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MARTe2-isttok/GAMs/ElectricProbesGAM/ElectricProbesGAM.cpp
Bernardo Carvalho c76250d3ab Added EProbes GAM 
Signed-off-by: Bernardo Carvalho <bernardo.carvalho@tecnico.ulisboa.pt>
2024-11-18 15:23:40 +00:00

256 lines
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/**
* @file ElectricProbesGAM.cpp
* @brief Source file for class ElectricProbesGAM
* @date 06/04/2018
* @author Andre Neto
*
* @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 ElectricProbesGAM (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 "AdvancedErrorManagement.h"
#include "ElectricProbesGAM.h"
/*---------------------------------------------------------------------------*/
/* Static definitions */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Method definitions */
/*---------------------------------------------------------------------------*/
namespace MARTeIsttok {
ElectricProbesGAM::ElectricProbesGAM() :
GAM(),
MessageI() {
gain = 0u;
//inputSignals = NULL_PTR(MARTe::float32 **);
//outputSignals = NULL_PTR(MARTe::float32 **);
// outputSignal1 = NULL;
inputElectricTop = NULL_PTR(MARTe::float32 *);
inputElectricInner = NULL_PTR(MARTe::float32 *);
inputElectricOuter = NULL_PTR(MARTe::float32 *);
inputElectricBottom = NULL_PTR(MARTe::float32 *);
outputEpR = NULL_PTR(MARTe::float32 *);
outputEpZ = NULL_PTR(MARTe::float32 *);
}
ElectricProbesGAM::~ElectricProbesGAM() {
//if (inputSignals != NULL_PTR(MARTe::float32 **)) {
// delete[] inputSignals;
//}
/*if (outputSignals != NULL_PTR(MARTe::float32 **)) {
delete[] outputSignals;
}
*/
}
bool ElectricProbesGAM::Initialise(MARTe::StructuredDataI & data) {
using namespace MARTe;
bool ok = GAM::Initialise(data);
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError, "Could not Initialise the GAM");
}
if (ok) {
ok = data.Read("Gain", gain);
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError, "The parameter Gain shall be set");
}
}
if (ok) {
REPORT_ERROR(ErrorManagement::Information, "Parameter Gain set to %d", gain);
}
return ok;
}
bool ElectricProbesGAM::Setup() {
using namespace MARTe;
uint32 numberOfInputSignals = GetNumberOfInputSignals();
bool ok = (numberOfInputSignals == 4u);
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError, "The number of input signals shall be equal to 4. numberOfInputSignals = %d ", numberOfInputSignals);
}
if (ok) {
uint32 n;
for (n = 0u; (n < numberOfInputSignals) && (ok); n++) {
StreamString inputSignalName;
ok = GetSignalName(InputSignals, n, inputSignalName);
TypeDescriptor inputSignalType = GetSignalType(InputSignals, n);
ok = (inputSignalType == Float32Bit);
if (!ok) {
const char8 * const inputSignalTypeStr = TypeDescriptor::GetTypeNameFromTypeDescriptor(inputSignalType);
REPORT_ERROR(ErrorManagement::ParametersError,
"The type of the input signals shall be float32. inputSignalType = %s", inputSignalTypeStr);
}
uint32 numberOfInputSamples = 0u;
if (ok) {
ok = GetSignalNumberOfSamples(InputSignals, n, numberOfInputSamples);
}
if (ok) {
ok = (numberOfInputSamples == 1u);
}
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError,
"The number of input signals samples shall be equal to 1. numberOfInputSamples = %d", numberOfInputSamples);
}
uint32 numberOfInputDimensions = 0u;
if (ok) {
ok = GetSignalNumberOfDimensions(InputSignals, n, numberOfInputDimensions);
}
if (ok) {
ok = (numberOfInputDimensions == 0u);
if (!ok) {
REPORT_ERROR(
ErrorManagement::ParametersError,
"The number of input signals dimensions shall be equal to 0. numberOfInputDimensions(%s) = %d", inputSignalName.Buffer(), numberOfInputDimensions);
}
}
uint32 numberOfInputElements = 0u;
if (ok) {
ok = GetSignalNumberOfElements(InputSignals, n, numberOfInputElements);
}
if (ok) {
ok = (numberOfInputElements == 1u);
}
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError,
"The number of input signal elements shall be equal to 1. numberOfInputElements(%s) = %d", inputSignalName.Buffer(), numberOfInputElements);
}
// if (ok) {
// inputSignals[n] = reinterpret_cast<float32 *>(GetInputSignalMemory(n));
// }
}
if (ok) {
inputElectricTop = reinterpret_cast<float32 *>(GetInputSignalMemory(0u));
inputElectricInner = reinterpret_cast<float32 *>(GetInputSignalMemory(1u));
inputElectricOuter = reinterpret_cast<float32 *>(GetInputSignalMemory(2u));
inputElectricBottom = reinterpret_cast<float32 *>(GetInputSignalMemory(3u));
REPORT_ERROR(ErrorManagement::Information, "InputSignals reinterpret_cast OK");
}
}
// OutputSignals
uint32 numberOfOutputSignals = GetNumberOfOutputSignals();
ok = (numberOfOutputSignals == 2u);
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError, "The number of output signals shall be equal to 2. numberOfOutputSignals = %d ", numberOfOutputSignals);
}
if (ok) {
uint32 n;
for (n = 0u; (n < numberOfOutputSignals) && (ok); n++) {
StreamString outputSignalName;
ok = GetSignalName(OutputSignals, n, outputSignalName);
TypeDescriptor outputSignalType = GetSignalType(OutputSignals, n);
ok = (outputSignalType == Float32Bit);
if (!ok) {
const char8 * const outputSignalTypeStr = TypeDescriptor::GetTypeNameFromTypeDescriptor(outputSignalType);
REPORT_ERROR(ErrorManagement::ParametersError,
"The type of the output signals shall be float32. outputSignalType = %s", outputSignalTypeStr);
}
uint32 numberOfOutputSamples = 0u;
if (ok) {
ok = GetSignalNumberOfSamples(OutputSignals, n, numberOfOutputSamples);
}
if (ok) {
ok = (numberOfOutputSamples == 1u);
}
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError,
"The number of output signals samples shall be equal to 1. numberOfOutputSamples = %d", numberOfOutputSamples);
}
uint32 numberOfOutputDimensions = 0u;
if (ok) {
ok = GetSignalNumberOfDimensions(OutputSignals, n, numberOfOutputDimensions);
}
if (ok) {
ok = (numberOfOutputDimensions == 0u);
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError,
"The number of output signals dimensions shall be equal to 0. numberOfOutputDimensions (%s) = %d", outputSignalName.Buffer(), numberOfOutputDimensions);
}
}
uint32 numberOfOutputElements = 0u;
if (ok) {
ok = GetSignalNumberOfElements(OutputSignals, n, numberOfOutputElements);
}
if (ok) {
ok = (numberOfOutputElements == 1u);
}
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError,
"The number of output signals elements shall be equal to 1. (%s) numberOfOutputElements = %d", outputSignalName.Buffer(), numberOfOutputElements);
}
}
if (ok) {
outputEpR = reinterpret_cast<float32 *>(GetOutputSignalMemory(0u));
outputEpZ = reinterpret_cast<float32 *>(GetOutputSignalMemory(1u));
}
}
return ok;
}
bool ElectricProbesGAM::Execute() {
//*outputSignal = *inputSignal;
*outputEpR = 4.3;
// *outputEpZ = 3.4;
*outputEpZ = *inputElectricTop;
//*outputSignal1 = *inputSignals[0]; // - *inputSignals[1];
//*outputSignal1 = *inputSignals[0] - *inputSignals[1];
return true;
}
bool ElectricProbesGAM::ExportData(MARTe::StructuredDataI & data) {
using namespace MARTe;
bool ok = GAM::ExportData(data);
if (ok) {
ok = data.CreateRelative("Parameters");
}
if (ok) {
ok = data.Write("Gain", gain);
}
if (ok) {
ok = data.MoveToAncestor(1u);
}
return ok;
}
CLASS_REGISTER(ElectricProbesGAM, "1.0")
//CLASS_METHOD_REGISTER(AtcaIopConfig, WriteEoWo)
}
// vim: syntax=cpp ts=4 sw=4 sts=4 sr et
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