Async_ConfigOnSwitchFS_MQTT_Ptr.ino

/****************************************************************************************************************************
  Async_ConfigOnSwitchFS_MQTT_Ptr.ino
  For ESP8266 / ESP32 boards

  ESPAsync_WiFiManager is a library for the ESP8266/Arduino platform, using (ESP)AsyncWebServer to enable easy
  configuration and reconfiguration of WiFi credentials using a Captive Portal.

  Modified from
  1. Tzapu               (https://github.com/tzapu/WiFiManager)
  2. Ken Taylor          (https://github.com/kentaylor)
  3. Alan Steremberg     (https://github.com/alanswx/ESPAsyncWiFiManager)
  4. Khoi Hoang          (https://github.com/khoih-prog/ESP_WiFiManager)

  Built by Khoi Hoang https://github.com/khoih-prog/ESPAsync_WiFiManager
  Licensed under MIT license
 *****************************************************************************************************************************/
/****************************************************************************************************************************
  This example will open a Config Portal when there is no stored WiFi Credentials or when a button is pressed.

  The Button is connected to pin
  - D27 / GPIO27 for ESP32  (const int BUTTON_PIN  = PIN_D27;)
  - D1 for ESP8266          (const int BUTTON_PIN  = PIN_D1;)

  You can reconfigure to use another pin, such as the convenience FLASH / BOOT button @ PIN_D0;.

  A password is required to connect to the Config Portal so that only who know the password can access the Config Portal.

  The Credentials, being input via Config Portal, will then be saved into LittleFS / SPIFFS file, and be used to connect to
  Adafruit MQTT Server at "io.adafruit.com" and publish a Temperature Topic

  Based on original sketch posted by "Marko"(https://github.com/wackoo-arduino) on https://forum.arduino.cc/index.php?topic=692108
 *****************************************************************************************************************************/

#if !( defined(ESP8266) ||  defined(ESP32) )
  #error This code is intended to run on the ESP8266 or ESP32 platform! Please check your Tools->Board setting.
#endif

#define ESP_ASYNC_WIFIMANAGER_VERSION_MIN_TARGET      "ESPAsync_WiFiManager v1.15.0"
#define ESP_ASYNC_WIFIMANAGER_VERSION_MIN             1015000

// Use from 0 to 4. Higher number, more debugging messages and memory usage.
#define _ESPASYNC_WIFIMGR_LOGLEVEL_    3

// To not display stored SSIDs and PWDs on Config Portal, select false. Default is true
// Even the stored Credentials are not display, just leave them all blank to reconnect and reuse the stored Credentials
//#define DISPLAY_STORED_CREDENTIALS_IN_CP        false

#include <Arduino.h>            // for button
#include <OneButton.h>          // for button

#include <FS.h>

// Now support ArduinoJson 6.0.0+ ( tested with v6.15.2 to v6.16.1 )
#include <ArduinoJson.h>        // get it from https://arduinojson.org/ or install via Arduino library manager

//For ESP32, To use ESP32 Dev Module, QIO, Flash 4MB/80MHz, Upload 921600
//Ported to ESP32
#ifdef ESP32
  #include <esp_wifi.h>
  #include <WiFi.h>
  #include <WiFiClient.h>

  // From v1.1.1
  #include <WiFiMulti.h>
  WiFiMulti wifiMulti;

  // LittleFS has higher priority than SPIFFS
  #if ( defined(ESP_ARDUINO_VERSION_MAJOR) && (ESP_ARDUINO_VERSION_MAJOR >= 2) )
    #define USE_LITTLEFS    true
    #define USE_SPIFFS      false
  #elif defined(ARDUINO_ESP32C3_DEV)
    // For core v1.0.6-, ESP32-C3 only supporting SPIFFS and EEPROM. To use v2.0.0+ for LittleFS
    #define USE_LITTLEFS          false
    #define USE_SPIFFS            true
  #endif

  #if USE_LITTLEFS
    // Use LittleFS
    #include "FS.h"

    // Check cores/esp32/esp_arduino_version.h and cores/esp32/core_version.h
    //#if ( ESP_ARDUINO_VERSION >= ESP_ARDUINO_VERSION_VAL(2, 0, 0) )  //(ESP_ARDUINO_VERSION_MAJOR >= 2)
    #if ( defined(ESP_ARDUINO_VERSION_MAJOR) && (ESP_ARDUINO_VERSION_MAJOR >= 2) )
      #if (_ESPASYNC_WIFIMGR_LOGLEVEL_ > 3)
        #warning Using ESP32 Core 1.0.6 or 2.0.0+
      #endif

      // The library has been merged into esp32 core from release 1.0.6
      #include <LittleFS.h>       // https://github.com/espressif/arduino-esp32/tree/master/libraries/LittleFS

      FS* filesystem =      &LittleFS;
      #define FileFS        LittleFS
      #define FS_Name       "LittleFS"
    #else
      #if (_ESPASYNC_WIFIMGR_LOGLEVEL_ > 3)
        #warning Using ESP32 Core 1.0.5-. You must install LITTLEFS library
      #endif

      // The library has been merged into esp32 core from release 1.0.6
      #include <LITTLEFS.h>       // https://github.com/lorol/LITTLEFS

      FS* filesystem =      &LITTLEFS;
      #define FileFS        LITTLEFS
      #define FS_Name       "LittleFS"
    #endif

  #elif USE_SPIFFS
    #include <SPIFFS.h>
    FS* filesystem =      &SPIFFS;
    #define FileFS        SPIFFS
    #define FS_Name       "SPIFFS"
  #else
    // +Use FFat
    #include <FFat.h>
    FS* filesystem =      &FFat;
    #define FileFS        FFat
    #define FS_Name       "FFat"
  #endif
  //////

  #define LED_BUILTIN       2
  #define LED_ON            HIGH
  #define LED_OFF           LOW

#else

  #include <ESP8266WiFi.h>          //https://github.com/esp8266/Arduino
  //needed for library
  #include <ESPAsyncDNSServer.h>

  // From v1.1.1
  #include <ESP8266WiFiMulti.h>
  ESP8266WiFiMulti wifiMulti;

  #define USE_LITTLEFS      true

  #if USE_LITTLEFS
    #include <LittleFS.h>
    FS* filesystem =      &LittleFS;
    #define FileFS        LittleFS
    #define FS_Name       "LittleFS"
  #else
    FS* filesystem =      &SPIFFS;
    #define FileFS        SPIFFS
    #define FS_Name       "SPIFFS"
  #endif
  //////

  #define ESP_getChipId()   (ESP.getChipId())

  #define LED_ON      LOW
  #define LED_OFF     HIGH
#endif

#include "Adafruit_MQTT.h"                //https://github.com/adafruit/Adafruit_MQTT_Library
#include "Adafruit_MQTT_Client.h"         //https://github.com/adafruit/Adafruit_MQTT_Library

#if ESP32

  //See file .../hardware/espressif/esp32/variants/(esp32|doitESP32devkitV1)/pins_arduino.h
  #define LED_BUILTIN       2         // Pin D2 mapped to pin GPIO2/ADC12 of ESP32, control on-board LED
  #define PIN_LED           2         // Pin D2 mapped to pin GPIO2/ADC12 of ESP32, control on-board LED

  #define PIN_D0            0         // Pin D0 mapped to pin GPIO0/BOOT/ADC11/TOUCH1 of ESP32
  #define PIN_D1            1         // Pin D1 mapped to pin GPIO1/TX0 of ESP32
  #define PIN_D2            2         // Pin D2 mapped to pin GPIO2/ADC12/TOUCH2 of ESP32
  #define PIN_D3            3         // Pin D3 mapped to pin GPIO3/RX0 of ESP32
  #define PIN_D4            4         // Pin D4 mapped to pin GPIO4/ADC10/TOUCH0 of ESP32
  #define PIN_D5            5         // Pin D5 mapped to pin GPIO5/SPISS/VSPI_SS of ESP32
  #define PIN_D6            6         // Pin D6 mapped to pin GPIO6/FLASH_SCK of ESP32
  #define PIN_D7            7         // Pin D7 mapped to pin GPIO7/FLASH_D0 of ESP32
  #define PIN_D8            8         // Pin D8 mapped to pin GPIO8/FLASH_D1 of ESP32
  #define PIN_D9            9         // Pin D9 mapped to pin GPIO9/FLASH_D2 of ESP32

  #define PIN_D10           10        // Pin D10 mapped to pin GPIO10/FLASH_D3 of ESP32
  #define PIN_D11           11        // Pin D11 mapped to pin GPIO11/FLASH_CMD of ESP32
  #define PIN_D12           12        // Pin D12 mapped to pin GPIO12/HSPI_MISO/ADC15/TOUCH5/TDI of ESP32
  #define PIN_D13           13        // Pin D13 mapped to pin GPIO13/HSPI_MOSI/ADC14/TOUCH4/TCK of ESP32
  #define PIN_D14           14        // Pin D14 mapped to pin GPIO14/HSPI_SCK/ADC16/TOUCH6/TMS of ESP32
  #define PIN_D15           15        // Pin D15 mapped to pin GPIO15/HSPI_SS/ADC13/TOUCH3/TDO of ESP32
  #define PIN_D16           16        // Pin D16 mapped to pin GPIO16/TX2 of ESP32
  #define PIN_D17           17        // Pin D17 mapped to pin GPIO17/RX2 of ESP32
  #define PIN_D18           18        // Pin D18 mapped to pin GPIO18/VSPI_SCK of ESP32
  #define PIN_D19           19        // Pin D19 mapped to pin GPIO19/VSPI_MISO of ESP32

  #define PIN_D21           21        // Pin D21 mapped to pin GPIO21/SDA of ESP32
  #define PIN_D22           22        // Pin D22 mapped to pin GPIO22/SCL of ESP32
  #define PIN_D23           23        // Pin D23 mapped to pin GPIO23/VSPI_MOSI of ESP32
  #define PIN_D24           24        // Pin D24 mapped to pin GPIO24 of ESP32
  #define PIN_D25           25        // Pin D25 mapped to pin GPIO25/ADC18/DAC1 of ESP32
  #define PIN_D26           26        // Pin D26 mapped to pin GPIO26/ADC19/DAC2 of ESP32
  #define PIN_D27           27        // Pin D27 mapped to pin GPIO27/ADC17/TOUCH7 of ESP32

  #define PIN_D32           32        // Pin D32 mapped to pin GPIO32/ADC4/TOUCH9 of ESP32
  #define PIN_D33           33        // Pin D33 mapped to pin GPIO33/ADC5/TOUCH8 of ESP32
  #define PIN_D34           34        // Pin D34 mapped to pin GPIO34/ADC6 of ESP32

  //Only GPIO pin < 34 can be used as output. Pins >= 34 can be only inputs
  //See .../cores/esp32/esp32-hal-gpio.h/c
  //#define digitalPinIsValid(pin)          ((pin) < 40 && esp32_gpioMux[(pin)].reg)
  //#define digitalPinCanOutput(pin)        ((pin) < 34 && esp32_gpioMux[(pin)].reg)
  //#define digitalPinToRtcPin(pin)         (((pin) < 40)?esp32_gpioMux[(pin)].rtc:-1)
  //#define digitalPinToAnalogChannel(pin)  (((pin) < 40)?esp32_gpioMux[(pin)].adc:-1)
  //#define digitalPinToTouchChannel(pin)   (((pin) < 40)?esp32_gpioMux[(pin)].touch:-1)
  //#define digitalPinToDacChannel(pin)     (((pin) == 25)?0:((pin) == 26)?1:-1)

  #define PIN_D35           35        // Pin D35 mapped to pin GPIO35/ADC7 of ESP32
  #define PIN_D36           36        // Pin D36 mapped to pin GPIO36/ADC0/SVP of ESP32
  #define PIN_D39           39        // Pin D39 mapped to pin GPIO39/ADC3/SVN of ESP32

  #define PIN_RX0            3        // Pin RX0 mapped to pin GPIO3/RX0 of ESP32
  #define PIN_TX0            1        // Pin TX0 mapped to pin GPIO1/TX0 of ESP32

  #define PIN_SCL           22        // Pin SCL mapped to pin GPIO22/SCL of ESP32
  #define PIN_SDA           21        // Pin SDA mapped to pin GPIO21/SDA of ESP32

#else

  //PIN_D0 can't be used for PWM/I2C
  #define PIN_D0            16        // Pin D0 mapped to pin GPIO16/USER/WAKE of ESP8266. This pin is also used for Onboard-Blue LED. PIN_D0 = 0 => LED ON
  #define PIN_D1            5         // Pin D1 mapped to pin GPIO5 of ESP8266
  #define PIN_D2            4         // Pin D2 mapped to pin GPIO4 of ESP8266
  #define PIN_D3            0         // Pin D3 mapped to pin GPIO0/FLASH of ESP8266
  #define PIN_D4            2         // Pin D4 mapped to pin GPIO2/TXD1 of ESP8266
  #define PIN_LED           2         // Pin D4 mapped to pin GPIO2/TXD1 of ESP8266, NodeMCU and WeMoS, control on-board LED
  #define PIN_D5            14        // Pin D5 mapped to pin GPIO14/HSCLK of ESP8266
  #define PIN_D6            12        // Pin D6 mapped to pin GPIO12/HMISO of ESP8266
  #define PIN_D7            13        // Pin D7 mapped to pin GPIO13/RXD2/HMOSI of ESP8266
  #define PIN_D8            15        // Pin D8 mapped to pin GPIO15/TXD2/HCS of ESP8266

  //Don't use pins GPIO6 to GPIO11 as already connected to flash, etc. Use them can crash the program
  //GPIO9(D11/SD2) and GPIO11 can be used only if flash in DIO mode ( not the default QIO mode)
  #define PIN_D11           9         // Pin D11/SD2 mapped to pin GPIO9/SDD2 of ESP8266
  #define PIN_D12           10        // Pin D12/SD3 mapped to pin GPIO10/SDD3 of ESP8266
  #define PIN_SD2           9         // Pin SD2 mapped to pin GPIO9/SDD2 of ESP8266
  #define PIN_SD3           10        // Pin SD3 mapped to pin GPIO10/SDD3 of ESP8266

  #define PIN_D9            3         // Pin D9 /RX mapped to pin GPIO3/RXD0 of ESP8266
  #define PIN_D10           1         // Pin D10/TX mapped to pin GPIO1/TXD0 of ESP8266
  #define PIN_RX            3         // Pin RX mapped to pin GPIO3/RXD0 of ESP8266
  #define PIN_TX            1         // Pin RX mapped to pin GPIO1/TXD0 of ESP8266

  #define LED_PIN           16        // Pin D0 mapped to pin GPIO16 of ESP8266. This pin is also used for Onboard-Blue LED. PIN_D0 = 0 => LED ON

#endif    //ESP32

#if ESP32
  #if ( USING_ESP32_S2 || USING_ESP32_C3 )
    const int BUTTON_PIN  = PIN_D3;
    const int RED_LED     = PIN_D4;
    const int BLUE_LED    = PIN_D5;
  #else
    const int BUTTON_PIN  = PIN_D27;
    const int RED_LED     = PIN_D26;
    const int BLUE_LED    = PIN_D25;
  #endif
#else
  const int BUTTON_PIN  = PIN_D1;
  const int RED_LED     = PIN_D2;
  const int BLUE_LED    = PIN_D5;
#endif    //ESP32

const char* CONFIG_FILE = "/ConfigMQTT.json";

// Default configuration values for Adafruit IO MQTT
// This actually works
#define AIO_SERVER              "io.adafruit.com"
#define AIO_SERVERPORT          "1883" //1883, or 8883 for SSL
#define AIO_USERNAME            "private" //Adafruit IO
#define AIO_KEY                 "private"

// Labels for custom parameters in WiFi manager
#define AIO_SERVER_Label             "AIO_SERVER_Label"
#define AIO_SERVERPORT_Label         "AIO_SERVERPORT_Label"
#define AIO_USERNAME_Label           "AIO_USERNAME_Label"
#define AIO_KEY_Label                "AIO_KEY_Label"

// Just dummy topics. To be updated later when got valid data from FS or Config Portal
String MQTT_Pub_Topic   = "private/feeds/Temperature";

// Variables to save custom parameters to...
// I would like to use these instead of #defines
#define custom_AIO_SERVER_LEN       20
#define custom_AIO_PORT_LEN          5
#define custom_AIO_USERNAME_LEN     20
#define custom_AIO_KEY_LEN          40

char custom_AIO_SERVER[custom_AIO_SERVER_LEN];
char custom_AIO_SERVERPORT[custom_AIO_PORT_LEN];
char custom_AIO_USERNAME[custom_AIO_USERNAME_LEN];
char custom_AIO_KEY[custom_AIO_KEY_LEN];

// Function Prototypes
void MQTT_connect();
bool readConfigFile();
bool writeConfigFile();

// From v1.1.1
// You only need to format the filesystem once
//#define FORMAT_FILESYSTEM       true
#define FORMAT_FILESYSTEM         false

#define MIN_AP_PASSWORD_SIZE    8

#define SSID_MAX_LEN            32
//From v1.0.10, WPA2 passwords can be up to 63 characters long.
#define PASS_MAX_LEN            64

typedef struct
{
  char wifi_ssid[SSID_MAX_LEN];
  char wifi_pw  [PASS_MAX_LEN];
}  WiFi_Credentials;

typedef struct
{
  String wifi_ssid;
  String wifi_pw;
}  WiFi_Credentials_String;

#define NUM_WIFI_CREDENTIALS      2

// Assuming max 49 chars
#define TZNAME_MAX_LEN            50
#define TIMEZONE_MAX_LEN          50

typedef struct
{
  WiFi_Credentials  WiFi_Creds [NUM_WIFI_CREDENTIALS];
  char TZ_Name[TZNAME_MAX_LEN];     // "America/Toronto"
  char TZ[TIMEZONE_MAX_LEN];        // "EST5EDT,M3.2.0,M11.1.0"
  uint16_t checksum;
} WM_Config;

WM_Config         WM_config;

#define  CONFIG_FILENAME              F("/wifi_cred.dat")
//////

// Indicates whether ESP has WiFi credentials saved from previous session, or double reset detected
bool initialConfig = false;

// Use false if you don't like to display Available Pages in Information Page of Config Portal
// Comment out or use true to display Available Pages in Information Page of Config Portal
// Must be placed before #include <ESPAsync_WiFiManager.h>
#define USE_AVAILABLE_PAGES     false

// From v1.0.10 to permit disable/enable StaticIP configuration in Config Portal from sketch. Valid only if DHCP is used.
// You'll loose the feature of dynamically changing from DHCP to static IP, or vice versa
// You have to explicitly specify false to disable the feature.
//#define USE_STATIC_IP_CONFIG_IN_CP          false

// Use false to disable NTP config. Advisable when using Cellphone, Tablet to access Config Portal.
// See Issue 23: On Android phone ConfigPortal is unresponsive (https://github.com/khoih-prog/ESP_WiFiManager/issues/23)
#define USE_ESP_WIFIMANAGER_NTP     true

// Just use enough to save memory. On ESP8266, can cause blank ConfigPortal screen
// if using too much memory
#define USING_AFRICA        false
#define USING_AMERICA       true
#define USING_ANTARCTICA    false
#define USING_ASIA          false
#define USING_ATLANTIC      false
#define USING_AUSTRALIA     false
#define USING_EUROPE        false
#define USING_INDIAN        false
#define USING_PACIFIC       false
#define USING_ETC_GMT       false

// Use true to enable CloudFlare NTP service. System can hang if you don't have Internet access while accessing CloudFlare
// See Issue #21: CloudFlare link in the default portal (https://github.com/khoih-prog/ESP_WiFiManager/issues/21)
#define USE_CLOUDFLARE_NTP          false

// New in v1.0.11
#define USING_CORS_FEATURE          true

////////////////////////////////////////////

// Use USE_DHCP_IP == true for dynamic DHCP IP, false to use static IP which you have to change accordingly to your network
#if (defined(USE_STATIC_IP_CONFIG_IN_CP) && !USE_STATIC_IP_CONFIG_IN_CP)
  // Force DHCP to be true
  #if defined(USE_DHCP_IP)
    #undef USE_DHCP_IP
  #endif
  #define USE_DHCP_IP     true
#else
  // You can select DHCP or Static IP here
  #define USE_DHCP_IP     true
  //#define USE_DHCP_IP     false
#endif

#if ( USE_DHCP_IP )
  // Use DHCP

  #if (_ESPASYNC_WIFIMGR_LOGLEVEL_ > 3)
    #warning Using DHCP IP
  #endif

  IPAddress stationIP   = IPAddress(0, 0, 0, 0);
  IPAddress gatewayIP   = IPAddress(192, 168, 2, 1);
  IPAddress netMask     = IPAddress(255, 255, 255, 0);

#else
  // Use static IP

  #if (_ESPASYNC_WIFIMGR_LOGLEVEL_ > 3)
    #warning Using static IP
  #endif

  #ifdef ESP32
    IPAddress stationIP   = IPAddress(192, 168, 2, 232);
  #else
    IPAddress stationIP   = IPAddress(192, 168, 2, 186);
  #endif

  IPAddress gatewayIP   = IPAddress(192, 168, 2, 1);
  IPAddress netMask     = IPAddress(255, 255, 255, 0);
#endif

////////////////////////////////////////////


#define USE_CONFIGURABLE_DNS      true

IPAddress dns1IP      = gatewayIP;
IPAddress dns2IP      = IPAddress(8, 8, 8, 8);

#define USE_CUSTOM_AP_IP          false

IPAddress APStaticIP  = IPAddress(192, 168, 100, 1);
IPAddress APStaticGW  = IPAddress(192, 168, 100, 1);
IPAddress APStaticSN  = IPAddress(255, 255, 255, 0);

#include <ESPAsync_WiFiManager.h>               //https://github.com/khoih-prog/ESPAsync_WiFiManager

// Redundant, for v1.10.0 only
//#include <ESPAsync_WiFiManager-Impl.h>          //https://github.com/khoih-prog/ESPAsync_WiFiManager


// For Config Portal
// SSID and PW for Config Portal
String ssid = "ESP_" + String(ESP_getChipId(), HEX);
String password;

// SSID and PW for your Router
String Router_SSID;
String Router_Pass;

#define HTTP_PORT           80

//Button config
OneButton btn = OneButton(
                  BUTTON_PIN,  // Input pin for the button
                  true,        // Button is active LOW
                  true         // Enable internal pull-up resistor
                );

// Create an ESP32 WiFiClient class to connect to the MQTT server
WiFiClient *client                    = NULL;

Adafruit_MQTT_Client    *mqtt         = NULL;
Adafruit_MQTT_Publish   *Temperature  = NULL;

///////////////////////////////////////////
// New in v1.4.0
/******************************************
   // Defined in ESPAsync_WiFiManager.h
  typedef struct
  {
  IPAddress _ap_static_ip;
  IPAddress _ap_static_gw;
  IPAddress _ap_static_sn;

  }  WiFi_AP_IPConfig;

  typedef struct
  {
  IPAddress _sta_static_ip;
  IPAddress _sta_static_gw;
  IPAddress _sta_static_sn;
  #if USE_CONFIGURABLE_DNS
  IPAddress _sta_static_dns1;
  IPAddress _sta_static_dns2;
  #endif
  }  WiFi_STA_IPConfig;
******************************************/

WiFi_AP_IPConfig  WM_AP_IPconfig;
WiFi_STA_IPConfig WM_STA_IPconfig;

void initAPIPConfigStruct(WiFi_AP_IPConfig &in_WM_AP_IPconfig)
{
  in_WM_AP_IPconfig._ap_static_ip   = APStaticIP;
  in_WM_AP_IPconfig._ap_static_gw   = APStaticGW;
  in_WM_AP_IPconfig._ap_static_sn   = APStaticSN;
}

void initSTAIPConfigStruct(WiFi_STA_IPConfig &in_WM_STA_IPconfig)
{
  in_WM_STA_IPconfig._sta_static_ip   = stationIP;
  in_WM_STA_IPconfig._sta_static_gw   = gatewayIP;
  in_WM_STA_IPconfig._sta_static_sn   = netMask;
#if USE_CONFIGURABLE_DNS
  in_WM_STA_IPconfig._sta_static_dns1 = dns1IP;
  in_WM_STA_IPconfig._sta_static_dns2 = dns2IP;
#endif
}

void displayIPConfigStruct(WiFi_STA_IPConfig in_WM_STA_IPconfig)
{
  LOGERROR3(F("stationIP ="), in_WM_STA_IPconfig._sta_static_ip, ", gatewayIP =", in_WM_STA_IPconfig._sta_static_gw);
  LOGERROR1(F("netMask ="), in_WM_STA_IPconfig._sta_static_sn);
#if USE_CONFIGURABLE_DNS
  LOGERROR3(F("dns1IP ="), in_WM_STA_IPconfig._sta_static_dns1, ", dns2IP =", in_WM_STA_IPconfig._sta_static_dns2);
#endif
}

void configWiFi(WiFi_STA_IPConfig in_WM_STA_IPconfig)
{
#if USE_CONFIGURABLE_DNS
  // Set static IP, Gateway, Subnetmask, DNS1 and DNS2. New in v1.0.5
  WiFi.config(in_WM_STA_IPconfig._sta_static_ip, in_WM_STA_IPconfig._sta_static_gw, in_WM_STA_IPconfig._sta_static_sn,
              in_WM_STA_IPconfig._sta_static_dns1, in_WM_STA_IPconfig._sta_static_dns2);
#else
  // Set static IP, Gateway, Subnetmask, Use auto DNS1 and DNS2.
  WiFi.config(in_WM_STA_IPconfig._sta_static_ip, in_WM_STA_IPconfig._sta_static_gw, in_WM_STA_IPconfig._sta_static_sn);
#endif
}

///////////////////////////////////////////

uint8_t connectMultiWiFi()
{
#if ESP32
  // For ESP32, this better be 0 to shorten the connect time.
  // For ESP32-S2/C3, must be > 500
#if ( USING_ESP32_S2 || USING_ESP32_C3 )
#define WIFI_MULTI_1ST_CONNECT_WAITING_MS           500L
#else
  // For ESP32 core v1.0.6, must be >= 500
#define WIFI_MULTI_1ST_CONNECT_WAITING_MS           800L
#endif
#else
  // For ESP8266, this better be 2200 to enable connect the 1st time
#define WIFI_MULTI_1ST_CONNECT_WAITING_MS             2200L
#endif

#define WIFI_MULTI_CONNECT_WAITING_MS                   500L

  uint8_t status;

  //WiFi.mode(WIFI_STA);

  LOGERROR(F("ConnectMultiWiFi with :"));

  if ( (Router_SSID != "") && (Router_Pass != "") )
  {
    LOGERROR3(F("* Flash-stored Router_SSID = "), Router_SSID, F(", Router_Pass = "), Router_Pass );
    LOGERROR3(F("* Add SSID = "), Router_SSID, F(", PW = "), Router_Pass );
    wifiMulti.addAP(Router_SSID.c_str(), Router_Pass.c_str());
  }

  for (uint8_t i = 0; i < NUM_WIFI_CREDENTIALS; i++)
  {
    // Don't permit NULL SSID and password len < MIN_AP_PASSWORD_SIZE (8)
    if ( (String(WM_config.WiFi_Creds[i].wifi_ssid) != "")
         && (strlen(WM_config.WiFi_Creds[i].wifi_pw) >= MIN_AP_PASSWORD_SIZE) )
    {
      LOGERROR3(F("* Additional SSID = "), WM_config.WiFi_Creds[i].wifi_ssid, F(", PW = "), WM_config.WiFi_Creds[i].wifi_pw );
    }
  }

  LOGERROR(F("Connecting MultiWifi..."));

  //WiFi.mode(WIFI_STA);

#if !USE_DHCP_IP
  // New in v1.4.0
  configWiFi(WM_STA_IPconfig);
  //////
#endif

  int i = 0;
  status = wifiMulti.run();
  delay(WIFI_MULTI_1ST_CONNECT_WAITING_MS);

  while ( ( i++ < 20 ) && ( status != WL_CONNECTED ) )
  {
    status = WiFi.status();

    if ( status == WL_CONNECTED )
      break;
    else
      delay(WIFI_MULTI_CONNECT_WAITING_MS);
  }

  if ( status == WL_CONNECTED )
  {
    LOGERROR1(F("WiFi connected after time: "), i);
    LOGERROR3(F("SSID:"), WiFi.SSID(), F(",RSSI="), WiFi.RSSI());
    LOGERROR3(F("Channel:"), WiFi.channel(), F(",IP address:"), WiFi.localIP() );
  }
  else
  {
    LOGERROR(F("WiFi not connected"));

#if ESP8266
    ESP.reset();
#else
    ESP.restart();
#endif
  }

  return status;
}

void toggleLED()
{
  //toggle state
  digitalWrite(LED_BUILTIN, !digitalRead(LED_BUILTIN));
}

#if USE_ESP_WIFIMANAGER_NTP

void printLocalTime()
{
#if ESP8266
  static time_t now;

  now = time(nullptr);

  if ( now > 1451602800 )
  {
    Serial.print("Local Date/Time: ");
    Serial.print(ctime(&now));
  }

#else
  struct tm timeinfo;

  getLocalTime( &timeinfo );

  // Valid only if year > 2000.
  // You can get from timeinfo : tm_year, tm_mon, tm_mday, tm_hour, tm_min, tm_sec
  if (timeinfo.tm_year > 100 )
  {
    Serial.print("Local Date/Time: ");
    Serial.print( asctime( &timeinfo ) );
  }

#endif
}

#endif

void heartBeatPrint()
{
#if USE_ESP_WIFIMANAGER_NTP
  printLocalTime();
#else
  static int num = 1;

  if (WiFi.status() == WL_CONNECTED)
    Serial.print(F("H"));        // H means connected to WiFi
  else
    Serial.print(F("F"));        // F means not connected to WiFi

  if (num == 80)
  {
    Serial.println();
    num = 1;
  }
  else if (num++ % 10 == 0)
  {
    Serial.print(F(" "));
  }

#endif
}

void publishMQTT()
{
  float some_number = 25.0 + (float) ( millis() % 100 ) /  100;

  // For debug only
  //Serial.print(F("Published Temp = "));
  //Serial.println(some_number);

  MQTT_connect();

  if (Temperature->publish(some_number))
  {
    Serial.print(F("T"));        // T means publishing OK
  }
  else
  {
    Serial.print(F("F"));        // F means publishing failure
  }
}

void check_WiFi()
{
  if ( (WiFi.status() != WL_CONNECTED) )
  {
    Serial.println(F("\nWiFi lost. Call connectMultiWiFi in loop"));
    connectMultiWiFi();
  }
}

void check_status()
{
  static ulong checkstatus_timeout  = 0;
  static ulong LEDstatus_timeout    = 0;
  static ulong checkwifi_timeout    = 0;
  static ulong mqtt_publish_timeout = 0;

  ulong current_millis = millis();

#define WIFICHECK_INTERVAL    1000L

#if USE_ESP_WIFIMANAGER_NTP
#define HEARTBEAT_INTERVAL    60000L
#else
#define HEARTBEAT_INTERVAL    10000L
#endif

#define LED_INTERVAL          2000L
#define PUBLISH_INTERVAL      60000L

  // Check WiFi every WIFICHECK_INTERVAL (1) seconds.
  if ((current_millis > checkwifi_timeout) || (checkwifi_timeout == 0))
  {
    check_WiFi();
    checkwifi_timeout = current_millis + WIFICHECK_INTERVAL;
  }

  if ((current_millis > LEDstatus_timeout) || (LEDstatus_timeout == 0))
  {
    // Toggle LED at LED_INTERVAL = 2s
    toggleLED();
    LEDstatus_timeout = current_millis + LED_INTERVAL;
  }

  // Print hearbeat every HEARTBEAT_INTERVAL (10) seconds.
  if ((current_millis > checkstatus_timeout) || (checkstatus_timeout == 0))
  {
    heartBeatPrint();
    checkstatus_timeout = current_millis + HEARTBEAT_INTERVAL;
  }

  // Check every PUBLISH_INTERVAL (60) seconds.
  if ((current_millis > mqtt_publish_timeout) || (mqtt_publish_timeout == 0))
  {
    if (WiFi.status() == WL_CONNECTED)
    {
      publishMQTT();
    }

    mqtt_publish_timeout = current_millis + PUBLISH_INTERVAL;
  }
}

int calcChecksum(uint8_t* address, uint16_t sizeToCalc)
{
  uint16_t checkSum = 0;

  for (uint16_t index = 0; index < sizeToCalc; index++)
  {
    checkSum += * ( ( (byte*) address ) + index);
  }

  return checkSum;
}

bool loadConfigData()
{
  File file = FileFS.open(CONFIG_FILENAME, "r");
  LOGERROR(F("LoadWiFiCfgFile "));

  memset((void *) &WM_config,       0, sizeof(WM_config));

  // New in v1.4.0
  memset((void *) &WM_STA_IPconfig, 0, sizeof(WM_STA_IPconfig));
  //////

  if (file)
  {
    file.readBytes((char *) &WM_config,   sizeof(WM_config));

    // New in v1.4.0
    file.readBytes((char *) &WM_STA_IPconfig, sizeof(WM_STA_IPconfig));
    //////

    file.close();
    LOGERROR(F("OK"));

    if ( WM_config.checksum != calcChecksum( (uint8_t*) &WM_config, sizeof(WM_config) - sizeof(WM_config.checksum) ) )
    {
      LOGERROR(F("WM_config checksum wrong"));

      return false;
    }

    // New in v1.4.0
    displayIPConfigStruct(WM_STA_IPconfig);
    //////

    return true;
  }
  else
  {
    LOGERROR(F("failed"));

    return false;
  }
}

void saveConfigData()
{
  File file = FileFS.open(CONFIG_FILENAME, "w");
  LOGERROR(F("SaveWiFiCfgFile "));

  if (file)
  {
    WM_config.checksum = calcChecksum( (uint8_t*) &WM_config, sizeof(WM_config) - sizeof(WM_config.checksum) );

    file.write((uint8_t*) &WM_config, sizeof(WM_config));

    displayIPConfigStruct(WM_STA_IPconfig);

    // New in v1.4.0
    file.write((uint8_t*) &WM_STA_IPconfig, sizeof(WM_STA_IPconfig));
    //////

    file.close();
    LOGERROR(F("OK"));
  }
  else
  {
    LOGERROR(F("failed"));
  }
}

void deleteOldInstances()
{
  // Delete previous instances
  if (mqtt)
  {
    delete mqtt;
    mqtt = NULL;

    Serial.println(F("Deleting old MQTT object"));
  }

  if (Temperature)
  {
    delete Temperature;
    Temperature = NULL;

    Serial.println(F("Deleting old Temperature object"));
  }
}

void createNewInstances()
{
  if (!client)
  {
    client = new WiFiClient;

    Serial.print(F("\nCreating new WiFi client object : "));
    Serial.println(client ? F("OK") : F("failed"));
  }

  // Create new instances from new data
  if (!mqtt)
  {
    // Setup the MQTT client class by passing in the WiFi client and MQTT server and login details.
    mqtt = new Adafruit_MQTT_Client(client, custom_AIO_SERVER, atoi(custom_AIO_SERVERPORT), custom_AIO_USERNAME,
                                    custom_AIO_KEY);

    Serial.print(F("Creating new MQTT object : "));

    if (mqtt)
    {
      Serial.println(F("OK"));
      Serial.println(String("AIO_SERVER = ")    + custom_AIO_SERVER    + ", AIO_SERVERPORT = "  + custom_AIO_SERVERPORT);
      Serial.println(String("AIO_USERNAME = ")  + custom_AIO_USERNAME  + ", AIO_KEY = "         + custom_AIO_KEY);
    }
    else
      Serial.println(F("Failed"));
  }

  if (!Temperature)
  {
    Serial.print(F("Creating new MQTT_Pub_Topic,  Temperature = "));
    Serial.println(MQTT_Pub_Topic);

    Temperature = new Adafruit_MQTT_Publish(mqtt, MQTT_Pub_Topic.c_str());

    Serial.print(F("Creating new Temperature object : "));

    if (Temperature)
    {
      Serial.println(F("OK"));
      Serial.println(String("Temperature MQTT_Pub_Topic = ")  + MQTT_Pub_Topic);
    }
    else
      Serial.println(F("Failed"));
  }
}

//event handler functions for button
static void handleClick()
{
  Serial.println(F("\nButton clicked!"));
  wifi_manager();
}

static void handleDoubleClick()
{
  Serial.println(F("\nButton double clicked!"));
}

static void handleLongPressStop()
{
  Serial.println(F("\nLong Button pressed!"));
  newConfigData();
}

void wifi_manager()
{
  Serial.println(F("\nConfig Portal requested."));
  digitalWrite(LED_BUILTIN, LED_ON); // turn the LED on by making the voltage LOW to tell us we are in configuration mode.

  //Local intialization. Once its business is done, there is no need to keep it around
  // Use this to default DHCP hostname to ESP8266-XXXXXX or ESP32-XXXXXX
  //ESPAsync_WiFiManager ESPAsync_wifiManager(&webServer, &dnsServer);
  // Use this to personalize DHCP hostname (RFC952 conformed)
  AsyncWebServer webServer(HTTP_PORT);

#if ( USING_ESP32_S2 || USING_ESP32_C3 )
  ESPAsync_WiFiManager ESPAsync_wifiManager(&webServer, NULL, "ConfigOnSwichFS-MQTT");
#else
  AsyncDNSServer dnsServer;

  ESPAsync_WiFiManager ESPAsync_wifiManager(&webServer, &dnsServer, "ConfigOnSwichFS-MQTT");
#endif

  //Check if there is stored WiFi router/password credentials.
  //If not found, device will remain in configuration mode until switched off via webserver.
  Serial.print(F("Opening Configuration Portal. "));

  Router_SSID = ESPAsync_wifiManager.WiFi_SSID();
  Router_Pass = ESPAsync_wifiManager.WiFi_Pass();

  // From v1.1.1, Don't permit NULL password
  if ( !initialConfig && (Router_SSID != "") && (Router_Pass != "") )
  {
    //If valid AP credential and not DRD, set timeout 120s.
    ESPAsync_wifiManager.setConfigPortalTimeout(120);
    Serial.println(F("Got stored Credentials. Timeout 120s"));
  }
  else
  {
    ESPAsync_wifiManager.setConfigPortalTimeout(0);

    Serial.print(F("No timeout : "));

    if (initialConfig)
    {
      Serial.println(F("DRD or No stored Credentials.."));
    }
    else
    {
      Serial.println(F("No stored Credentials."));
    }
  }

  //Local intialization. Once its business is done, there is no need to keep it around

  // Extra parameters to be configured
  // After connecting, parameter.getValue() will get you the configured value
  // Format: <ID> <Placeholder text> <default value> <length> <custom HTML> <label placement>
  // (*** we are not using <custom HTML> and <label placement> ***)

  // AIO_SERVER
  ESPAsync_WMParameter AIO_SERVER_FIELD(AIO_SERVER_Label, "AIO SERVER", custom_AIO_SERVER, custom_AIO_SERVER_LEN + 1);

  // AIO_SERVERPORT
  ESPAsync_WMParameter AIO_SERVERPORT_FIELD(AIO_SERVERPORT_Label, "AIO SERVER PORT", custom_AIO_SERVERPORT,
                                            custom_AIO_PORT_LEN + 1);

  // AIO_USERNAME
  ESPAsync_WMParameter AIO_USERNAME_FIELD(AIO_USERNAME_Label, "AIO USERNAME", custom_AIO_USERNAME,
                                          custom_AIO_USERNAME_LEN + 1);

  // AIO_KEY
  ESPAsync_WMParameter AIO_KEY_FIELD(AIO_KEY_Label, "AIO KEY", custom_AIO_KEY, custom_AIO_KEY_LEN + 1);

  // add all parameters here
  // order of adding is not important
  ESPAsync_wifiManager.addParameter(&AIO_SERVER_FIELD);
  ESPAsync_wifiManager.addParameter(&AIO_SERVERPORT_FIELD);
  ESPAsync_wifiManager.addParameter(&AIO_USERNAME_FIELD);
  ESPAsync_wifiManager.addParameter(&AIO_KEY_FIELD);

  // Sets timeout in seconds until configuration portal gets turned off.
  // If not specified device will remain in configuration mode until
  // switched off via webserver or device is restarted.
  //ESPAsync_wifiManager.setConfigPortalTimeout(120);

  ESPAsync_wifiManager.setMinimumSignalQuality(-1);

  // From v1.0.10 only
  // Set config portal channel, default = 1. Use 0 => random channel from 1-13
  ESPAsync_wifiManager.setConfigPortalChannel(0);
  //////

#if USE_CUSTOM_AP_IP
  //set custom ip for portal
  // New in v1.4.0
  ESPAsync_wifiManager.setAPStaticIPConfig(WM_AP_IPconfig);
  //////
#endif

#if !USE_DHCP_IP
  // Set (static IP, Gateway, Subnetmask, DNS1 and DNS2) or (IP, Gateway, Subnetmask). New in v1.0.5
  // New in v1.4.0
  ESPAsync_wifiManager.setSTAStaticIPConfig(WM_STA_IPconfig);
  //////
#endif

  // New from v1.1.1
#if USING_CORS_FEATURE
  ESPAsync_wifiManager.setCORSHeader("Your Access-Control-Allow-Origin");
#endif

  // Start an access point
  // and goes into a blocking loop awaiting configuration.
  // Once the user leaves the portal with the exit button
  // processing will continue
  // SSID to uppercase
  ssid.toUpperCase();
  password = "My" + ssid;

  Serial.print(F("Starting configuration portal @ "));

#if USE_CUSTOM_AP_IP
  Serial.print(APStaticIP);
#else
  Serial.print(F("192.168.4.1"));
#endif

  Serial.print(F(", SSID = "));
  Serial.print(ssid);
  Serial.print(F(", PWD = "));
  Serial.println(password);

#if DISPLAY_STORED_CREDENTIALS_IN_CP
  // New. Update Credentials, got from loadConfigData(), to display on CP
  ESPAsync_wifiManager.setCredentials(WM_config.WiFi_Creds[0].wifi_ssid, WM_config.WiFi_Creds[0].wifi_pw,
                                      WM_config.WiFi_Creds[1].wifi_ssid, WM_config.WiFi_Creds[1].wifi_pw);
#endif

  if (!ESPAsync_wifiManager.startConfigPortal((const char *) ssid.c_str(), password.c_str()))
  {
    Serial.println(F("Not connected to WiFi but continuing anyway."));
  }
  else
  {
    // If you get here you have connected to the WiFi
    Serial.println(F("Connected...yeey :)"));
    Serial.print(F("Local IP: "));
    Serial.println(WiFi.localIP());
  }

  // Only clear then save data if CP entered and with new valid Credentials
  // No CP => stored getSSID() = ""
  if ( String(ESPAsync_wifiManager.getSSID(0)) != "" && String(ESPAsync_wifiManager.getSSID(1)) != "" )
  {
    // Stored  for later usage, from v1.1.0, but clear first
    memset(&WM_config, 0, sizeof(WM_config));

    for (uint8_t i = 0; i < NUM_WIFI_CREDENTIALS; i++)
    {
      String tempSSID = ESPAsync_wifiManager.getSSID(i);
      String tempPW   = ESPAsync_wifiManager.getPW(i);

      if (strlen(tempSSID.c_str()) < sizeof(WM_config.WiFi_Creds[i].wifi_ssid) - 1)
        strcpy(WM_config.WiFi_Creds[i].wifi_ssid, tempSSID.c_str());
      else
        strncpy(WM_config.WiFi_Creds[i].wifi_ssid, tempSSID.c_str(), sizeof(WM_config.WiFi_Creds[i].wifi_ssid) - 1);

      if (strlen(tempPW.c_str()) < sizeof(WM_config.WiFi_Creds[i].wifi_pw) - 1)
        strcpy(WM_config.WiFi_Creds[i].wifi_pw, tempPW.c_str());
      else
        strncpy(WM_config.WiFi_Creds[i].wifi_pw, tempPW.c_str(), sizeof(WM_config.WiFi_Creds[i].wifi_pw) - 1);

      // Don't permit NULL SSID and password len < MIN_AP_PASSWORD_SIZE (8)
      if ( (String(WM_config.WiFi_Creds[i].wifi_ssid) != "")
           && (strlen(WM_config.WiFi_Creds[i].wifi_pw) >= MIN_AP_PASSWORD_SIZE) )
      {
        LOGERROR3(F("* Add SSID = "), WM_config.WiFi_Creds[i].wifi_ssid, F(", PW = "), WM_config.WiFi_Creds[i].wifi_pw );
        wifiMulti.addAP(WM_config.WiFi_Creds[i].wifi_ssid, WM_config.WiFi_Creds[i].wifi_pw);
      }
    }

#if USE_ESP_WIFIMANAGER_NTP
    String tempTZ   = ESPAsync_wifiManager.getTimezoneName();

    if (strlen(tempTZ.c_str()) < sizeof(WM_config.TZ_Name) - 1)
      strcpy(WM_config.TZ_Name, tempTZ.c_str());
    else
      strncpy(WM_config.TZ_Name, tempTZ.c_str(), sizeof(WM_config.TZ_Name) - 1);

    const char * TZ_Result = ESPAsync_wifiManager.getTZ(WM_config.TZ_Name);

    if (strlen(TZ_Result) < sizeof(WM_config.TZ) - 1)
      strcpy(WM_config.TZ, TZ_Result);
    else
      strncpy(WM_config.TZ, TZ_Result, sizeof(WM_config.TZ_Name) - 1);

    if ( strlen(WM_config.TZ_Name) > 0 )
    {
      LOGERROR3(F("Saving current TZ_Name ="), WM_config.TZ_Name, F(", TZ = "), WM_config.TZ);

#if ESP8266
      configTime(WM_config.TZ, "pool.ntp.org");
#else
      //configTzTime(WM_config.TZ, "pool.ntp.org" );
      configTzTime(WM_config.TZ, "time.nist.gov", "0.pool.ntp.org", "1.pool.ntp.org");
#endif
    }
    else
    {
      LOGERROR(F("Current Timezone Name is not set. Enter Config Portal to set."));
    }

#endif

    // New in v1.4.0
    ESPAsync_wifiManager.getSTAStaticIPConfig(WM_STA_IPconfig);
    //////

    saveConfigData();
  }

  // Getting posted form values and overriding local variables parameters
  // Config file is written regardless the connection state
  strcpy(custom_AIO_SERVER, AIO_SERVER_FIELD.getValue());
  strcpy(custom_AIO_SERVERPORT, AIO_SERVERPORT_FIELD.getValue());
  strcpy(custom_AIO_USERNAME, AIO_USERNAME_FIELD.getValue());
  strcpy(custom_AIO_KEY, AIO_KEY_FIELD.getValue());

  // Writing JSON config file to flash for next boot
  writeConfigFile();

  digitalWrite(LED_BUILTIN, LED_OFF); // Turn LED off as we are not in configuration mode.

  deleteOldInstances();

  MQTT_Pub_Topic = String(custom_AIO_USERNAME) + "/feeds/Temperature";
  createNewInstances();
}

bool readConfigFile()
{
  // this opens the config file in read-mode
  File f = FileFS.open(CONFIG_FILE, "r");

  if (!f)
  {
    Serial.println(F("Config File not found"));
    return false;
  }
  else
  {
    // we could open the file
    size_t size = f.size();
    // Allocate a buffer to store contents of the file.
    std::unique_ptr<char[]> buf(new char[size + 1]);

    // Read and store file contents in buf
    f.readBytes(buf.get(), size);
    // Closing file
    f.close();
    // Using dynamic JSON buffer which is not the recommended memory model, but anyway
    // See https://github.com/bblanchon/ArduinoJson/wiki/Memory%20model

#if (ARDUINOJSON_VERSION_MAJOR >= 6)

    DynamicJsonDocument json(1024);
    auto deserializeError = deserializeJson(json, buf.get());

    if ( deserializeError )
    {
      Serial.println(F("JSON parseObject() failed"));
      return false;
    }

    serializeJson(json, Serial);

#else

    DynamicJsonBuffer jsonBuffer;
    // Parse JSON string
    JsonObject& json = jsonBuffer.parseObject(buf.get());

    // Test if parsing succeeds.
    if (!json.success())
    {
      Serial.println(F("JSON parseObject() failed"));
      return false;
    }

    json.printTo(Serial);

#endif

    // Parse all config file parameters, override
    // local config variables with parsed values
    if (json.containsKey(AIO_SERVER_Label))
    {
      strcpy(custom_AIO_SERVER, json[AIO_SERVER_Label]);
    }

    if (json.containsKey(AIO_SERVERPORT_Label))
    {
      strcpy(custom_AIO_SERVERPORT, json[AIO_SERVERPORT_Label]);
    }

    if (json.containsKey(AIO_USERNAME_Label))
    {
      strcpy(custom_AIO_USERNAME, json[AIO_USERNAME_Label]);
    }

    if (json.containsKey(AIO_KEY_Label))
    {
      strcpy(custom_AIO_KEY, json[AIO_KEY_Label]);
    }
  }

  Serial.println(F("\nConfig File successfully parsed"));

  return true;
}

bool writeConfigFile()
{
  Serial.println(F("Saving Config File"));

#if (ARDUINOJSON_VERSION_MAJOR >= 6)
  DynamicJsonDocument json(1024);
#else
  DynamicJsonBuffer jsonBuffer;
  JsonObject& json = jsonBuffer.createObject();
#endif

  // JSONify local configuration parameters
  json[AIO_SERVER_Label]      = custom_AIO_SERVER;
  json[AIO_SERVERPORT_Label]  = custom_AIO_SERVERPORT;
  json[AIO_USERNAME_Label]    = custom_AIO_USERNAME;
  json[AIO_KEY_Label]         = custom_AIO_KEY;

  // Open file for writing
  File f = FileFS.open(CONFIG_FILE, "w");

  if (!f)
  {
    Serial.println(F("Failed to open Config File for writing"));
    return false;
  }

#if (ARDUINOJSON_VERSION_MAJOR >= 6)
  serializeJsonPretty(json, Serial);
  // Write data to file and close it
  serializeJson(json, f);
#else
  json.prettyPrintTo(Serial);
  // Write data to file and close it
  json.printTo(f);
#endif

  f.close();

  Serial.println(F("\nConfig File successfully saved"));
  return true;
}

// this function is just to display newly saved data,
// it is not necessary though, because data is displayed
// after WiFi manager resets ESP32
void newConfigData()
{
  Serial.println();
  Serial.print(F("custom_AIO_SERVER: "));
  Serial.println(custom_AIO_SERVER);
  Serial.print(F("custom_SERVERPORT: "));
  Serial.println(custom_AIO_SERVERPORT);
  Serial.print(F("custom_USERNAME_KEY: "));
  Serial.println(custom_AIO_USERNAME);
  Serial.print(F("custom_KEY: "));
  Serial.println(custom_AIO_KEY);
  Serial.println();
}

void MQTT_connect()
{
  int8_t ret;

  MQTT_Pub_Topic = String(custom_AIO_USERNAME) + "/feeds/Temperature";

  createNewInstances();

  // Return if already connected
  if (mqtt->connected())
  {
    return;
  }

  Serial.println(F("Connecting to MQTT (3 attempts)..."));

  uint8_t attempt = 3;

  while ((ret = mqtt->connect()) != 0)
  {
    // connect will return 0 for connected
    Serial.println(mqtt->connectErrorString(ret));
    Serial.println(F("Another attemtpt to connect to MQTT in 2 seconds..."));
    mqtt->disconnect();
    delay(2000);  // wait 2 seconds
    attempt--;

    if (attempt == 0)
    {
      Serial.println(F("MQTT connection failed. Continuing with program..."));
      return;
    }
  }

  Serial.println(F("MQTT connection successful!"));
}

// Setup function
void setup()
{
  // Initialize the LED digital pin as an output.
  pinMode(LED_BUILTIN, OUTPUT);

  // Put your setup code here, to run once
  Serial.begin(115200);

  while (!Serial);

  delay(200);

  Serial.print(F("\nStarting Async_ConfigOnSwichFS_MQTT_Ptr using "));
  Serial.print(FS_Name);
  Serial.print(F(" on "));
  Serial.println(ARDUINO_BOARD);
  Serial.println(ESP_ASYNC_WIFIMANAGER_VERSION);

#if defined(ESP_ASYNC_WIFIMANAGER_VERSION_INT)

  if (ESP_ASYNC_WIFIMANAGER_VERSION_INT < ESP_ASYNC_WIFIMANAGER_VERSION_MIN)
  {
    Serial.print("Warning. Must use this example on Version later than : ");
    Serial.println(ESP_ASYNC_WIFIMANAGER_VERSION_MIN_TARGET);
  }

#endif

  Serial.setDebugOutput(false);

  btn.attachClick(handleClick);
  btn.attachDoubleClick(handleDoubleClick);
  btn.attachLongPressStop(handleLongPressStop);

  if (FORMAT_FILESYSTEM)
    FileFS.format();

  // Format FileFS if not yet
#ifdef ESP32

  if (!FileFS.begin(true))
#else
  if (!FileFS.begin())
#endif
  {
#ifdef ESP8266
    FileFS.format();
#endif

    Serial.println(F("SPIFFS/LittleFS failed! Already tried formatting."));

    if (!FileFS.begin())
    {
      // prevents debug info from the library to hide err message.
      delay(100);

#if USE_LITTLEFS
      Serial.println(F("LittleFS failed!. Please use SPIFFS or EEPROM. Stay forever"));
#else
      Serial.println(F("SPIFFS failed!. Please use LittleFS or EEPROM. Stay forever"));
#endif

      while (true)
      {
        delay(1);
      }
    }
  }

  // New in v1.4.0
  initAPIPConfigStruct(WM_AP_IPconfig);
  initSTAIPConfigStruct(WM_STA_IPconfig);
  //////

  if (!readConfigFile())
  {
    Serial.println(F("Can't read Config File, using default values"));
  }

  // Load stored data, the addAP ready for MultiWiFi reconnection
  bool configDataLoaded = loadConfigData();

  // Pretend CP is necessary as we have no AP Credentials
  initialConfig = true;

  if (configDataLoaded)
  {
#if USE_ESP_WIFIMANAGER_NTP

    if ( strlen(WM_config.TZ_Name) > 0 )
    {
      LOGERROR3(F("Current TZ_Name ="), WM_config.TZ_Name, F(", TZ = "), WM_config.TZ);

#if ESP8266
      configTime(WM_config.TZ, "pool.ntp.org");
#else
      //configTzTime(WM_config.TZ, "pool.ntp.org" );
      configTzTime(WM_config.TZ, "time.nist.gov", "0.pool.ntp.org", "1.pool.ntp.org");
#endif
    }
    else
    {
      Serial.println(F("Current Timezone is not set. Enter Config Portal to set."));
    }

#endif

    for (uint8_t i = 0; i < NUM_WIFI_CREDENTIALS; i++)
    {
      // Don't permit NULL SSID and password len < MIN_AP_PASSWORD_SIZE (8)
      if ( (String(WM_config.WiFi_Creds[i].wifi_ssid) != "")
           && (strlen(WM_config.WiFi_Creds[i].wifi_pw) >= MIN_AP_PASSWORD_SIZE) )
      {
        LOGERROR3(F("* Add SSID = "), WM_config.WiFi_Creds[i].wifi_ssid, F(", PW = "), WM_config.WiFi_Creds[i].wifi_pw );
        wifiMulti.addAP(WM_config.WiFi_Creds[i].wifi_ssid, WM_config.WiFi_Creds[i].wifi_pw);
        initialConfig = false;
      }
    }
  }

  if (initialConfig)
  {
    Serial.println(F("Open Config Portal without Timeout: No stored WiFi Credentials"));

    wifi_manager();
  }
  else if ( WiFi.status() != WL_CONNECTED )
  {
    Serial.println(F("ConnectMultiWiFi in setup"));

    connectMultiWiFi();
  }

  digitalWrite(LED_BUILTIN, LED_OFF); // Turn led off as we are not in configuration mode.
}

// Loop function
void loop()
{
  // checking button state all the time
  btn.tick();

  // this is just for checking if we are connected to WiFi
  check_status();
}