#include #include "esp_log.h" AnalogCard::AnalogCard() : dac0(DAC0_ADDRESS), dac1(DAC1_ADDRESS), dac2(DAC2_ADDRESS), dac3(DAC3_ADDRESS), analogInputBankA(), analogInputBankB(), dac_change_callbacks() { } void AnalogCard::dacWrite(uint8_t pin, uint16_t value) { ESP_LOGV("AnalogCard", "DAC Write: %d, %d", pin, value); this->setDACState(pin, value > 0); this->setDACValue(pin, value); } void AnalogCard::setDACState(uint8_t pin, bool state) { ESP_LOGD("AnalogCard", "Setting DAC state: %d, %d", pin, state); this->dac_state[pin] = state; this->sendDataToDAC(pin, this->dac_value[pin]*state); for (int i = 0; i < this->dac_change_callbacks.size(); i++) { this->dac_change_callbacks[i](pin, state, this->dac_value[pin]); } } void AnalogCard::setDACValue(uint8_t pin, uint16_t value) { ESP_LOGD("AnalogCard", "Setting DAC value: %d, %d", pin, value); this->dac_value[pin] = value; this->sendDataToDAC(pin, value*this->dac_state[pin]); for (int i = 0; i < this->dac_change_callbacks.size(); i++) { this->dac_change_callbacks[i](pin, this->dac_state[pin], value); } } uint16_t AnalogCard::getDACValue(uint8_t pin) { return this->dac_value[pin]; } bool AnalogCard::getDACState(uint8_t pin) { return this->dac_state[pin]; } void AnalogCard::sendDataToDAC(uint8_t pin, uint16_t value) { switch (pin) { case 0: this->dac0.writeDAC(value); break; case 1: this->dac1.writeDAC(value); break; case 2: this->dac2.writeDAC(value); break; case 3: this->dac3.writeDAC(value); break; } } uint16_t AnalogCard::analogRead(uint8_t pin) { if (pin >= 0 && pin <= 3) { return this->analogInputBankA.readADC_SingleEnded(pin); } else if (pin >= 4 && pin <= 7) { return this->analogInputBankB.readADC_SingleEnded(pin - 4); } return 65535; } bool AnalogCard::begin() { if (!this->dac0.begin()) { ESP_LOGE("AnalogCard", "Card Analog ERROR: Failed to install DAC0"); return false; } if (!this->dac1.begin()) { ESP_LOGE("AnalogCard", "Card Analog ERROR: Failed to install DAC1"); return false; } if (!this->dac2.begin()) { ESP_LOGE("AnalogCard", "Card Analog ERROR: Failed to install DAC2"); return false; } if (!this->dac3.begin()) { ESP_LOGE("AnalogCard", "Card Analog ERROR: Failed to install DAC3"); return false; } if (!this->analogInputBankA.begin()) { ESP_LOGE("AnalogCard", "Card Analog ERROR: Failed to install analog input bank A"); return false; } if (!this->analogInputBankB.begin()) { ESP_LOGE("AnalogCard", "Card Analog ERROR: Failed to install analog input bank B"); return false; } return true; } void AnalogCard::loop() { } uint8_t AnalogCard::getType() { return CARD_TYPE_ANALOG; } void AnalogCard::registerDACChangeCallback(std::function callback) { this->dac_change_callbacks.push_back(callback); } // void AnalogCard::deregisterDACChangeCallback(std::function callback) // { // for (int i = 0; i < this->dac_change_callbacks.size(); i++) // { // if (this->dac_change_callbacks[i].target() == callback.target()) // { // this->dac_change_callbacks.erase(this->dac_change_callbacks.begin() + i); // break; // } // } // }