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Eeprom.ino
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Eeprom.ino
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//Memory:
// 0: memAlok
// 1: device
// 2: sleep mode
// 3: wifi ready
// 4: WiFi AP switch
// 5: analogSW
// 6: sensorAnalog
// 7: sensorDigital
// 8: sensorDigital2
// 9: startS1
// 10: startS2
// 11: stayoffS1
// 12: stayoffS2
// 13: milis pulseTime
// 14: seconds pulseTime
// 15: minutes pulseTime
// 16: hours pulseTime
// 17: milis pulseTime2
// 18: seconds pulseTime2
// 19: minutes pulseTime2
// 20: hours pulseTime2
// 21: brightness light
// 22: brightness leds
// 23: current calibration high
// 24: light effect
// 25: led mode
// 26: threshold1 light
// 27: threshold2 sound
// 28: current calibration low
// 29: resistance
// 30: motor speed
// 31-35: wifi AP name
// 36-50: wifi name
// 51-65: wifi password
// 66-90: mqtt server
// 91-105: mqtt user
//106-120: mqtt password
//121-135: ota password
//136-150: device name
//151-165: server address
//166: temperature correction
//167: humidity correction
//168: remote update off
//169: motor when stopped keep powered
//170-175: web password
//176: min (moister dry, light night)
//177: max (moister wet, light day)
//178: current threshold low
//179: current threshold high
//180: motor speed multiplier (higher get lower speed)
void eeprom_begin() {
mem.begin();
device = mem.readAndCheck(device, 1, "devicePurpose", 1, 9);
sleepMode = mem.readAndCheck(sleepMode, 2, "sleepMode", 0, 2);
report("wifi: " + String(mem.read(3)) );
wi_fi.switchAP = mem.readAndCheck(wi_fi.switchAP, 4, "wifiSwitch", 0, 2);
updateStart = mem.readAndCheck(1, 168, "updateRemote", 0, 1);
analogSW = mem.readAndCheck(analogSW, 5, "analogSwitch", 0, 3);
sensorAnalog = mem.readAndCheck(sensorAnalog, 6, "sensorAnalog", 0, 11);
sensorDigital1 = mem.readAndCheck(sensorDigital1, 7, "sensorDigital", 0, 9);
sensorDigital2 = mem.readAndCheck(sensorDigital2, 8, "sensorDigital2", 0, 6);
relay.startS1 = mem.readAndCheck(relay.startS1, 9, "startState1", 0, 1);
relay.startS2 = mem.readAndCheck(relay.startS2, 10, "startState2", 0, 1);
relay.stayoffS1 = mem.readAndCheck(relay.stayoffS1, 11, "stayOff1", 0, 3);
relay.stayoffS2 = mem.readAndCheck(relay.stayoffS2, 12, "stayOff2", 0, 3);
relay.timePulse1 = createPulseTime(mem.read(13), mem.read(14), mem.read(15), mem.read(16));
relay.timePulse2 = createPulseTime(mem.read(17), mem.read(18), mem.read(19), mem.read(20));
relay.light.brightness = mem.readAndCheck(relay.light.brightness, 21, "brightnessLight", 0, 254);
relay.diodBright = mem.readAndCheck(relay.diodBright, 22, "brightnessDiod", 0, 177);
relay.light.effect = mem.readAndCheck(relay.light.effect, 24, "lightEffect", 0, 4);
relay.diodLight = mem.readAndCheck(relay.diodLight, 25, "diodMode", 0, 3);
threshold1 = mem.readAndCheck(25, 26, "threshold1", 1, 99);
sound.threshold = mem.readAndCheck(sound.threshold, 27, "thresholdSound", 0, 1024);
ampere.zeroPoint = mem.readAndCheck(ampere.zeroPoint, 28, 23, "ampereZeroPoint");
ampere.threshold = mem.readAndCheck(ampere.threshold, 178, 179, "ampereSwitchThreshold");
potentiometer.resistance(mem.readAndCheck(potentiometer.resistance(), 29, "resistance", 0, 99));
wi_fi.nameAP = mem.readAndCheck("", "wifiAPname", 31, 35, false);
wi_fi.ssid = mem.readAndCheck(wi_fi.ssid, "wifiSSID", 36, 50, false);
wi_fi.password = mem.readAndCheck(wi_fi.password, "wifiPass", 51, 65, true);
if (wi_fi.password != "") newWIFIpass = "*";
mqtt_server = mem.readAndCheck(mqtt_server, "MQTTserver", 66, 90, false);
mqtt_user = mem.readAndCheck(mqtt_user, "MQTTuser", 91, 105, false);
mqtt_password = mem.readAndCheck(mqtt_password, "MQTTpass", 106, 120, true);
if (mqtt_password != "") newMQTTpass = "*";
OTA_password = mem.readAndCheck(OTA_password, "OTApass", 121, 135, true);
if (OTA_password != "") newOTApass = "*";
deviceName = mem.readAndCheck(deviceName, "deviceName", 136, 150, false);
update_server = mem.readAndCheck(update_server, "updateServer", 151, 165, false);
termistor.fixTemperature = mem.readAndCheck(0, 166, "fixTemperature", 0, 99) / 10.0;
termistor.fixHumidity = mem.readAndCheck(termistor.fixHumidity, 167, "fixHumidity", 0, 25);
motor.speed(mem.readAndCheck(motor.speed(), 30, "motorSpeed", 4, 1024));
motor.disabled = mem.readAndCheck(0, 169, "motorDisabled", 0, 1);
motor.multiplier = mem.readAndCheck(motor.multiplier, 180, "motorMultiplier", 25, 85);
analog.min = mem.readAndCheck(analog.min, 176, "minAnalog", 0, 1024);
analog.max = mem.readAndCheck(analog.max, 177, "maxAnalog", 0, 1024);
}
/////////////////////////////
//// Create Pulse Time /////
/////////////////////////////
long createPulseTime(int milis, int seconds, int minutes, int hours) {
long pulse = 0;
if (milis != 0) {
pulse += milis;
report("milis: " + String(milis));
}
if (seconds != 0) {
pulse += seconds*1000UL;
report("seconds: " + String(seconds));
}
if (minutes != 0) {
pulse += minutes*60*1000UL;
report("minutes: " + String(minutes));
}
if (hours != 0) {
pulse += hours*60*60*1000UL;
report("hours: " + String(hours));
}
report("pulseTime: " + String(pulse));
return pulse;
}
////////////////////////////////////
//// Is Movement Sensor Active /////
////////////////////////////////////
bool IsMotionSensor() {
if (sensorAnalog == 1 or sensorDigital1 == 1 or sensorDigital2 == 1) {
return true;
} else {
return false;
}
}
/////////////////////////
//// Byte to String /////
/////////////////////////
String byteToString(int value) {
return String(char(value));
}