thermo-bibli/code-grappe
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code-grappe/src/main.cpp

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// psswd's into include/secret.h
// others settings in main.h
#include "main.h"
using namespace std;
DHT sensors[SENSORS_NUMBER] = {DHT(4, DHT22), DHT(5, DHT22), DHT(18, DHT22), DHT(19, DHT22), DHT(03, DHT22)};
float temp[SENSORS_NUMBER];
float hum[SENSORS_NUMBER];
WiFiClient WifiClient;
PubSubClient MqttClient(WifiClient);
WiFiUDP NtpUDP;
NTPClient TimeClient(NtpUDP, "europe.pool.ntp.org", 0, 60000);
Pangodream_18650_CL Battery(ADC_PIN, CONV_FACTOR, READS);
RTC_DS3231 rtc;
//---------------- Réveil --------------------//
int mesure_freq = 600; // temps entre deux réveils en secondes
//-------------------- FONCTIONS --------------------//
//-------------- Connexion MQTT --------------//
void setupMQTT(const char *address, int port)
{
MqttClient.setServer(address, port);
}
void setupWIFI(const char *wifi_name, const char *password)
{
Serial.println('\n');
WiFi.begin(wifi_name, password);
Serial.print("Connecting to ");
Serial.print(wifi_name);
while ((WiFi.status() != WL_CONNECTED) && (millis() <= 60000))
{
Serial.println("Nouvelle tentative de connexion...");
delay(500);
Serial.print('.');
}
Serial.println('\n');
Serial.println("Connection established!");
Serial.print("IP address:\t");
Serial.println(WiFi.localIP());
}
void reconnect(void)
{
Serial.println("Connecting to MQTT Broker...");
while (!MqttClient.connected())
{
Serial.print(".");
if (MqttClient.connect(ESPNAME, MQTT_USER, MQTT_MDP))
{
Serial.println("Connected.");
}
}
}
//-------------- Initialisation et lecture des capteurs --------------//
void initSensors(DHT *sensors, int number)
{
int i;
for (i = 0; i < number; i++)
{
sensors[i].begin();
}
}
void readSensors(DHT sensors[], float temp[], float hum[], int number)
{
int i;
for (i = 0; i < number; i++)
{
*(temp + i) = sensors[i].readTemperature();
*(hum + i) = sensors[i].readHumidity();
}
}
//-------------------- Sleep de l'ESP --------------------//
/*
void sleep()
{
esp_sleep_enable_timer_wakeup(TIME_TO_SLEEP * US_TO_S_FACTOR);
esp_deep_sleep_start();
}
//exemple d'une triple utilisation de valeur pour une fonction utilise pour la date
std::tuple<int, int, int> getDate()
{
time_t rawtime = TimeClient.getEpochTime();
struct tm *ti;
ti = localtime(&rawtime);
int year = ti->tm_year + 1900;
int month = (ti->tm_mon + 1) < 10 ? 0 + (ti->tm_mon + 1) : (ti->tm_mon + 1);
int day = (ti->tm_mday) < 10 ? 0 + (ti->tm_mday) : (ti->tm_mday);
return std::make_tuple(year, month, day);
}
*/
//-------------------- Programmation du réveil de l'alimentation --------------------//
void wakeup(){
// initializing the rtc
if(!rtc.begin()) {
Serial.println("Couldn't find RTC!");
Serial.flush();
while (1) delay(10);
}
if(rtc.lostPower()) {
// this will adjust to the date and time at compilation
rtc.adjust(DateTime(F(__DATE__), F(__TIME__)));
}
//we don't need the 32K Pin, so disable it
rtc.disable32K();
// set alarm 1, 2 flag to false (so alarm 1, 2 didn't happen so far)
// if not done, this easily leads to problems, as both register aren't reset on reboot/recompile
rtc.clearAlarm(1);
rtc.clearAlarm(2);
// stop oscillating signals at SQW Pin
// otherwise setAlarm1 will fail
rtc.writeSqwPinMode(DS3231_OFF);
// turn off alarm 2 (in case it isn't off already)
// again, this isn't done at reboot, so a previously set alarm could easily go overlooked
rtc.disableAlarm(2);
// schedule an alarm 10 seconds in the future
if(!rtc.setAlarm1(
rtc.now() + TimeSpan(mesure_freq),
DS3231_A1_Second // this mode triggers the alarm when the seconds match. See Doxygen for other options
)) {
Serial.println("Error, alarm wasn't set!");
}else {
Serial.println("Alarm will happen in 10 seconds!");
}
}
//-------------------- Création de trames --------------------//
void writeMessage(char *txt, float *temp, float *hum, int number)
{
int chargelvl = Battery.getBatteryChargeLevel();
switch (number)
{
case 1:
sprintf(txt, "|%s|%0.2f|%0.2f", CLUSTER, temp[0], hum[0]);
break;
case 2:
sprintf(txt, "|%s|%0.2f %0.2f|%0.2f %0.2f", CLUSTER, temp[0], temp[1], hum[0], hum[1]);
break;
case 3:
sprintf(txt, "|%s|%0.2f %0.2f %0.2f|%0.2f %0.2f %0.2f", CLUSTER, temp[0], temp[1], temp[2], hum[0], hum[1], hum[2]);
break;
case 4:
sprintf(txt, "|%s|%0.2f %0.2f %0.2f %0.2f|%0.2f %0.2f %0.2f %0.2f", CLUSTER, temp[0], temp[1], temp[2], temp[3], hum[0], hum[1], hum[2], hum[3]);
break;
case 5:
sprintf(txt, "|%s|%0.2f %0.2f %0.2f %0.2f %0.2f|%0.2f %0.2f %0.2f %0.2f %0.2f|%d", CLUSTER, temp[0], temp[1], temp[2], temp[3], temp[4], hum[0], hum[1], hum[2], hum[3], hum[4], chargelvl);
break;
case 6:
sprintf(txt, "|%s|%0.2f %0.2f %0.2f %0.2f %0.2f %0.2f|%0.2f %0.2f %0.2f %0.2f %0.2f %0.2f", CLUSTER, temp[0], temp[1], temp[2], temp[3], temp[4], temp[5], hum[0], hum[1], hum[2], hum[3], hum[4], hum[5]);
break;
default:
Serial.println("Erreur, temp et hum sont trop longs : trop de capteurs");
break;
}
}
//-------------------- Initialisation --------------------//
void setup()
{
Serial.begin(9600);
setupWIFI(SSID, SSID_PWD);
setupMQTT(MQTT_ADDRESS, MQTT_PORT);
initSensors(sensors, SENSORS_NUMBER);
TimeClient.begin();
delay(2000);
}
//-------------------- Boucle pringicipale --------------------//
void loop()
{
int year, month, day;
int lenght;
char time[30];
char date[30];
char msg[70];
MqttClient.loop();
if (!MqttClient.connected())
{
reconnect();
}
readSensors(sensors, temp, hum, SENSORS_NUMBER);
writeMessage(msg, temp, hum, SENSORS_NUMBER);
Serial.print("une trame de data : ");
Serial.println(msg);
TimeClient.update();
TimeClient.getFormattedTime().toCharArray(time, 30);
tie(year, month, day) = getDate();
lenght = sprintf(date, "%d-%d-%d ", year, month, day);
sprintf(date + lenght, time);
sprintf(date + strlen(date), msg);
MqttClient.publish(TOPIC, date);
delay(2000);
Serial.println("Extinction de l'ESP ! ");
wakeup();
}
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