Obsługa przekaźników za pomocą Supla oraz przycisków zewnętrznych

Masz pomysł na funkcjonalność lub koncepcję na rozwój projektu. Opisz wszystko tutaj.
Post Reply
elmaya
Posts: 212
Joined: Wed Jun 27, 2018 5:48 pm
Location: Sevilla

Sun Apr 14, 2019 8:21 am

Witajcie.

Dotychczas moje projekty / kompilacje były dostępne tylko w anglojęzycznej części forum, gdyż nie znam języka polskiego. Jednak z pomocą translatora oraz uprzejmości kolegi z polski (@edm pomaga w tłumaczeniu), postaram się stopniowo przetłumaczyć wszystkie swoje projekty. Także w miarę możliwości, nowe projekty również będę publikował w polskiej wersji. W przypadku pytań, postaram się udzielić odpowiedzi, lecz proszę o wyrozumiałość. Translator różnie tłumaczy, a i kolega pewnie nie zawsze od razu będzie miał czas.

Przedstawiam firmware umożliwiające obsługę do 16 przekaźników, także za pomocą przycisków zewnętrznych.

Ponadto w firmware zastosowano:
- zaawansowane Menu config,
- funkcja aktualizacji oprogramowania OTA (bez konieczności podłączania konwertera USB), w celu podniesienia bezpieczeństwa zastosowano autoryzowany dostęp do aktualizacji,
- możliwość zmiany nazwy modułu na własną z poziomu Menu config.


Ustawienia portów:
GPIO5 /D1 Przycisk przełączania przekaźnika kanał 1- Konieczny pull-up, podłącz do GND. (Active - connect to GND)

GPIO4 /D2 Przycisk przełączania przekaźnika kanał 2- Konieczny pull-up, podłącz do GND. (Active - connect to GND)

GPIO2 /D4 Przycisk przełączania przekaźnika kanał 3- Konieczny pull-up, podłącz do GND. (Active - connect to GND)

GPI14 /D5 Przycisk przełączania przekaźnika kanał 4- Konieczny pull-up, podłącz do GND. (Active - connect to GND)

GPIO12/D6 Przycisk przełączania przekaźnika kanał 5- Konieczny pull-up, podłącz do GND. (Active - connect to GND)

GPIO13/D7 Przycisk przełączania przekaźnika kanał 6- Konieczny pull-up, podłącz do GND. (Active - connect to GND)

GPIO3 /RX Przycisk przełączania przekaźnika kanał 7- Konieczny pull-up, podłącz do GND. (Active - connect to GND)

GPIO1 /TX Przycisk przełączania przekaźnika kanał 8- Konieczny pull-up, podłącz do GND. (Active - connect to GND)

Kanał 9 do 16 A0 użyj rezystora 8 x 1kohm

GPIO15/D8 rejestry zmianowe (shift registers), pin dane 14 do 74595

GPIO16/D0 rejestry zmianowe (shift registers), pin zegar 11 do 74595

GPIO0 /D3 rejestry zmianowe (shift registers), zwora pin 12 do 74595

Pierwszy rejestr zmianowy Q7'pin 9, drugi rejestr zmianowy, dane pin 14

Image

Code: Select all

#include <FS.h>       // ---- esp board manager 2.4.2 --- iwip Variant V2 higher Bandwidth
#include <ShiftRegister74HC595.h>   //https://github.com/Simsso/ShiftRegister74HC595
#include <ESP8266WiFi.h>
#define SUPLADEVICE_CPP
#include <SuplaDevice.h>
// create shift register object (number of shift registers, data pin 14 on 74595, clock pin 11 on 74595, latch pin 12 on 74595)
ShiftRegister74HC595 sr (2, 15, 16, 0); 
#include <math.h>
#include <ESP8266WebServer.h>
#include <DNSServer.h>
#include <WiFiManager.h> 
#include <ArduinoJson.h> //--------- https://github.com/bblanchon/ArduinoJson/tree/v5.13.2 ------
#include <EEPROM.h>
#include <DoubleResetDetector.h> 
#include <ESP8266WebServer.h>
#include <ESP8266mDNS.h>
#include <ESPEFC.h>  // modification of ESP8266HTTPUpdateServer that includes erases flash and wifi credentials
extern "C"
{
#include "user_interface.h"
}
#define DRD_TIMEOUT 30 // Number of seconds after reset during which a  subseqent reset will be considered a double reset.
#define DRD_ADDRESS 0 // RTC Memory Address for the DoubleResetDetector to use
DoubleResetDetector drd(DRD_TIMEOUT, DRD_ADDRESS);
int uno = 1;
bool pr_wifi = true;
bool start = true;
bool eep = LOW;          //             ---------------- Eeprom ------------------
int epr = 0;             //             ----------- Eepron read loops ------------
int s;                   //             ---------------- Status ------------------
int an;
int buttonValue = 0;
unsigned long wifi_checkDelay = 60000;  // wifi reconect delay
unsigned long wifimilis;
unsigned long eep_milis;
#define BEGIN_PIN 100
unsigned int Rs = 100000;
double Vcc = 3.3;

#define BTN_COUNT 16

WiFiClient client;
ESP8266WebServer httpServer(81);
ESPEFC httpUpdater;
const char* host = "supla";
char Supla_server[80];
char Location_id[15];
char Location_Pass[34];
char Supla_name[51];
char update_path[21];
char update_username[21];
char update_password[21];
byte mac[6];

//flag for saving data
bool shouldSaveConfig = false;
bool initialConfig = false;
int timeout           = 180; // seconds to run for wifi config

void saveConfigCallback () {                 //callback notifying us of the need to save config
  Serial.println("Should save config");
  shouldSaveConfig = true;
}
void ondemandwifiCallback () {

  WiFiManagerParameter custom_Supla_server("server", "supla server", Supla_server, 80);
  WiFiManagerParameter custom_Location_id("ID", "Location id", Location_id, 15);
  WiFiManagerParameter custom_Location_Pass("Password", "Location Pass", Location_Pass, 34);
  WiFiManagerParameter custom_Supla_name("name", "Supla Device Name", Supla_name, 51,"required");
  WiFiManagerParameter custom_update_path("updatePath", "/xxxx update path", update_path, 21,"required");
  WiFiManagerParameter custom_update_username("updateUsername", "update username", update_username, 21,"required");
  WiFiManagerParameter custom_update_password("updatePassword", "update password", update_password, 21,"required");


  WiFiManager wifiManager;
  wifiManager.setBreakAfterConfig(true);
  wifiManager.setSaveConfigCallback(saveConfigCallback);
  
  wifiManager.addParameter(&custom_Supla_server);
  wifiManager.addParameter(&custom_Location_id);
  wifiManager.addParameter(&custom_Location_Pass);
  wifiManager.addParameter(&custom_Supla_name);
  wifiManager.addParameter(&custom_update_path);
  wifiManager.addParameter(&custom_update_username);
  wifiManager.addParameter(&custom_update_password);

  wifiManager.setCustomHeadElement("<style>html{ background-color: #01DF3A;}</style><div class='s'><svg version='1.1' id='l' x='0' y='0' viewBox='0 0 200 200' xml:space='preserve'><path d='M59.3,2.5c18.1,0.6,31.8,8,40.2,23.5c3.1,5.7,4.3,11.9,4.1,18.3c-0.1,3.6-0.7,7.1-1.9,10.6c-0.2,0.7-0.1,1.1,0.6,1.5c12.8,7.7,25.5,15.4,38.3,23c2.9,1.7,5.8,3.4,8.7,5.3c1,0.6,1.6,0.6,2.5-0.1c4.5-3.6,9.8-5.3,15.7-5.4c12.5-0.1,22.9,7.9,25.2,19c1.9,9.2-2.9,19.2-11.8,23.9c-8.4,4.5-16.9,4.5-25.5,0.2c-0.7-0.3-1-0.2-1.5,0.3c-4.8,4.9-9.7,9.8-14.5,14.6c-5.3,5.3-10.6,10.7-15.9,16c-1.8,1.8-3.6,3.7-5.4,5.4c-0.7,0.6-0.6,1,0,1.6c3.6,3.4,5.8,7.5,6.2,12.2c0.7,7.7-2.2,14-8.8,18.5c-12.3,8.6-30.3,3.5-35-10.4c-2.8-8.4,0.6-17.7,8.6-22.8c0.9-0.6,1.1-1,0.8-2c-2-6.2-4.4-12.4-6.6-18.6c-6.3-17.6-12.7-35.1-19-52.7c-0.2-0.7-0.5-1-1.4-0.9c-12.5,0.7-23.6-2.6-33-10.4c-8-6.6-12.9-15-14.2-25c-1.5-11.5,1.7-21.9,9.6-30.7C32.5,8.9,42.2,4.2,53.7,2.7c0.7-0.1,1.5-0.2,2.2-0.2C57,2.4,58.2,2.5,59.3,2.5z M76.5,81c0,0.1,0.1,0.3,0.1,0.6c1.6,6.3,3.2,12.6,4.7,18.9c4.5,17.7,8.9,35.5,13.3,53.2c0.2,0.9,0.6,1.1,1.6,0.9c5.4-1.2,10.7-0.8,15.7,1.6c0.8,0.4,1.2,0.3,1.7-0.4c11.2-12.9,22.5-25.7,33.4-38.7c0.5-0.6,0.4-1,0-1.6c-5.6-7.9-6.1-16.1-1.3-24.5c0.5-0.8,0.3-1.1-0.5-1.6c-9.1-4.7-18.1-9.3-27.2-14c-6.8-3.5-13.5-7-20.3-10.5c-0.7-0.4-1.1-0.3-1.6,0.4c-1.3,1.8-2.7,3.5-4.3,5.1c-4.2,4.2-9.1,7.4-14.7,9.7C76.9,80.3,76.4,80.3,76.5,81z M89,42.6c0.1-2.5-0.4-5.4-1.5-8.1C83,23.1,74.2,16.9,61.7,15.8c-10-0.9-18.6,2.4-25.3,9.7c-8.4,9-9.3,22.4-2.2,32.4c6.8,9.6,19.1,14.2,31.4,11.9C79.2,67.1,89,55.9,89,42.6z M102.1,188.6c0.6,0.1,1.5-0.1,2.4-0.2c9.5-1.4,15.3-10.9,11.6-19.2c-2.6-5.9-9.4-9.6-16.8-8.6c-8.3,1.2-14.1,8.9-12.4,16.6C88.2,183.9,94.4,188.6,102.1,188.6z M167.7,88.5c-1,0-2.1,0.1-3.1,0.3c-9,1.7-14.2,10.6-10.8,18.6c2.9,6.8,11.4,10.3,19,7.8c7.1-2.3,11.1-9.1,9.6-15.9C180.9,93,174.8,88.5,167.7,88.5z'/></svg>");

  wifiManager.setMinimumSignalQuality();

    wifiManager.setConfigPortalTimeout(timeout);

    if (!wifiManager.startConfigPortal("Supla 16x16")) {
      Serial.println("Not connected to WiFi but continuing anyway.");
    } else {
      
      Serial.println("connected...yeey :)");    //if you get here you have connected to the WiFi
    }
    //read updated parameters
    strcpy(Supla_server, custom_Supla_server.getValue());
    strcpy(Location_id, custom_Location_id.getValue());
    strcpy(Location_Pass, custom_Location_Pass.getValue());
    strcpy(Supla_name, custom_Supla_name.getValue());
    strcpy(update_path, custom_update_path.getValue());
    strcpy(update_username, custom_update_username.getValue());
    strcpy(update_password, custom_update_password.getValue());
   
  WiFi.softAPdisconnect(true);   //  close AP
}

typedef struct {  //------------------------------------------- BTN ----------------------------------------------------
  int pin;
  int relay_pin;
  int channel;
  char last_val;
  int ms;
  unsigned long last_time;
  bool mem;
} _btn_t;

_btn_t btn[BTN_COUNT];

void supla_timer() {
  char v;
  unsigned long now = millis();
  {
  for(int a=0;a<BTN_COUNT;a++)
    if (btn[a].pin > 0) {
        v = digitalRead(btn[a].pin);
        if (v != btn[a].last_val && now - btn[a].last_time ) {
           btn[a].last_val = v;
           btn[a].last_time = now;
           delay(75);
           v = digitalRead(btn[a].pin);
           if (v==0)
             {
              if ( btn[a].ms > 0 ) {
                     SuplaDevice.relayOn(btn[a].channel, btn[a].ms);
                     Serial.println(" monostable");
                 } else {
                 if ( (btn[a].mem) == 1 ) {   //   ----------------- == 1 if channel is false... == 0 if channel is true -----------------------
                  SuplaDevice.relayOff(btn[a].channel);
                  Serial.print("BTN Switsh off relay ");
                  Serial.println(btn[a].relay_pin);
                 } else {
                  SuplaDevice.relayOn(btn[a].channel, 0);
                  Serial.print("BTN Switsh on relay ");
                  Serial.println(btn[a].relay_pin);
                 }        
             }
             }}
      }
    }
}
void supla_btn_init() {
  for(int a=0;a<BTN_COUNT;a++)
    if (btn[a].pin > 0) {
        pinMode(btn[a].pin, INPUT_PULLUP);
        btn[a].last_val = digitalRead(btn[a].pin);
        btn[a].last_time = millis();
    }
}
int supla_DigitalRead(int channelNumber, uint8_t pin) {
   
      if (channelNumber == 0){
        if (btn[0].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 1){
        if (btn[1].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 2){
        if (btn[2].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 3){
        if (btn[3].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 4){
        if (btn[4].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 5){
        if (btn[5].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 6){
        if (btn[6].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 7){
        if (btn[7].mem ==0) return 0;      
        else return 1;      
      }
      if (channelNumber == 8){
        if (btn[8].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 9){
        if (btn[9].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 10){
        if (btn[10].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 11){
        if (btn[11].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 12){
        if (btn[12].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 13){
        if (btn[13].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 14){
        if (btn[14].mem ==0) return 0;      
        else return 1;
      }
      if (channelNumber == 15){
        if (btn[15].mem ==0) return 0;      
        else return 1;      
      }  
}
void suplaDigitalWrite(int channelNumber, uint8_t pin, uint8_t val) {  //------------------------------------------------  Virtual ----------------------------
         
     if (channelNumber == 0){
       btn[0].mem =val;
       sr.set(0, btn[0].mem); // set single pin 
       eep_milis = millis() + 2000 ;
     }
     if (channelNumber == 1){
       btn[1].mem =val;
       sr.set(1, btn[1].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 2){
       btn[2].mem =val;
       sr.set(2, btn[2].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 3){
       btn[3].mem =val;
       sr.set(3, btn[3].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 4){
       btn[4].mem =val;
       sr.set(4, btn[4].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 5){
       btn[5].mem =val;
       sr.set(5, btn[5].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 6){
       btn[6].mem =val;
       sr.set(6, btn[6].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 7){
       btn[7].mem =val;
       sr.set(7, btn[7].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 8){
       btn[8].mem =val;
       sr.set(8, btn[8].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
      if (channelNumber == 9){
       btn[9].mem =val;
       sr.set(9, btn[9].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 10){
       btn[10].mem =val;
       sr.set(10, btn[10].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 11){
       btn[11].mem =val;
       delay(50);
       sr.set(11, btn[11].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 12){
       btn[12].mem =val;
       sr.set(12, btn[12].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 13){
       btn[13].mem =val;
       sr.set(13, btn[13].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 14){
       btn[14].mem =val;
       sr.set(14, btn[14].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }
     if (channelNumber == 15){
       btn[15].mem =val;
       sr.set(15, btn[15].mem); // set single pin
       eep_milis = millis() + 2000 ; 
     }     
  return; 
}

void Eeprom_save() {                  //----------EEPROM write  ---------------------- EEprom

        if (start){
          return;
        }
      for(int e=0;e<BTN_COUNT;e++) {  //  ---check relay except it have delay (staircase)
         if ( btn[e].ms > 0 ) {
                     continue;
         } else {
        eep = (btn[e].mem);                    //  --- read relay state
        if (eep != EEPROM.read(e)){            //  --- compare relay state with memorized state          
         EEPROM.write(e,eep);                  //  --- if different write memory
         Serial.print("EEPROM.");
         Serial.print(e);
         Serial.print(" write.");
         Serial.print((eep));
         Serial.print(" channel ");
         Serial.println((btn[e].channel));
         EEPROM.commit();         
        }
     }
   }
}
void Eepron_read() {                  //----------EEPROM read  ---------------------- EEprom                                

         eep = EEPROM.read(epr);               //  ---read relay state       
         Serial.print("EEPROM.");
         Serial.print(epr);
         Serial.print(" read.");
         Serial.print((eep));
         Serial.print(" channel ");
         Serial.println((btn[epr].channel));
       
        if (eep == HIGH){                    //  --- if 1 send relay on
          SuplaDevice.relayOn(epr, 0);       //  --- only one channel in each pass
          }  
}
void status_func(int status, const char *msg) {     //    ------------------------ Status --------------------------
 s=status;                                          //    -- to check if we are registered and ready before restore from memory
}
void setup() {  //------------------------------------------------ Setup ----------------------------------------------

  wifi_set_sleep_type(NONE_SLEEP_T);

  Serial.begin(115200);
  
  EEPROM.begin(512);

  if (WiFi.SSID()==""){
    //Serial.println("We haven't got any access point credentials, so get them now");   
    initialConfig = true;
  } 
  //read configuration from FS json
  Serial.println("mounting FS...");
  
  if (SPIFFS.begin()) {
    Serial.println("mounted file system");
    if (SPIFFS.exists("/config1.json")) {
      //file exists, reading and loading
      Serial.println("reading config file");
      File configFile = SPIFFS.open("/config1.json", "r");
      if (configFile) {
        Serial.println("opened config file");
        size_t size = configFile.size();
        // Allocate a buffer to store contents of the file.
        std::unique_ptr<char[]> buf(new char[size]);

        configFile.readBytes(buf.get(), size);
        DynamicJsonBuffer jsonBuffer;         
        JsonObject& json = jsonBuffer.parseObject(buf.get());
        //json.printTo(Serial);   //print config data to serial on startup
        if (json.success()) {
          Serial.println("\nparsed json");

          strcpy(Supla_server, json["Supla_server"]);
          strcpy(Location_id, json["Location_id"]);
          strcpy(Location_Pass, json["Location_Pass"]);
          strcpy(Supla_name, json["Supla_name"]);         
          strcpy(update_path, json["update_path"]);
          strcpy(update_username, json["update_username"]);
          strcpy(update_password, json["update_password"]);

        } else {
          Serial.println("failed to load json config");
          initialConfig = true;
        }
      }
    }
  } else {
    Serial.println("failed to mount FS");
  }
  
  if (drd.detectDoubleReset()) {
    Serial.println("Double Reset Detected");
    ondemandwifiCallback ();
  } else {
    Serial.println("No Double Reset Detected");
  }
  
  WiFi.mode(WIFI_STA); // Force to station mode because if device was switched off while in access point mode it will start up next time in access point mode.

   uint8_t mac[WL_MAC_ADDR_LENGTH];
   WiFi.macAddress(mac);
   char GUID[SUPLA_GUID_SIZE] = {mac[WL_MAC_ADDR_LENGTH - 6], mac[WL_MAC_ADDR_LENGTH - 5], mac[WL_MAC_ADDR_LENGTH - 4], mac[WL_MAC_ADDR_LENGTH - 3],                                
                                 mac[WL_MAC_ADDR_LENGTH - 2], mac[WL_MAC_ADDR_LENGTH - 1], mac[WL_MAC_ADDR_LENGTH - 1], mac[WL_MAC_ADDR_LENGTH - 2], 
                                 mac[WL_MAC_ADDR_LENGTH - 3], mac[WL_MAC_ADDR_LENGTH - 4], mac[WL_MAC_ADDR_LENGTH - 5], mac[WL_MAC_ADDR_LENGTH - 6]};
          
  SuplaDevice.addRelay(101, false);   
  SuplaDevice.addRelay(102, false);  
  SuplaDevice.addRelay(103, false); 
  SuplaDevice.addRelay(104, false);   
  SuplaDevice.addRelay(105, false);  
  SuplaDevice.addRelay(106, false); 
  SuplaDevice.addRelay(107, false);   
  SuplaDevice.addRelay(108, false);
  SuplaDevice.addRelay(109, false);   
  SuplaDevice.addRelay(110, false);  
  SuplaDevice.addRelay(111, false); 
  SuplaDevice.addRelay(112, false);   
  SuplaDevice.addRelay(113, false);  
  SuplaDevice.addRelay(114, false); 
  SuplaDevice.addRelay(115, false);   
  SuplaDevice.addRelay(116, false);
     

  memset(btn, 0, sizeof(btn));
  btn[0].pin =5;          // pin gpio buton  0 = no buton
  btn[0].relay_pin =101;  // pin gpio Relay
  btn[0].channel =0;      // channel
  btn[0].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[0].mem =0;
  btn[1].pin =4;          // pin gpio buton  0 = no buton
  btn[1].relay_pin =102;  // pin gpio Relay
  btn[1].channel =1;      // channel
  btn[1].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[1].mem =0;
  btn[2].pin =2;          // pin gpio buton  0 = no buton
  btn[2].relay_pin =103;  // pin gpio Relay
  btn[2].channel =2;      // channel
  btn[2].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[2].mem =0;
  btn[3].pin =14;         // pin gpio buton  0 = no buton 
  btn[3].relay_pin =104;  // pin gpio Relay
  btn[3].channel =3;      // channel
  btn[3].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[3].mem =0;
  btn[4].pin =12;         // pin gpio buton  0 = no buton
  btn[4].relay_pin =105;  // pin gpio Relay
  btn[4].channel =4;      // channel
  btn[4].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[4].mem =0;
  btn[5].pin =13;         // pin gpio buton  0 = no buton
  btn[5].relay_pin =106;  // pin gpio Relay
  btn[5].channel =5;      // channel
  btn[5].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[5].mem =0;
  btn[6].pin =3;         // pin gpio buton  0 = no buton
  btn[6].relay_pin =107;    // pin gpio Relay
  btn[6].channel =6;      // channel
  btn[6].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[6].mem =0;
  btn[7].pin =1;          // pin gpio buton  0 = no buton
  btn[7].relay_pin =108;  // pin gpio Relay
  btn[7].channel =7;      // channel
  btn[7].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[7].mem =0;
  btn[8].pin =22;          // pin gpio buton  0 = no buton
  btn[8].relay_pin =109;  // pin gpio Relay
  btn[8].channel =8;      // channel
  btn[8].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[8].mem =0;
  btn[9].pin =22;          // pin gpio buton  0 = no buton
  btn[9].relay_pin =110;  // pin gpio Relay
  btn[9].channel =9;      // channel
  btn[9].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[9].mem =0;
  btn[10].pin =22;          // pin gpio buton  0 = no buton
  btn[10].relay_pin =111;  // pin gpio Relay
  btn[10].channel =10;      // channel
  btn[10].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[10].mem =0;
  btn[11].pin =22;         // pin gpio buton  0 = no buton 
  btn[11].relay_pin =112;  // pin gpio Relay
  btn[11].channel =11;      // channel
  btn[11].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[11].mem =0;
  btn[12].pin =22;         // pin gpio buton  0 = no buton
  btn[12].relay_pin =113;  // pin gpio Relay
  btn[12].channel =12;      // channel
  btn[12].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[12].mem =0;
  btn[13].pin =22;         // pin gpio buton  0 = no buton
  btn[13].relay_pin =114;  // pin gpio Relay
  btn[13].channel =13;      // channel
  btn[13].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[13].mem =0;
  btn[14].pin =22;         // pin gpio buton  0 = no buton
  btn[14].relay_pin =115;    // pin gpio Relay
  btn[14].channel =14;      // channel
  btn[14].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[14].mem =0;
  btn[15].pin =22;          // pin gpio buton  0 = no buton
  btn[15].relay_pin =116;  // pin gpio Relay
  btn[15].channel =15;      // channel
  btn[15].ms =0;           //  if = 0 Bistable -- if > 0 Monostable for X ms
  btn[15].mem =0;
  supla_btn_init();

  SuplaDevice.setDigitalReadFuncImpl(&supla_DigitalRead);    //            ------Send Value to server -------
  SuplaDevice.setDigitalWriteFuncImpl(&suplaDigitalWrite);   //        -------  Read Value from server   -------
  SuplaDevice.setTimerFuncImpl(&supla_timer);
  SuplaDevice.setStatusFuncImpl(&status_func);    //   ----------------------------- Status -----------------------------
  SuplaDevice.setName(Supla_name);

  int LocationID = atoi(Location_id);
  SuplaDevice.begin(GUID,              // Global Unique Identifier 
                    mac,               // Ethernet MAC address
                    Supla_server,      // SUPLA server address
                    LocationID,        // Location ID 
                    Location_Pass);    // Location Password
                           
}

void loop() {

  drd.loop();

  if (start){
    // read_initial_relay_state
    for(int i=0;i<BTN_COUNT;i++){      //  ---check relay except der have delay (staircase)
     if ( (btn[i].ms) > 0 ) {
                     continue;
         } else {
        eep = EEPROM.read(i);               //  ---read relay state
       if (eep >= 2 ){
         EEPROM.write(i,0);                  
         Serial.println("epp correct");
         EEPROM.commit();
       }
         Serial.print("Recover.");
         Serial.print(i);
         Serial.print(" read.");
         Serial.print((eep));
         Serial.print(" channel ");
         Serial.println((btn[i].channel));
         btn[i].mem =eep;
             
         sr.set(btn[i].channel, eep); // set single pin      
         }
    }
    start = false;
  }
  
  if (initialConfig){
    for(int i=0;i<BTN_COUNT;i++){ 
     if ( (btn[i].ms) > 0 ) {
                     continue;
     } else {
        EEPROM.write(i,0); 
     }
   } 
    ondemandwifiCallback () ;
  }

  if (shouldSaveConfig) {
    Serial.println("saving config");
    DynamicJsonBuffer jsonBuffer;
    JsonObject& json = jsonBuffer.createObject();
    json["Supla_server"] = Supla_server;
    json["Location_id"] = Location_id;
    json["Location_Pass"] = Location_Pass;
    json["Supla_name"] = Supla_name;
    json["update_path"] = update_path;
    json["update_username"] = update_username;
    json["update_password"] = update_password;

    File configFile = SPIFFS.open("/config1.json", "w");
    if (!configFile) {
      Serial.println("failed to open config file for writing");
    }
    json.prettyPrintTo(Serial);
    json.printTo(configFile);
    configFile.close();
    Serial.println("config saved");
    shouldSaveConfig = false;
    initialConfig = false; 
    WiFi.mode(WIFI_STA);
    ESP.restart();
    delay(5000); 
  }
  
  if (WiFi.status() != WL_CONNECTED) { 
    WiFi_up();
    pr_wifi = true;
  }
  else if ((WiFi.status() == WL_CONNECTED)  && (pr_wifi)){
    Serial.println("");
    Serial.println("CONNECTED");
    Serial.print("local IP: ");
    Serial.println(WiFi.localIP());
    Serial.print("subnetMask: ");
    Serial.println(WiFi.subnetMask());
    Serial.print("gatewayIP: ");
    Serial.println(WiFi.gatewayIP());
    long rssi = WiFi.RSSI();
    Serial.print("Signal Strength (RSSI): ");
    Serial.print(rssi);
    Serial.println(" dBm"); 
    pr_wifi = false;      
  MDNS.begin(host);
  httpUpdater.setup(&httpServer, update_path, update_username, update_password);
  httpServer.begin();
  MDNS.addService("http", "tcp", 81);
  Serial.printf("HTTPUpdateServer ready! Open http://%s.local:81%s in your browser and login with username '%s' and password '%s'\n", host, update_path, update_username, update_password);
  }
  
  SuplaDevice.iterate();
  analog_switch();
  httpServer.handleClient();
  
  if (millis() > eep_milis){
     Eeprom_save() ;   //        ------------------------------Eepron save callback -----------------------------   
     eep_milis = millis() + 5000 ;
     }     
  
  switch (s) {    //    ------------------------------------------------ Status ------------------------------------
  case 17:      // -----     STATUS_REGISTERED_AND_READY
  if (epr<BTN_COUNT){
   Eepron_read() ;                // ------------------------------- Eeprom read callback -------------------------------
   epr = epr+1;                   // -------- 1 loop for each output 8 in total ----------
   
  }
    break;
    
    case 10:      // --------------------- REGISTER_IN_PROGRESS  ----------------------
    epr = 0 ;
    break;
  }
}


// Supla.org ethernet layer
    int supla_arduino_tcp_read(void *buf, int count) {
        _supla_int_t size = client.available();
       
        if ( size > 0 ) {
            if ( size > count ) size = count;
            return client.read((uint8_t *)buf, size);
        };
    
        return -1;
    };
    
    int supla_arduino_tcp_write(void *buf, int count) {
        return client.write((const uint8_t *)buf, count);
    };
    
    bool supla_arduino_svr_connect(const char *server, int port) {
          return client.connect(server, 2015);
    }
    
    bool supla_arduino_svr_connected(void) {
          return client.connected();
    }
    
    void supla_arduino_svr_disconnect(void) {
         client.stop();
    }
    
    void supla_arduino_eth_setup(uint8_t mac[6], IPAddress *ip) {

       WiFi_up();
    }

SuplaDeviceCallbacks supla_arduino_get_callbacks(void) {
          SuplaDeviceCallbacks cb;
          
          cb.tcp_read = &supla_arduino_tcp_read;
          cb.tcp_write = &supla_arduino_tcp_write;
          cb.eth_setup = &supla_arduino_eth_setup;
          cb.svr_connected = &supla_arduino_svr_connected;
          cb.svr_connect = &supla_arduino_svr_connect;
          cb.svr_disconnect = &supla_arduino_svr_disconnect;
          cb.get_temperature = NULL;
          cb.get_temperature_and_humidity = NULL;
          cb.get_rgbw_value = NULL;
          cb.set_rgbw_value = NULL;
          
          return cb;
}

void WiFi_up(){ // conect to wifi
 
  if (millis() > wifimilis)  {
  WiFi.begin();
  Serial.println("CONNECTING WIFI"); 
  }
  wifimilis = (millis() + wifi_checkDelay) ;
}
void analog_switch(){
   
  buttonValue = analogRead(A0); //Read analog value from A0 pin
  
  if (buttonValue<=50){   //For no button:
  delay (50);
  return;
  }
  else
  {
   delay (50);
   buttonValue = analogRead(A0);
   Serial.print ("analog read: ");
   Serial.println(buttonValue);
   
  if (buttonValue>=113 && buttonValue<=153){ //For 1st button:
    Serial.println("read: 9 ");
    an = 8;
    analogRelay() ;
    delay (500);
    return;
  }  
  else if (buttonValue>=256 && buttonValue<=296){//For 2nd button:
    Serial.println("read: 10 ");
    an = 9;
    analogRelay() ;
    delay (500);
    return;
  }  
  else if (buttonValue>=389  && buttonValue<=429){//For 3rd button:
    Serial.println("read: 11 ");
    an = 10;
    analogRelay() ;
    delay (500);
    return;
  }  
  else if (buttonValue>=525  && buttonValue<=565){//For 4th button:
    Serial.println("read: 12 ");
    an = 11;
    analogRelay() ;
    delay (500);
    return;
  }    
  else if (buttonValue>=654  && buttonValue<=694){//For 5rd button:
    Serial.println("read: 13 ");
    an = 12;
    analogRelay() ;
    delay (500);
    return;
  }  
  else if (buttonValue>=796  && buttonValue<=836){//For 6th button:
    Serial.println("read: 14 ");
    an = 13;
    analogRelay() ;
    delay (500);
    return;
  }  
  else if (buttonValue>=930  && buttonValue<=970){//For 7rd button:
    Serial.println("read: 15 ");
    an = 14;
    analogRelay() ;
    delay (500);
    return;
  }  
  else if (buttonValue>=1000 ){//For 8th button:
    Serial.println("read: 16 ");
    an = 15;
    analogRelay() ;
    delay (500);
    return;
  } 
 }  
}
void analogRelay(){
  
   if ( btn[an].ms > 0 ) {
                     SuplaDevice.relayOn(btn[an].channel, btn[an].ms);
                     Serial.println(" monostable");
                 } else {
                 if ( (btn[an].mem) == 1 ) {   //   ----------------- == 1 if channel is false... == 0 if channel is true -----------------------
                  SuplaDevice.relayOff(btn[an].channel);
                  Serial.print("BTN Switsh off relay ");
                  Serial.println(btn[an].relay_pin);
                 } else {
                  SuplaDevice.relayOn(btn[an].channel, 0);
                  Serial.print("BTN Switsh on relay ");
                  Serial.println(btn[an].relay_pin);
                 }        
             } 
             delay (500);
}
arduino_files_and_libraries.rar
arduino_files_and_libraries
(126.97 KiB) Downloaded 33 times

Image

Parametry wgrywania dla "ESP Falsh Download Tool":
CreystalFreq 26M
SPI SPEED 40 MHz
SPI MODE DOUT
BAUDRATE 11520
FLASH SIZE 16Mbit (2MByte)

supla_595_reset_to_Config16x16_V2_DOUT_16Mbit.bin ------------> 0x00000

Image

// TRYB KONFIGURACJI
Aby przełączyć urządzenie w tryb konfiguracji, naciśnij w tym przypadku Reset_Button 2 razy.
W trybie konfiguracji urządzenie przechodzi w tryb punktu dostępu (AP).
Aby wprowadzić lub zmienić ustawienia, musisz:
- Zaloguj się na https://cloud.supla.org (rejestracja jest bezpłatna)
- Połącz się z WiFi o nazwie (Supla16x16) z dowolnego komputera z kartą sieci bezprzewodowej i przeglądarką internetową.
- Otwórz stronę dostępu: http://192.168.4.1
- Wprowadź nazwę użytkownika i hasło do WiFi, za pomocą którego urządzenie uzyska dostęp do Internetu.
- Wpisz adres serwera, identyfikator lokalizacji i hasło lokalizacji, które zostaną dostarczone po zalogowaniu się na cloud.supla.org


supla_595_reset_to_Config16x16_V3_DOUT_16Mbit.rar
compiled firmware
(260.33 KiB) Downloaded 24 times
Post Reply