#include #include #include #include #include #include #include #if HAVE_DYNAMIC_BOOST_TEST #define BOOST_TEST_DYN_LINK #endif #define NVERBOSE // to suppress our messages when throwing #define BOOST_TEST_MODULE BlackoilStateTest #define BOOST_TEST_MAIN #include #include #include #include #include #include #include "opm/core/grid/GridManager.hpp" #include "opm/core/simulator/BlackoilState.hpp" using namespace Opm; using namespace std; // ACTNUM 1 998*2 3 std::vector get_testBlackoilStateActnum() { std::vector actnum(10 * 10 * 10, 2); actnum.front() = 1; actnum.back() = 3; return actnum; } BOOST_AUTO_TEST_CASE(EqualsDifferentDeckReturnFalse) { const string filename1 = "testBlackoilState1.DATA"; const string filename2 = "testBlackoilState2.DATA"; const auto es1 = Opm::Parser::parse(filename1); auto eg1 = es1.getInputGrid(); std::vector actnum = get_testBlackoilStateActnum(); eg1.resetACTNUM(actnum.data()); const auto es2 = Opm::Parser::parse(filename2); const auto& eg2 = es2.getInputGrid(); GridManager gridManager1(eg1); const UnstructuredGrid& grid1 = *gridManager1.c_grid(); GridManager gridManager2(eg2); const UnstructuredGrid& grid2 = *gridManager2.c_grid(); BlackoilState state1( UgGridHelpers::numCells( grid1 ) , UgGridHelpers::numFaces( grid1 ) , 3); BlackoilState state2( UgGridHelpers::numCells( grid2 ) , UgGridHelpers::numFaces( grid2 ) , 3); BOOST_CHECK( ! state1.equal(state2) ); } BOOST_AUTO_TEST_CASE(EqualsNumericalDifferenceReturnFalse) { const string filename = "testBlackoilState1.DATA"; const auto es = Opm::Parser::parse(filename); auto eg = es.getInputGrid(); std::vector actnum = get_testBlackoilStateActnum(); eg.resetACTNUM(actnum.data()); GridManager gridManager(eg); const UnstructuredGrid& grid = *gridManager.c_grid(); BlackoilState state1( UgGridHelpers::numCells( grid ) , UgGridHelpers::numFaces( grid ) , 3); BlackoilState state2( UgGridHelpers::numCells( grid ) , UgGridHelpers::numFaces( grid ) , 3); BOOST_CHECK( state1.equal(state2) ); { std::vector& p1 = state1.pressure(); std::vector& p2 = state2.pressure(); p1[0] = p1[0] * 2 + 1; BOOST_CHECK( ! state1.equal(state2) ); p1[0] = p2[0]; BOOST_CHECK( state1.equal(state2) ); } { std::vector& gor1 = state1.gasoilratio(); std::vector& gor2 = state2.gasoilratio(); gor1[0] = gor1[0] * 2 + 1; BOOST_CHECK( ! state1.equal(state2) ); gor1[0] = gor2[0]; BOOST_CHECK( state1.equal(state2) ); } { std::vector& p1 = state1.facepressure(); std::vector& p2 = state2.facepressure(); p1[0] = p1[0] * 2 + 1; BOOST_CHECK( ! state1.equal(state2) ); p1[0] = p2[0]; BOOST_CHECK( state1.equal(state2) ); } { std::vector& f1 = state1.faceflux(); std::vector& f2 = state2.faceflux(); if (f1.size() > 0 ) { f1[0] = f1[0] * 2 + 1; BOOST_CHECK( ! state1.equal(state2) ); f1[0] = f2[0]; BOOST_CHECK( state1.equal(state2) ); } } { std::vector& sv1 = state1.surfacevol(); std::vector& sv2 = state2.surfacevol(); if (sv1.size() > 0) { sv1[0] = sv1[0] * 2 + 1; BOOST_CHECK( ! state1.equal(state2) ); sv1[0] = sv2[0]; BOOST_CHECK( state1.equal(state2) ); } } { std::vector& sat1 = state1.saturation(); std::vector& sat2 = state2.saturation(); sat1[0] = sat1[0] * 2 + 1; BOOST_CHECK( ! state1.equal(state2) ); sat1[0] = sat2[0]; BOOST_CHECK( state1.equal(state2) ); } }