ESPMegaPRO-v3-SDK/ESPMegaPRO-firmware/lib/ESPMegaPRO/ClimateIoT.cpp

132 lines
3.9 KiB
C++

#include <ClimateIoT.hpp>
ClimateIoT::ClimateIoT() {
}
ClimateIoT::~ClimateIoT() {
// Destructor implementation
}
bool ClimateIoT::begin(uint8_t card_id, ExpansionCard *card, PubSubClient *mqtt, char *base_topic) {
this->card = (ClimateCard *)card;
// Reister Callbacks
auto bindedSensorCallback = std::bind(&ClimateIoT::handleSensorUpdate, this, std::placeholders::_1, std::placeholders::_2);
this->card->registerSensorCallback(bindedSensorCallback);
auto bindedAirConditionerCallback = std::bind(&ClimateIoT::handleAirConditionerUpdate, this, std::placeholders::_1, std::placeholders::_2, std::placeholders::_3);
this->card->registerChangeCallback(bindedAirConditionerCallback);
return true;
}
void ClimateIoT::handleMqttMessage(char *topic, char *payload) {
uint8_t topic_length = strlen(topic);
if (this->processSetTemperatureMessage(topic, payload, topic_length))
return;
if (this->processSetModeMessage(topic, payload, topic_length))
return;
if (this->processSetFanSpeedMessage(topic, payload, topic_length))
return;
if (this->processRequestStateMessage(topic, payload, topic_length))
return;
}
void ClimateIoT::publishClimateTemperature() {
char payload[5];
itoa(this->card->getTemperature(), payload, 10);
this->publishRelative(AC_TEMPERATURE_REPORT_TOPIC, payload);
}
void ClimateIoT::publishClimateMode() {
char payload[2];
itoa(this->card->getMode(), payload, 10);
this->publishRelative(AC_MODE_REPORT_TOPIC, payload);
}
void ClimateIoT::publishClimateFanSpeed() {
char payload[2];
itoa(this->card->getFanSpeed(), payload, 10);
this->publishRelative(AC_FAN_SPEED_REPORT_TOPIC, payload);
}
void ClimateIoT::publishSensor() {
this->publishRoomTemperature();
this->publishHumidity();
}
void ClimateIoT::publishClimate() {
this->publishClimateTemperature();
this->publishClimateMode();
this->publishClimateFanSpeed();
}
void ClimateIoT::publishRoomTemperature() {
char payload[5];
itoa(this->card->getRoomTemperature(), payload, 10);
this->publishRelative(AC_ROOM_TEMPERATURE_REPORT_TOPIC, payload);
}
void ClimateIoT::publishHumidity() {
if (this->card->getSensorType() == AC_SENSOR_TYPE_DHT22) {
char payload[5];
itoa(this->card->getHumidity(), payload, 10);
this->publishRelative(AC_HUMIDITY_REPORT_TOPIC, payload);
}
}
void ClimateIoT::handleStateChange(uint8_t temperature, uint8_t mode, uint8_t fan_speed) {
this->publishClimate();
}
void ClimateIoT::publishReport() {
this->publishClimate();
this->publishSensor();
}
void ClimateIoT::subscribe() {
this->subscribeRelative(AC_TEMPERATURE_SET_TOPIC);
this->subscribeRelative(AC_MODE_SET_TOPIC);
this->subscribeRelative(AC_FAN_SPEED_SET_TOPIC);
}
void ClimateIoT::loop() {
}
uint8_t ClimateIoT::getType() {
return CARD_TYPE_CLIMATE;
}
bool ClimateIoT::processSetTemperatureMessage(char *topic, char *payload, uint8_t topic_length) {
if (!strcmp(topic, AC_TEMPERATURE_SET_TOPIC)) {
uint8_t temperature = atoi(payload);
this->card->setTemperature(temperature);
return true;
}
return false;
}
bool ClimateIoT::processSetModeMessage(char *topic, char *payload, uint8_t topic_length) {
if (!strcmp(topic, AC_MODE_SET_TOPIC)) {
uint8_t mode = atoi(payload);
this->card->setMode(mode);
return true;
}
return false;
}
bool ClimateIoT::processSetFanSpeedMessage(char *topic, char *payload, uint8_t topic_length) {
if (!strcmp(topic, AC_FAN_SPEED_SET_TOPIC)) {
uint8_t fan_speed = atoi(payload);
this->card->setFanSpeed(fan_speed);
return true;
}
return false;
}
bool ClimateIoT::processRequestStateMessage(char *topic, char *payload, uint8_t topic_length) {
if (!strcmp(topic, AC_REQUEST_STATE_TOPIC)) {
this->publishReport();
return true;
}
return false;
}