5c9405fffc
- min PWM value (%) - IRQs per rotation
333 lines
12 KiB
C++
333 lines
12 KiB
C++
#pragma once
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#ifndef USERMOD_DALLASTEMPERATURE
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#error The "PWM fan" usermod requires "Dallas Temeprature" usermod to function properly.
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#endif
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#include "wled.h"
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// PWM & tacho code curtesy of @KlausMu
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// https://github.com/KlausMu/esp32-fan-controller/tree/main/src
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// adapted for WLED usermod by @blazoncek
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// tacho counter
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static volatile unsigned long counter_rpm = 0;
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// Interrupt counting every rotation of the fan
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// https://desire.giesecke.tk/index.php/2018/01/30/change-global-variables-from-isr/
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static void IRAM_ATTR rpm_fan() {
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counter_rpm++;
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}
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class PWMFanUsermod : public Usermod {
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private:
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bool initDone = false;
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bool enabled = true;
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unsigned long msLastTachoMeasurement = 0;
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uint16_t last_rpm = 0;
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#ifdef ARDUINO_ARCH_ESP32
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uint8_t pwmChannel = 255;
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#endif
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#ifdef USERMOD_DALLASTEMPERATURE
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UsermodTemperature* tempUM;
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#endif
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// configurable parameters
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int8_t tachoPin = -1;
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int8_t pwmPin = -1;
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uint8_t tachoUpdateSec = 30;
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float targetTemperature = 25.0;
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uint8_t minPWMValuePct = 50;
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uint8_t numberOfInterrupsInOneSingleRotation = 2; // Number of interrupts ESP32 sees on tacho signal on a single fan rotation. All the fans I've seen trigger two interrups.
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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 _tachoPin[];
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static const char _pwmPin[];
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static const char _temperature[];
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static const char _tachoUpdateSec[];
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static const char _minPWMValuePct[];
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static const char _IRQperRotation[];
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void initTacho(void) {
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if (tachoPin < 0 || !pinManager.allocatePin(tachoPin, false, PinOwner::UM_Unspecified)){
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tachoPin = -1;
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return;
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}
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pinMode(tachoPin, INPUT);
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digitalWrite(tachoPin, HIGH);
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attachInterrupt(digitalPinToInterrupt(tachoPin), rpm_fan, FALLING);
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DEBUG_PRINTLN(F("Tacho sucessfully initialized."));
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}
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void deinitTacho(void) {
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if (tachoPin < 0) return;
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detachInterrupt(digitalPinToInterrupt(tachoPin));
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pinManager.deallocatePin(tachoPin, PinOwner::UM_Unspecified);
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tachoPin = -1;
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}
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void updateTacho(void) {
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if (tachoPin < 0) return;
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// start of tacho measurement
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// detach interrupt while calculating rpm
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detachInterrupt(digitalPinToInterrupt(tachoPin));
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// calculate rpm
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last_rpm = (counter_rpm * 60) / numberOfInterrupsInOneSingleRotation;
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last_rpm /= tachoUpdateSec;
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// reset counter
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counter_rpm = 0;
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// store milliseconds when tacho was measured the last time
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msLastTachoMeasurement = millis();
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// attach interrupt again
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attachInterrupt(digitalPinToInterrupt(tachoPin), rpm_fan, FALLING);
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}
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// https://randomnerdtutorials.com/esp32-pwm-arduino-ide/
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void initPWMfan(void) {
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if (pwmPin < 0 || !pinManager.allocatePin(pwmPin, true, PinOwner::UM_Unspecified)) {
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pwmPin = -1;
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return;
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}
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#ifdef ESP8266
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analogWriteRange(255);
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analogWriteFreq(WLED_PWM_FREQ);
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#else
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pwmChannel = pinManager.allocateLedc(1);
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if (pwmChannel == 255) { //no more free LEDC channels
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deinitPWMfan(); return;
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}
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// configure LED PWM functionalitites
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ledcSetup(pwmChannel, 25000, 8);
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// attach the channel to the GPIO to be controlled
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ledcAttachPin(pwmPin, pwmChannel);
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#endif
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DEBUG_PRINTLN(F("Fan PWM sucessfully initialized."));
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}
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void deinitPWMfan(void) {
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if (pwmPin < 0) return;
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pinManager.deallocatePin(pwmPin, PinOwner::UM_Unspecified);
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#ifdef ARDUINO_ARCH_ESP32
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pinManager.deallocateLedc(pwmChannel, 1);
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#endif
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pwmPin = -1;
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}
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void updateFanSpeed(uint8_t pwmValue){
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if (pwmPin < 0) return;
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#ifdef ESP8266
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analogWrite(pwmPin, pwmValue);
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#else
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ledcWrite(pwmChannel, pwmValue);
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#endif
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}
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float getActualTemperature(void) {
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#ifdef USERMOD_DALLASTEMPERATURE
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if (tempUM != nullptr)
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return tempUM->getTemperatureC();
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#endif
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return -127.0f;
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}
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void setFanPWMbasedOnTemperature(void) {
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float temp = getActualTemperature();
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float difftemp = temp - targetTemperature;
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// Default to run fan at full speed.
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int newPWMvalue = 255;
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int pwmStep = ((100 - minPWMValuePct) * newPWMvalue) / (7*100);
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int pwmMinimumValue = (minPWMValuePct * newPWMvalue) / 100;
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if ((temp == NAN) || (temp <= 0.0)) {
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DEBUG_PRINTLN(F("WARNING: no temperature value available. Cannot do temperature control. Will set PWM fan to 255."));
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} else if (difftemp <= 0.0) {
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// Temperature is below target temperature. Run fan at minimum speed.
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newPWMvalue = pwmMinimumValue;
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} else if (difftemp <= 0.5) {
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newPWMvalue = pwmMinimumValue + pwmStep;
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} else if (difftemp <= 1.0) {
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newPWMvalue = pwmMinimumValue + 2*pwmStep;
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} else if (difftemp <= 1.5) {
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newPWMvalue = pwmMinimumValue + 3*pwmStep;
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} else if (difftemp <= 2.0) {
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newPWMvalue = pwmMinimumValue + 4*pwmStep;
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} else if (difftemp <= 2.5) {
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newPWMvalue = pwmMinimumValue + 5*pwmStep;
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} else if (difftemp <= 3.0) {
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newPWMvalue = pwmMinimumValue + 6*pwmStep;
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}
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updateFanSpeed(newPWMvalue);
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}
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public:
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// gets called once at boot. Do all initialization that doesn't depend on
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// network here
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void setup() {
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#ifdef USERMOD_DALLASTEMPERATURE
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// This Usermod requires Temperature usermod
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tempUM = (UsermodTemperature*) usermods.lookup(USERMOD_ID_TEMPERATURE);
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#endif
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initTacho();
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initPWMfan();
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updateFanSpeed((minPWMValuePct * 255) / 100); // inital fan speed
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initDone = true;
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}
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// gets called every time WiFi is (re-)connected. Initialize own network
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// interfaces here
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void connected() {}
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/*
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* Da loop.
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*/
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void loop() {
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if (!enabled || strip.isUpdating()) return;
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unsigned long now = millis();
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if ((now - msLastTachoMeasurement) < (tachoUpdateSec * 1000)) return;
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updateTacho();
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setFanPWMbasedOnTemperature();
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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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if (tachoPin < 0) 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 data = user.createNestedArray(FPSTR(_name));
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data.add(last_rpm);
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data.add(F("rpm"));
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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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* 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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*/
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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() can be used to add custom persistent settings to the cfg.json file in the "um" (usermod) object.
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* It will be called by WLED when settings are actually saved (for example, LED settings are saved)
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* If you want to force saving the current state, use serializeConfig() in your loop().
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*
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* CAUTION: serializeConfig() will initiate a filesystem write operation.
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* It might cause the LEDs to stutter and will cause flash wear if called too often.
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* Use it sparingly and always in the loop, never in network callbacks!
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*
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* addToConfig() will also not yet add your setting to one of the settings pages automatically.
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* To make that work you still have to add the setting to the HTML, xml.cpp and set.cpp manually.
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*
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* I highly recommend checking out the basics of ArduinoJson serialization and deserialization in order to use custom settings!
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*/
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void addToConfig(JsonObject& root) {
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JsonObject top = root.createNestedObject(FPSTR(_name)); // usermodname
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top[FPSTR(_enabled)] = enabled;
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top[FPSTR(_pwmPin)] = pwmPin;
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top[FPSTR(_tachoPin)] = tachoPin;
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top[FPSTR(_tachoUpdateSec)] = tachoUpdateSec;
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top[FPSTR(_temperature)] = targetTemperature;
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top[FPSTR(_minPWMValuePct)] = minPWMValuePct;
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top[FPSTR(_IRQperRotation)] = numberOfInterrupsInOneSingleRotation;
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DEBUG_PRINTLN(F("Autosave config saved."));
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}
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/*
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* readFromConfig() can be used to read back the custom settings you added with addToConfig().
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* This is called by WLED when settings are loaded (currently this only happens once immediately after boot)
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*
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* readFromConfig() is called BEFORE setup(). This means you can use your persistent values in setup() (e.g. pin assignments, buffer sizes),
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* but also that if you want to write persistent values to a dynamic buffer, you'd need to allocate it here instead of in setup.
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* If you don't know what that is, don't fret. It most likely doesn't affect your use case :)
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*
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* The function should return true if configuration was successfully loaded or false if there was no configuration.
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*/
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bool readFromConfig(JsonObject& root) {
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int8_t newTachoPin = tachoPin;
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int8_t newPwmPin = pwmPin;
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JsonObject top = root[FPSTR(_name)];
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DEBUG_PRINT(FPSTR(_name));
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if (top.isNull()) {
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DEBUG_PRINTLN(F(": No config found. (Using defaults.)"));
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return false;
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}
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enabled = top[FPSTR(_enabled)] | enabled;
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newTachoPin = top[FPSTR(_tachoPin)] | newTachoPin;
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newPwmPin = top[FPSTR(_pwmPin)] | newPwmPin;
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tachoUpdateSec = top[FPSTR(_tachoUpdateSec)] | tachoUpdateSec;
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tachoUpdateSec = (uint8_t) max(1,(int)tachoUpdateSec); // bounds checking
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targetTemperature = top[FPSTR(_temperature)] | targetTemperature;
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minPWMValuePct = top[FPSTR(_minPWMValuePct)] | minPWMValuePct;
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minPWMValuePct = (uint8_t) min(100,max(0,(int)minPWMValuePct)); // bounds checking
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numberOfInterrupsInOneSingleRotation = top[FPSTR(_IRQperRotation)] | numberOfInterrupsInOneSingleRotation;
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numberOfInterrupsInOneSingleRotation = (uint8_t) max(1,(int)numberOfInterrupsInOneSingleRotation); // bounds checking
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if (!initDone) {
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// first run: reading from cfg.json
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tachoPin = newTachoPin;
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pwmPin = newPwmPin;
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DEBUG_PRINTLN(F(" config loaded."));
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} else {
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DEBUG_PRINTLN(F(" config (re)loaded."));
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// changing paramters from settings page
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if (tachoPin != newTachoPin || pwmPin != newPwmPin) {
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DEBUG_PRINTLN(F("Re-init pins."));
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// deallocate pin and release interrupts
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deinitTacho();
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deinitPWMfan();
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tachoPin = newTachoPin;
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pwmPin = newPwmPin;
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// initialise
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setup();
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}
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}
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// use "return !top["newestParameter"].isNull();" when updating Usermod with new features
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return !top[FPSTR(_IRQperRotation)].isNull();
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}
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/*
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* getId() allows you to optionally give your V2 usermod an unique ID (please define it in const.h!).
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* This could be used in the future for the system to determine whether your usermod is installed.
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*/
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uint16_t getId() {
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return USERMOD_ID_PWM_FAN;
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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 PWMFanUsermod::_name[] PROGMEM = "PWM-fan";
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const char PWMFanUsermod::_enabled[] PROGMEM = "enabled";
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const char PWMFanUsermod::_tachoPin[] PROGMEM = "tacho-pin";
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const char PWMFanUsermod::_pwmPin[] PROGMEM = "PWM-pin";
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const char PWMFanUsermod::_temperature[] PROGMEM = "target-temp-C";
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const char PWMFanUsermod::_tachoUpdateSec[] PROGMEM = "tacho-update-s";
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const char PWMFanUsermod::_minPWMValuePct[] PROGMEM = "min-PWM-percent";
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const char PWMFanUsermod::_IRQperRotation[] PROGMEM = "IRQs-per-rotation";
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