Rotary Encoder, Four Line Display, and Auto Save Usermods (#1722)

* Ability to lookup Usermod by id so Usermods can use other Usermods. * Rotary Encoder UI using two Usermods * Updates. More to come, probably. * Updated rotary usermod to honor USE_FOUR_LINE_DISPLAY if you want to use four line display. It should be truly optional, now. * minor logic improvement to showing the current time in clock mode. * improved 24 hour display foratting and ability to use the FourLineDisplayUsermod without the RotaryEncoderUIUsermod (option disable sleep and clock modes). * Improved ordering of defines in the FourLineDisplayUsermod to put options people might need to change together toward the top. * relocate plugins. add mention of the Wire requirement. * usermod filenames changed, updating comment in const.h * fix usermod locations. * fix usermods_list to include changed folder. * Improved for both usermods: install, config, and docs. Included sample platform_override.ini. * Updated name of SDA and SCL defines for config of display * update docs. * Wrong year. Fixed. * Fix youtube link, improve config of sleep/clock when the rotary usermod isn't installed. * Minor fixes to four line display. Addition of Auto Save v2 usermod. * Allow config for auto-save to set the preset number to use. Load preset at startup (so brightness is set correctly). * Updated docs for Auto Save. * Updated docs for Auto Save. Co-authored-by: Kevin Dorff <kevin@macbookpro-kevin-wifi.local>
2021-02-09 10:15:43 -06:00 · 2021-02-09 10:15:43 -06:00 · 8e71c3ae17
commit 8e71c3ae17
parent 94941a7732
11 changed files with 1341 additions and 0 deletions
--- a/usermods/usermod_v2_auto_save/readme.md
+++ b/usermods/usermod_v2_auto_save/readme.md
@ -0,0 +1,45 @@
 # Auto Save
 v2 Usermod to automatically save settings 
 to preset number AUTOSAVE_PRESET_NUM after a change to any of
 * brightness
 * effect speed
 * effect intensity
 * mode (effect)
 * palette
 but it will wait for AUTOSAVE_SETTLE_MS milliseconds, a "settle" 
 period in case there are other changes (any change will 
 extend the "settle" window).
 It will additionally load preset AUTOSAVE_PRESET_NUM at startup.
 during the first `loop()`.  Reasoning below.
 AutoSaveUsermod is standalone, but if FourLineDisplayUsermod is installed, it will notify the user of the saved changes.
 Note: I don't love that WLED doesn't respect the brightness of the preset being auto loaded, so the AutoSaveUsermod will set the AUTOSAVE_PRESET_NUM preset in the first loop, so brightness IS honored. This means WLED will effectively ignore Default brightness and Apply N preset at boot when the AutoSaveUsermod is installed.
 ## Installation
 Copy and update the example `platformio_override.ini.sample` 
 from the Rotary Encoder UI usermode folder to the root directory of your particular build.
 This file should be placed in the same directory as `platformio.ini`.
 ### Define Your Options
 * `USERMOD_AUTO_SAVE`   - define this to have this the Auto Save usermod included wled00\usermods_list.cpp
 * `USERMOD_FOUR_LINE_DISLAY`   - define this to have this the Four Line Display mod included wled00\usermods_list.cpp - also tells this usermod that the display is available (see the Four Line Display usermod `readme.md` for more details)
 * `AUTOSAVE_SETTLE_MS`         - Minimum time to wave before auto saving, defaults to 10000  (10s)
 * `AUTOSAVE_PRESET_NUM`        - Preset number to auto-save to, auto-load at startup from, defaults to 99
 ### PlatformIO requirements
 No special requirements.
 Note: the Four Line Display usermod requires the libraries `U8g2` and `Wire`.
 ## Change Log
 2021-02
 * First public release
--- a/usermods/usermod_v2_auto_save/usermod_v2_auto_save.h
+++ b/usermods/usermod_v2_auto_save/usermod_v2_auto_save.h
@ -0,0 +1,192 @@
 #pragma once
 #include "wled.h"
 //
 // v2 Usermod to automatically save settings 
 // to preset number AUTOSAVE_PRESET_NUM after a change to any of
 //
 // * brightness
 // * effect speed
 // * effect intensity
 // * mode (effect)
 // * palette
 //
 // but it will wait for AUTOSAVE_SETTLE_MS milliseconds, a "settle" 
 // period in case there are other changes (any change will 
 // extend the "settle" window).
 //
 // It will additionally load preset AUTOSAVE_PRESET_NUM at startup.
 // during the first `loop()`.  Reasoning below.
 //
 // AutoSaveUsermod is standalone, but if FourLineDisplayUsermod 
 // is installed, it will notify the user of the saved changes.
 //
 // Note: I don't love that WLED doesn't respect the brightness 
 // of the preset being auto loaded, so the AutoSaveUsermod 
 // will set the AUTOSAVE_PRESET_NUM preset in the first loop, 
 // so brightness IS honored. This means WLED will effectively 
 // ignore Default brightness and Apply N preset at boot when 
 // the AutoSaveUsermod is installed.
 //How long to wait after settings change to auto-save
 #ifndef AUTOSAVE_SETTLE_MS
 #define AUTOSAVE_SETTLE_MS 10*1000
 #endif
 //Preset number to save to
 #ifndef AUTOSAVE_PRESET_NUM
 #define AUTOSAVE_PRESET_NUM 99
 #endif
 //  "Auto save MM-DD HH:MM:SS"
 #define PRESET_NAME_BUFFER_SIZE 25
 class AutoSaveUsermod : public Usermod {
  private:
    // If we've detected the need to auto save, this will
    // be non zero.
    unsigned long autoSaveAfter = 0;
    char presetNameBuffer[PRESET_NAME_BUFFER_SIZE];
    bool firstLoop = true;
    uint8_t knownBrightness = 0;
    uint8_t knownEffectSpeed = 0;
    uint8_t knownEffectIntensity = 0;
    uint8_t knownMode = 0;
    uint8_t knownPalette = 0;
 #ifdef USERMOD_FOUR_LINE_DISLAY
    FourLineDisplayUsermod* display;
 #endif
  public:
    // gets called once at boot. Do all initialization that doesn't depend on
    // network here
    void setup() {
 #ifdef USERMOD_FOUR_LINE_DISLAY    
    // This Usermod has enhanced funcionality if
    // FourLineDisplayUsermod is available.
    display = (FourLineDisplayUsermod*) usermods.lookup(USERMOD_ID_FOUR_LINE_DISP);
 #endif
    }
    // gets called every time WiFi is (re-)connected. Initialize own network
    // interfaces here
    void connected() {}
    /**
     * Da loop.
     */
    void loop() {
      unsigned long now = millis();
      uint8_t currentMode = strip.getMode();
      uint8_t currentPalette = strip.getSegment(0).palette;
      if (firstLoop) {
        firstLoop = false;
        applyPreset(AUTOSAVE_PRESET_NUM);
        knownBrightness = bri;
        knownEffectSpeed = effectSpeed;
        knownEffectIntensity = effectIntensity;
        knownMode = currentMode;
        knownPalette = currentPalette;
        return;
      }
      unsigned long wouldAutoSaveAfter = now + AUTOSAVE_SETTLE_MS;
      if (knownBrightness != bri) {
        knownBrightness = bri;
        autoSaveAfter = wouldAutoSaveAfter;
      } else if (knownEffectSpeed != effectSpeed) {
        knownEffectSpeed = effectSpeed;
        autoSaveAfter = wouldAutoSaveAfter;
      } else if (knownEffectIntensity != effectIntensity) {
        knownEffectIntensity = effectIntensity;
        autoSaveAfter = wouldAutoSaveAfter;
      } else if (knownMode != currentMode) {
        knownMode = currentMode;
        autoSaveAfter = wouldAutoSaveAfter;
      } else if (knownPalette != currentPalette) {
        knownPalette = currentPalette;
        autoSaveAfter = wouldAutoSaveAfter;
      }
      if (autoSaveAfter && now > autoSaveAfter) {
        autoSaveAfter = 0;
        // Time to auto save. You may have some flickry?
        saveSettings();
        displayOverlay();
      }
    }
    void saveSettings() {
      updateLocalTime();
      sprintf(presetNameBuffer, 
        "Auto save %02d-%02d %02d:%02d:%02d",
        month(localTime), day(localTime),
        hour(localTime), minute(localTime), second(localTime));
      savePreset(AUTOSAVE_PRESET_NUM, true, presetNameBuffer);
    }
    void displayOverlay() {
 #ifdef USERMOD_FOUR_LINE_DISLAY
      if (display != nullptr) {
        display->wakeDisplay();
        display->overlay("Settings", "Auto Saved", 1500);
      }
 #endif
    }
    /*
     * addToJsonState() can be used to add custom entries to the /json/state part of the JSON API (state object).
     * Values in the state object may be modified by connected clients
     */
    void addToJsonState(JsonObject& root) {
    }
    /*
     * readFromJsonState() can be used to receive data clients send to the /json/state part of the JSON API (state object).
     * Values in the state object may be modified by connected clients
     */
    void readFromJsonState(JsonObject& root) {
    }
    /*
     * addToConfig() can be used to add custom persistent settings to the cfg.json file in the "um" (usermod) object.
     * It will be called by WLED when settings are actually saved (for example, LED settings are saved)
     * If you want to force saving the current state, use serializeConfig() in your loop().
     * 
     * CAUTION: serializeConfig() will initiate a filesystem write operation.
     * It might cause the LEDs to stutter and will cause flash wear if called too often.
     * Use it sparingly and always in the loop, never in network callbacks!
     * 
     * addToConfig() will also not yet add your setting to one of the settings pages automatically.
     * To make that work you still have to add the setting to the HTML, xml.cpp and set.cpp manually.
     * 
     * I highly recommend checking out the basics of ArduinoJson serialization and deserialization in order to use custom settings!
     */
    void addToConfig(JsonObject& root) {
    }
    /*
     * readFromConfig() can be used to read back the custom settings you added with addToConfig().
     * This is called by WLED when settings are loaded (currently this only happens once immediately after boot)
     * 
     * readFromConfig() is called BEFORE setup(). This means you can use your persistent values in setup() (e.g. pin assignments, buffer sizes),
     * 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.
     * If you don't know what that is, don't fret. It most likely doesn't affect your use case :)
     */
    void readFromConfig(JsonObject& root) {
    }
    /*
     * getId() allows you to optionally give your V2 usermod an unique ID (please define it in const.h!).
     * This could be used in the future for the system to determine whether your usermod is installed.
     */
    uint16_t getId() {
      return USERMOD_ID_AUTO_SAVE;
    }
 };
--- a/usermods/usermod_v2_four_line_display/readme.md
+++ b/usermods/usermod_v2_four_line_display/readme.md
@ -0,0 +1,39 @@
 # Rotary Encoder UI Usermod
 First, thanks to the authors of the ssd11306_i2c_oled_u8g2 mod.
 This usermod provides a four line display using either
 128x32 or 128x64 OLED displays.
 It's can operate independently, but starts to provide
 a relatively complete on-device UI when paired with the 
 Rotary Encoder UI usermod. I strongly encourage you to use 
 them together.
 [See the pair of usermods in action](https://www.youtube.com/watch?v=tITQY80rIOA)
 ## Installation
 Copy and update the example `platformio_override.ini.sample` 
 from the Rotary Encoder UI usermode folder to the root directory of your particular build.
 This file should be placed in the same directory as `platformio.ini`.
 ### Define Your Options
 * `USERMOD_FOUR_LINE_DISLAY`   - define this to have this the Four Line Display mod included wled00\usermods_list.cpp - also tells Rotary Encoder usermod, if installed, that the display is available
 * `FLD_PIN_SCL`                - The display SCL pin, defaults to 5
 * `FLD_PIN_SDA`                - The display SDA pin, defaults to 4
 * `FLIP_MODE`                  - Set to 0 or 1
 * `LINE_HEIGHT`                - Set to 1 or 2
 There are other `#define` values in the Usermod that might be of interest.
 ### PlatformIO requirements
 This usermod requires the `U8g2` and `Wire` libraries. See the 
 `platformio_override.ini.sample` found in the Rotary Encoder
 UI usermod folder for how to include these using `platformio_override.ini`.
 ## Change Log
 2021-02
 * First public release
--- a/usermods/usermod_v2_four_line_display/usermod_v2_four_line_display.h
+++ b/usermods/usermod_v2_four_line_display/usermod_v2_four_line_display.h
@ -0,0 +1,530 @@
 #pragma once
 #include "wled.h"
 #include <U8x8lib.h> // from https://github.com/olikraus/u8g2/
 //
 // Insired by the v1 usermod: ssd1306_i2c_oled_u8g2
 //
 // v2 usermod for using 128x32 or 128x64 i2c
 // OLED displays to provide a four line display
 // for WLED.
 //
 // This Usermod works best, by far, when coupled with RotaryEncoderUIUsermod.
 //
 // Make sure to enable NTP and set your time zone in WLED Config | Time.
 //
 // REQUIREMENT: You must add the following requirements to
 // REQUIREMENT: "lib_deps" within platformio.ini / platformio_override.ini
 // REQUIREMENT: *  U8g2  (the version already in platformio.ini is fine)
 // REQUIREMENT: *  Wire
 //
 //The SCL and SDA pins are defined here. 
 #ifndef FLD_PIN_SCL
 #define FLD_PIN_SCL 5
 #endif
 #ifndef FLD_PIN_SDA
 #define FLD_PIN_SDA 4
 #endif
 // U8X8_SSD1306_128X32_UNIVISION_HW_I2C u8x8(
 //   U8X8_PIN_NONE, FLD_PIN_SCL, FLD_PIN_SDA); 
 U8X8_SH1106_128X64_WINSTAR_HW_I2C u8x8(
  U8X8_PIN_NONE, FLD_PIN_SCL, FLD_PIN_SDA); 
 // Screen upside down? Change to 0 or 1
 #ifndef FLIP_MODE
 #define FLIP_MODE 0
 #endif
 // LINE_HEIGHT 1 is single height, for 128x32 displays.
 // LINE_HEIGHT 2 makes the 128x64 screen display at double height.
 #ifndef LINE_HEIGHT
 #define LINE_HEIGHT 2
 #endif
 // If you aren't also including RotaryEncoderUIUsermod
 // you probably want to set both
 //     SLEEP_MODE_ENABLED false
 //     CLOCK_MODE_ENABLED false
 // as you will never be able wake the display / disable the clock.
 #ifdef USERMOD_ROTARY_ENCODER_UI
 #ifndef SLEEP_MODE_ENABLED
 #define SLEEP_MODE_ENABLED true
 #endif
 #ifndef CLOCK_MODE_ENABLED
 #define CLOCK_MODE_ENABLED true
 #endif
 #else
 #define SLEEP_MODE_ENABLED false
 #define CLOCK_MODE_ENABLED false
 #endif
 // When to time out to the clock or blank the screen
 // if SLEEP_MODE_ENABLED.
 #define SCREEN_TIMEOUT_MS  15*1000
 #define TIME_INDENT        0
 #define DATE_INDENT        2
 // Minimum time between redrawing screen in ms
 #define USER_LOOP_REFRESH_RATE_MS 1000
 #if LINE_HEIGHT == 2
 #define DRAW_STRING draw1x2String
 #define DRAW_GLYPH draw1x2Glyph
 #define DRAW_BIG_STRING draw2x2String
 #else
 #define DRAW_STRING drawString
 #define DRAW_GLYPH drawGlyph
 #define DRAW_BIG_STRING draw2x2String
 #endif
 // Extra char (+1) for null
 #define LINE_BUFFER_SIZE            16+1
 #define FLD_LINE_3_BRIGHTNESS       0
 #define FLD_LINE_3_EFFECT_SPEED     1
 #define FLD_LINE_3_EFFECT_INTENSITY 2
 #define FLD_LINE_3_PALETTE          3
 #if LINE_HEIGHT == 2
 #define TIME_LINE  1
 #else
 #define TIME_LINE  0
 #endif
 class FourLineDisplayUsermod : public Usermod {
  private:
    unsigned long lastTime = 0;
    // needRedraw marks if redraw is required to prevent often redrawing.
    bool needRedraw = true;
    // Next variables hold the previous known values to determine if redraw is
    // required.
    String knownSsid = "";
    IPAddress knownIp;
    uint8_t knownBrightness = 0;
    uint8_t knownEffectSpeed = 0;
    uint8_t knownEffectIntensity = 0;
    uint8_t knownMode = 0;
    uint8_t knownPalette = 0;
    uint8_t knownMinute = 99;
    uint8_t knownHour = 99;
    bool displayTurnedOff = false;
    long lastUpdate = 0;
    long lastRedraw = 0;
    long overlayUntil = 0;
    byte lineThreeType = FLD_LINE_3_BRIGHTNESS;
    // Set to 2 or 3 to mark lines 2 or 3. Other values ignored.
    byte markLineNum = 0;
    char lineBuffer[LINE_BUFFER_SIZE];
    // If display does not work or looks corrupted check the
    // constructor reference:
    // https://github.com/olikraus/u8g2/wiki/u8x8setupcpp
    // or check the gallery:
    // https://github.com/olikraus/u8g2/wiki/gallery
  public:
    // gets called once at boot. Do all initialization that doesn't depend on
    // network here
    void setup() {
      u8x8.begin();
      u8x8.setFlipMode(FLIP_MODE);
      u8x8.setPowerSave(0);
      u8x8.setContrast(10); //Contrast setup will help to preserve OLED lifetime. In case OLED need to be brighter increase number up to 255
      u8x8.setFont(u8x8_font_chroma48medium8_r);
      u8x8.DRAW_STRING(0, 0*LINE_HEIGHT, "Loading...");
    }
    // gets called every time WiFi is (re-)connected. Initialize own network
    // interfaces here
    void connected() {}
    /**
     * Da loop.
     */
    void loop() {
      if (millis() - lastUpdate < USER_LOOP_REFRESH_RATE_MS) {
        return;
      }
      lastUpdate = millis();
      redraw(false);
    }
    /**
     * Redraw the screen (but only if things have changed
     * or if forceRedraw).
     */
    void redraw(bool forceRedraw) {
      if (overlayUntil > 0) {
        if (millis() >= overlayUntil) {
          // Time to display the overlay has elapsed.
          overlayUntil = 0;
          forceRedraw = true;
        }
        else {
          // We are still displaying the overlay
          // Don't redraw.
          return;
        }
      }
      // Check if values which are shown on display changed from the last time.
      if (forceRedraw) {
        needRedraw = true;
      } else if (((apActive) ? String(apSSID) : WiFi.SSID()) != knownSsid) {
        needRedraw = true;
      } else if (knownIp != (apActive ? IPAddress(4, 3, 2, 1) : WiFi.localIP())) {
        needRedraw = true;
      } else if (knownBrightness != bri) {
        needRedraw = true;
      } else if (knownEffectSpeed != effectSpeed) {
        needRedraw = true;
      } else if (knownEffectIntensity != effectIntensity) {
        needRedraw = true;
      } else if (knownMode != strip.getMode()) {
        needRedraw = true;
      } else if (knownPalette != strip.getSegment(0).palette) {
        needRedraw = true;
      }
      if (!needRedraw) {
        // Nothing to change.
        // Turn off display after 3 minutes with no change.
        if(SLEEP_MODE_ENABLED && !displayTurnedOff &&
            (millis() - lastRedraw > SCREEN_TIMEOUT_MS)) {
          // We will still check if there is a change in redraw()
          // and turn it back on if it changed.
          sleepOrClock(true);
        }
        else if (displayTurnedOff && CLOCK_MODE_ENABLED) {
          showTime();
        }
        return;
      }
      needRedraw = false;
      lastRedraw = millis();
      if (displayTurnedOff)
      {
        // Turn the display back on
        sleepOrClock(false);
      }
      // Update last known values.
      #if defined(ESP8266)
      knownSsid = apActive ? WiFi.softAPSSID() : WiFi.SSID();
      #else
      knownSsid = WiFi.SSID();
      #endif
      knownIp = apActive ? IPAddress(4, 3, 2, 1) : WiFi.localIP();
      knownBrightness = bri;
      knownMode = strip.getMode();
      knownPalette = strip.getSegment(0).palette;
      knownEffectSpeed = effectSpeed;
      knownEffectIntensity = effectIntensity;
      // Do the actual drawing
      u8x8.clear();
      u8x8.setFont(u8x8_font_chroma48medium8_r);
      // First row with Wifi name
      String ssidString = knownSsid.substring(0, u8x8.getCols() > 1 ? u8x8.getCols() - 2 : 0);
      u8x8.DRAW_STRING(1, 0*LINE_HEIGHT, ssidString.c_str());
      // Print `~` char to indicate that SSID is longer, than owr dicplay
      if (knownSsid.length() > u8x8.getCols()) {
        u8x8.DRAW_STRING(u8x8.getCols() - 1, 0*LINE_HEIGHT, "~");
      }
      // Second row with IP or Psssword
      // Print password in AP mode and if led is OFF.
      if (apActive && bri == 0) {
        u8x8.DRAW_STRING(1, 1*LINE_HEIGHT, apPass);
      }
      else {
        String ipString = knownIp.toString();
        u8x8.DRAW_STRING(1, 1*LINE_HEIGHT, ipString.c_str());
      }
      // Third row with mode name
      showCurrentEffectOrPalette(JSON_mode_names, 2, knownMode);
      switch(lineThreeType) {
        case FLD_LINE_3_BRIGHTNESS:
          sprintf(lineBuffer, "Brightness %d", bri);
          u8x8.DRAW_STRING(1, 3*LINE_HEIGHT, lineBuffer);
          break;
        case FLD_LINE_3_EFFECT_SPEED:
          sprintf(lineBuffer, "FX Speed %d", effectSpeed);
          u8x8.DRAW_STRING(1, 3*LINE_HEIGHT, lineBuffer);
          break;
        case FLD_LINE_3_EFFECT_INTENSITY:
          sprintf(lineBuffer, "FX Intense %d", effectIntensity);
          u8x8.DRAW_STRING(1, 3*LINE_HEIGHT, lineBuffer);
          break;
        case FLD_LINE_3_PALETTE:
          showCurrentEffectOrPalette(JSON_palette_names, 3, knownPalette);
          break;
      }
      u8x8.setFont(u8x8_font_open_iconic_arrow_1x1);
      u8x8.DRAW_GLYPH(0, markLineNum*LINE_HEIGHT, 66); // arrow icon
      u8x8.setFont(u8x8_font_open_iconic_embedded_1x1);
      u8x8.DRAW_GLYPH(0, 0*LINE_HEIGHT, 80); // wifi icon
      u8x8.DRAW_GLYPH(0, 1*LINE_HEIGHT, 68); // home icon
    }
    /**
     * Display the current effect or palette (desiredEntry) 
     * on the appropriate line (row).
     * 
     * TODO: Should we cache the current effect and 
     * TODO: palette name? This seems expensive.
     */
    void showCurrentEffectOrPalette(const char json[], uint8_t row, uint8_t desiredEntry) {
      uint8_t qComma = 0;
      bool insideQuotes = false;
      // advance past the mark for markLineNum that may exist.
      uint8_t printedChars = 1;
      char singleJsonSymbol;
      // Find the mode name in JSON
      for (size_t i = 0; i < strlen_P(json); i++) {
        singleJsonSymbol = pgm_read_byte_near(json + i);
        switch (singleJsonSymbol) {
        case '"':
          insideQuotes = !insideQuotes;
          break;
        case '[':
        case ']':
          break;
        case ',':
          qComma++;
        default:
          if (!insideQuotes || (qComma != desiredEntry)) {
            break;
          }
          u8x8.DRAW_GLYPH(printedChars, row * LINE_HEIGHT, singleJsonSymbol);
          printedChars++;
        }
        if ((qComma > desiredEntry) || (printedChars > u8x8.getCols() - 2)) {
          break;
        }
      }
    }
    /**
     * If there screen is off or in clock is displayed,
     * this will return true. This allows us to throw away
     * the first input from the rotary encoder but
     * to wake up the screen.
     */
    bool wakeDisplay() {
      if (displayTurnedOff) {
        // Turn the display back on
        sleepOrClock(false);
        redraw(true);
        return true;
      }
      return false;
    }
    /**
     * Allows you to show up to two lines as overlay for a
     * period of time.
     * Clears the screen and prints on the middle two lines.
     */
    void overlay(const char* line1, const char *line2, long showHowLong) {
      if (displayTurnedOff) {
        // Turn the display back on
        sleepOrClock(false);
      }
      // Print the overlay
      u8x8.clear();
      u8x8.setFont(u8x8_font_chroma48medium8_r);
      if (line1) {
        u8x8.DRAW_STRING(0, 1*LINE_HEIGHT, line1);
      }
      if (line2) {
        u8x8.DRAW_STRING(0, 2*LINE_HEIGHT, line2);
      }
      overlayUntil = millis() + showHowLong;
    }
    /**
     * Specify what data should be defined on line 3
     * (the last line).
     */
    void setLineThreeType(byte newLineThreeType) {
      if (newLineThreeType == FLD_LINE_3_BRIGHTNESS || 
          newLineThreeType == FLD_LINE_3_EFFECT_SPEED || 
          newLineThreeType == FLD_LINE_3_EFFECT_INTENSITY || 
          newLineThreeType == FLD_LINE_3_PALETTE) {
        lineThreeType = newLineThreeType;
      }
      else {
        // Unknown value.
        lineThreeType = FLD_LINE_3_BRIGHTNESS; 
      }
    }
    /**
     * Line 2 or 3 (last two lines) can be marked with an
     * arrow in the first column. Pass 2 or 3 to this to
     * specify which line to mark with an arrow.
     * Any other values are ignored.
     */
    void setMarkLine(byte newMarkLineNum) {
      if (newMarkLineNum == 2 || newMarkLineNum == 3) {
        markLineNum = newMarkLineNum;
      }
      else {
        markLineNum = 0;
      }
    }
    /*
     * addToJsonInfo() can be used to add custom entries to the /json/info part of the JSON API.
     * Creating an "u" object allows you to add custom key/value pairs to the Info section of the WLED web UI.
     * Below it is shown how this could be used for e.g. a light sensor
     */
    /*
    void addToJsonInfo(JsonObject& root)
    {
      int reading = 20;
      //this code adds "u":{"Light":[20," lux"]} to the info object
      JsonObject user = root["u"];
      if (user.isNull()) user = root.createNestedObject("u");
      JsonArray lightArr = user.createNestedArray("Light"); //name
      lightArr.add(reading); //value
      lightArr.add(" lux"); //unit
    }
    */
    /**
     * Enable sleep (turn the display off) or clock mode.
     */
    void sleepOrClock(bool enabled) {
      if (enabled) {
        if (CLOCK_MODE_ENABLED) {
          showTime();
        }
        else {
          u8x8.setPowerSave(1);
        }
        displayTurnedOff = true;
      }
      else {
        if (!CLOCK_MODE_ENABLED) {
          u8x8.setPowerSave(0);
        }
        displayTurnedOff = false;
      }
    }
    /**
     * Display the current date and time in large characters
     * on the middle rows. Based 24 or 12 hour depending on
     * the useAMPM configuration.
     */
    void showTime() {
      updateLocalTime();
      byte minuteCurrent = minute(localTime);
      byte hourCurrent = hour(localTime);
      if (knownMinute == minuteCurrent && knownHour == hourCurrent) {
        // Time hasn't changed.
        return;
      }
      knownMinute = minuteCurrent;
      knownHour = hourCurrent;
      u8x8.clear();
      u8x8.setFont(u8x8_font_chroma48medium8_r);
      int currentMonth = month(localTime);
      sprintf(lineBuffer, "%s %d", monthShortStr(currentMonth), day(localTime));
      u8x8.DRAW_BIG_STRING(DATE_INDENT, TIME_LINE*LINE_HEIGHT, lineBuffer);
      byte showHour = hourCurrent;
      boolean isAM = false;
      if (useAMPM) {
        if (showHour == 0) {
          showHour = 12;
          isAM = true;
        } 
        else if (showHour > 12) {
          showHour -= 12;
          isAM = false;
        }
        else {
          isAM = true;
        }
      }
      sprintf(lineBuffer, "%02d:%02d %s", showHour, minuteCurrent, useAMPM ? (isAM ? "AM" : "PM") : "");
      // For time, we always use LINE_HEIGHT of 2 since
      // we are printing it big.
      u8x8.DRAW_BIG_STRING(TIME_INDENT + (useAMPM ? 0 : 2), (TIME_LINE + 1) * 2, lineBuffer);
    }
    /*
     * addToJsonState() can be used to add custom entries to the /json/state part of the JSON API (state object).
     * Values in the state object may be modified by connected clients
     */
    void addToJsonState(JsonObject& root) {
    }
    /*
     * readFromJsonState() can be used to receive data clients send to the /json/state part of the JSON API (state object).
     * Values in the state object may be modified by connected clients
     */
    void readFromJsonState(JsonObject& root) {
    }
    /*
     * addToConfig() can be used to add custom persistent settings to the cfg.json file in the "um" (usermod) object.
     * It will be called by WLED when settings are actually saved (for example, LED settings are saved)
     * If you want to force saving the current state, use serializeConfig() in your loop().
     * 
     * CAUTION: serializeConfig() will initiate a filesystem write operation.
     * It might cause the LEDs to stutter and will cause flash wear if called too often.
     * Use it sparingly and always in the loop, never in network callbacks!
     * 
     * addToConfig() will also not yet add your setting to one of the settings pages automatically.
     * To make that work you still have to add the setting to the HTML, xml.cpp and set.cpp manually.
     * 
     * I highly recommend checking out the basics of ArduinoJson serialization and deserialization in order to use custom settings!
     */
    void addToConfig(JsonObject& root) {
    }
    /*
     * readFromConfig() can be used to read back the custom settings you added with addToConfig().
     * This is called by WLED when settings are loaded (currently this only happens once immediately after boot)
     * 
     * readFromConfig() is called BEFORE setup(). This means you can use your persistent values in setup() (e.g. pin assignments, buffer sizes),
     * 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.
     * If you don't know what that is, don't fret. It most likely doesn't affect your use case :)
     */
    void readFromConfig(JsonObject& root) {
    }
    /*
     * getId() allows you to optionally give your V2 usermod an unique ID (please define it in const.h!).
     * This could be used in the future for the system to determine whether your usermod is installed.
     */
    uint16_t getId() {
      return USERMOD_ID_FOUR_LINE_DISP;
    }
 };
--- a/usermods/usermod_v2_rotary_encoder_ui/platformio_override.ini.sample
+++ b/usermods/usermod_v2_rotary_encoder_ui/platformio_override.ini.sample
@ -0,0 +1,46 @@
 [platformio]
 default_envs = d1_mini
 ; default_envs = esp32dev
 [env:esp32dev]
 board = esp32dev
 platform = espressif32@2.0
 build_unflags = ${common.build_unflags}
 build_flags =
    ${common.build_flags_esp32} 
    -D USERMOD_FOUR_LINE_DISLAY -D FLD_PIN_SCL=22 -D FLD_PIN_SDA=21
    -D USERMOD_ROTARY_ENCODER_UI -D ENCODER_DT_PIN=18 -D ENCODER_CLK_PIN=5 -D ENCODER_SW_PIN=19  
    -D USERMOD_AUTO_SAVE -D AUTOSAVE_PRESET_NUM=1
    -D LEDPIN=16 -D BTNPIN=13
 upload_speed = 460800
 lib_ignore =
  ESPAsyncTCP
  ESPAsyncUDP
 [env:d1_mini]
 board = d1_mini
 platform = ${common.platform_wled_default}
 platform_packages = ${common.platform_packages}
 upload_speed = 460800
 board_build.ldscript = ${common.ldscript_4m1m}
 build_unflags = ${common.build_unflags}
 build_flags =
    ${common.build_flags_esp8266} 
    -D USERMOD_FOUR_LINE_DISLAY -D FLD_PIN_SCL=5 -D FLD_PIN_SDA=4
    -D USERMOD_ROTARY_ENCODER_UI -D ENCODER_DT_PIN=12 -D ENCODER_CLK_PIN=14 -D ENCODER_SW_PIN=13
    -D USERMOD_AUTO_SAVE -D AUTOSAVE_PRESET_NUM=1
    -D LEDPIN=3 -D BTNPIN=0
 monitor_filters = esp8266_exception_decoder
 [env]
 lib_deps =
    fastled/FastLED @ 3.3.2
    NeoPixelBus @ 2.6.0
    ESPAsyncTCP @ 1.2.0
    ESPAsyncUDP
    AsyncTCP @ 1.0.3
    IRremoteESP8266 @ 2.7.3
    https://github.com/lorol/LITTLEFS.git
    https://github.com/Aircoookie/ESPAsyncWebServer.git @ ~2.0.0
    U8g2@~2.27.2
    Wire
--- a/usermods/usermod_v2_rotary_encoder_ui/readme.md
+++ b/usermods/usermod_v2_rotary_encoder_ui/readme.md
@ -0,0 +1,33 @@
 # Rotary Encoder UI Usermod
 First, thanks to the authors of other Rotary Encoder usermods.
 This usermod starts to provide a relatively complete on-device
 UI when paired with the Four Line Display usermod. I strongly
 encourage you to try them together.
 [See the pair of usermods in action](https://www.youtube.com/watch?v=tITQY80rIOA)
 ## Installation
 Copy and update the example `platformio_override.ini.sample` to the root directory of your particular build.
 This file should be placed in the same directory as `platformio.ini`.
 ### Define Your Options
 * `USERMOD_ROTARY_ENCODER_UI`  - define this to have this user mod included wled00\usermods_list.cpp
 * `USERMOD_FOUR_LINE_DISLAY`   - define this to have this the Four Line Display mod included wled00\usermods_list.cpp - also tells this usermod that the display is available (see the Four Line Display usermod `readme.md` for more details)
 * `ENCODER_DT_PIN`             - The encoders DT pin, defaults to 12
 * `ENCODER_CLK_PIN`            - The encoders CLK pin, defaults to 14
 * `ENCODER_SW_PIN`             - The encoders SW pin, defaults to 13
 ### PlatformIO requirements
 No special requirements.
 Note: the Four Line Display usermod requires the libraries `U8g2` and `Wire`.
 ## Change Log
 2021-02
 * First public release
--- a/usermods/usermod_v2_rotary_encoder_ui/usermod_v2_rotary_encoder_ui.h
+++ b/usermods/usermod_v2_rotary_encoder_ui/usermod_v2_rotary_encoder_ui.h
@ -0,0 +1,420 @@
 #pragma once
 #include "wled.h"
 //
 // Inspired by the v1 usermods
 // * rotary_encoder_change_brightness
 // * rotary_encoder_change_effect
 //
 // v2 usermod that provides a rotary encoder-based UI.
 //
 // This Usermod works best coupled with FourLineDisplayUsermod.
 //
 // This usermod allows you to control:
 // 
 // * Brightness
 // * Selected Effect
 // * Effect Speed
 // * Effect Intensity
 // * Palette
 // 
 // Change between modes by pressing a button.
 //
 #ifndef ENCODER_DT_PIN
 #define ENCODER_DT_PIN 12
 #endif
 #ifndef ENCODER_CLK_PIN
 #define ENCODER_CLK_PIN 14
 #endif
 #ifndef ENCODER_SW_PIN
 #define ENCODER_SW_PIN 13
 #endif
 #ifndef USERMOD_FOUR_LINE_DISLAY
 // These constants won't be defined if we aren't using FourLineDisplay.
 #define FLD_LINE_3_BRIGHTNESS       0
 #define FLD_LINE_3_EFFECT_SPEED     0
 #define FLD_LINE_3_EFFECT_INTENSITY 0
 #define FLD_LINE_3_PALETTE          0
 #endif
 // The last UI state
 #define LAST_UI_STATE 4
 /**
 * Array of mode indexes in alphabetical order.
 * Should be ordered from JSON_mode_names array in FX.h.
 * 
 * NOTE: If JSON_mode_names changes, this will need to be updated.
 */
 const byte modes_alpha_order[] = {
    0, 27, 38, 115, 1, 26, 91, 68, 2, 88, 102, 114, 28, 31, 32,
    30, 29, 111, 52, 34, 8, 74, 67, 112, 18, 19, 96, 7, 117, 12,
    69, 66, 45, 42, 90, 89, 110, 87, 46, 53, 82, 100, 58, 64, 75,
    41, 57, 47, 44, 76, 77, 59, 70, 71, 72, 73, 107, 62, 101, 65,
    98, 105, 109, 97, 48, 49, 95, 63, 78, 43, 9, 33, 5, 79, 99,
    15, 37, 16, 10, 11, 40, 60, 108, 92, 93, 94, 103, 83, 84, 20,
    21, 22, 85, 86, 39, 61, 23, 25, 24, 104, 6, 36, 13, 14, 35,
    54, 56, 55, 116, 17, 81, 80, 106, 51, 50, 113, 3, 4 };
 /**
 * Array of palette indexes in alphabetical order.
 * Should be ordered from JSON_palette_names array in FX.h.
 *
 * NOTE: If JSON_palette_names changes, this will need to be updated.
 */
 const byte palettes_alpha_order[] = { 
  0, 1, 2, 3, 4, 5, 18, 46, 51, 50, 55, 39, 26, 22, 15,
  48, 52, 53, 7, 37, 24, 30, 35, 10, 32, 28, 29, 36, 31,
  25, 8, 38, 40, 41, 9, 44, 47, 6, 20, 11, 12, 16, 33, 
  14, 49, 27, 19, 13, 21, 54, 34, 45, 23, 43, 17, 42 };
 class RotaryEncoderUIUsermod : public Usermod {
 private:
  int fadeAmount = 10;             // Amount to change every step (brightness)
  unsigned long currentTime;
  unsigned long loopTime;
  const int pinA = ENCODER_DT_PIN;     // DT from encoder
  const int pinB = ENCODER_CLK_PIN;    // CLK from encoder
  const int pinC = ENCODER_SW_PIN;     // SW from encoder
  unsigned char select_state = 0;      // 0: brightness, 1: effect, 2: effect speed
  unsigned char button_state = HIGH;
  unsigned char prev_button_state = HIGH;
 #ifdef USERMOD_FOUR_LINE_DISLAY
  FourLineDisplayUsermod* display;
 #else
  void* display = nullptr;
 #endif
  unsigned char Enc_A;
  unsigned char Enc_B;
  unsigned char Enc_A_prev = 0;
  bool currentEffectAndPaleeteInitialized = false;
  uint8_t effectCurrentIndex = 0;
  uint8_t effectPaletteIndex = 0;
 public:
  /*
     * setup() is called once at boot. WiFi is not yet connected at this point.
     * You can use it to initialize variables, sensors or similar.
     */
  void setup()
  {
    pinMode(pinA, INPUT_PULLUP);
    pinMode(pinB, INPUT_PULLUP);
    pinMode(pinC, INPUT_PULLUP);
    currentTime = millis();
    loopTime = currentTime;
 #ifdef USERMOD_FOUR_LINE_DISLAY    
    // This Usermod uses FourLineDisplayUsermod for the best experience.
    // But it's optional. But you want it.
    display = (FourLineDisplayUsermod*) usermods.lookup(USERMOD_ID_FOUR_LINE_DISP);
    if (display != nullptr) {
      display->setLineThreeType(FLD_LINE_3_BRIGHTNESS);
      display->setMarkLine(3);
    }
 #endif
  }
  /*
     * connected() is called every time the WiFi is (re)connected
     * Use it to initialize network interfaces
     */
  void connected()
  {
    //Serial.println("Connected to WiFi!");
  }
  /*
     * loop() is called continuously. Here you can check for events, read sensors, etc.
     * 
     * Tips:
     * 1. You can use "if (WLED_CONNECTED)" to check for a successful network connection.
     *    Additionally, "if (WLED_MQTT_CONNECTED)" is available to check for a connection to an MQTT broker.
     * 
     * 2. Try to avoid using the delay() function. NEVER use delays longer than 10 milliseconds.
     *    Instead, use a timer check as shown here.
     */
  void loop()
  {
    currentTime = millis(); // get the current elapsed time
    // Initialize effectCurrentIndex and effectPaletteIndex to
    // current state. We do it here as (at least) effectCurrent
    // is not yet initialized when setup is called.
    if (!currentEffectAndPaleeteInitialized) {
      findCurrentEffectAndPalette();
    }
    if (currentTime >= (loopTime + 2)) // 2ms since last check of encoder = 500Hz
    {
      button_state = digitalRead(pinC);
      if (prev_button_state != button_state)
      {
        if (button_state == LOW)
        {
          prev_button_state = button_state;
          char newState = select_state + 1;
          if (newState > LAST_UI_STATE) newState = 0;
          bool changedState = true;
          if (display != nullptr) {
            switch(newState) {
              case 0:
                changedState = changeState("Brightness", FLD_LINE_3_BRIGHTNESS, 3);
                break;
              case 1:
                changedState = changeState("Select FX", FLD_LINE_3_EFFECT_SPEED, 2);
                break;
              case 2:
                changedState = changeState("FX Speed", FLD_LINE_3_EFFECT_SPEED, 3);
                break;
              case 3:
                changedState = changeState("FX Intensity", FLD_LINE_3_EFFECT_INTENSITY, 3);
                break;
              case 4:
                changedState = changeState("Palette", FLD_LINE_3_PALETTE, 3);
                break;
            }
          }
          if (changedState) {
            select_state = newState;
          }
        }
        else
        {
          prev_button_state = button_state;
        }
      }
      int Enc_A = digitalRead(pinA); // Read encoder pins
      int Enc_B = digitalRead(pinB);
      if ((!Enc_A) && (Enc_A_prev))
      { // A has gone from high to low
        if (Enc_B == HIGH)
        { // B is high so clockwise
          switch(select_state) {
            case 0:
              changeBrightness(true);
              break;
            case 1:
              changeEffect(true);
              break;
            case 2:
              changeEffectSpeed(true);
              break;
            case 3:
              changeEffectIntensity(true);
              break;
            case 4:
              changePalette(true);
              break;
          }
        }
        else if (Enc_B == LOW)
        { // B is low so counter-clockwise
          switch(select_state) {
            case 0:
              changeBrightness(false);
              break;
            case 1:
              changeEffect(false);
              break;
            case 2:
              changeEffectSpeed(false);
              break;
            case 3:
              changeEffectIntensity(false);
              break;
            case 4:
              changePalette(false);
              break;
          }
        }
      }
      Enc_A_prev = Enc_A;     // Store value of A for next time
      loopTime = currentTime; // Updates loopTime
    }
  }
  void findCurrentEffectAndPalette() {
    currentEffectAndPaleeteInitialized = true;
    for (uint8_t i = 0; i < strip.getModeCount(); i++) {
      byte value = modes_alpha_order[i];
      if (modes_alpha_order[i] == effectCurrent) {
        effectCurrentIndex = i;
        break;
      }
    }
    for (uint8_t i = 0; i < strip.getPaletteCount(); i++) {
      byte value = palettes_alpha_order[i];
      if (palettes_alpha_order[i] == strip.getSegment(0).palette) {
        effectPaletteIndex = i;
        break;
      }
    }
  }
  boolean changeState(const char *stateName, byte lineThreeMode, byte markedLine) {
 #ifdef USERMOD_FOUR_LINE_DISLAY
    if (display != nullptr) {
      if (display->wakeDisplay()) {
        // Throw away wake up input
        return false;
      }
      display->overlay("Mode change", stateName, 1500);
      display->setLineThreeType(lineThreeMode);
      display->setMarkLine(markedLine);
    }
  #endif
    return true;
  }
  void lampUdated() {
    bool fxChanged = strip.setEffectConfig(effectCurrent, effectSpeed, effectIntensity, effectPalette);
    //call for notifier -> 0: init 1: direct change 2: button 3: notification 4: nightlight 5: other (No notification)
    // 6: fx changed 7: hue 8: preset cycle 9: blynk 10: alexa
    colorUpdated(NOTIFIER_CALL_MODE_DIRECT_CHANGE);
    updateInterfaces(NOTIFIER_CALL_MODE_DIRECT_CHANGE);
  }
  void changeBrightness(bool increase) {
 #ifdef USERMOD_FOUR_LINE_DISLAY
    if (display && display->wakeDisplay()) {
      // Throw away wake up input
      return;
    }
 #endif
    if (increase) {
      bri = (bri + fadeAmount <= 255) ? (bri + fadeAmount) : 255;
    }
    else {
      bri = (bri - fadeAmount >= 0) ? (bri - fadeAmount) : 0;
    }
    lampUdated();
  }
  void changeEffect(bool increase) {
 #ifdef USERMOD_FOUR_LINE_DISLAY
    if (display && display->wakeDisplay()) {
      // Throw away wake up input
      return;
    }
 #endif
    if (increase) {
      effectCurrentIndex = (effectCurrentIndex + 1 >= strip.getModeCount()) ? 0 : (effectCurrentIndex + 1);
    }
    else {
      effectCurrentIndex = (effectCurrentIndex - 1 < 0) ? (strip.getModeCount() - 1) : (effectCurrentIndex - 1);
    }
    effectCurrent = modes_alpha_order[effectCurrentIndex];
    lampUdated();
  }
  void changeEffectSpeed(bool increase) {
 #ifdef USERMOD_FOUR_LINE_DISLAY
    if (display && display->wakeDisplay()) {
      // Throw away wake up input
      return;
    }
 #endif
    if (increase) {
      effectSpeed = (effectSpeed + fadeAmount <= 255) ? (effectSpeed + fadeAmount) : 255;
    }
    else {
      effectSpeed = (effectSpeed - fadeAmount >= 0) ? (effectSpeed - fadeAmount) : 0;
    }
    lampUdated();
  }
  void changeEffectIntensity(bool increase) {
 #ifdef USERMOD_FOUR_LINE_DISLAY
    if (display && display->wakeDisplay()) {
      // Throw away wake up input
      return;
    }
 #endif
    if (increase) {
      effectIntensity = (effectIntensity + fadeAmount <= 255) ? (effectIntensity + fadeAmount) : 255;
    }
    else {
      effectIntensity = (effectIntensity - fadeAmount >= 0) ? (effectIntensity - fadeAmount) : 0;
    }
    lampUdated();
  }
  void changePalette(bool increase) {
 #ifdef USERMOD_FOUR_LINE_DISLAY
    if (display && display->wakeDisplay()) {
      // Throw away wake up input
      return;
    }
 #endif
    if (increase) {
      effectPaletteIndex = (effectPaletteIndex + 1 >= strip.getPaletteCount()) ? 0 : (effectPaletteIndex + 1);
    }
    else {
      effectPaletteIndex = (effectPaletteIndex - 1 < 0) ? (strip.getPaletteCount() - 1) : (effectPaletteIndex - 1);
    }
    effectPalette = palettes_alpha_order[effectPaletteIndex];
    lampUdated();
  }
  /*
     * addToJsonInfo() can be used to add custom entries to the /json/info part of the JSON API.
     * Creating an "u" object allows you to add custom key/value pairs to the Info section of the WLED web UI.
     * Below it is shown how this could be used for e.g. a light sensor
     */
  /*
    void addToJsonInfo(JsonObject& root)
    {
      int reading = 20;
      //this code adds "u":{"Light":[20," lux"]} to the info object
      JsonObject user = root["u"];
      if (user.isNull()) user = root.createNestedObject("u");
      JsonArray lightArr = user.createNestedArray("Light"); //name
      lightArr.add(reading); //value
      lightArr.add(" lux"); //unit
    }
    */
  /*
     * addToJsonState() can be used to add custom entries to the /json/state part of the JSON API (state object).
     * Values in the state object may be modified by connected clients
     */
  void addToJsonState(JsonObject &root)
  {
    //root["user0"] = userVar0;
  }
  /*
     * readFromJsonState() can be used to receive data clients send to the /json/state part of the JSON API (state object).
     * Values in the state object may be modified by connected clients
     */
  void readFromJsonState(JsonObject &root)
  {
    userVar0 = root["user0"] | userVar0; //if "user0" key exists in JSON, update, else keep old value
    //if (root["bri"] == 255) Serial.println(F("Don't burn down your garage!"));
  }
  /*
     * getId() allows you to optionally give your V2 usermod an unique ID (please define it in const.h!).
     * This could be used in the future for the system to determine whether your usermod is installed.
     */
  uint16_t getId()
  {
    return USERMOD_ID_ROTARY_ENC_UI;
  }
  //More methods can be added in the future, this example will then be extended.
  //Your usermod will remain compatible as it does not need to implement all methods from the Usermod base class!
 };
--- a/wled00/const.h
+++ b/wled00/const.h
@ -21,6 +21,9 @@
 #define USERMOD_ID_FIXNETSERVICES 4            //Usermod "usermod_Fix_unreachable_netservices.h"
 #define USERMOD_ID_PIRSWITCH      5            //Usermod "usermod_PIR_sensor_switch.h"
 #define USERMOD_ID_IMU            6            //Usermod "usermod_mpu6050_imu.h"
 #define USERMOD_ID_FOUR_LINE_DISP 7            //Usermod "usermod_v2_four_line_display.h 
 #define USERMOD_ID_ROTARY_ENC_UI  8            //Usermod "usermod_v2_rotary_encoder_ui.h"
 #define USERMOD_ID_AUTO_SAVE      9            //Usermod "usermod_v2_auto_save.h"
 //Access point behavior
 #define AP_BEHAVIOR_BOOT_NO_CONN  0            //Open AP when no connection after boot
--- a/wled00/fcn_declare.h
+++ b/wled00/fcn_declare.h
@ -221,6 +221,7 @@ class UsermodManager {
    void readFromConfig(JsonObject& obj);
    bool add(Usermod* um);
    Usermod* lookup(uint16_t mod_id);
    byte getModCount();
 };
--- a/wled00/um_manager.cpp
+++ b/wled00/um_manager.cpp
@ -15,6 +15,18 @@ void UsermodManager::readFromJsonState(JsonObject& obj) { for (byte i = 0; i < n
 void UsermodManager::addToConfig(JsonObject& obj)       { for (byte i = 0; i < numMods; i++) ums[i]->addToConfig(obj); }
 void UsermodManager::readFromConfig(JsonObject& obj)    { for (byte i = 0; i < numMods; i++) ums[i]->readFromConfig(obj); }
 /*
 * Enables usermods to lookup another Usermod.
 */
 Usermod* UsermodManager::lookup(uint16_t mod_id) {
  for (byte i = 0; i < numMods; i++) {
    if (ums[i]->getId() == mod_id) {
      return ums[i];
    }
  }
  return nullptr;
 }
 bool UsermodManager::add(Usermod* um)
 {
  if (numMods >= WLED_MAX_USERMODS || um == nullptr) return false;
--- a/wled00/usermods_list.cpp
+++ b/wled00/usermods_list.cpp
@ -21,6 +21,16 @@
 #include "usermod_v2_SensorsToMqtt.h"
 #endif
 #ifdef USERMOD_FOUR_LINE_DISLAY
 #include "../usermods/usermod_v2_four_line_display/usermod_v2_four_line_display.h"
 #endif
 #ifdef USERMOD_ROTARY_ENCODER_UI
 #include "../usermods/usermod_v2_rotary_encoder_ui/usermod_v2_rotary_encoder_ui.h"
 #endif
 #ifdef USERMOD_AUTO_SAVE
 #include "../usermods/usermod_v2_auto_save/usermod_v2_auto_save.h"
 #endif
 void registerUsermods()
 {
 /*
@ -39,4 +49,14 @@ void registerUsermods()
 #ifdef USERMOD_SENSORSTOMQTT
  usermods.add(new UserMod_SensorsToMQTT());
 #endif
 #ifdef USERMOD_FOUR_LINE_DISLAY
  usermods.add(new FourLineDisplayUsermod());
 #endif
 #ifdef USERMOD_ROTARY_ENCODER_UI
  usermods.add(new RotaryEncoderUIUsermod());
 #endif
 #ifdef USERMOD_AUTO_SAVE
  usermods.add(new AutoSaveUsermod());
 #endif
 }