIMERG0.wdtwprotect.wdt_wkey=0x50D83AA1; //MWDT_LL_WKEY_VALUE? write enable TIMERG0.wdtfeed.wdt_feed=1; // feed dog TIMERG0.wdtwprotect.wdt_wkey=0; // write protect #else TIMERG0.wdt_wprotect=TIMG_WDT_WKEY_VALUE; // write enable TIMERG0.wdt_feed=1; // feed dog TIMERG0.wdt_wprotect=0; // write protect #endif // feed dog 1 //TIMERG1.wdt_wprotect=TIMG_WDT_WKEY_VALUE; // write enable //TIMERG1.wdt_feed=1; // feed dog //TIMERG1.wdt_wprotect=0; // write protect } /* void enableCoreWDT(byte core){ TaskHandle_t idle = xTaskGetIdleTaskHandleForCPU(core); if(idle == NULL){ DIAG(F("Get idle rask on core %d failed"),core); } else { if(esp_task_wdt_add(idle) != ESP_OK){ DIAG(F("Failed to add Core %d IDLE task to WDT"),core); } else { DIAG(F("Added Core %d IDLE task to WDT"),core); } } } void disableCoreWDT(byte core){ TaskHandle_t idle = xTaskGetIdleTaskHandleForCPU(core); if(idle == NULL || esp_task_wdt_delete(idle) != ESP_OK){ DIAG(F("Failed to remove Core %d IDLE task from WDT"),core); } } */ class NetworkClient { public: NetworkClient(WiFiClient c) { wifi = c; inUse = true; }; bool active(byte clientId) { if (!inUse) return false; if(!wifi.connected()) { DIAG(F("Remove client %d"), clientId); CommandDistributor::forget(clientId); wifi.stop(); inUse = false; return false; } return true; } bool recycle(WiFiClient c) { if (wifi == c) { if (inUse == true) DIAG(F("WARNING: Duplicate")); else DIAG(F("Returning")); inUse = true; return true; } if (inUse == false) { wifi = c; inUse = true; return true; } return false; }; WiFiClient wifi; private: bool inUse; }; static std::vector clients; // a list to hold all clients static WiFiServer *server = NULL; static RingStream *outboundRing = new RingStream(10240); static bool APmode = false; #ifdef WIFI_TASK_ON_CORE0 void wifiLoop(void *){ for(;;){ WifiESP::loop(); } } #endif char asciitolower(char in) { if (in <= 'Z' && in >= 'A') return in - ('Z' - 'z'); return in; } bool WifiESP::setup(const char *SSid, const char *password, const char *hostname, int port, const byte channel, const bool forceAP) { bool havePassword = true; bool haveSSID = true; bool wifiUp = false; uint8_t tries = 40; //#ifdef SERIAL_BT_COMMANDS //return false; //#endif // tests // enableCoreWDT(1); // disableCoreWDT(0); // clean start WiFi.mode(WIFI_STA); WiFi.disconnect(true); // differnet settings that did not improve for haba // WiFi.useStaticBuffers(true); // WiFi.setScanMethod(WIFI_ALL_CHANNEL_SCAN); // WiFi.setSortMethod(WIFI_CONNECT_AP_BY_SECURITY); const char *yourNetwork = "Your network "; if (strncmp(yourNetwork, SSid, 13) == 0 || strncmp("", SSid, 13) == 0) haveSSID = false; if (strncmp(yourNetwork, password, 13) == 0 || strncmp("", password, 13) == 0) havePassword = false; if (haveSSID && havePassword && !forceAP) { WiFi.setHostname(hostname); // Strangely does not work unless we do it HERE! WiFi.mode(WIFI_STA); WiFi.setScanMethod(WIFI_ALL_CHANNEL_SCAN); // Scan all channels so we find strongest // (default in Wifi library is first match) #ifdef SERIAL_BT_COMMANDS WiFi.setSleep(true); #else WiFi.setSleep(false); #endif WiFi.setAutoReconnect(true); WiFi.begin(SSid, password); while (WiFi.status() != WL_CONNECTED && tries) { Serial.print('.'); tries--; delay(500); } if (WiFi.status() == WL_CONNECTED) { // DIAG(F("Wifi STA IP %s"),WiFi.localIP().toString().c_str()); DIAG(F("Wifi in STA mode")); LCD(7, F("IP: %s"), WiFi.localIP().toString().c_str()); wifiUp = true; } else { DIAG(F("Could not connect to Wifi SSID %s"),SSid); DIAG(F("Forcing one more Wifi restart")); esp_wifi_start(); esp_wifi_connect(); tries=40; while (WiFi.status() != WL_CONNECTED && tries) { Serial.print('.'); tries--; delay(500); } if (WiFi.status() == WL_CONNECTED) { DIAG(F("Wifi STA IP 2nd try %s"),WiFi.localIP().toString().c_str()); wifiUp = true; } else { DIAG(F("Wifi STA mode FAIL. Will revert to AP mode")); haveSSID=false; } } } if (!haveSSID || forceAP) { // prepare all strings String strSSID(forceAP ? SSid : "DCCEX_"); String strPass( (forceAP && havePassword) ? password : "PASS_"); if (!forceAP) { String strMac = WiFi.macAddress(); strMac.remove(0,9); strMac.replace(":",""); strMac.replace(":",""); // convert mac addr hex chars to lower case to be compatible with AT software std::transform(strMac.begin(), strMac.end(), strMac.begin(), asciitolower); strSSID.concat(strMac); strPass.concat(strMac); } WiFi.mode(WIFI_AP); #ifdef SERIAL_BT_COMMANDS WiFi.setSleep(true); #else WiFi.setSleep(false); #endif if (WiFi.softAP(strSSID.c_str(), havePassword ? password : strPass.c_str(), channel, false, 8)) { // DIAG(F("Wifi AP SSID %s PASS %s"),strSSID.c_str(),havePassword ? password : strPass.c_str()); DIAG(F("Wifi in AP mode")); LCD(5, F("Wifi: %s"), strSSID.c_str()); if (!havePassword) LCD(6, F("PASS: %s"),strPass.c_str()); // DIAG(F("Wifi AP IP %s"),WiFi.softAPIP().toString().c_str()); LCD(7, F("IP: %s"),WiFi.softAPIP().toString().c_str()); wifiUp = true; APmode = true; } else { DIAG(F("Could not set up AP with Wifi SSID %s"),strSSID.c_str()); } } if (!wifiUp) { DIAG(F("Wifi setup all fail (STA and AP mode)")); // no idea to go on return false; } // Now Wifi is up, register the mDNS service if(!MDNS.begin(hostname)) { DIAG(F("Wifi setup failed to start mDNS")); } if(!MDNS.addService("withrottle", "tcp", 2560)) { DIAG(F("Wifi setup failed to add withrottle service to mDNS")); } server = new WiFiServer(port); // start listening on tcp port server->begin(); // server started here #ifdef WIFI_TASK_ON_CORE0 //start loop task if (pdPASS != xTaskCreatePinnedToCore( wifiLoop, /* Task function. */ "wifiLoop",/* name of task. */ 10000, /* Stack size of task */ NULL, /* parameter of the task */ 1, /* priority of the task */ NULL, /* Task handle to keep track of created task */ 0)) { /* pin task to core 0 */ DIAG(F("Could not create wifiLoop task")); return false; } // report server started after wifiLoop creation // when everything looks good DIAG(F("Server starting (core 0) port %d"),port); #else DIAG(F("Server will be started on port %d"),port); #endif return true; } const char *wlerror[] = { "WL_IDLE_STATUS", "WL_NO_SSID_AVAIL", "WL_SCAN_COMPLETED", "WL_CONNECTED", "WL_CONNECT_FAILED", "WL_CONNECTION_LOST", "WL_DISCONNECTED" }; void WifiESP::loop() { int clientId; //tmp loop var // really no good way to check for LISTEN especially in AP mode? wl_status_t wlStatus; if (APmode || (wlStatus = WiFi.status()) == WL_CONNECTED) { if (server->hasClient()) { WiFiClient client; while (client = server->available()) { for (clientId=0; clientId=clients.size()) { NetworkClient nc(client); clients.push_back(nc); DIAG(F("New client %d, %s:%d"), clientId, client.remoteIP().toString().c_str(),client.remotePort()); } } } // loop over all connected clients // this removes as a side effect inactive clients when checking ::active() for (clientId=0; clientId 0) { // read data from client byte cmd[len+1]; for(int i=0; iread(); if (clientId >= 0) { // We have data to send in outboundRing // and we have a valid clientId. // First read it out to buffer // and then look if it can be sent because // we can not leave it in the ring for ever int count=outboundRing->count(); { char buffer[count+1]; // one extra for '\0' for(int i=0;iread(); if (c >= 0) // Panic check, should never be false buffer[i] = (char)c; else { DIAG(F("Ringread fail at %d"),i); break; } } // buffer filled, end with '\0' so we can use it as C string buffer[count]='\0'; if((unsigned int)clientId <= clients.size() && clients[clientId].active(clientId)) { if (Diag::CMD || Diag::WITHROTTLE) DIAG(F("SEND %d:%s"), clientId, buffer); clients[clientId].wifi.write(buffer,count); } else { DIAG(F("Unsent(%d): %s"), clientId, buffer); } } } } else if (!APmode) { // in STA mode but not connected any more // kick it again if (wlStatus <= 6) { DIAG(F("Wifi aborted with error %s. Kicking Wifi!"), wlerror[wlStatus]); esp_wifi_start(); esp_wifi_connect(); uint8_t tries=40; while (WiFi.status() != WL_CONNECTED && tries) { Serial.print('.'); tries--; delay(500); } } else { // all well, probably //DIAG(F("Running BT")); } } // when loop() is running on core0 we must // feed the core0 wdt ourselves as yield() // is not necessarily yielding to a low // prio task. On core1 this is not a problem // as there the wdt is disabled by the // arduio IDE startup routines. if (xPortGetCoreID() == 0) { feedTheDog0(); yield(); } } #endif //ESP32