esp32-timed-switch/esp32-timed-switch.ino

#include "esp_system.h"
#include "sntp.h"
#include "time.h"
#include <WiFi.h>
#include <WiFiUdp.h>
#include <Preferences.h>
#include "scheduler.h"
#include "scheduler_prefs.h"


// Init const and global objects

// PREFRENCES
Preferences preferences;
#define RW_MODE false
#define RO_MODE true

// WIFI
const char* ssid                = "/tmp/lab";
const char* password            = "bitte2cucung";
const uint8_t wifi_loop_max     = 10;

// NTP
bool sntp_initialized           = false;
const char* ntpServer1          = "pool.ntp.org";
const char* ntpServer2          = "time.nist.gov";
const long  gmtOffset_sec       = 2 * 3600;  // GMT + 2
const int   daylightOffset_sec  = 0;

// TIMER
hw_timer_t*timer_main           = NULL;
uint32_t timer_interval         = 3000000;
uint16_t timer_interval_in_secs = timer_interval / 1000000;
;

// SCHEDULER
bool brun_scheduler              = true;
uint8_t current_hour            = HOUR_DEFAULT;
uint8_t current_minute          = MINUTE_DEFAULT;
uint8_t current_second          = 0;
uint32_t current_ts             = 0;
uint32_t next_event_ts          = 0;
int scheduler_1[24] ; //       = {A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60,A60};
int scheduler_2[24] ; //       = {A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00,A00};
int* scheduler_list[]      = {
  scheduler_1,
  scheduler_2
  };

// PINS
unsigned int PIN_1 = 12;
unsigned int PIN_2 = 14;
unsigned int PIN_3 = 27;
unsigned int PIN_4 = 26;
unsigned int PIN_5 = 20;
unsigned int PIN_6 = 33;
unsigned int PIN_7 = 32;
unsigned int PIN_8 = 35;
unsigned int pin_list[2] = {
  PIN_1,
  PIN_2
  };

// HTTP
WiFiClient http_client;
WiFiServer http_server(80); 
String request;


// Local functions

// Time helper
uint32_t get_timestamp( uint8_t hour, uint8_t minute, uint8_t second){
  return ( 3600 * hour  + 60 * minute + second) % 86400;
}

bool event_keep_waiting( uint32_t current_ts, uint32_t event_ts ){

  // basic case
  // ts: 11h 41m 11s
  // ev: 11h 44m 0s
  // ts < ev => TRUE
  if ( current_ts < event_ts ){
    return true;
  }
  // if time looped at midnight
  // ts: 23h 57m 21s
  // ev: 0h 1m 0s
  // ts > ev => TRUE (for high to very low values )
  if( (current_ts - event_ts) > 600 && event_ts < 300 ) {
    return true;
  }
  // ts: 11h 44m 11s
  // ev: 11h 44m 0s
  // ts > ev => FALSE
  return false;
}


// NTP Callback
void timeavailable(struct timeval *t)
{
  Serial.println("NTP::Got time adjustment from NTP!");
  sntp_initialized = true;
  return;
}

// TIMER Callback
void IRAM_ATTR onTimer(){
  brun_scheduler = true;
}


void run_scheduler(){
  // Serial.println("onTimer::run");
  // Get the current time via NTP, or downgrade
  if ( sntp_initialized ){
    struct tm timeinfo;
    time_t now;
    time(&now);
    localtime_r(&now, &timeinfo);
    current_hour = timeinfo.tm_hour;
    current_minute = timeinfo.tm_min;
    current_second = timeinfo.tm_sec;

  // If no NTP clock
  }else{

    // Serial.println("onTimer::NO NTP");
    current_second += timer_interval_in_secs;
    if(current_second >= 60) {
      current_second = 0;
      current_minute += 1;
      if(current_minute >= 60) {
        current_minute = 0;
        current_hour += 1;
        if(current_hour >=  24) {
          current_hour = 0;
        }
      }
    }

  }

  // If not expected to run exit
  current_ts = get_timestamp( current_hour, current_minute, current_second );
  Serial.printf("onTimer::check event %d %d\n", current_ts, next_event_ts);
  if( event_keep_waiting( current_ts, next_event_ts  ) ){
    return;
  }

  // Set the next target
  next_event_ts = get_timestamp( current_hour, current_minute + EVENT_INC_MINUTE, current_second );
  Serial.println("Reconfigure the Relays!");

  // Run the relays reconfiguration
  for ( int i = 0; i < 2; i++ ) {
    // Get a pointer to the current array
    int* scheduler         = scheduler_list[i];
    unsigned int pin            = pin_list[i];
    // Set the expected status
    uint8_t minutes_by_5        = (current_minute / 5);
    int hourly_12_values   = scheduler[current_hour];
    // Serial.printf("Check hour(%d) >> minutes(%d x 5)\n", hourly_12_values, minutes_by_5);

    char buffer[40];

    if (( hourly_12_values >> minutes_by_5 ) & 1) {
      digitalWrite(pin, HIGH);
      sprintf (buffer, "Pin %d is up ", pin);
    } else {
      digitalWrite(pin, LOW);
      sprintf (buffer, "Pin %d is down ", pin);
    }
    Serial.println(buffer);    // Get the expected status
  }

  Serial.println("Reconfiguration over");
  return;
}

void setup(){

  // HARDWARE
  Serial.begin(115200);
  delay(1000);
  Serial.println("Starting.");
  pinMode(PIN_1, OUTPUT);
  pinMode(PIN_2, OUTPUT);
  // PREFERENCES
  Serial.println("Setup::PREFERENCES");
  preferences.begin(PREF_NAMESPACE, RW_MODE);
  preferences.clear();
 
  bool pref_init = preferences.isKey("test");
  if (pref_init == false) {
    Serial.println("preferences not exist");
    preferences.putBool("test", true);
    preferences.putBytes(RELAY_1_SCHEDULE, scheduler_1_default, sizeof(scheduler_1_default));
    preferences.putBytes(RELAY_2_SCHEDULE, scheduler_2_default, sizeof(scheduler_2_default));
    /// ... more to come
  }
  bool test = preferences.getBool("test");
  preferences.getBytes(RELAY_1_SCHEDULE, scheduler_1, preferences.getBytesLength(RELAY_1_SCHEDULE));
  preferences.getBytes(RELAY_2_SCHEDULE, scheduler_2, preferences.getBytesLength(RELAY_2_SCHEDULE));
  preferences.end();
  Serial.println("Setup::PREFERENCES::end");

  // WIFI
  Serial.println("Setup::WIFI");
  Serial.printf("Connecting to %s ", ssid);
  WiFi.begin(ssid, password);
  uint8_t wifi_loop_count = 0;
  while (WiFi.status() != WL_CONNECTED or wifi_loop_count < wifi_loop_max ) {
    delay(1000);   
    wifi_loop_count++;
    Serial.print(".");
  }
  
  // TIMER
  Serial.println("Setup::Timer");
  timer_main = timerBegin(0, 80, true);
  timerAttachInterrupt(timer_main, &onTimer, true);
  timerAlarmWrite(timer_main, timer_interval, true);
  timerAlarmEnable(timer_main);

  // NTP
  Serial.println("Setup::NTP");
  sntp_set_time_sync_notification_cb(timeavailable);
  configTime(gmtOffset_sec, daylightOffset_sec, ntpServer1, ntpServer2);
  delay(5000);

  // SCHEDULER
  Serial.println("Setup::SCHEDULER");
  next_event_ts = get_timestamp( HOUR_DEFAULT, MINUTE_DEFAULT, 10 );


  // HTTP
  Serial.println("Setup::HTTP");
  http_server.begin(); 
  Serial.print("Connect to IP Address: ");
  Serial.print("http://");
  Serial.println(WiFi.localIP());

  // Todo
}


void html() {
  http_client.println("HTTP/1.1 200 OK");
  http_client.println("Content-Type: text/html");
  http_client.println("Connection: close");
  http_client.println();

  http_client.println("<!DOCTYPE HTML>");
  http_client.println("<html>");
  http_client.println("</body>");
  http_client.println("</html>");
  
}

void loop(){

  if( brun_scheduler == true ){
    brun_scheduler = false;
    run_scheduler();
  }


  http_client = http_server.available();
  if (!http_client) {
    return;
  }

  while (http_client.connected()) {
    if (http_client.available()) {
      char c = http_client.read();

      request += c;

      if (c == '\n') {
        String postres = http_client.readString();
        int indp = postres.indexOf("progo=")+6;
        Serial.println(postres);
        Serial.println(request);


        html();
        break;
      }
    }
  }

  delay(1);
  request = "";
  http_client.stop();


}