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// -*- C++ -*-
/**
* @brief The test file of class PointToPointConnection for standard methods
*
* Copyright 2005-2025 Airbus-EDF-IMACS-ONERA-Phimeca
*
* This library is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this library. If not, see <http://www.gnu.org/licenses/>.
*
*/
#include "openturns/OT.hxx"
#include "openturns/OTtestcode.hxx"
using namespace OT;
using namespace OT::Test;
int main(int, char *[])
{
TESTPREAMBLE;
OStream fullprint(std::cout);
try
{
// Construction based on two functions
{
/* Create an instance */
PointToPointConnection myFunc(SymbolicFunction("x", "sin(x)"), SymbolicFunction("x", "cos(x)"));
fullprint << "myFunc=" << myFunc << std::endl;
/* Get the input and output description */
fullprint << "myFunc input description=" << myFunc.getInputDescription() << std::endl;
fullprint << "myFunc output description=" << myFunc.getOutputDescription() << std::endl;
/* Get the input and output dimension */
fullprint << "myFunc input dimension=" << myFunc.getInputDimension() << std::endl;
fullprint << "myFunc output dimension=" << myFunc.getOutputDimension() << std::endl;
/* Connection on a point */
Point point(myFunc.getInputDimension(), 1.0);
fullprint << "point=" << point << std::endl;
fullprint << "myFunc(point)=" << myFunc(point) << std::endl;
fullprint << "myFunc.gradient(point)=" << myFunc.gradient(point) << std::endl;
fullprint << "myFunc.hessian(point)=" << myFunc.hessian(point) << std::endl;
/* Get the number of calls */
fullprint << "called " << myFunc.getEvaluationCallsNumber() << " times" << std::endl;
}
// Construction based on a PointToFieldFunction followed by a FieldToPointFunction
{
// Create a KarhunenLoeveResult
Mesh mesh(IntervalMesher(Indices(1, 9)).build(Interval(-1.0, 1.0)));
AbsoluteExponential cov1D(Point(1, 1.0));
KarhunenLoeveP1Algorithm algo(mesh, cov1D, 1.0e-2);
algo.run();
KarhunenLoeveResult result(algo.getResult());
// Create a PointToFieldFunction
KarhunenLoeveLifting lifting(result);
// Create a FieldToPointFunction
KarhunenLoeveProjection projection(result);
/* Create an instance */
PointToPointConnection myFunc(projection, lifting);
fullprint << "myFunc=" << myFunc << std::endl;
/* Get the input and output description */
fullprint << "myFunc input description=" << myFunc.getInputDescription() << std::endl;
fullprint << "myFunc output description=" << myFunc.getOutputDescription() << std::endl;
/* Get the input and output dimension */
fullprint << "myFunc input dimension=" << myFunc.getInputDimension() << std::endl;
fullprint << "myFunc output dimension=" << myFunc.getOutputDimension() << std::endl;
/* Connection on a point */
Point point(myFunc.getInputDimension(), 1.0);
fullprint << "point=" << point << std::endl;
fullprint << "myFunc(point)=" << myFunc(point) << std::endl;
assert_almost_equal(myFunc.gradient(point), IdentityMatrix(8));
assert_almost_equal(myFunc.hessian(point), SymmetricTensor(8, 8), 0.0, 1e-7);
/* Get the number of calls */
fullprint << "called " << myFunc.getEvaluationCallsNumber() << " times" << std::endl;
}
} // try
catch (TestFailed & ex)
{
std::cerr << ex << std::endl;
return ExitCode::Error;
}
return ExitCode::Success;
}
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