#include "config.hpp" #define MAX_ATTEMPTS_WIFI_CONNECTION 20 Preferences preferences; Adafruit_MCP23X17 mcp; std::vector screenNameMap(SCREEN_COUNT); void setup() { setupPreferences(); setupHardware(); if (mcp.digitalRead(3) == LOW) { WiFi.eraseAP(); blinkDelay(100, 3); } setupDisplays(); tryImprovSetup(); setupWebserver(); // setupWifi(); setupTime(); finishSetup(); setupTasks(); setupTimers(); setupWebsocketClients(); setupButtonTask(); } void tryImprovSetup() { // if (mcp.digitalRead(3) == LOW) // { // WiFi.persistent(false); // blinkDelay(100, 3); // } // else { WiFi.begin(); } uint8_t x_buffer[16]; uint8_t x_position = 0; while (WiFi.status() != WL_CONNECTED) { if (Serial.available() > 0) { uint8_t b = Serial.read(); if (parse_improv_serial_byte(x_position, b, x_buffer, onImprovCommandCallback, onImprovErrorCallback)) { x_buffer[x_position++] = b; } else { x_position = 0; } } esp_task_wdt_reset(); } } void setupTime() { configTime(preferences.getInt("gmtOffset", TIME_OFFSET_SECONDS), 0, NTP_SERVER); struct tm timeinfo; while (!getLocalTime(&timeinfo)) { configTime(preferences.getInt("gmtOffset", TIME_OFFSET_SECONDS), 0, NTP_SERVER); delay(500); Serial.println(F("Retry set time")); } Serial.println(&timeinfo, "%A, %B %d %Y %H:%M:%S"); } void setupPreferences() { preferences.begin("btclock", false); setFgColor(preferences.getUInt("fgColor", DEFAULT_FG_COLOR)); setBgColor(preferences.getUInt("bgColor", DEFAULT_BG_COLOR)); screenNameMap[SCREEN_BLOCK_HEIGHT] = "Block Height"; screenNameMap[SCREEN_MSCW_TIME] = "Sats per dollar"; screenNameMap[SCREEN_BTC_TICKER] = "Ticker"; screenNameMap[SCREEN_TIME] = "Time"; screenNameMap[SCREEN_HALVING_COUNTDOWN] = "Halving countdown"; } void setupWebsocketClients() { setupBlockNotify(); setupPriceNotify(); } void setupTimers() { xTaskCreate(setupTimeUpdateTimer, "setupTimeUpdateTimer", 2048, NULL, tskIDLE_PRIORITY, NULL); xTaskCreate(setupScreenRotateTimer, "setupScreenRotateTimer", 2048, NULL, tskIDLE_PRIORITY, NULL); } void finishSetup() { if (preferences.getBool("ledStatus", false)) { setLights(preferences.getUInt("ledColor", 0xFFCC00)); } else { clearLeds(); } } std::vector getScreenNameMap() { return screenNameMap; } void setupHardware() { setupLeds(); WiFi.setHostname(getMyHostname().c_str());; if (psramInit()) { Serial.println(F("PSRAM is correctly initialized")); } else { Serial.println(F("PSRAM not available")); } Wire.begin(35, 36, 400000); if (!mcp.begin_I2C(0x20)) { Serial.println(F("Error MCP23017")); // while (1) // ; } else { pinMode(MCP_INT_PIN, INPUT_PULLUP); mcp.setupInterrupts(false, false, LOW); for (int i = 0; i < 4; i++) { mcp.pinMode(i, INPUT_PULLUP); mcp.setupInterruptPin(i, LOW); } for (int i = 8; i <= 14; i++) { mcp.pinMode(i, OUTPUT); } } } void improvGetAvailableWifiNetworks() { int networkNum = WiFi.scanNetworks(); for (int id = 0; id < networkNum; ++id) { std::vector data = improv::build_rpc_response( improv::GET_WIFI_NETWORKS, {WiFi.SSID(id), String(WiFi.RSSI(id)), (WiFi.encryptionType(id) == WIFI_AUTH_OPEN ? "NO" : "YES")}, false); improv_send_response(data); } // final response std::vector data = improv::build_rpc_response(improv::GET_WIFI_NETWORKS, std::vector{}, false); improv_send_response(data); } bool improv_connectWifi(std::string ssid, std::string password) { uint8_t count = 0; WiFi.begin(ssid.c_str(), password.c_str()); while (WiFi.status() != WL_CONNECTED) { blinkDelay(500, 2); if (count > MAX_ATTEMPTS_WIFI_CONNECTION) { WiFi.disconnect(); return false; } count++; } return true; } void onImprovErrorCallback(improv::Error err) { blinkDelayColor(100, 1, 255,0,0); // pixels.setPixelColor(0, pixels.Color(255, 0, 0)); // pixels.setPixelColor(1, pixels.Color(255, 0, 0)); // pixels.setPixelColor(2, pixels.Color(255, 0, 0)); // pixels.setPixelColor(3, pixels.Color(255, 0, 0)); // pixels.show(); // vTaskDelay(pdMS_TO_TICKS(100)); // pixels.clear(); // pixels.show(); // vTaskDelay(pdMS_TO_TICKS(100)); } std::vector getLocalUrl() { return { // URL where user can finish onboarding or use device // Recommended to use website hosted by device String("http://" + WiFi.localIP().toString()).c_str()}; } bool onImprovCommandCallback(improv::ImprovCommand cmd) { switch (cmd.command) { case improv::Command::GET_CURRENT_STATE: { if ((WiFi.status() == WL_CONNECTED)) { improv_set_state(improv::State::STATE_PROVISIONED); std::vector data = improv::build_rpc_response(improv::GET_CURRENT_STATE, getLocalUrl(), false); improv_send_response(data); } else { improv_set_state(improv::State::STATE_AUTHORIZED); } break; } case improv::Command::WIFI_SETTINGS: { if (cmd.ssid.length() == 0) { improv_set_error(improv::Error::ERROR_INVALID_RPC); break; } improv_set_state(improv::STATE_PROVISIONING); if (improv_connectWifi(cmd.ssid, cmd.password)) { blinkDelay(100, 3); // std::array epdContent = {"S", "U", "C", "C", "E", "S", "S"}; // setEpdContent(epdContent); improv_set_state(improv::STATE_PROVISIONED); std::vector data = improv::build_rpc_response(improv::WIFI_SETTINGS, getLocalUrl(), false); improv_send_response(data); setupWebserver(); } else { improv_set_state(improv::STATE_STOPPED); improv_set_error(improv::Error::ERROR_UNABLE_TO_CONNECT); } break; } case improv::Command::GET_DEVICE_INFO: { std::vector infos = { // Firmware name "BTClock", // Firmware version "1.0.0", // Hardware chip/variant "ESP32S3", // Device name "BTClock"}; std::vector data = improv::build_rpc_response(improv::GET_DEVICE_INFO, infos, false); improv_send_response(data); break; } case improv::Command::GET_WIFI_NETWORKS: { improvGetAvailableWifiNetworks(); // std::array epdContent = {"W", "E", "B", "W", "I", "F", "I"}; // setEpdContent(epdContent); break; } default: { improv_set_error(improv::ERROR_UNKNOWN_RPC); return false; } } return true; } void improv_set_state(improv::State state) { std::vector data = {'I', 'M', 'P', 'R', 'O', 'V'}; data.resize(11); data[6] = improv::IMPROV_SERIAL_VERSION; data[7] = improv::TYPE_CURRENT_STATE; data[8] = 1; data[9] = state; uint8_t checksum = 0x00; for (uint8_t d : data) checksum += d; data[10] = checksum; Serial.write(data.data(), data.size()); } void improv_send_response(std::vector &response) { std::vector data = {'I', 'M', 'P', 'R', 'O', 'V'}; data.resize(9); data[6] = improv::IMPROV_SERIAL_VERSION; data[7] = improv::TYPE_RPC_RESPONSE; data[8] = response.size(); data.insert(data.end(), response.begin(), response.end()); uint8_t checksum = 0x00; for (uint8_t d : data) checksum += d; data.push_back(checksum); Serial.write(data.data(), data.size()); } void improv_set_error(improv::Error error) { std::vector data = {'I', 'M', 'P', 'R', 'O', 'V'}; data.resize(11); data[6] = improv::IMPROV_SERIAL_VERSION; data[7] = improv::TYPE_ERROR_STATE; data[8] = 1; data[9] = error; uint8_t checksum = 0x00; for (uint8_t d : data) checksum += d; data[10] = checksum; Serial.write(data.data(), data.size()); }