#include "ThermalComponent.h" ThermalComponent::ThermalComponent(object_id_t reportingObjectId, uint8_t domainId, gp_id_t temperaturePoolId, gp_id_t targetStatePoolId, gp_id_t currentStatePoolId, gp_id_t requestPoolId, LocalPoolDataSetBase* dataSet, AbstractTemperatureSensor* sensor, AbstractTemperatureSensor* firstRedundantSensor, AbstractTemperatureSensor* secondRedundantSensor, ThermalModuleIF* thermalModule, Parameters parameters, Priority priority) : ThermalComponentCore(reportingObjectId, domainId, temperaturePoolId, targetStatePoolId, currentStatePoolId, requestPoolId, dataSet, { parameters.lowerOpLimit, parameters.upperOpLimit, parameters.heaterOn, parameters.hysteresis, parameters.heaterSwitchoff }, ThermalComponentIF::STATE_REQUEST_NON_OPERATIONAL), nopParameters({ parameters.lowerNopLimit, parameters.upperNopLimit }) { } ThermalComponent::~ThermalComponent() { } ReturnValue_t ThermalComponent::setTargetState(int8_t newState) { // GlobDataSet mySet; // gp_int8_t writableTargetState(targetState.getDataPoolId(), // &mySet, PoolVariableIF::VAR_READ_WRITE); // mySet.read(); // if ((writableTargetState == STATE_REQUEST_OPERATIONAL) // && (newState != STATE_REQUEST_IGNORE)) { // return HasReturnvaluesIF::RETURN_FAILED; // } // switch (newState) { // case STATE_REQUEST_NON_OPERATIONAL: // writableTargetState = newState; // mySet.commit(PoolVariableIF::VALID); // return HasReturnvaluesIF::RETURN_OK; // default: // return ThermalComponentCore::setTargetState(newState); // } return HasReturnvaluesIF::RETURN_OK; } ReturnValue_t ThermalComponent::setLimits(const uint8_t* data, size_t size) { if (size != 4 * sizeof(parameters.lowerOpLimit)) { return MonitoringIF::INVALID_SIZE; } size_t readSize = size; SerializeAdapter::deSerialize(&nopParameters.lowerNopLimit, &data, &readSize, SerializeIF::Endianness::BIG); SerializeAdapter::deSerialize(¶meters.lowerOpLimit, &data, &readSize, SerializeIF::Endianness::BIG); SerializeAdapter::deSerialize(¶meters.upperOpLimit, &data, &readSize, SerializeIF::Endianness::BIG); SerializeAdapter::deSerialize(&nopParameters.upperNopLimit, &data, &readSize, SerializeIF::Endianness::BIG); return HasReturnvaluesIF::RETURN_OK; } ThermalComponentIF::State ThermalComponent::getState(float temperature, ThermalComponentCore::Parameters parameters, int8_t targetState) { if (temperature < nopParameters.lowerNopLimit) { return OUT_OF_RANGE_LOW; } else { State state = ThermalComponentCore::getState(temperature, parameters, targetState); if (state != NON_OPERATIONAL_HIGH && state != NON_OPERATIONAL_HIGH_IGNORED) { return state; } if (temperature > nopParameters.upperNopLimit) { state = OUT_OF_RANGE_HIGH; } if (targetState == STATE_REQUEST_IGNORE) { state = getIgnoredState(state); } return state; } } void ThermalComponent::checkLimits(ThermalComponentIF::State state) { //if (targetState == STATE_REQUEST_OPERATIONAL || targetState == STATE_REQUEST_IGNORE) { // ThermalComponentCore::checkLimits(state); // return; //} //If component is not operational, it checks the NOP limits. //temperatureMonitor.translateState(state, temperature.value, // nopParameters.lowerNopLimit, nopParameters.upperNopLimit, false); } ThermalComponentIF::HeaterRequest ThermalComponent::getHeaterRequest( int8_t targetState, float temperature, ThermalComponentCore::Parameters parameters) { if (targetState == STATE_REQUEST_IGNORE) { isHeating = false; return HEATER_DONT_CARE; } if (temperature > nopParameters.upperNopLimit - parameters.heaterSwitchoff) { isHeating = false; return HEATER_REQUEST_EMERGENCY_OFF; } float nopHeaterLimit = nopParameters.lowerNopLimit + parameters.heaterOn; float opHeaterLimit = parameters.lowerOpLimit + parameters.heaterOn; if (isHeating) { nopHeaterLimit += parameters.hysteresis; opHeaterLimit += parameters.hysteresis; } if (temperature < nopHeaterLimit) { isHeating = true; return HEATER_REQUEST_EMERGENCY_ON; } if ((targetState == STATE_REQUEST_OPERATIONAL) || (targetState == STATE_REQUEST_HEATING)) { if (temperature < opHeaterLimit) { isHeating = true; return HEATER_REQUEST_ON; } if (temperature > parameters.upperOpLimit - parameters.heaterSwitchoff) { isHeating = false; return HEATER_REQUEST_OFF; } } isHeating = false; return HEATER_DONT_CARE; } ThermalComponentIF::State ThermalComponent::getIgnoredState(int8_t state) { switch (state) { case OUT_OF_RANGE_LOW: return OUT_OF_RANGE_LOW_IGNORED; case OUT_OF_RANGE_HIGH: return OUT_OF_RANGE_HIGH_IGNORED; case OUT_OF_RANGE_LOW_IGNORED: return OUT_OF_RANGE_LOW_IGNORED; case OUT_OF_RANGE_HIGH_IGNORED: return OUT_OF_RANGE_HIGH_IGNORED; default: return ThermalComponentCore::getIgnoredState(state); } } ReturnValue_t ThermalComponent::getParameter(uint8_t domainId, uint16_t parameterId, ParameterWrapper* parameterWrapper, const ParameterWrapper* newValues, uint16_t startAtIndex) { ReturnValue_t result = ThermalComponentCore::getParameter(domainId, parameterId, parameterWrapper, newValues, startAtIndex); if (result != INVALID_IDENTIFIER_ID) { return result; } switch (parameterId) { case 12: parameterWrapper->set(nopParameters.lowerNopLimit); break; case 13: parameterWrapper->set(nopParameters.upperNopLimit); break; default: return INVALID_IDENTIFIER_ID; } return HasReturnvaluesIF::RETURN_OK; }