ROL
step/test_15.cpp
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1// @HEADER
2// *****************************************************************************
3// Rapid Optimization Library (ROL) Package
4//
5// Copyright 2014 NTESS and the ROL contributors.
6// SPDX-License-Identifier: BSD-3-Clause
7// *****************************************************************************
8// @HEADER
9
14#define USE_HESSVEC 1
15
16#include "ROL_GetTestProblems.hpp"
17#include "ROL_OptimizationSolver.hpp"
18#include "ROL_Stream.hpp"
19#include "Teuchos_GlobalMPISession.hpp"
20
21#include <iostream>
22//#include <fenv.h>
23
24typedef double RealT;
25
26int main(int argc, char *argv[]) {
27 //feenableexcept(FE_DIVBYZERO | FE_INVALID | FE_OVERFLOW);
28
29 Teuchos::GlobalMPISession mpiSession(&argc, &argv);
30
31 // This little trick lets us print to std::cout only if a (dummy) command-line argument is provided.
32 int iprint = argc - 1;
33 ROL::Ptr<std::ostream> outStream;
34 ROL::nullstream bhs; // outputs nothing
35 if (iprint > 0)
36 outStream = ROL::makePtrFromRef(std::cout);
37 else
38 outStream = ROL::makePtrFromRef(bhs);
39
40 int errorFlag = 0;
41
42 // *** Test body.
43
44 try {
45
46 std::string filename = "input.xml";
47 auto parlist = ROL::getParametersFromXmlFile( filename );
48 parlist->sublist("General").set("Inexact Hessian-Times-A-Vector",true);
49#if USE_HESSVEC
50 parlist->sublist("General").set("Inexact Hessian-Times-A-Vector",false);
51#endif
52 parlist->sublist("Step").set("Type","Trust Region");
53
54 for ( ROL::ETestOptProblem prob = ROL::TESTOPTPROBLEM_ROSENBROCK; prob < ROL::TESTOPTPROBLEM_LAST; prob++ ) {
55 // Get Objective Function
56 ROL::Ptr<ROL::Vector<RealT> > x0;
57 std::vector<ROL::Ptr<ROL::Vector<RealT> > > z;
58 ROL::Ptr<ROL::OptimizationProblem<RealT> > problem;
59 ROL::GetTestProblem<RealT>(problem,x0,z,prob);
60 if (problem->getProblemType() == ROL::TYPE_B) {
61 if ( prob == ROL::TESTOPTPROBLEM_HS2 || prob == ROL::TESTOPTPROBLEM_BVP ) {
62 parlist->sublist("Step").sublist("Line Search").set("Initial Step Size",1.e-4);
63 parlist->sublist("Step").sublist("Trust Region").set("Initial Radius",-1.e1);
64 parlist->sublist("Step").sublist("Trust Region").set("Safeguard Size",1.e-4);
65 parlist->sublist("Status Test").set("Gradient Tolerance",1.e-6);
66 }
67 else if ( prob == ROL::TESTOPTPROBLEM_HS25 ) {
68 parlist->sublist("Step").sublist("Line Search").set("Initial Step Size",1.0);
69 parlist->sublist("Step").sublist("Trust Region").set("Initial Radius",1.e3);
70 parlist->sublist("Step").sublist("Trust Region").set("Safeguard Size",1.e4);
71 parlist->sublist("Status Test").set("Gradient Tolerance",1.e-8);
72 }
73 else {
74 parlist->sublist("Step").sublist("Line Search").set("Initial Step Size",1.0);
75 parlist->sublist("Step").sublist("Trust Region").set("Initial Radius",-1.e1);
76 parlist->sublist("Step").sublist("Trust Region").set("Safeguard Size",1.e4);
77 parlist->sublist("Status Test").set("Gradient Tolerance",1.e-6);
78 }
79 parlist->sublist("General").set("Scale for Epsilon Active Sets",1.0);
80 if ( prob == ROL::TESTOPTPROBLEM_HS4 ) {
81 parlist->sublist("General").set("Scale for Epsilon Active Sets",1.e-2);
82 }
83 *outStream << std::endl << std::endl << ROL:: ETestOptProblemToString(prob) << std::endl << std::endl;
84
85 // Get Dimension of Problem
86 int dim = x0->dimension();
87 parlist->sublist("General").sublist("Krylov").set("Iteration Limit", 2*dim);
88
89 // Error Vector
90 ROL::Ptr<ROL::Vector<RealT> > e = x0->clone();
91 e->zero();
92
93 parlist->sublist("Step").sublist("Trust Region").set("Subproblem Solver", "Lin-More");
94 parlist->sublist("Step").sublist("Trust Region").set("Subproblem Model", "Lin-More");
95 *outStream << std::endl << std::endl << "Lin-More" << std::endl << std::endl;
96
97 // Define Solver
98 ROL::OptimizationSolver<RealT> solver(*problem,*parlist);
99
100 // Run Solver
101 solver.solve(*outStream);
102
103 // Compute Error
104 RealT err(0);
105 for (int i = 0; i < static_cast<int>(z.size()); ++i) {
106 e->set(*x0);
107 e->axpy(-1.0,*z[i]);
108 if (i == 0) {
109 err = e->norm();
110 }
111 else {
112 err = std::min(err,e->norm());
113 }
114 }
115 *outStream << std::endl << "Norm of Error: " << err << std::endl;
116 }
117 }
118 }
119 catch (std::logic_error& err) {
120 *outStream << err.what() << std::endl;
121 errorFlag = -1000;
122 }; // end try
123
124 if (errorFlag != 0)
125 std::cout << "End Result: TEST FAILED" << std::endl;
126 else
127 std::cout << "End Result: TEST PASSED" << std::endl;
128
129 return 0;
130
131}
132
ROL_GetTestProblems.hpp
Contains definitions of test objective functions.
ROL_OptimizationSolver.hpp
ROL_Stream.hpp
Defines a no-output stream class ROL::NullStream and a function makeStreamPtr which either wraps a re...
ROL::OptimizationSolver
Provides a simplified interface for solving a wide range of optimization problems.
Definition ROL_OptimizationSolver.hpp:29
ROL::OptimizationSolver::solve
int solve(const ROL::Ptr< StatusTest< Real > > &status=ROL::nullPtr, const bool combineStatus=true)
Solve optimization problem with no iteration output.
Definition ROL_OptimizationSolver.hpp:180
RealT
double RealT
Definition function/constraint/test_01.cpp:29
ROL::ETestOptProblemToString
std::string ETestOptProblemToString(ETestOptProblem to)
Definition ROL_GetTestProblems.hpp:169
ROL::TESTOPTPROBLEM_ROSENBROCK
@ TESTOPTPROBLEM_ROSENBROCK
Definition ROL_GetTestProblems.hpp:120
ROL::TYPE_B
@ TYPE_B
Definition ROL_Types.hpp:226
main
int main(int argc, char *argv[])
Definition step/test_15.cpp:26
RealT
double RealT
Definition step/test_15.cpp:24
dim
constexpr auto dim
Definition vector/test_11.cpp:23
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