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GY-63_MS5611/libraries/DHTlib/dht.cpp
Rob Tillaart d3791d6a17 0.1.36 DHTlib
2023-10-25 17:25:03 +02:00

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//
// FILE: dht.cpp
// AUTHOR: Rob Tillaart
// VERSION: 0.1.36
// PURPOSE: DHT Temperature & Humidity Sensor library for Arduino, AVR optimized
// URL: https://github.com/RobTillaart/DHTlib
// http://arduino.cc/playground/Main/DHTLib
//
// inspired by DHT11 library
#include "dht.h"
#define DHTLIB_DHT11_WAKEUP 18
#define DHTLIB_DHT_WAKEUP 1
#define DHTLIB_DHT11_LEADING_ZEROS 1
#define DHTLIB_DHT_LEADING_ZEROS 6
// max timeout is 100 microseconds.
// For a 16 MHz processor 100 microseconds is 1600 clock cycles
// loops using DHTLIB_TIMEOUT use at least 4 clock cycles
// so 100 us takes max 400 loops
// so by dividing F_CPU by 40000 we "fail" as fast as possible
#ifndef F_CPU
#define DHTLIB_TIMEOUT 1000 // should be approx. clock/40000
#else
#define DHTLIB_TIMEOUT (F_CPU/40000)
#endif
/////////////////////////////////////////////////////
//
// PUBLIC
//
int8_t dht::read11(uint8_t pin)
{
// READ VALUES
if (_disableIRQ) noInterrupts();
int8_t result = _readSensor(pin, DHTLIB_DHT11_WAKEUP, DHTLIB_DHT11_LEADING_ZEROS);
if (_disableIRQ) interrupts();
// these bits are always zero, masking them reduces errors.
bits[0] &= 0x7F;
bits[2] &= 0x7F;
// CONVERT AND STORE
humidity = bits[0]; // bits[1] == 0;
temperature = bits[2]; // bits[3] == 0;
// TEST CHECKSUM
uint8_t sum = bits[0] + bits[1] + bits[2] + bits[3];
if (bits[4] != sum)
{
return DHTLIB_ERROR_CHECKSUM;
}
return result;
}
int8_t dht::read12(uint8_t pin)
{
// READ VALUES
if (_disableIRQ) noInterrupts();
int8_t result = _readSensor(pin, DHTLIB_DHT11_WAKEUP, DHTLIB_DHT11_LEADING_ZEROS);
if (_disableIRQ) interrupts();
// CONVERT AND STORE
humidity = bits[0] + bits[1] * 0.1;
temperature = bits[2] + (bits[3] & 0x7F) * 0.1;
if (bits[3] & 0x80) // negative temperature
{
temperature = -temperature;
}
// TEST CHECKSUM
uint8_t sum = bits[0] + bits[1] + bits[2] + bits[3];
if (bits[4] != sum)
{
return DHTLIB_ERROR_CHECKSUM;
}
return result;
}
int8_t dht::read(uint8_t pin)
{
// READ VALUES
if (_disableIRQ) noInterrupts();
int8_t result = _readSensor(pin, DHTLIB_DHT_WAKEUP, DHTLIB_DHT_LEADING_ZEROS);
if (_disableIRQ) interrupts();
// these bits are always zero, masking them reduces errors.
bits[0] &= 0x03;
bits[2] &= 0x83;
// CONVERT AND STORE
humidity = (bits[0] * 256 + bits[1]) * 0.1;
int16_t t = ((bits[2] & 0x7F) * 256 + bits[3]);
if (t == 0)
{
temperature = 0.0; // prevent -0.0;
}
else
{
temperature = t * 0.1;
if((bits[2] & 0x80) == 0x80 )
{
temperature = -temperature;
}
}
// HEXDUMP DEBUG
/*
Serial.println();
// CHECKSUM
if (_bits[4] < 0x10) Serial.print(0);
Serial.print(_bits[4], HEX);
Serial.print(" ");
// TEMPERATURE
if (_bits[2] < 0x10) Serial.print(0);
Serial.print(_bits[2], HEX);
if (_bits[3] < 0x10) Serial.print(0);
Serial.print(_bits[3], HEX);
Serial.print(" ");
Serial.print(temperature, 1);
Serial.print(" ");
// HUMIDITY
if (_bits[0] < 0x10) Serial.print(0);
Serial.print(_bits[0], HEX);
if (_bits[1] < 0x10) Serial.print(0);
Serial.print(_bits[1], HEX);
Serial.print(" ");
Serial.print(humidity, 1);
*/
// TEST CHECKSUM
uint8_t sum = bits[0] + bits[1] + bits[2] + bits[3];
if (bits[4] != sum)
{
return DHTLIB_ERROR_CHECKSUM;
}
return result;
}
/////////////////////////////////////////////////////
//
// PRIVATE
//
int8_t dht::_readSensor(uint8_t pin, uint8_t wakeupDelay, uint8_t leadingZeroBits)
{
// INIT BUFFERVAR TO RECEIVE DATA
uint8_t mask = 128;
uint8_t idx = 0;
uint8_t data = 0;
uint8_t state = LOW;
uint8_t pstate = LOW;
uint16_t zeroLoop = DHTLIB_TIMEOUT;
uint16_t delta = 0;
leadingZeroBits = 40 - leadingZeroBits; // reverse counting...
// replace digitalRead() with Direct Port Reads.
// reduces footprint ~100 bytes => portability issue?
// direct port read is about 3x faster
uint8_t bit = digitalPinToBitMask(pin);
uint8_t port = digitalPinToPort(pin);
volatile uint8_t *PIR = portInputRegister(port);
// REQUEST SAMPLE
pinMode(pin, OUTPUT);
digitalWrite(pin, LOW); // T-be
if (wakeupDelay > 8) delay(wakeupDelay);
else delayMicroseconds(wakeupDelay * 1000UL);
digitalWrite(pin, HIGH); // T-go
pinMode(pin, INPUT);
uint16_t loopCount = DHTLIB_TIMEOUT * 2; // 200 uSec max
// while(digitalRead(pin) == HIGH)
while ((*PIR & bit) != LOW )
{
if (--loopCount == 0)
{
return DHTLIB_ERROR_CONNECT;
}
}
// GET ACKNOWLEDGE or TIMEOUT
loopCount = DHTLIB_TIMEOUT;
// while(digitalRead(pin) == LOW)
while ((*PIR & bit) == LOW ) // T-rel
{
if (--loopCount == 0)
{
return DHTLIB_ERROR_ACK_L;
}
}
loopCount = DHTLIB_TIMEOUT;
// while(digitalRead(pin) == HIGH)
while ((*PIR & bit) != LOW ) // T-reh
{
if (--loopCount == 0)
{
return DHTLIB_ERROR_ACK_H;
}
}
loopCount = DHTLIB_TIMEOUT;
// READ THE OUTPUT - 40 BITS => 5 BYTES
for (uint8_t i = 40; i != 0; )
{
// WAIT FOR FALLING EDGE
state = (*PIR & bit);
if (state == LOW && pstate != LOW)
{
if (i > leadingZeroBits) // DHT22 first 6 bits are all zero !! DHT11 only 1
{
zeroLoop = min(zeroLoop, loopCount);
delta = (DHTLIB_TIMEOUT - zeroLoop)/4;
}
else if ( loopCount <= (zeroLoop - delta) ) // long -> one
{
data |= mask;
}
mask >>= 1;
if (mask == 0) // next byte
{
mask = 128;
bits[idx] = data;
idx++;
data = 0;
}
// next bit
--i;
// reset timeout flag
loopCount = DHTLIB_TIMEOUT;
}
pstate = state;
// Check timeout
if (--loopCount == 0)
{
return DHTLIB_ERROR_TIMEOUT;
}
}
// pinMode(pin, OUTPUT);
// digitalWrite(pin, HIGH);
return DHTLIB_OK;
}
// -- END OF FILE --
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