2020-05-28 02:20:02 +02:00
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#pragma once
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#include "wled.h"
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2021-05-07 12:41:39 +02:00
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#include "OneWire.h"
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2020-05-28 02:20:02 +02:00
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2021-05-07 12:41:39 +02:00
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//Pin defaults for QuinLed Dig-Uno if not overriden
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2021-01-17 15:00:14 +01:00
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#ifndef TEMPERATURE_PIN
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2021-05-07 12:41:39 +02:00
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#ifdef ARDUINO_ARCH_ESP32
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#define TEMPERATURE_PIN 18
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#else //ESP8266 boards
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#define TEMPERATURE_PIN 14
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#endif
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2021-01-17 15:00:14 +01:00
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#endif
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2020-05-28 02:20:02 +02:00
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2020-09-13 19:26:27 +02:00
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// the frequency to check temperature, 1 minute
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#ifndef USERMOD_DALLASTEMPERATURE_MEASUREMENT_INTERVAL
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#define USERMOD_DALLASTEMPERATURE_MEASUREMENT_INTERVAL 60000
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#endif
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2020-05-28 02:20:02 +02:00
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2020-09-13 19:26:27 +02:00
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// how many seconds after boot to take first measurement, 20 seconds
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#ifndef USERMOD_DALLASTEMPERATURE_FIRST_MEASUREMENT_AT
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#define USERMOD_DALLASTEMPERATURE_FIRST_MEASUREMENT_AT 20000
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2020-09-13 19:26:27 +02:00
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#endif
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2020-05-28 02:20:02 +02:00
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class UsermodTemperature : public Usermod {
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2020-05-28 02:20:02 +02:00
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private:
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bool initDone = false;
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OneWire *oneWire;
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// GPIO pin used for sensor (with a default compile-time fallback)
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int8_t temperaturePin = TEMPERATURE_PIN;
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// measurement unit (true==°C, false==°F)
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bool degC = true;
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unsigned long readingInterval = USERMOD_DALLASTEMPERATURE_MEASUREMENT_INTERVAL;
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2020-09-13 19:26:27 +02:00
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// set last reading as "40 sec before boot", so first reading is taken after 20 sec
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unsigned long lastMeasurement = UINT32_MAX - (USERMOD_DALLASTEMPERATURE_MEASUREMENT_INTERVAL - USERMOD_DALLASTEMPERATURE_FIRST_MEASUREMENT_AT);
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// last time requestTemperatures was called
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// used to determine when we can read the sensors temperature
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// we have to wait at least 93.75 ms after requestTemperatures() is called
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unsigned long lastTemperaturesRequest;
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float temperature = -100; // default to -100, DS18B20 only goes down to -50C
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// indicates requestTemperatures has been called but the sensor measurement is not complete
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bool waitingForConversion = false;
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// flag to indicate we have finished the first readTemperature call
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2020-09-13 19:26:27 +02:00
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// allows this library to report to the user how long until the first
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// measurement
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bool readTemperatureComplete = false;
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// flag set at startup if DS18B20 sensor not found, avoids trying to keep getting
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// temperature if flashed to a board without a sensor attached
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bool disabled = false;
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2021-05-07 12:41:39 +02:00
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// strings to reduce flash memory usage (used more than twice)
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static const char _name[];
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static const char _enabled[];
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static const char _readInterval[];
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//Dallas sensor quick (& dirty) reading. Credit to - Author: Peter Scargill, August 17th, 2013
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int16_t readDallas() {
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byte i;
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byte data[2];
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int16_t result; // raw data from sensor
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oneWire->reset();
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oneWire->write(0xCC); // skip ROM
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oneWire->write(0xBE); // read (temperature) from EEPROM
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for (i=0; i < 2; i++) data[i] = oneWire->read(); // first 2 bytes contain temperature
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for (i=2; i < 8; i++) oneWire->read(); // read unused bytes
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result = (data[1]<<8) | data[0];
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result >>= 4; // 9-bit precision accurate to 1°C (/16)
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if (data[1]&0x80) result |= 0xF000; // fix negative value
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//if (data[0]&0x08) ++result;
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oneWire->reset();
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oneWire->write(0xCC); // skip ROM
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oneWire->write(0x44,0); // request new temperature reading (without parasite power)
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return result;
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}
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void requestTemperatures() {
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readDallas();
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lastTemperaturesRequest = millis();
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waitingForConversion = true;
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DEBUG_PRINTLN(F("Requested temperature."));
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}
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void readTemperature() {
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temperature = readDallas();
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lastMeasurement = millis();
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waitingForConversion = false;
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readTemperatureComplete = true;
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DEBUG_PRINTF("Read temperature %2.1f.\n", temperature);
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2020-05-28 02:20:02 +02:00
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}
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bool findSensor() {
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DEBUG_PRINTLN(F("Searching for sensor..."));
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uint8_t deviceAddress[8] = {0,0,0,0,0,0,0,0};
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// find out if we have DS18xxx sensor attached
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oneWire->reset_search();
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while (oneWire->search(deviceAddress)) {
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if (oneWire->crc8(deviceAddress, 7) == deviceAddress[7]) {
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switch (deviceAddress[0]) {
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case 0x10: // DS18S20
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case 0x22: // DS18B20
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case 0x28: // DS1822
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case 0x3B: // DS1825
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case 0x42: // DS28EA00
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DEBUG_PRINTLN(F("Sensor found."));
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return true;
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}
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}
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}
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return false;
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}
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public:
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2020-05-28 02:20:02 +02:00
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void setup() {
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int retries = 10;
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// pin retrieved from cfg.json (readFromConfig()) prior to running setup()
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if (!pinManager.allocatePin(temperaturePin,false)) {
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temperaturePin = -1; // allocation failed
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disabled = true;
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DEBUG_PRINTLN(F("Temperature pin allocation failed."));
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} else {
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if (!disabled) {
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// config says we are enabled
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oneWire = new OneWire(temperaturePin);
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if (!oneWire->reset())
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disabled = true; // resetting 1-Wire bus yielded an error
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else
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while ((disabled=!findSensor()) && retries--) delay(25); // try to find sensor
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}
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2020-09-13 19:26:27 +02:00
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}
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initDone = true;
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2020-05-28 02:20:02 +02:00
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}
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void loop() {
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2021-01-21 01:21:16 +01:00
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if (disabled || strip.isUpdating()) return;
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2020-09-13 19:26:27 +02:00
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unsigned long now = millis();
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// check to see if we are due for taking a measurement
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// lastMeasurement will not be updated until the conversion
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// is complete the the reading is finished
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if (now - lastMeasurement < readingInterval) return;
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2020-09-13 19:26:27 +02:00
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2021-05-07 12:41:39 +02:00
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// we are due for a measurement, if we are not already waiting
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// for a conversion to complete, then make a new request for temps
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if (!waitingForConversion) {
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requestTemperatures();
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return;
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}
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2020-09-13 19:26:27 +02:00
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// we were waiting for a conversion to complete, have we waited log enough?
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if (now - lastTemperaturesRequest >= 100 /* 93.75ms per the datasheet but can be up to 750ms */) {
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readTemperature();
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2020-05-28 02:20:02 +02:00
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if (WLED_MQTT_CONNECTED) {
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char subuf[64];
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strcpy(subuf, mqttDeviceTopic);
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if (-100 <= temperature) {
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// dont publish super low temperature as the graph will get messed up
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// the DallasTemperature library returns -127C or -196.6F when problem
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// reading the sensor
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strcat_P(subuf, PSTR("/temperature"));
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mqtt->publish(subuf, 0, false, String(temperature).c_str());
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strcat_P(subuf, PSTR("_f"));
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mqtt->publish(subuf, 0, false, String((float)temperature * 1.8f + 32).c_str());
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} else {
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// publish something else to indicate status?
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}
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}
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}
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}
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2021-05-07 12:41:39 +02:00
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/*
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* API calls te enable data exchange between WLED modules
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*/
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inline float getTemperatureC() {
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return (float)temperature;
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}
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inline float getTemperatureF() {
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return (float)temperature * 1.8f + 32;
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}
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/*
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* addToJsonInfo() can be used to add custom entries to the /json/info part of the JSON API.
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* Creating an "u" object allows you to add custom key/value pairs to the Info section of the WLED web UI.
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* Below it is shown how this could be used for e.g. a light sensor
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*/
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void addToJsonInfo(JsonObject& root) {
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// dont add temperature to info if we are disabled
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if (disabled) return;
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JsonObject user = root["u"];
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if (user.isNull()) user = root.createNestedObject("u");
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JsonArray temp = user.createNestedArray(FPSTR(_name));
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//temp.add(F("Loaded."));
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if (!readTemperatureComplete) {
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// if we haven't read the sensor yet, let the user know
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// that we are still waiting for the first measurement
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temp.add((USERMOD_DALLASTEMPERATURE_FIRST_MEASUREMENT_AT - millis()) / 1000);
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temp.add(F(" sec until read"));
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return;
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}
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if (temperature <= -100) {
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temp.add(0);
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temp.add(F(" Sensor Error!"));
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return;
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}
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temp.add(degC ? temperature : (float)temperature * 1.8f + 32);
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if (degC) temp.add(F("°C"));
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else temp.add(F("°F"));
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}
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/**
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* addToJsonState() can be used to add custom entries to the /json/state part of the JSON API (state object).
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* Values in the state object may be modified by connected clients
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*/
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//void addToJsonState(JsonObject &root)
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//{
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//}
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/**
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* readFromJsonState() can be used to receive data clients send to the /json/state part of the JSON API (state object).
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* Values in the state object may be modified by connected clients
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* Read "<usermodname>_<usermodparam>" from json state and and change settings (i.e. GPIO pin) used.
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*/
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//void readFromJsonState(JsonObject &root) {
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// if (!initDone) return; // prevent crash on boot applyPreset()
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//}
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/**
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* addToConfig() (called from set.cpp) stores persistent properties to cfg.json
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*/
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void addToConfig(JsonObject &root) {
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// we add JSON object: {"Temperature": {"pin": 0, "degC": true}}
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JsonObject top = root.createNestedObject(FPSTR(_name)); // usermodname
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top[FPSTR(_enabled)] = !disabled;
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top["pin"] = temperaturePin; // usermodparam
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top["degC"] = degC; // usermodparam
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top[FPSTR(_readInterval)] = readingInterval / 1000;
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DEBUG_PRINTLN(F("Temperature config saved."));
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}
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/**
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* readFromConfig() is called before setup() to populate properties from values stored in cfg.json
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*/
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void readFromConfig(JsonObject &root) {
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// we look for JSON object: {"Temperature": {"pin": 0, "degC": true}}
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JsonObject top = root[FPSTR(_name)];
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int8_t newTemperaturePin = temperaturePin;
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if (!top.isNull() && top["pin"] != nullptr) {
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if (top[FPSTR(_enabled)].is<bool>()) {
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disabled = !top[FPSTR(_enabled)].as<bool>();
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} else {
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String str = top[FPSTR(_enabled)]; // checkbox -> off or on
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disabled = (bool)(str=="off"); // off is guaranteed to be present
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}
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newTemperaturePin = min(39,max(-1,top["pin"].as<int>()));
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if (top["degC"].is<bool>()) {
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// reading from cfg.json
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degC = top["degC"].as<bool>();
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} else {
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// new configuration from set.cpp
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String str = top["degC"]; // checkbox -> off or on
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degC = (bool)(str!="off"); // off is guaranteed to be present
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}
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readingInterval = min(120,max(10,top[FPSTR(_readInterval)].as<int>())) * 1000; // convert to ms
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DEBUG_PRINTLN(F("Temperature config (re)loaded."));
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} else {
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DEBUG_PRINTLN(F("No config found. (Using defaults.)"));
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}
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if (!initDone) {
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// first run: reading from cfg.json
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temperaturePin = newTemperaturePin;
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} else {
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// changing paramters from settings page
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if (newTemperaturePin != temperaturePin) {
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// deallocate pin and release memory
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delete oneWire;
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pinManager.deallocatePin(temperaturePin);
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temperaturePin = newTemperaturePin;
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// initialise
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setup();
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}
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}
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}
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uint16_t getId()
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{
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return USERMOD_ID_TEMPERATURE;
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}
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};
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// strings to reduce flash memory usage (used more than twice)
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const char UsermodTemperature::_name[] PROGMEM = "Temperature";
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const char UsermodTemperature::_enabled[] PROGMEM = "enabled";
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const char UsermodTemperature::_readInterval[] PROGMEM = "read-interval-s";
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