int main(int argc, char *argv[]) { LibUtilities::SessionReaderSharedPtr vSession = LibUtilities::SessionReader::CreateInstance(argc, argv); LibUtilities::CommSharedPtr vComm = vSession->GetComm(); MultiRegions::ContField3DHomogeneous1DSharedPtr Exp_u, Exp_v, Exp_w; StdRegions::ConstFactorMap factors; FlagList flags; if( (argc != 2) && (argc != 3)) { fprintf(stderr,"Usage: Deriv3DHomo2D meshfile [SysSolnType] \n"); exit(1); } //---------------------------------------------- // Read in mesh from input file SpatialDomains::MeshGraphSharedPtr graph2D = MemoryManager<SpatialDomains::MeshGraph2D>::AllocateSharedPtr(vSession); //---------------------------------------------- //---------------------------------------------- // Define Expansion int nzpoints; NekDouble lz; int FFT; vSession->LoadParameter("HomModesZ", nzpoints); vSession->LoadParameter("LZ", lz); vSession->LoadParameter("USEFFT", FFT); bool useFFT = false; bool deal = false; if(FFT==1){useFFT = true;} const LibUtilities::PointsKey PkeyZ(nzpoints,LibUtilities::eFourierSingleModeSpaced); const LibUtilities::BasisKey BkeyZ(LibUtilities::eFourierHalfModeRe,nzpoints,PkeyZ); Exp_u = MemoryManager<MultiRegions::ContField3DHomogeneous1D>::AllocateSharedPtr(vSession,BkeyZ,lz,useFFT,deal,graph2D,vSession->GetVariable(0)); Exp_v = MemoryManager<MultiRegions::ContField3DHomogeneous1D>::AllocateSharedPtr(vSession,BkeyZ,lz,useFFT,deal,graph2D,vSession->GetVariable(1)); Exp_w = MemoryManager<MultiRegions::ContField3DHomogeneous1D>::AllocateSharedPtr(vSession,BkeyZ,lz,useFFT,deal,graph2D,vSession->GetVariable(2)); //---------------------------------------------- // Print summary of solution details flags.set(eUseGlobal, false); const SpatialDomains::ExpansionMap &expansions = graph2D->GetExpansions(); LibUtilities::BasisKey bkey0 = expansions.begin()->second->m_basisKeyVector[0]; cout << "Calculating Derivatives (Homogeneous in z-plane):" << endl; cout << " Lz : " << lz << endl; cout << " N.modes : " << bkey0.GetNumModes() << endl; cout << " N.Z h**o modes : " << BkeyZ.GetNumModes() << endl; cout << endl; //---------------------------------------------- //---------------------------------------------- // Set up coordinates of mesh for Forcing function evaluation int nq = Exp_u->GetTotPoints(); Array<OneD,NekDouble> xc0,xc1,xc2; xc0 = Array<OneD,NekDouble>(nq,0.0); xc1 = Array<OneD,NekDouble>(nq,0.0); xc2 = Array<OneD,NekDouble>(nq,0.0); Exp_u->GetCoords(xc0,xc1,xc2); //---------------------------------------------- Array<OneD,NekDouble> dudx,dvdy,dwdz; Array<OneD,NekDouble> dump; dump = Array<OneD,NekDouble>(nq,0.0); dudx = Array<OneD,NekDouble>(nq,0.0); dvdy = Array<OneD,NekDouble>(nq,0.0); dwdz = Array<OneD,NekDouble>(nq,0.0); //---------------------------------------------- // Define initial fields LibUtilities::EquationSharedPtr ffunc_u = vSession->GetFunction("InitialCondition", 0); LibUtilities::EquationSharedPtr ffunc_v = vSession->GetFunction("InitialCondition", 1); LibUtilities::EquationSharedPtr ffunc_w = vSession->GetFunction("InitialCondition", 2); LibUtilities::EquationSharedPtr exac_u = vSession->GetFunction("ExactSolution", 0); LibUtilities::EquationSharedPtr exac_v = vSession->GetFunction("ExactSolution", 1); LibUtilities::EquationSharedPtr exac_w = vSession->GetFunction("ExactSolution", 2); ffunc_u->Evaluate(xc0,xc1,xc2,Exp_u->UpdatePhys()); ffunc_v->Evaluate(xc0,xc1,xc2,Exp_v->UpdatePhys()); ffunc_w->Evaluate(xc0,xc1,xc2,Exp_w->UpdatePhys()); exac_u->Evaluate(xc0,xc1,xc2,dudx); exac_v->Evaluate(xc0,xc1,xc2,dvdy); exac_w->Evaluate(xc0,xc1,xc2,dwdz); //---------------------------------------------- //Taking derivative and printing the error cout << "Deriv u" << endl; Exp_u->PhysDeriv(Exp_u->GetPhys(),Exp_u->UpdatePhys(),dump,dump); cout << "Deriv u done" << endl; cout << "L infinity error: " << Exp_u->Linf(Exp_u->GetPhys(), dudx) << endl; cout << "L 2 error : " << Exp_u->L2 (Exp_u->GetPhys(), dudx) << endl; Exp_v->PhysDeriv(Exp_v->GetPhys(),dump,Exp_v->UpdatePhys(),dump); cout << "L infinity error: " << Exp_v->Linf(Exp_v->GetPhys(), dvdy) << endl; cout << "L 2 error : " << Exp_v->L2 (Exp_v->GetPhys(), dvdy) << endl; Exp_w->PhysDeriv(Exp_w->GetPhys(),dump,dump,Exp_w->UpdatePhys()); cout << "L infinity error: " << Exp_w->Linf(Exp_w->GetPhys(), dwdz) << endl; cout << "L 2 error : " << Exp_w->L2 (Exp_w->GetPhys(), dwdz) << endl; return 0; }
int main(int argc, char *argv[]) { MultiRegions::ContField3DSharedPtr Exp,Fce,Sol; int i, nq, coordim; Array<OneD,NekDouble> fce,sol; Array<OneD,NekDouble> xc0,xc1,xc2; NekDouble lambda; vector<string> vFilenames; if(argc != 6) { fprintf(stderr,"Usage: TimingCGHelmSolve3D Type MeshSize NumModes OptimisationLevel OperatorToTest\n"); fprintf(stderr," where: - Type is one of the following:\n"); fprintf(stderr," 1: Regular Hexahedrons \n"); fprintf(stderr," 2: Deformed Hexahedrons (may not be supported) \n"); fprintf(stderr," 3: Regular Tetrahedrons \n"); fprintf(stderr," where: - MeshSize is 1/h \n"); fprintf(stderr," where: - NumModes is the number of 1D modes of the expansion \n"); fprintf(stderr," where: - OptimisationLevel is one of the following:\n"); fprintf(stderr," 0: Use elemental sum-factorisation evaluation \n"); fprintf(stderr," 2: Use elemental matrix evaluation using blockmatrices \n"); fprintf(stderr," 3: Use global matrix evaluation \n"); fprintf(stderr," 4: Use optimal evaluation (this option requires optimisation-files being set-up) \n"); fprintf(stderr," where: - OperatorToTest is one of the following:\n"); fprintf(stderr," 0: BwdTrans \n"); fprintf(stderr," 1: Inner Product \n"); fprintf(stderr," 2: Mass Matrix \n"); exit(1); } boost::filesystem::path basePath(BASE_PATH); int Type = atoi(argv[1]); int MeshSize = atoi(argv[2]); int NumModes = atoi(argv[3]); int optLevel = atoi(argv[4]); int opToTest = atoi(argv[5]); //---------------------------------------------- // Retrieve the necessary input files stringstream MeshFileName; stringstream MeshFileDirectory; stringstream BCfileName; stringstream ExpansionsFileName; stringstream GlobOptFileName; switch(Type) { case 1: { MeshFileDirectory << "RegularHexMeshes"; MeshFileName << "UnitCube_RegularHexMesh_h_1_" << MeshSize << ".xml"; } break; case 2: { MeshFileDirectory << "DeformedHexMeshes"; MeshFileName << "UnitCube_DeformedHexMesh_h_1_" << MeshSize << ".xml"; } break; case 3: { MeshFileDirectory << "RegularTetMeshes"; MeshFileName << "UnitCube_RegularTetMesh_h_1_" << MeshSize << ".xml"; } break; default: { cerr << "Type should be equal to one of the following values: "<< endl; cerr << " 1: Regular Hexahedrons" << endl; cerr << " 2: Deformed Hexahedrons" << endl; cerr << " 3: Regular Tetrahedrons" << endl; exit(1); } } BCfileName << "UnitCube_DirichletBoundaryConditions.xml"; ExpansionsFileName << "NektarExpansionsNummodes" << NumModes << ".xml"; switch(optLevel) { case 0: { GlobOptFileName << "NoGlobalMat.xml"; } break; case 2: { GlobOptFileName << "DoBlockMat.xml"; } break; case 3: { GlobOptFileName << "DoGlobalMat.xml"; } break; case 4: { ASSERTL0(false,"Optimisation level not set up"); } break; default: { ASSERTL0(false,"Unrecognised optimisation level"); } } boost::filesystem::path MeshFilePath = basePath / boost::filesystem::path("InputFiles") / boost::filesystem::path("Geometry") / boost::filesystem::path(MeshFileDirectory.str()) / boost::filesystem::path(MeshFileName.str()); vFilenames.push_back(PortablePath(MeshFilePath)); boost::filesystem::path BCfilePath = basePath / boost::filesystem::path("InputFiles") / boost::filesystem::path("Conditions") / boost::filesystem::path(BCfileName.str()); vFilenames.push_back(PortablePath(BCfilePath)); boost::filesystem::path ExpansionsFilePath = basePath / boost::filesystem::path("InputFiles") / boost::filesystem::path("Expansions") / boost::filesystem::path(ExpansionsFileName.str()); vFilenames.push_back(PortablePath(ExpansionsFilePath)); boost::filesystem::path GlobOptFilePath = basePath / boost::filesystem::path("InputFiles") / boost::filesystem::path("Optimisation") / boost::filesystem::path(GlobOptFileName.str()); vFilenames.push_back(PortablePath(GlobOptFilePath)); //---------------------------------------------- StdRegions::MatrixType type; switch (opToTest) { case 0: type = StdRegions::eBwdTrans; break; case 1: type = StdRegions::eIProductWRTBase; break; case 2: type = StdRegions::eMass; break; case 3: type = StdRegions::eHelmholtz; break; default: cout << "Operator " << opToTest << " not defined." << endl; } LibUtilities::SessionReaderSharedPtr vSession = LibUtilities::SessionReader::CreateInstance(argc, argv, vFilenames); //---------------------------------------------- // Read in mesh from input file SpatialDomains::MeshGraphSharedPtr graph3D = MemoryManager<SpatialDomains::MeshGraph3D>::AllocateSharedPtr(vSession); //---------------------------------------------- //---------------------------------------------- // Print summary of solution details lambda = vSession->GetParameter("Lambda"); //---------------------------------------------- //---------------------------------------------- // Define Expansion Exp = MemoryManager<MultiRegions::ContField3D> ::AllocateSharedPtr(vSession, graph3D, vSession->GetVariable(0)); //---------------------------------------------- int NumElements = Exp->GetExpSize(); //---------------------------------------------- // Set up coordinates of mesh for Forcing function evaluation coordim = Exp->GetCoordim(0); nq = Exp->GetTotPoints(); xc0 = Array<OneD,NekDouble>(nq,0.0); xc1 = Array<OneD,NekDouble>(nq,0.0); xc2 = Array<OneD,NekDouble>(nq,0.0); switch(coordim) { case 1: Exp->GetCoords(xc0); break; case 2: Exp->GetCoords(xc0,xc1); break; case 3: Exp->GetCoords(xc0,xc1,xc2); break; } //---------------------------------------------- //---------------------------------------------- // Define forcing function for first variable defined in file fce = Array<OneD,NekDouble>(nq); LibUtilities::EquationSharedPtr ffunc = vSession->GetFunction("Forcing",0); for(i = 0; i < nq; ++i) { fce[i] = ffunc->Evaluate(xc0[i],xc1[i],xc2[i]); } //---------------------------------------------- //---------------------------------------------- // Setup expansion containing the forcing function Fce = MemoryManager<MultiRegions::ContField3D>::AllocateSharedPtr(*Exp); Fce->SetPhys(fce); //---------------------------------------------- //---------------------------------------------- // See if there is an exact solution, if so // evaluate and plot errors LibUtilities::EquationSharedPtr ex_sol = vSession->GetFunction("ExactSolution",0); //---------------------------------------------- // evaluate exact solution sol = Array<OneD,NekDouble>(nq); for(i = 0; i < nq; ++i) { sol[i] = ex_sol->Evaluate(xc0[i],xc1[i],xc2[i]); } Sol = MemoryManager<MultiRegions::ContField3D>::AllocateSharedPtr(*Exp); Sol->SetPhys(sol); Sol->SetPhysState(true); //---------------------------------------------- NekDouble L2Error; NekDouble LinfError; if (type == StdRegions::eHelmholtz) { FlagList flags; flags.set(eUseGlobal, true); StdRegions::ConstFactorMap factors; factors[StdRegions::eFactorLambda] = lambda; //---------------------------------------------- // Helmholtz solution taking physical forcing Exp->HelmSolve(Fce->GetPhys(), Exp->UpdateCoeffs(),flags,factors); // GeneralMatrixOp does not impose boundary conditions. // MultiRegions::GlobalMatrixKey key(type, lambda, Exp->GetLocalToGlobalMap()); // Exp->GeneralMatrixOp (key, Fce->GetPhys(),Exp->UpdateContCoeffs(), true); //---------------------------------------------- //---------------------------------------------- // Backward Transform Solution to get solved values at Exp->BwdTrans(Exp->GetCoeffs(), Exp->UpdatePhys(), MultiRegions::eGlobal); //---------------------------------------------- L2Error = Exp->L2 (Sol->GetPhys()); LinfError = Exp->Linf(Sol->GetPhys()); } else { Exp->FwdTrans(Sol->GetPhys(), Exp->UpdateCoeffs(), MultiRegions::eGlobal); //---------------------------------------------- // Backward Transform Solution to get solved values at Exp->BwdTrans(Exp->GetCoeffs(), Exp->UpdatePhys(), MultiRegions::eGlobal); //---------------------------------------------- L2Error = Exp->L2 (Sol->GetPhys()); LinfError = Exp->Linf(Sol->GetPhys()); } //-------------------------------------------- // alternative error calculation /* const LibUtilities::PointsKey PkeyT1(30,LibUtilities::eGaussLobattoLegendre); const LibUtilities::PointsKey PkeyT2(30,LibUtilities::eGaussRadauMAlpha1Beta0); const LibUtilities::PointsKey PkeyQ1(30,LibUtilities::eGaussLobattoLegendre); const LibUtilities::PointsKey PkeyQ2(30,LibUtilities::eGaussLobattoLegendre); const LibUtilities::BasisKey BkeyT1(LibUtilities::eModified_A,NumModes,PkeyT1); const LibUtilities::BasisKey BkeyT2(LibUtilities::eModified_B,NumModes,PkeyT2); const LibUtilities::BasisKey BkeyQ1(LibUtilities::eModified_A,NumModes,PkeyQ1); const LibUtilities::BasisKey BkeyQ2(LibUtilities::eModified_A,NumModes,PkeyQ2); MultiRegions::ExpList3DSharedPtr ErrorExp = MemoryManager<MultiRegions::ExpList3D>::AllocateSharedPtr(BkeyT1,BkeyT2,BkeyT3,BkeyQ1,BkeyQ2,BkeyQ3,graph3D); int ErrorCoordim = ErrorExp->GetCoordim(0); int ErrorNq = ErrorExp->GetTotPoints(); Array<OneD,NekDouble> ErrorXc0(ErrorNq,0.0); Array<OneD,NekDouble> ErrorXc1(ErrorNq,0.0); Array<OneD,NekDouble> ErrorXc2(ErrorNq,0.0); switch(ErrorCoordim) { case 1: ErrorExp->GetCoords(ErrorXc0); break; case 2: ErrorExp->GetCoords(ErrorXc0,ErrorXc1); break; case 3: ErrorExp->GetCoords(ErrorXc0,ErrorXc1,ErrorXc2); break; } // evaluate exact solution Array<OneD,NekDouble> ErrorSol(ErrorNq); for(i = 0; i < ErrorNq; ++i) { ErrorSol[i] = ex_sol->Evaluate(ErrorXc0[i],ErrorXc1[i],ErrorXc2[i]); } // calcualte spectral/hp approximation on the quad points of this new // expansion basis Exp->GlobalToLocal(Exp->GetContCoeffs(),ErrorExp->UpdateCoeffs()); ErrorExp->BwdTrans_IterPerExp(ErrorExp->GetCoeffs(),ErrorExp->UpdatePhys()); NekDouble L2ErrorBis = ErrorExp->L2 (ErrorSol); NekDouble LinfErrorBis = ErrorExp->Linf(ErrorSol); */ //-------------------------------------------- #if 0 cout << "L infinity error: " << LinfErrorBis << endl; cout << "L 2 error: " << L2ErrorBis << endl; #endif //---------------------------------------------- NekDouble exeTime; int NumCalls; exeTime = TimeMatrixOp(type, Exp, Fce, NumCalls, lambda); int nLocCoeffs = Exp->GetLocalToGlobalMap()->GetNumLocalCoeffs(); int nGlobCoeffs = Exp->GetLocalToGlobalMap()->GetNumGlobalCoeffs(); int nLocBndCoeffs = Exp->GetLocalToGlobalMap()->GetNumLocalBndCoeffs(); int nGlobBndCoeffs = Exp->GetLocalToGlobalMap()->GetNumGlobalBndCoeffs(); int nLocDirCoeffs = Exp->GetLocalToGlobalMap()->GetNumLocalDirBndCoeffs(); int nGlobDirCoeffs = Exp->GetLocalToGlobalMap()->GetNumGlobalDirBndCoeffs(); // MultiRegions::GlobalMatrixKey key(StdRegions::eHelmholtz,lambda,Exp->GetLocalToGlobalMap()); // int nnz = Exp->GetGlobalMatrixNnz(key); ostream &outfile = cout; outfile.precision(0); outfile << setw(10) << Type << " "; outfile << setw(10) << NumElements << " "; outfile << setw(10) << NumModes << " "; outfile << setw(10) << NumCalls << " "; outfile << setw(10) << fixed << noshowpoint << exeTime << " "; outfile << setw(10) << fixed << noshowpoint << ((NekDouble) (exeTime/((NekDouble)NumCalls))) << " "; outfile.precision(7); outfile << setw(15) << scientific << noshowpoint << L2Error << " "; outfile << setw(15) << scientific << noshowpoint << "- "; // << L2ErrorBis << " "; outfile << setw(15) << scientific << noshowpoint << LinfError << " "; outfile << setw(15) << scientific << noshowpoint << "- ";// << LinfErrorBis << " "; outfile << setw(10) << nLocCoeffs << " "; outfile << setw(10) << nGlobCoeffs << " "; outfile << setw(10) << nLocBndCoeffs << " "; outfile << setw(10) << nGlobBndCoeffs << " "; outfile << setw(10) << nLocDirCoeffs << " "; outfile << setw(10) << nGlobDirCoeffs << " "; outfile << setw(10) << "- "; // << nnz << " "; outfile << setw(10) << optLevel << " "; outfile << endl; //---------------------------------------------- return 0; }