mh
/
mhsw-espurna


								/*


								DHT MODULE


								Copyright (C) 2016-2017 by Xose Pérez <xose dot perez at gmail dot com>


								*/


								#if DHT_SUPPORT


								double _dhtTemperature = 0;

								unsigned int _dhtHumidity = 0;


								// -----------------------------------------------------------------------------

								// HAL

								// https://github.com/gosouth/DHT22/blob/master/main/DHT22.c

								// -----------------------------------------------------------------------------


								#define DHT_MAX_DATA                5

								#define DHT_MAX_ERRORS              5

								#define DHT_MIN_INTERVAL            2000

								#define DHT_OK                      0

								#define DHT_CHECKSUM_ERROR          -1

								#define DHT_TIMEOUT_ERROR           -2


								#define DHT11                       11

								#define DHT22                       22

								#define DHT21                       21

								#define AM2301                      21


								unsigned long _getSignalLevel(unsigned char gpio, int usTimeOut, bool state) {

									unsigned long uSec = 1;

									while (digitalRead(gpio) == state) {

								        if (++uSec > usTimeOut) return 0;

								        delayMicroseconds(1);

									}

									return uSec;

								}


								int readDHT(unsigned char gpio, unsigned char type) {


								    static unsigned long last_ok = 0;

								    if (millis() - last_ok < DHT_MIN_INTERVAL) return DHT_OK;


								    unsigned long low = 0;

								    unsigned long high = 0;


								    static unsigned char errors = 0;

								    uint8_t dhtData[DHT_MAX_DATA] = {0};

								    uint8_t byteInx = 0;

								    uint8_t bitInx = 7;


									// Send start signal to DHT sensor

									if (++errors > DHT_MAX_ERRORS) {

								        errors = 0;

								        digitalWrite(gpio, HIGH);

								        delay(250);

								    }

								    pinMode(gpio, OUTPUT);

									digitalWrite(gpio, LOW);

									delay(20);

								    noInterrupts();

								    digitalWrite(gpio, HIGH);

								    delayMicroseconds(40);

								    pinMode(gpio, INPUT_PULLUP);

								    delayMicroseconds(10);


									// DHT will keep the line low for 80 us and then high for 80us

									low = _getSignalLevel(gpio, 85, LOW);

									if (low==0) return DHT_TIMEOUT_ERROR;

									high = _getSignalLevel(gpio, 85, HIGH);

								    if (high==0) return DHT_TIMEOUT_ERROR;


									// No errors, read the 40 data bits

									for( int k = 0; k < 40; k++ ) {


										// Starts new data transmission with >50us low signal

										low = _getSignalLevel(gpio, 56, LOW);

										if (low==0) return DHT_TIMEOUT_ERROR;


										// Check to see if after >70us rx data is a 0 or a 1

										high = _getSignalLevel(gpio, 75, HIGH);

								        if (high==0) return DHT_TIMEOUT_ERROR;


										// add the current read to the output data

										// since all dhtData array where set to 0 at the start,

										// only look for "1" (>28us us)

										if (high > low) dhtData[byteInx] |= (1 << bitInx);


										// index to next byte

										if (bitInx == 0) {

								            bitInx = 7;

								            ++byteInx;

								        } else {

								    		--bitInx;

								        }


									}


								    interrupts();


								    // Verify checksum

								    if (dhtData[4] != ((dhtData[0] + dhtData[1] + dhtData[2] + dhtData[3]) & 0xFF)) {

								        return DHT_CHECKSUM_ERROR;

								    }


									// Get humidity from Data[0] and Data[1]

								    if (type == DHT11) {

								        _dhtHumidity = dhtData[0];

								    } else {

									   _dhtHumidity = dhtData[0] * 256 + dhtData[1];

									   _dhtHumidity /= 10;

								    }


									// Get temp from Data[2] and Data[3]

								    if (type == DHT11) {

								        _dhtTemperature = dhtData[2];

								    } else {

								        _dhtTemperature = (dhtData[2] & 0x7F) * 256 + dhtData[3];

								        _dhtTemperature /= 10;

								        if (dhtData[2] & 0x80) _dhtTemperature *= -1;

								    }


								    last_ok = millis();

								    errors = 0;

									return DHT_OK;


								}


								int readDHT() {

								    return readDHT(DHT_PIN, DHT_TYPE);

								}


								// -----------------------------------------------------------------------------

								// Private

								// -----------------------------------------------------------------------------


								void _dhtWebSocketOnSend(JsonObject& root) {

								    root["dhtVisible"] = 1;

								    root["dhtTmp"] = getDHTTemperature();

								    root["dhtHum"] = getDHTHumidity();

								}


								// -----------------------------------------------------------------------------

								// Values

								// -----------------------------------------------------------------------------


								double getDHTTemperature(bool celsius) {

								    double value = celsius ? _dhtTemperature : _dhtTemperature * 1.8 + 32;

								    double correction = getSetting("tmpCorrection", TEMPERATURE_CORRECTION).toFloat();

								    return roundTo(value + correction, DHT_TEMPERATURE_DECIMALS);

								}


								double getDHTTemperature() {

								    return getDHTTemperature(true);

								}


								unsigned int getDHTHumidity() {

								    return _dhtHumidity;

								}


								void dhtSetup() {


								    #if WEB_SUPPORT


								        // Websockets

								        wsOnSendRegister(_dhtWebSocketOnSend);


								        apiRegister(DHT_TEMPERATURE_TOPIC, DHT_TEMPERATURE_TOPIC, [](char * buffer, size_t len) {

								            dtostrf(_dhtTemperature, 1-len, 1, buffer);

								        });

								        apiRegister(DHT_HUMIDITY_TOPIC, DHT_HUMIDITY_TOPIC, [](char * buffer, size_t len) {

								            snprintf_P(buffer, len, PSTR("%d"), _dhtHumidity);

								        });


								    #endif


								}


								void dhtLoop() {


								    // Check if we should read new data

								    static unsigned long last_update = 0;

								    if ((millis() - last_update > DHT_UPDATE_INTERVAL) || (last_update == 0)) {

								        last_update = millis();


								        // Read sensor data

								        if (readDHT(DHT_PIN, DHT_TYPE) == DHT_OK) {


								            unsigned char tmpUnits = getSetting("tmpUnits", TMP_UNITS).toInt();

								            double t = getDHTTemperature(tmpUnits == TMP_CELSIUS);

								            unsigned int h = getDHTHumidity();


								            char temperature[6];

								            char humidity[6];

								            dtostrf(t, 1-sizeof(temperature), 1, temperature);

								            itoa((unsigned int) h, humidity, 10);


								            DEBUG_MSG_P(PSTR("[DHT] Temperature: %s%s\n"), temperature, (tmpUnits == TMP_CELSIUS) ? "ºC" : "ºF");

								            DEBUG_MSG_P(PSTR("[DHT] Humidity: %s\n"), humidity);


								            // Send MQTT messages

								            mqttSend(getSetting("dhtTmpTopic", DHT_TEMPERATURE_TOPIC).c_str(), temperature);

								            mqttSend(getSetting("dhtHumTopic", DHT_HUMIDITY_TOPIC).c_str(), humidity);


								            // Send to Domoticz

								            #if DOMOTICZ_SUPPORT

								            {

								                domoticzSend("dczTmpIdx", 0, temperature);

								                int status;

								                if (h > 70) {

								                    status = HUMIDITY_WET;

								                } else if (h > 45) {

								                    status = HUMIDITY_COMFORTABLE;

								                } else if (h > 30) {

								                    status = HUMIDITY_NORMAL;

								                } else {

								                    status = HUMIDITY_DRY;

								                }

								                char buffer[2];

								                snprintf_P(buffer, sizeof(buffer), PSTR("%d"), status);

								                domoticzSend("dczHumIdx", humidity, buffer);

								            }

								            #endif


								            #if INFLUXDB_SUPPORT

								                idbSend(getSetting("dhtTmpTopic", DHT_TEMPERATURE_TOPIC).c_str(), temperature);

								                idbSend(getSetting("dhtHumTopic", DHT_HUMIDITY_TOPIC).c_str(), humidity);

								            #endif


								            // Update websocket clients

								            #if WEB_SUPPORT

								                char buffer[100];

								                snprintf_P(buffer, sizeof(buffer), PSTR("{\"dhtVisible\": 1, \"dhtTmp\": %s, \"dhtHum\": %s, \"tmpUnits\": %d}"), temperature, humidity, tmpUnits);

								                wsSend(buffer);

								            #endif


								        }


								    }


								}


								#endif