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

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#include <InternalDisplay.hpp>
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void InternalDisplay::begin(ESPMegaIoT *iot, std::function<rtctime_t()> getRtcTime) {
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ESP_LOGD("InternalDisplay", "Assigning IoT Module and RTC Time Getter");
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this->iot = iot;
this->getRtcTime = getRtcTime;
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ESP_LOGD("InternalDisplay", "Acquiring Network and MQTT Configs");
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this->mqttConfig = this->iot->getMqttConfig();
this->networkConfig = this->iot->getNetworkConfig();
// Register callbacks
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ESP_LOGD("InternalDisplay", "Registering Callbacks");
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auto bindedPageChangeCallback = std::bind(&InternalDisplay::handlePageChange, this, std::placeholders::_1);
this->registerPageChangeCallback(bindedPageChangeCallback);
auto bindedTouchCallback = std::bind(&InternalDisplay::handleTouch, this, std::placeholders::_1, std::placeholders::_2, std::placeholders::_3);
this->registerTouchCallback(bindedTouchCallback);
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ESP_LOGD("InternalDisplay", "Binding Page Change Callback");
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auto bindedInputStateChangeCallback = std::bind(&InternalDisplay::handleInputStateChange, this, std::placeholders::_1, std::placeholders::_2);
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ESP_LOGD("InternalDisplay", "Binding Input State Change Callback");
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auto bindedPwmStateChangeCallback = std::bind(&InternalDisplay::handlePwmStateChange, this, std::placeholders::_1, std::placeholders::_2, std::placeholders::_3);
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ESP_LOGD("InternalDisplay", "Registering inputCard Callbacks");
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this->inputCard->registerCallback(bindedInputStateChangeCallback);
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ESP_LOGD("InternalDisplay", "Registering outputCard Callbacks");
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this->outputCard->registerChangeCallback(bindedPwmStateChangeCallback);
// Initialize the display
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ESP_LOGD("InternalDisplay", "Initializing DisplayAdapter");
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this->displayAdapter->begin(115200);
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ESP_LOGD("InternalDisplay", "Setting DisplayAdapter Timeout");
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this->displayAdapter->setTimeout(100);
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ESP_LOGD("InternalDisplay", "Flushing DisplayAdapter");
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this->displayAdapter->flush();
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ESP_LOGD("InternalDisplay", "Resetting Display");
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this->reset();
delay(500);
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ESP_LOGD("InternalDisplay", "Jumping to Page 1");
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this->jumpToPage(1);
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ESP_LOGD("InternalDisplay", "Display Initialization Complete");
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}
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void InternalDisplay::loop() {
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// Keep reading the Serial Adapter
this->recieveSerialCommand();
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// Refresh the top bar every 5 seconds
static uint32_t lastTopBarRefresh;
if (millis() - lastTopBarRefresh > INTERNAL_DISPLAY_TOP_BAR_REFRESH_INTERVAL) {
this->updateStatusIcons(this->iot->networkConnected(), this->iot->mqttConnected());
lastTopBarRefresh = millis();
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}
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// Refresh the clock every 10 seconds
static uint32_t lastClockRefresh;
if (millis() - lastClockRefresh > INTERNAL_DISPLAY_CLOCK_REFRESH_INTERVAL) {
this->updateClock();
lastClockRefresh = millis();
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}
}
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void InternalDisplay::handleInputStateChange(uint8_t pin, bool state) {
// If the input card is binded to the display and the current page is the input page
// then update the respective input component
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if (this->inputCard!=nullptr || this->currentPage != INTERNAL_DISPLAY_INPUT_PAGE) return;
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// Update the input state
this->setInputMarker(pin, state);
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}
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void InternalDisplay::handlePwmStateChange(uint8_t pin, bool state, uint16_t value) {
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// If the output card is binded to the display and the current page is the output page
// then update the respective output component
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if (this->outputCard!=nullptr || this->currentPage != INTERNAL_DISPLAY_OUTPUT_PAGE) return;
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// Update the output state
this->setOutputBar(pin, value);
this->setOutputStateColor(pin, state);
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// Refresh the PWM Adjustment page if the current page is the PWM Adjustment page and the pin is the same
if (this->currentPage == INTERNAL_DISPLAY_PWM_ADJUSTMENT_PAGE && this->pmwAdjustmentPin == pin) {
this->refreshPWMAdjustment();
}
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}
void InternalDisplay::handlePageChange(uint8_t page) {
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// Refresh the page
this->refreshPage(page);
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}
void InternalDisplay::saveNetworkConfig() {
// TODO: implementation
}
void InternalDisplay::saveMQTTConfig() {
// TODO: implementation
}
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void InternalDisplay::updateStatusIcons(bool networkStatus, bool mqttStatus) {
this->setNumber("server.pic", mqttStatus ? PIC_MQTT_CONNECTED : PIC_MQTT_DISCONNECTED);
this->setNumber("lan.pic", networkStatus ? PIC_LAN_CONNECTED : PIC_LAN_DISCONNECTED);
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}
void InternalDisplay::updateClock() {
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rtctime_t time = this->getRtcTime();
this->displayAdapter->print("time.txt=");
this->displayAdapter->print(time.hours%12);
this->displayAdapter->print(":");
this->displayAdapter->print(time.minutes);
this->displayAdapter->print(" ");
this->displayAdapter->print(time.hours/12 ? "PM" : "AM");
this->sendStopBytes();
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}
void InternalDisplay::refreshPage() {
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this->refreshPage(this->currentPage);
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}
void InternalDisplay::refreshPage(uint8_t page) {
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switch (page) {
case INTERNAL_DISPLAY_DASHBOARD_PAGE:
this->refreshDashboard();
break;
case INTERNAL_DISPLAY_INPUT_PAGE:
this->refreshInput();
break;
case INTERNAL_DISPLAY_OUTPUT_PAGE:
this->refreshOutput();
break;
case INTERNAL_DISPLAY_AC_PAGE:
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if (this->climateCard == nullptr) {
this->jumpToPage(INTERNAL_DISPLAY_CLIMATE_NULL_PTR_PAGE);
break;
}
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this->refreshAC();
break;
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case INTERNAL_DISPLAY_PWM_ADJUSTMENT_PAGE:
this->refreshPWMAdjustment();
break;
default:
break;
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}
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}
void InternalDisplay::refreshDashboard() {
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// The dashboard have the following components:
// 1. Hostname
// 2. IP Address
// 3. MQTT Server with port
// 4. MQTT Connection status
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this->setString("hostname.txt", this->networkConfig->hostname);
// Construct the IP address string
static char ip_address[25];
sprintf(ip_address, "%d.%d.%d.%d", this->networkConfig->ip[0], this->networkConfig->ip[1], this->networkConfig->ip[2], this->networkConfig->ip[3]);
this->setString("ip_address.txt", ip_address);
// Send the MQTT server and port
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this->displayAdapter->print("server_address.txt=\"");
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this->displayAdapter->print(this->mqttConfig->mqtt_server);
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this->displayAdapter->print("\"");
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this->sendStopBytes();
// Send the MQTT connection status
this->setString("status_txt.txt", this->iot->mqttConnected() ? MSG_MQTT_CONNECTED : MSG_MQTT_DISCONNECTED);
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}
void InternalDisplay::refreshInput() {
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for (uint8_t i=0; i<16; i++) {
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this->setInputMarker(i, this->inputCard->digitalRead(i, false));
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}
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}
void InternalDisplay::refreshOutput() {
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for (uint8_t i=0; i<16; i++) {
this->setOutputBar(i, this->outputCard->getValue(i));
this->setOutputStateColor(i, this->outputCard->getState(i));
}
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}
void InternalDisplay::refreshAC() {
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this->displayAdapter->print("temp.txt=\"");
this->displayAdapter->print(this->climateCard->getTemperature());
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this->displayAdapter->print("C\"");
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this->sendStopBytes();
this->displayAdapter->print("fan_auto.pic=");
this->displayAdapter->print(this->climateCard->getFanSpeed() == AC_FAN_SPEED_AUTO ? PIC_AC_FAN_SPEED_AUTO_ACTIVE : PIC_AC_FAN_SPEED_AUTO_INACTIVE);
this->sendStopBytes();
this->displayAdapter->print("fan_low.pic=");
this->displayAdapter->print(this->climateCard->getFanSpeed() == AC_FAN_SPEED_LOW ? PIC_AC_FAN_SPEED_LOW_ACTIVE : PIC_AC_FAN_SPEED_LOW_INACTIVE);
this->sendStopBytes();
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this->displayAdapter->print("fan_mid.pic=");
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this->displayAdapter->print(this->climateCard->getFanSpeed() == AC_FAN_SPEED_MEDIUM ? PIC_AC_FAN_SPEED_MEDIUM_ACTIVE : PIC_AC_FAN_SPEED_MEDIUM_INACTIVE);
this->sendStopBytes();
this->displayAdapter->print("fan_high.pic=");
this->displayAdapter->print(this->climateCard->getFanSpeed() == AC_FAN_SPEED_HIGH ? PIC_AC_FAN_SPEED_HIGH_ACTIVE : PIC_AC_FAN_SPEED_HIGH_INACTIVE);
this->sendStopBytes();
this->displayAdapter->print("mode_off.pic=");
this->displayAdapter->print(this->climateCard->getMode() == AC_MODE_OFF ? PIC_AC_MODE_OFF_ACTIVE : PIC_AC_MODE_OFF_INACTIVE);
this->sendStopBytes();
this->displayAdapter->print("mode_fan.pic=");
this->displayAdapter->print(this->climateCard->getMode() == AC_MODE_FAN_ONLY ? PIC_AC_MODE_FAN_ACTIVE : PIC_AC_MODE_FAN_INACTIVE);
this->sendStopBytes();
this->displayAdapter->print("mode_cool.pic=");
this->displayAdapter->print(this->climateCard->getMode() == AC_MODE_COOL ? PIC_AC_MODE_COOL_ACTIVE : PIC_AC_MODE_COOL_INACTIVE);
this->sendStopBytes();
if (this->climateCard->getSensorType() == AC_SENSOR_TYPE_DHT22) {
this->displayAdapter->print("roomtemp.txt=\"");
this->displayAdapter->print(this->climateCard->getRoomTemperature());
this->displayAdapter->print("C\"");
this->sendStopBytes();
this->displayAdapter->print("roomhumid.txt=\"");
this->displayAdapter->print(this->climateCard->getHumidity());
this->displayAdapter->print("%\"");
this->sendStopBytes();
}
else if(this->climateCard->getSensorType() == AC_SENSOR_TYPE_DS18B20) {
this->displayAdapter->print("roomtemp.txt=\"");
this->displayAdapter->print(this->climateCard->getRoomTemperature());
this->displayAdapter->print("C\"");
this->sendStopBytes();
this->setString("roomhumid.txt", "N/A");
}
else {
this->setString("roomtemp.txt", "N/A");
this->setString("roomhumid.txt", "N/A");
}
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}
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void InternalDisplay::setOutputBar(uint8_t pin, uint16_t value) {
// Write the value to the output bar
this->displayAdapter->print("j");
this->displayAdapter->print(pin);
this->displayAdapter->print(".val=");
this->displayAdapter->print((int)(value*100/4095));
this->sendStopBytes();
}
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void InternalDisplay::setOutputStateColor(uint8_t pin, bool state) {
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this->displayAdapter->print("j");
this->displayAdapter->print(pin);
this->displayAdapter->print(".ppic=");
this->displayAdapter->print(state ? PIC_PWM_BAR_ON : PIC_PWM_BAR_OFF);
this->sendStopBytes();
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}
void InternalDisplay::setInputMarker(uint8_t pin, bool state) {
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this->displayAdapter->print("I");
this->displayAdapter->print(pin);
this->displayAdapter->print(".val=");
this->displayAdapter->print(state ? 0:1);
this->sendStopBytes();
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}
InternalDisplay::InternalDisplay(HardwareSerial *displayAdapter) : ESPMegaDisplay(displayAdapter) {
this->currentPage = INTERNAL_DISPLAY_DASHBOARD_PAGE;
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this->iot = nullptr;
this->inputCard = nullptr;
this->outputCard = nullptr;
this->climateCard = nullptr;
this->pmwAdjustmentPin = 0;
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}
void InternalDisplay::bindInputCard(DigitalInputCard *inputCard) {
this->inputCard = inputCard;
}
void InternalDisplay::bindOutputCard(DigitalOutputCard *outputCard) {
this->outputCard = outputCard;
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}
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// This assume that your ClimeateCard has the mode and fan speed names in the following order:
// mode: [off, fan_only, cool]
// fan_speed: [auto, low, medium, high]
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void InternalDisplay::bindClimateCard(ClimateCard *climateCard) {
this->climateCard = climateCard;
}
void InternalDisplay::refreshPWMAdjustment() {
// The PWM Adjustment page have the following components:
// pwm_value -> a slider to adjust the PWM value
// pwm_state -> a button to toggle the PWM state
// pwm_id -> a text to show the PWM pin
// Refresh the PWM pin
this->refreshPWMAdjustmentId();
// Refresh the PWM value
this->refreshPWMAdjustmentSlider();
// Refresh the PWM state
this->refreshPWMAdjustmentState();
}
void InternalDisplay::refreshPWMAdjustmentId() {
// Send the PWM pin
this->displayAdapter->print("pwm_id.txt=\"P");
this->displayAdapter->print(pmwAdjustmentPin);
this->displayAdapter->print("\"");
this->sendStopBytes();
}
void InternalDisplay::refreshPWMAdjustmentSlider() {
// Send the PWM value
this->displayAdapter->print("pwm_value.val=");
this->displayAdapter->print(this->outputCard->getValue(this->pmwAdjustmentPin));
this->sendStopBytes();
}
void InternalDisplay::refreshPWMAdjustmentState() {
// Send the PWM state
this->displayAdapter->print("pwm_state.txt=\"");
this->displayAdapter->print(this->outputCard->getState(this->pmwAdjustmentPin) ? MSG_PWM_ADJUSTMENT_STATE_ON : MSG_PWM_ADJUSTMENT_STATE_OFF);
this->displayAdapter->print("\"");
this->sendStopBytes();
}
void InternalDisplay::handleTouch(uint8_t page, uint8_t component, uint8_t type) {
// Switch based on the page
switch (page) {
case INTERNAL_DISPLAY_AC_PAGE:
this->handleACTouch(type, component);
break;
case INTERNAL_DISPLAY_PWM_ADJUSTMENT_PAGE:
this->handlePWMAdjustmentTouch(type, component);
break;
default:
break;
}
}
void InternalDisplay::handleACTouch(uint8_t type, uint8_t component) {
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// b1 [component 18] -> inclement AC temperature by 1
// b0 [component 17] -> declement AC temperature by 1
// fan_auto [component 4] -> set the fan speed to auto
// fan_low [component 5] -> set the fan speed to low
// fan_med [component 6] -> set the fan speed to medium
// fan_high [component 7] -> set the fan speed to high
// mode_off [component 10] -> set the mode to off
// mode_fan [component 9] -> set the mode to fan only
// mode_cool [component 8] -> set the mode to cool
// For b0 and b1, if the type is not release then return
// For other components, if the type is not press then return
if ((component == 17 || component == 18) && type != TOUCH_TYPE_RELEASE) return;
if ((component != 17 && component != 18) && type != TOUCH_TYPE_PRESS) return;
// Switch based on the component
switch (component) {
case 17:
// Decrement the temperature
this->climateCard->setTemperature(this->climateCard->getTemperature() - 1);
break;
case 18:
// Increment the temperature
this->climateCard->setTemperature(this->climateCard->getTemperature() + 1);
break;
case 4:
// Set the fan speed to auto
this->climateCard->setFanSpeed(AC_FAN_SPEED_AUTO);
break;
case 5:
// Set the fan speed to low
this->climateCard->setFanSpeed(AC_FAN_SPEED_LOW);
break;
case 6:
// Set the fan speed to medium
this->climateCard->setFanSpeed(AC_FAN_SPEED_MEDIUM);
break;
case 7:
// Set the fan speed to high
this->climateCard->setFanSpeed(AC_FAN_SPEED_HIGH);
break;
case 10:
// Set the mode to off
this->climateCard->setMode(AC_MODE_OFF);
break;
case 9:
// Set the mode to fan only
this->climateCard->setMode(AC_MODE_FAN_ONLY);
break;
case 8:
// Set the mode to cool
this->climateCard->setMode(AC_MODE_COOL);
break;
default:
break;
}
// Refresh the AC page
this->refreshAC();
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}
void InternalDisplay::handlePWMAdjustmentTouch(uint8_t type, uint8_t component) {
// b0 [component 5] -> decrement the PWM id if its greater than 0, else set it to 15
// b1 [component 6] -> increment the PWM id if its less than 15, else set it to 0
// pwm_state [component 4] -> toggle the PWM state
// pwm_value [component 1] -> set the PWM value based on the slider value
// If the type is not release then return
if (type != TOUCH_TYPE_RELEASE) return;
uint16_t val = 0;
// switch based on the component
switch (component) {
case 5:
// Decrement the PWM id
this->pmwAdjustmentPin = this->pmwAdjustmentPin > 0 ? this->pmwAdjustmentPin - 1 : 15;
this->refreshPWMAdjustment();
break;
case 6:
// Increment the PWM id
this->pmwAdjustmentPin = this->pmwAdjustmentPin < 15 ? this->pmwAdjustmentPin + 1 : 0;
this->refreshPWMAdjustment();
break;
case 4:
// Toggle the PWM state
this->outputCard->setState(this->pmwAdjustmentPin, !this->outputCard->getState(this->pmwAdjustmentPin));
this->refreshPWMAdjustmentState();
break;
case 1:
// Set the PWM value
val = (uint16_t)this -> getNumber("pwm_value.val");
this->outputCard->setValue(this->pmwAdjustmentPin, val);
break;
default:
break;
}
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}