/** * @file JATerminalInterfaceGAM.cpp * @brief Source file for class JATerminalInterfaceGAM * @date Feb 19, 2019 * @author kuchida * * @copyright Copyright 2015 F4E | European Joint Undertaking for ITER and * the Development of Fusion Energy ('Fusion for Energy'). * Licensed under the EUPL, Version 1.1 or - as soon they will be approved * by the European Commission - subsequent versions of the EUPL (the "Licence") * You may not use this work except in compliance with the Licence. * You may obtain a copy of the Licence at: http://ec.europa.eu/idabc/eupl * * @warning Unless required by applicable law or agreed to in writing, * software distributed under the Licence is distributed on an "AS IS" * basis, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express * or implied. See the Licence permissions and limitations under the Licence. * @details This source file contains the definition of all the methods for * the class JATerminalInterfaceGAM (public, protected, and private). Be aware that some * methods, such as those inline could be defined on the header file, instead. */ /*---------------------------------------------------------------------------*/ /* Standard header includes */ /*---------------------------------------------------------------------------*/ /*---------------------------------------------------------------------------*/ /* Project header includes */ /*---------------------------------------------------------------------------*/ #include "JATerminalInterfaceGAM.h" #include "AdvancedErrorManagement.h" /*---------------------------------------------------------------------------*/ /* Static definitions */ /*---------------------------------------------------------------------------*/ /*---------------------------------------------------------------------------*/ /* Method definitions */ /*---------------------------------------------------------------------------*/ JATerminalInterfaceGAM::JATerminalInterfaceGAM() { // Fixed GAM input aps_hvon_term = 0; // Parameters which get from Input signals. mhvps_hvon = NULL_PTR(MARTe::uint32 *); aps_hvon = NULL_PTR(MARTe::uint32 *); aps_swon = NULL_PTR(MARTe::uint32 *); bps_hvon = NULL_PTR(MARTe::uint32 *); bps_swon = NULL_PTR(MARTe::uint32 *); stateMachineOutput = NULL_PTR(MARTe::uint32 *); // write out target. outputSignalNI6259 = NULL_PTR(MARTe::uint32 *); outputSignalNI6528P3 = NULL_PTR(MARTe::uint8 *); outputSignalNI6528P4 = NULL_PTR(MARTe::uint8 *); aps_hvon_state = 0; aps_swon_state = 0; mhvps_hvon_state = 0; bps_hvon_state = 0; bps_swon_state = 0; p3Value = 0; p4Value = 0; } JATerminalInterfaceGAM::~JATerminalInterfaceGAM() { } bool JATerminalInterfaceGAM::Initialise(MARTe::StructuredDataI & data) { using namespace MARTe; bool ok = GAM::Initialise(data); if (ok) { ok = data.Read("mhvps_hvon_term", mhvps_hvon_term); if (!ok) { REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The mhvps_hvon_term shall be specified"); } } if (ok) { ok = data.Read("aps_hvon_term", aps_hvon_term); if (!ok) { REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The aps_hvon_term shall be specified"); } } if (ok) { ok = data.Read("aps_swon_term", aps_swon_term); if (!ok) { REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The aps_swon_term shall be specified"); } } if (ok) { ok = data.Read("bps_hvon_term", bps_hvon_term); if (!ok) { REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The bps_hvon_term shall be specified"); } } if (ok) { ok = data.Read("bps_swon_term", bps_swon_term); if (!ok) { REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The bps_swon_term shall be specified"); } } return ok; } bool JATerminalInterfaceGAM::PrepareNextState(const MARTe::char8 * const currentStateName, const MARTe::char8 * const nextStateName) { return true; } bool JATerminalInterfaceGAM::Setup() { using namespace MARTe; bool ok = (numberOfInputSignals == 9u); if (ok) { ok = (numberOfOutputSignals == 3u); if (!ok) { REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "Three output signals shall be defined"); } } else { REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "Nine input signals shall be defined"); } if (ok) { uint32 c; for (c = 0u; c < numberOfInputSignals; c++) { TypeDescriptor inputType = GetSignalType(InputSignals, c); ok = (inputType == UnsignedInteger32Bit || inputType == UnsignedInteger8Bit); if (!ok) { StreamString signalName; (void) GetSignalName(InputSignals, c, signalName); REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "Signal %s shall be defined as uint32 or uint8", signalName.Buffer()); } } } if (ok) { uint32 c; for (c = 0u; c < numberOfOutputSignals; c++) { TypeDescriptor outputType = GetSignalType(OutputSignals, c); ok = (outputType == UnsignedInteger32Bit || outputType == UnsignedInteger8Bit); if (!ok) { StreamString signalName; (void) GetSignalName(InputSignals, c, signalName); REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "Signal %s shall be defined as uint32 or uint8", signalName.Buffer()); } } } if (ok) { //mhvps_manm = reinterpret_cast(GetInputSignalMemory(0)); mhvps_hvon = reinterpret_cast(GetInputSignalMemory(0)); //aps_manm = reinterpret_cast(GetInputSignalMemory(2)); aps_hvon = reinterpret_cast(GetInputSignalMemory(1)); aps_swon = reinterpret_cast(GetInputSignalMemory(2)); //bps_manm = reinterpret_cast(GetInputSignalMemory(5)); bps_hvon = reinterpret_cast(GetInputSignalMemory(3)); bps_swon = reinterpret_cast(GetInputSignalMemory(4)); short_pulse_mode = reinterpret_cast(GetInputSignalMemory(5)); stateMachineOutput = reinterpret_cast(GetInputSignalMemory(6)); ni6528p3Value = reinterpret_cast(GetInputSignalMemory(7)); ni6528p4Value = reinterpret_cast(GetInputSignalMemory(8)); outputSignalNI6259 = reinterpret_cast(GetOutputSignalMemory(0)); outputSignalNI6528P3 = reinterpret_cast(GetOutputSignalMemory(1)); outputSignalNI6528P4 = reinterpret_cast(GetOutputSignalMemory(2)); } return ok; } bool JATerminalInterfaceGAM::Execute() { using namespace MARTe; uint8 sm = *stateMachineOutput; //Update HVPS state aps_hvon_state = ((sm >> (0))&1); aps_swon_state = ((sm >> (4))&1); mhvps_hvon_state = ((sm >> (2))&1); bps_hvon_state = ((sm >> (1))&1); bps_swon_state = ((sm >> (3))&1); if(*short_pulse_mode == 1){ p3Value = 1*aps_hvon_state + 8*bps_hvon_state +16*bps_swon_state; *outputSignalNI6259 = 1*aps_swon_state; //uint8 ni6528p3ValueTemp = 0;//*ni6528p3Value; //ni6528p3ValueTemp &= ~(1<<2); //Does not turn on ni6258 aps switch //Update terminal value //*outputSignalNI6528P3 = ~(ni6528p3ValueTemp | p3Value); *outputSignalNI6528P3 = ~p3Value; //REPORT_ERROR(ErrorManagement::Debug, "short pulse mode with p3: %d.", p3Value); } else { p3Value = 1*aps_hvon_state +2*aps_swon_state + 8*bps_hvon_state +16*bps_swon_state; //REPORT_ERROR(ErrorManagement::Debug, "long pulse mode with p3: %d.", p3Value); } p4Value = 8*mhvps_hvon_state; *outputSignalNI6528P4 = ~(*ni6528p4Value | p4Value); return true; } CLASS_REGISTER(JATerminalInterfaceGAM, "1.0")