function/test_05.cpp

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#include "ROL_SimpleEqConstrained.hpp"
#include "ROL_StdVector.hpp"
#include "ROL_NonlinearLeastSquaresObjective.hpp"
#include "ROL_Algorithm.hpp"
#include "ROL_Stream.hpp"
#include "Teuchos_GlobalMPISession.hpp"
 
#include <iostream>
 
typedef double RealT;
 
 
int main(int argc, char *argv[]) {
 
  Teuchos::GlobalMPISession mpiSession(&argc, &argv);
 
  // This little trick lets us print to std::cout only if a (dummy) command-line argument is provided.
  int iprint     = argc - 1;
  ROL::Ptr<std::ostream> outStream;
  ROL::nullstream bhs; // outputs nothing
  if (iprint > 0)
    outStream = ROL::makePtrFromRef(std::cout);
  else
    outStream = ROL::makePtrFromRef(bhs);
 
  int errorFlag  = 0;
 
  // *** Example body.
 
  try {
 
    ROL::Ptr<ROL::Objective<RealT> > obj;
    ROL::Ptr<ROL::Constraint<RealT> > constr;
    ROL::Ptr<ROL::Vector<RealT> > x;
    ROL::Ptr<ROL::Vector<RealT> > sol;
 
    // Retrieve objective, constraint, iteration vector, solution vector.
    ROL::ZOO::getSimpleEqConstrained<RealT> SEC;
    obj    = SEC.getObjective();
    constr = SEC.getEqualityConstraint();
    x      = SEC.getInitialGuess();
    sol    = SEC.getSolution();
 
    // Inititalize vectors
    int dim = 5;
    int nc = 3;
    RealT left = -1e0, right = 1e0;
    ROL::Ptr<std::vector<RealT> > xtest_ptr = ROL::makePtr<std::vector<RealT>>(dim, 0.0);
    ROL::Ptr<std::vector<RealT> > g_ptr = ROL::makePtr<std::vector<RealT>>(dim, 0.0);
    ROL::Ptr<std::vector<RealT> > d_ptr = ROL::makePtr<std::vector<RealT>>(dim, 0.0);
    ROL::Ptr<std::vector<RealT> > v_ptr = ROL::makePtr<std::vector<RealT>>(dim, 0.0);
    ROL::Ptr<std::vector<RealT> > vc_ptr = ROL::makePtr<std::vector<RealT>>(nc, 0.0);
    ROL::Ptr<std::vector<RealT> > vl_ptr = ROL::makePtr<std::vector<RealT>>(nc, 0.0);
    ROL::StdVector<RealT> xtest(xtest_ptr);
    ROL::StdVector<RealT> g(g_ptr);
    ROL::StdVector<RealT> d(d_ptr);
    ROL::StdVector<RealT> v(v_ptr);
    ROL::StdVector<RealT> vc(vc_ptr);
    ROL::StdVector<RealT> vl(vl_ptr);
    // set xtest, d, v
    for (int i=0; i<dim; i++) {
      (*xtest_ptr)[i] = ( (RealT)rand() / (RealT)RAND_MAX ) * (right - left) + left;
      (*d_ptr)[i] = ( (RealT)rand() / (RealT)RAND_MAX ) * (right - left) + left;
      (*v_ptr)[i] = ( (RealT)rand() / (RealT)RAND_MAX ) * (right - left) + left;
    }
    // set vc, vl
    for (int i=0; i<nc; i++) {
      (*vc_ptr)[i] = ( (RealT)rand() / (RealT)RAND_MAX ) * (right - left) + left;
      (*vl_ptr)[i] = ( (RealT)rand() / (RealT)RAND_MAX ) * (right - left) + left;
    }
 
    xtest.set(*x);
 
    // Initialize nonlinear least squares objectives
    ROL::NonlinearLeastSquaresObjective<RealT> nlls(constr,*x,vc,false);
    ROL::NonlinearLeastSquaresObjective<RealT> gnnlls(constr,*x,vc,true);
 
    // Check derivatives
    constr->checkApplyJacobian(xtest, v, vc, true, *outStream);                 *outStream << "\n";
    constr->checkApplyAdjointJacobian(xtest, vl, vc, xtest, true, *outStream);  *outStream << "\n";
    constr->checkApplyAdjointHessian(xtest, vl, d, xtest, true, *outStream);    *outStream << "\n";
    nlls.checkGradient(xtest, d, true, *outStream);                             *outStream << "\n"; 
    nlls.checkHessVec(xtest, v, true, *outStream);                              *outStream << "\n";
    nlls.checkHessSym(xtest, d, v, true, *outStream);                           *outStream << "\n";
    
    // Define algorithm.
    ROL::ParameterList parlist;
    std::string stepname = "Trust Region";
    parlist.sublist("Step").sublist(stepname).set("Subproblem Solver","Truncated CG");
    parlist.sublist("Status Test").set("Gradient Tolerance",1.e-10);
    parlist.sublist("Status Test").set("Constraint Tolerance",1.e-10);
    parlist.sublist("Status Test").set("Step Tolerance",1.e-18);
    parlist.sublist("Status Test").set("Iteration Limit",100);
    ROL::Algorithm<RealT> algo(stepname, parlist);
 
    // Run Algorithm
    *outStream << "\nSOLVE USING FULL HESSIAN\n";
    x->set(xtest);
    algo.run(*x, nlls, true, *outStream);
    algo.reset();
    *outStream << "\nSOLVE USING GAUSS-NEWTON HESSIAN\n";
    x->set(xtest);
    algo.run(*x, gnnlls, true, *outStream);
  }
  catch (std::logic_error err) {
    *outStream << err.what() << "\n";
    errorFlag = -1000;
  }; // end try
 
  if (errorFlag != 0)
    std::cout << "End Result: TEST FAILED\n";
  else
    std::cout << "End Result: TEST PASSED\n";
 
  return 0;
 
}