Merge branch 'master' into merge-master

This commit is contained in:
Blaz Kristan 2022-04-04 21:16:18 +02:00
commit 70b4cdf520
5 changed files with 359 additions and 34 deletions

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# Si7021 to MQTT (with Home Assistant Auto Discovery) usermod
This usermod implements support for [Si7021 I²C temperature and humidity sensors](https://www.silabs.com/documents/public/data-sheets/Si7021-A20.pdf).
The sensor data will *not* be shown on the WLED UI (so far) but published via MQTT to WLED's "build in" MQTT device topic.
```
temperature: $mqttDeviceTopic/si7021_temperature
humidity: $mqttDeviceTopic/si7021_humidity
```
Additionally the following sensors can be published:
```
heat_index: $mqttDeviceTopic/si7021_heat_index
dew_point: $mqttDeviceTopic/si7021_dew_point
absolute_humidity: $mqttDeviceTopic/si7021_absolute_humidity
```
Sensor data will be updated/send every 60 seconds.
This usermod also supports Home Assistant Auto Discovery.
## Settings via Usermod Setup
- `enabled`: Enables this usermod
- `Send Dew Point, Abs. Humidity and Heat Index`: Enables additional sensors
- `Home Assistant MQTT Auto-Discovery`: Enables Home Assistant Auto Discovery
# Installation
## Hardware
Attach the Si7021 sensor to the I²C interface.
Default PINs ESP32:
```
SCL_PIN = 22;
SDA_PIN = 21;
```
Default PINs ESP8266:
```
SCL_PIN = 5;
SDA_PIN = 4;
```
## Software
Add to `build_flags` in platformio.ini:
```
-D USERMOD_SI7021_MQTT_HA
```
Add to `lib_deps` in platformio.ini:
```
adafruit/Adafruit Si7021 Library @ 1.4.0
BME280@~3.0.0
```
# Credits
- Aircoookie for making WLED
- Other usermod creators for example code (`sensors_to_mqtt` and `multi_relay` especially)
- You, for reading this

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#pragma once
// this is remixed from usermod_v2_SensorsToMqtt.h (sensors_to_mqtt usermod)
// and usermod_multi_relay.h (multi_relay usermod)
#include "wled.h"
#include <Adafruit_Si7021.h>
#include <EnvironmentCalculations.h> // EnvironmentCalculations::HeatIndex(), ::DewPoint(), ::AbsoluteHumidity()
Adafruit_Si7021 si7021;
#ifdef ARDUINO_ARCH_ESP32 //ESP32 boards
uint8_t SCL_PIN = 22;
uint8_t SDA_PIN = 21;
#else //ESP8266 boards
uint8_t SCL_PIN = 5;
uint8_t SDA_PIN = 4;
#endif
class Si7021_MQTT_HA : public Usermod
{
private:
bool sensorInitialized = false;
bool mqttInitialized = false;
float sensorTemperature = 0;
float sensorHumidity = 0;
float sensorHeatIndex = 0;
float sensorDewPoint = 0;
float sensorAbsoluteHumidity= 0;
String mqttTemperatureTopic = "";
String mqttHumidityTopic = "";
String mqttHeatIndexTopic = "";
String mqttDewPointTopic = "";
String mqttAbsoluteHumidityTopic = "";
unsigned long nextMeasure = 0;
bool enabled = false;
bool haAutoDiscovery = true;
bool sendAdditionalSensors = true;
// strings to reduce flash memory usage (used more than twice)
static const char _name[];
static const char _enabled[];
static const char _sendAdditionalSensors[];
static const char _haAutoDiscovery[];
void _initializeSensor()
{
sensorInitialized = si7021.begin();
Serial.printf("Si7021_MQTT_HA: sensorInitialized = %d\n", sensorInitialized);
}
void _initializeMqtt()
{
mqttTemperatureTopic = String(mqttDeviceTopic) + "/si7021_temperature";
mqttHumidityTopic = String(mqttDeviceTopic) + "/si7021_humidity";
mqttHeatIndexTopic = String(mqttDeviceTopic) + "/si7021_heat_index";
mqttDewPointTopic = String(mqttDeviceTopic) + "/si7021_dew_point";
mqttAbsoluteHumidityTopic = String(mqttDeviceTopic) + "/si7021_absolute_humidity";
// Update and publish sensor data
_updateSensorData();
_publishSensorData();
if (haAutoDiscovery) {
_publishHAMqttSensor("temperature", "Temperature", mqttTemperatureTopic, "temperature", "°C");
_publishHAMqttSensor("humidity", "Humidity", mqttHumidityTopic, "humidity", "%");
if (sendAdditionalSensors) {
_publishHAMqttSensor("heat_index", "Heat Index", mqttHeatIndexTopic, "temperature", "°C");
_publishHAMqttSensor("dew_point", "Dew Point", mqttDewPointTopic, "", "°C");
_publishHAMqttSensor("absolute_humidity", "Absolute Humidity", mqttAbsoluteHumidityTopic, "", "g/m³");
}
}
mqttInitialized = true;
}
void _publishHAMqttSensor(
const String &name,
const String &friendly_name,
const String &state_topic,
const String &deviceClass,
const String &unitOfMeasurement)
{
if (WLED_MQTT_CONNECTED) {
String topic = String("homeassistant/sensor/") + mqttClientID + "/" + name + "/config";
StaticJsonDocument<300> doc;
doc["name"] = String(serverDescription) + " " + friendly_name;
doc["state_topic"] = state_topic;
doc["unique_id"] = String(mqttClientID) + name;
if (unitOfMeasurement != "")
doc["unit_of_measurement"] = unitOfMeasurement;
if (deviceClass != "")
doc["device_class"] = deviceClass;
doc["expire_after"] = 1800;
JsonObject device = doc.createNestedObject("device"); // attach the sensor to the same device
device["name"] = String(serverDescription);
device["model"] = "WLED";
device["manufacturer"] = "Aircoookie";
device["identifiers"] = String("wled-") + String(serverDescription);
device["sw_version"] = VERSION;
String payload;
serializeJson(doc, payload);
mqtt->publish(topic.c_str(), 0, true, payload.c_str());
}
}
void _updateSensorData()
{
sensorTemperature = si7021.readTemperature();
sensorHumidity = si7021.readHumidity();
// Serial.print("Si7021_MQTT_HA: Temperature: ");
// Serial.print(sensorTemperature, 2);
// Serial.print("\tHumidity: ");
// Serial.print(sensorHumidity, 2);
if (sendAdditionalSensors) {
EnvironmentCalculations::TempUnit envTempUnit(EnvironmentCalculations::TempUnit_Celsius);
sensorHeatIndex = EnvironmentCalculations::HeatIndex(sensorTemperature, sensorHumidity, envTempUnit);
sensorDewPoint = EnvironmentCalculations::DewPoint(sensorTemperature, sensorHumidity, envTempUnit);
sensorAbsoluteHumidity = EnvironmentCalculations::AbsoluteHumidity(sensorTemperature, sensorHumidity, envTempUnit);
// Serial.print("\tHeat Index: ");
// Serial.print(sensorHeatIndex, 2);
// Serial.print("\tDew Point: ");
// Serial.print(sensorDewPoint, 2);
// Serial.print("\tAbsolute Humidity: ");
// Serial.println(sensorAbsoluteHumidity, 2);
}
// else
// Serial.println("");
}
void _publishSensorData()
{
if (WLED_MQTT_CONNECTED) {
mqtt->publish(mqttTemperatureTopic.c_str(), 0, false, String(sensorTemperature).c_str());
mqtt->publish(mqttHumidityTopic.c_str(), 0, false, String(sensorHumidity).c_str());
if (sendAdditionalSensors) {
mqtt->publish(mqttHeatIndexTopic.c_str(), 0, false, String(sensorHeatIndex).c_str());
mqtt->publish(mqttDewPointTopic.c_str(), 0, false, String(sensorDewPoint).c_str());
mqtt->publish(mqttAbsoluteHumidityTopic.c_str(), 0, false, String(sensorAbsoluteHumidity).c_str());
}
}
}
public:
void addToConfig(JsonObject& root)
{
JsonObject top = root.createNestedObject(FPSTR(_name));
top[FPSTR(_enabled)] = enabled;
top[FPSTR(_sendAdditionalSensors)] = sendAdditionalSensors;
top[FPSTR(_haAutoDiscovery)] = haAutoDiscovery;
}
bool readFromConfig(JsonObject& root)
{
JsonObject top = root[FPSTR(_name)];
bool configComplete = !top.isNull();
configComplete &= getJsonValue(top[FPSTR(_enabled)], enabled);
configComplete &= getJsonValue(top[FPSTR(_sendAdditionalSensors)], sendAdditionalSensors);
configComplete &= getJsonValue(top[FPSTR(_haAutoDiscovery)], haAutoDiscovery);
return configComplete;
}
void onMqttConnect(bool sessionPresent) {
if (mqttDeviceTopic[0] != 0)
_initializeMqtt();
}
void setup()
{
if (enabled) {
Serial.println("Si7021_MQTT_HA: Starting!");
Wire.begin(SDA_PIN, SCL_PIN);
Serial.println("Si7021_MQTT_HA: Initializing sensors.. ");
_initializeSensor();
}
}
// gets called every time WiFi is (re-)connected.
void connected()
{
nextMeasure = millis() + 5000; // Schedule next measure in 5 seconds
}
void loop()
{
yield();
if (!enabled || strip.isUpdating()) return; // !sensorFound ||
unsigned long tempTimer = millis();
if (tempTimer > nextMeasure) {
nextMeasure = tempTimer + 60000; // Schedule next measure in 60 seconds
if (!sensorInitialized) {
Serial.println("Si7021_MQTT_HA: Error! Sensors not initialized in loop()!");
_initializeSensor();
return; // lets try again next loop
}
if (WLED_MQTT_CONNECTED) {
if (!mqttInitialized)
_initializeMqtt();
// Update and publish sensor data
_updateSensorData();
_publishSensorData();
}
else {
Serial.println("Si7021_MQTT_HA: Missing MQTT connection. Not publishing data");
mqttInitialized = false;
}
}
}
uint16_t getId()
{
return USERMOD_ID_SI7021_MQTT_HA;
}
};
// strings to reduce flash memory usage (used more than twice)
const char Si7021_MQTT_HA::_name[] PROGMEM = "Si7021 MQTT (Home Assistant)";
const char Si7021_MQTT_HA::_enabled[] PROGMEM = "enabled";
const char Si7021_MQTT_HA::_sendAdditionalSensors[] PROGMEM = "Send Dew Point, Abs. Humidity and Heat Index";
const char Si7021_MQTT_HA::_haAutoDiscovery[] PROGMEM = "Home Assistant MQTT Auto-Discovery";

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@ -75,6 +75,7 @@
#define USERMOD_ID_WIZLIGHTS 26 //Usermod "wizlights.h" #define USERMOD_ID_WIZLIGHTS 26 //Usermod "wizlights.h"
#define USERMOD_ID_WORDCLOCK 27 //Usermod "usermod_v2_word_clock.h" #define USERMOD_ID_WORDCLOCK 27 //Usermod "usermod_v2_word_clock.h"
#define USERMOD_ID_MY9291 28 //Usermod "usermod_MY9291.h" #define USERMOD_ID_MY9291 28 //Usermod "usermod_MY9291.h"
#define USERMOD_ID_SI7021_MQTT_HA 29 //Usermod "usermod_si7021_mqtt_ha.h"
//Access point behavior //Access point behavior
#define AP_BEHAVIOR_BOOT_NO_CONN 0 //Open AP when no connection after boot #define AP_BEHAVIOR_BOOT_NO_CONN 0 //Open AP when no connection after boot

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@ -105,6 +105,13 @@ void handleE131Packet(e131_packet_t* p, IPAddress clientIP, byte protocol){
realtimeIP = clientIP; realtimeIP = clientIP;
byte wChannel = 0; byte wChannel = 0;
uint16_t totalLen = strip.getLengthTotal(); uint16_t totalLen = strip.getLengthTotal();
uint16_t availDMXLen = dmxChannels - DMXAddress + 1;
uint16_t dataOffset = DMXAddress;
// DMX data in Art-Net packet starts at index 0, for E1.31 at index 1
if (protocol == P_ARTNET && dataOffset > 0) {
dataOffset--;
}
switch (DMXMode) { switch (DMXMode) {
case DMX_MODE_DISABLED: case DMX_MODE_DISABLED:
@ -113,55 +120,55 @@ void handleE131Packet(e131_packet_t* p, IPAddress clientIP, byte protocol){
case DMX_MODE_SINGLE_RGB: // RGB only case DMX_MODE_SINGLE_RGB: // RGB only
if (uni != e131Universe) return; if (uni != e131Universe) return;
if (dmxChannels-DMXAddress+1 < 3) return; if (availDMXLen < 3) return;
realtimeLock(realtimeTimeoutMs, mde); realtimeLock(realtimeTimeoutMs, mde);
if (realtimeOverride && !(realtimeMode && useMainSegmentOnly)) return; if (realtimeOverride && !(realtimeMode && useMainSegmentOnly)) return;
wChannel = (dmxChannels-DMXAddress+1 > 3) ? e131_data[DMXAddress+3] : 0; wChannel = (availDMXLen > 3) ? e131_data[dataOffset+3] : 0;
for (uint16_t i = 0; i < totalLen; i++) for (uint16_t i = 0; i < totalLen; i++)
setRealtimePixel(i, e131_data[DMXAddress+0], e131_data[DMXAddress+1], e131_data[DMXAddress+2], wChannel); setRealtimePixel(i, e131_data[dataOffset+0], e131_data[dataOffset+1], e131_data[dataOffset+2], wChannel);
break; break;
case DMX_MODE_SINGLE_DRGB: // Dimmer + RGB case DMX_MODE_SINGLE_DRGB: // Dimmer + RGB
if (uni != e131Universe) return; if (uni != e131Universe) return;
if (dmxChannels-DMXAddress+1 < 4) return; if (availDMXLen < 4) return;
realtimeLock(realtimeTimeoutMs, mde); realtimeLock(realtimeTimeoutMs, mde);
if (realtimeOverride && !(realtimeMode && useMainSegmentOnly)) return; if (realtimeOverride && !(realtimeMode && useMainSegmentOnly)) return;
wChannel = (dmxChannels-DMXAddress+1 > 4) ? e131_data[DMXAddress+4] : 0; wChannel = (availDMXLen > 4) ? e131_data[dataOffset+4] : 0;
if (DMXOldDimmer != e131_data[DMXAddress+0]) { if (DMXOldDimmer != e131_data[dataOffset+0]) {
DMXOldDimmer = e131_data[DMXAddress+0]; DMXOldDimmer = e131_data[dataOffset+0];
bri = e131_data[DMXAddress+0]; bri = e131_data[dataOffset+0];
strip.setBrightness(bri, true); strip.setBrightness(bri, true);
} }
for (uint16_t i = 0; i < totalLen; i++) for (uint16_t i = 0; i < totalLen; i++)
setRealtimePixel(i, e131_data[DMXAddress+1], e131_data[DMXAddress+2], e131_data[DMXAddress+3], wChannel); setRealtimePixel(i, e131_data[dataOffset+1], e131_data[dataOffset+2], e131_data[dataOffset+3], wChannel);
break; break;
case DMX_MODE_EFFECT: // Length 1: Apply Preset ID, length 11-13: apply effect config case DMX_MODE_EFFECT: // Length 1: Apply Preset ID, length 11-13: apply effect config
if (uni != e131Universe) return; if (uni != e131Universe) return;
if (dmxChannels-DMXAddress+1 < 11) { if (availDMXLen < 11) {
if (dmxChannels-DMXAddress+1 > 1) return; if (availDMXLen > 1) return;
applyPreset(e131_data[DMXAddress+0], CALL_MODE_NOTIFICATION); applyPreset(e131_data[dataOffset+0], CALL_MODE_NOTIFICATION);
return; return;
} }
if (DMXOldDimmer != e131_data[DMXAddress+0]) { if (DMXOldDimmer != e131_data[dataOffset+0]) {
DMXOldDimmer = e131_data[DMXAddress+0]; DMXOldDimmer = e131_data[dataOffset+0];
bri = e131_data[DMXAddress+0]; bri = e131_data[dataOffset+0];
} }
if (e131_data[DMXAddress+1] < MODE_COUNT) if (e131_data[dataOffset+1] < MODE_COUNT)
effectCurrent = e131_data[DMXAddress+ 1]; effectCurrent = e131_data[dataOffset+ 1];
effectSpeed = e131_data[DMXAddress+ 2]; // flickers effectSpeed = e131_data[dataOffset+ 2]; // flickers
effectIntensity = e131_data[DMXAddress+ 3]; effectIntensity = e131_data[dataOffset+ 3];
effectPalette = e131_data[DMXAddress+ 4]; effectPalette = e131_data[dataOffset+ 4];
col[0] = e131_data[DMXAddress+ 5]; col[0] = e131_data[dataOffset+ 5];
col[1] = e131_data[DMXAddress+ 6]; col[1] = e131_data[dataOffset+ 6];
col[2] = e131_data[DMXAddress+ 7]; col[2] = e131_data[dataOffset+ 7];
colSec[0] = e131_data[DMXAddress+ 8]; colSec[0] = e131_data[dataOffset+ 8];
colSec[1] = e131_data[DMXAddress+ 9]; colSec[1] = e131_data[dataOffset+ 9];
colSec[2] = e131_data[DMXAddress+10]; colSec[2] = e131_data[dataOffset+10];
if (dmxChannels-DMXAddress+1 > 11) if (availDMXLen > 11)
{ {
col[3] = e131_data[DMXAddress+11]; //white col[3] = e131_data[dataOffset+11]; //white
colSec[3] = e131_data[DMXAddress+12]; colSec[3] = e131_data[dataOffset+12];
} }
transitionDelayTemp = 0; // act fast transitionDelayTemp = 0; // act fast
colorUpdated(CALL_MODE_NOTIFICATION); // don't send UDP colorUpdated(CALL_MODE_NOTIFICATION); // don't send UDP
@ -177,22 +184,26 @@ void handleE131Packet(e131_packet_t* p, IPAddress clientIP, byte protocol){
const uint16_t dmxChannelsPerLed = is4Chan ? 4 : 3; const uint16_t dmxChannelsPerLed = is4Chan ? 4 : 3;
const uint16_t ledsPerUniverse = is4Chan ? MAX_4_CH_LEDS_PER_UNIVERSE : MAX_3_CH_LEDS_PER_UNIVERSE; const uint16_t ledsPerUniverse = is4Chan ? MAX_4_CH_LEDS_PER_UNIVERSE : MAX_3_CH_LEDS_PER_UNIVERSE;
if (realtimeOverride && !(realtimeMode && useMainSegmentOnly)) return; if (realtimeOverride && !(realtimeMode && useMainSegmentOnly)) return;
uint16_t previousLeds, dmxOffset; uint16_t previousLeds, dmxOffset, ledsTotal;
if (previousUniverses == 0) { if (previousUniverses == 0) {
if (dmxChannels-DMXAddress < 1) return; if (availDMXLen < 1) return;
dmxOffset = DMXAddress; dmxOffset = dataOffset;
previousLeds = 0; previousLeds = 0;
// First DMX address is dimmer in DMX_MODE_MULTIPLE_DRGB mode. // First DMX address is dimmer in DMX_MODE_MULTIPLE_DRGB mode.
if (DMXMode == DMX_MODE_MULTIPLE_DRGB) { if (DMXMode == DMX_MODE_MULTIPLE_DRGB) {
strip.setBrightness(e131_data[dmxOffset++], true); strip.setBrightness(e131_data[dmxOffset++], true);
ledsTotal = (availDMXLen - 1) / dmxChannelsPerLed;
} else {
ledsTotal = availDMXLen / dmxChannelsPerLed;
} }
} else { } else {
// All subsequent universes start at the first channel. // All subsequent universes start at the first channel.
dmxOffset = (protocol == P_ARTNET) ? 0 : 1; dmxOffset = (protocol == P_ARTNET) ? 0 : 1;
uint16_t ledsInFirstUniverse = (MAX_CHANNELS_PER_UNIVERSE - DMXAddress) / dmxChannelsPerLed; uint16_t dimmerOffset = (DMXMode == DMX_MODE_MULTIPLE_DRGB) ? 1 : 0;
uint16_t ledsInFirstUniverse = ((MAX_CHANNELS_PER_UNIVERSE - DMXAddress + 1) - dimmerOffset) / dmxChannelsPerLed;
previousLeds = ledsInFirstUniverse + (previousUniverses - 1) * ledsPerUniverse; previousLeds = ledsInFirstUniverse + (previousUniverses - 1) * ledsPerUniverse;
ledsTotal = previousLeds + (dmxChannels / dmxChannelsPerLed);
} }
uint16_t ledsTotal = previousLeds + (dmxChannels - dmxOffset +1) / dmxChannelsPerLed;
if (!is4Chan) { if (!is4Chan) {
for (uint16_t i = previousLeds; i < ledsTotal; i++) { for (uint16_t i = previousLeds; i < ledsTotal; i++) {
setRealtimePixel(i, e131_data[dmxOffset], e131_data[dmxOffset+1], e131_data[dmxOffset+2], 0); setRealtimePixel(i, e131_data[dmxOffset], e131_data[dmxOffset+1], e131_data[dmxOffset+2], 0);

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@ -128,6 +128,10 @@
#include "../usermods/MY9291/usermode_MY9291.h" #include "../usermods/MY9291/usermode_MY9291.h"
#endif #endif
#ifdef USERMOD_SI7021_MQTT_HA
#include "../usermods/Si7021_MQTT_HA/usermod_si7021_mqtt_ha.h"
#endif
void registerUsermods() void registerUsermods()
{ {
/* /*
@ -243,4 +247,8 @@ void registerUsermods()
#ifdef USERMOD_MY9291 #ifdef USERMOD_MY9291
usermods.add(new MY9291Usermod()); usermods.add(new MY9291Usermod());
#endif #endif
#ifdef USERMOD_SI7021_MQTT_HA
usermods.add(new Si7021_MQTT_HA());
#endif
} }