Exemple #1
0
int main(int argc, char *argv[])
{
    LibUtilities::SessionReaderSharedPtr vSession
            = LibUtilities::SessionReader::CreateInstance(argc, argv);

    LibUtilities::CommSharedPtr vComm = vSession->GetComm();

    MultiRegions::DisContField3DSharedPtr Exp, Fce;
    int     i, nq,  coordim;
    Array<OneD,NekDouble>  fce; 
    Array<OneD,NekDouble>  xc0,xc1,xc2; 
    StdRegions::ConstFactorMap factors;

    if(argc < 2)
    {
        fprintf(stderr,"Usage: HDGHelmholtz3D  meshfile [solntype]\n");
        exit(1);
    }

    LibUtilities::FieldIOSharedPtr fld = MemoryManager<LibUtilities::FieldIO>::AllocateSharedPtr(vComm);

    //----------------------------------------------
    // Read in mesh from input file
    SpatialDomains::MeshGraphSharedPtr graph3D = 
        MemoryManager<SpatialDomains::MeshGraph3D>::AllocateSharedPtr(vSession);
    //----------------------------------------------

    //----------------------------------------------
    // Print summary of solution details
    factors[StdRegions::eFactorLambda] = vSession->GetParameter("Lambda");
    factors[StdRegions::eFactorTau] = 1.0;
    const SpatialDomains::ExpansionMap &expansions = graph3D->GetExpansions();
    LibUtilities::BasisKey bkey0
                            = expansions.begin()->second->m_basisKeyVector[0];

    if (vComm->GetRank() == 0)
    {
            cout << "Solving 3D Helmholtz:"  << endl;
            cout << "  - Communication: " 
                 << vSession->GetComm()->GetType() << " (" 
                 << vSession->GetComm()->GetSize() 
                 << " processes)" << endl;
            cout << "  - Solver type  : " 
                 << vSession->GetSolverInfo("GlobalSysSoln") << endl;
            cout << "  - Lambda       : " 
                 << factors[StdRegions::eFactorLambda] << endl;
            cout << "  - No. modes    : " 
                 << bkey0.GetNumModes() << endl;
            cout << endl;
    }
    //----------------------------------------------
   
    //----------------------------------------------
    // Define Expansion 
    Exp = MemoryManager<MultiRegions::DisContField3D>::
        AllocateSharedPtr(vSession,graph3D,vSession->GetVariable(0));
    //----------------------------------------------
    Timing("Read files and define exp ..");
    
    //----------------------------------------------
    // 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);

    ffunc->Evaluate(xc0, xc1, xc2, fce);

    //----------------------------------------------


    //----------------------------------------------
    // Setup expansion containing the  forcing function
    Fce = MemoryManager<MultiRegions::DisContField3D>::AllocateSharedPtr(*Exp);
    Fce->SetPhys(fce);
    //----------------------------------------------
    Timing("Define forcing ..");
  
    //----------------------------------------------
    // Helmholtz solution taking physical forcing 
    Exp->HelmSolve(Fce->GetPhys(), Exp->UpdateCoeffs(), NullFlagList, factors);
    //----------------------------------------------
    
    Timing("Helmholtz Solve ..");

#if 0
    for(i = 0; i < 100; ++i)
    {
        Exp->HelmSolve(Fce->GetPhys(), Exp->UpdateCoeffs(), NullFlagList, factors);
    }
    
    Timing("100 Helmholtz Solves:... ");
#endif 

    //----------------------------------------------
    // Backward Transform Solution to get solved values at 
    Exp->BwdTrans(Exp->GetCoeffs(), Exp->UpdatePhys());
    //----------------------------------------------
    Timing("Backward Transform ..");
    
    //-----------------------------------------------
    // Write solution to file
    string out = vSession->GetSessionName() + ".fld";
    std::vector<LibUtilities::FieldDefinitionsSharedPtr> FieldDef
                                                = Exp->GetFieldDefinitions();
    std::vector<std::vector<NekDouble> > FieldData(FieldDef.size());

    for(i = 0; i < FieldDef.size(); ++i)
    {
        FieldDef[i]->m_fields.push_back("u");
        Exp->AppendFieldData(FieldDef[i], FieldData[i]);
    }
    fld->Write(out, FieldDef, FieldData);
    //-----------------------------------------------
    
    //----------------------------------------------
    // See if there is an exact solution, if so 
    // evaluate and plot errors
    LibUtilities::EquationSharedPtr ex_sol =
        vSession->GetFunction("ExactSolution", 0);
    
    if(ex_sol)
    {
        //----------------------------------------------
        // evaluate exact solution 
        ex_sol->Evaluate(xc0, xc1, xc2,  fce);

        //----------------------------------------------

        //--------------------------------------------
        // Calculate L_inf error 
        Fce->SetPhys(fce);
        Fce->SetPhysState(true);

        NekDouble vLinfError = Exp->Linf(Exp->GetPhys(), Fce->GetPhys());
        NekDouble vL2Error   = Exp->L2  (Exp->GetPhys(), Fce->GetPhys());
        NekDouble vH1Error   = Exp->H1  (Exp->GetPhys(), Fce->GetPhys());

        if (vComm->GetRank() == 0)
        {
            cout << "L infinity error: " << vLinfError << endl;
            cout << "L 2 error       : " << vL2Error   << endl;
            cout << "H 1 error       : " << vH1Error   << endl;
        }
        //--------------------------------------------        
    }
    
    Timing("Output ..");

    //----------------------------------------------        
    
    vSession->Finalise();
    
    return 0;
}
Exemple #2
0
int main(int argc, char *argv[])
{
    Array<OneD,NekDouble>  fce;
    Array<OneD,NekDouble>  xc0,xc1,xc2;

    if(argc < 2)
    {
        fprintf(stderr,"Usage: XmlToTecplot meshfile\n");
        exit(1);
    }

    LibUtilities::SessionReader::RegisterCmdLineFlag(
        "multi-zone", "m", "Output multi-zone format (one element per zone).");

    LibUtilities::SessionReaderSharedPtr vSession
            = LibUtilities::SessionReader::CreateInstance(argc, argv);

    //----------------------------------------------
    // Read in mesh from input file
    string meshfile(argv[argc-1]);
    SpatialDomains::MeshGraphSharedPtr graphShPt
        = SpatialDomains::MeshGraph::Read(vSession);
    //----------------------------------------------

    //----------------------------------------------
    // Set up Expansion information
    SpatialDomains::ExpansionMap emap = graphShPt->GetExpansions();
    SpatialDomains::ExpansionMapIter it;

    for (it = emap.begin(); it != emap.end(); ++it)
    {
        for (int i = 0; i < it->second->m_basisKeyVector.size(); ++i)
        {
            LibUtilities::BasisKey  tmp1 = it->second->m_basisKeyVector[i];
            LibUtilities::PointsKey tmp2 = tmp1.GetPointsKey();
            it->second->m_basisKeyVector[i] = LibUtilities::BasisKey(
                tmp1.GetBasisType(), tmp1.GetNumModes(),
                LibUtilities::PointsKey(tmp1.GetNumModes(),
                                        LibUtilities::ePolyEvenlySpaced));
        }
    }
    //----------------------------------------------

    //----------------------------------------------
    // Define Expansion
    int expdim  = graphShPt->GetMeshDimension();
    Array<OneD, MultiRegions::ExpListSharedPtr> Exp(1);

    switch(expdim)
    {
        case 1:
        {
            MultiRegions::ExpList1DSharedPtr Exp1D;
            Exp1D = MemoryManager<MultiRegions::ExpList1D>::AllocateSharedPtr(vSession,graphShPt);
            Exp[0] = Exp1D;
            break;
        }
        case 2:
        {
            if(vSession->DefinesSolverInfo("HOMOGENEOUS"))
            {
                std::string HomoStr = vSession->GetSolverInfo("HOMOGENEOUS");
                MultiRegions::ExpList3DHomogeneous1DSharedPtr Exp3DH1;

                ASSERTL0(
                    HomoStr == "HOMOGENEOUS1D" || HomoStr == "Homogeneous1D" ||
                    HomoStr == "1D"            || HomoStr == "Homo1D",
                    "Only 3DH1D supported for XML output currently.");

                int nplanes;
                vSession->LoadParameter("HomModesZ", nplanes);

                // choose points to be at evenly spaced points at nplanes + 1
                // points
                const LibUtilities::PointsKey Pkey(
                    nplanes + 1, LibUtilities::ePolyEvenlySpaced);
                const LibUtilities::BasisKey  Bkey(
                    LibUtilities::eFourier, nplanes, Pkey);
                NekDouble lz = vSession->GetParameter("LZ");

                Exp3DH1 = MemoryManager<MultiRegions::ExpList3DHomogeneous1D>
                    ::AllocateSharedPtr(
                        vSession, Bkey, lz, false, false, graphShPt);
                Exp[0] = Exp3DH1;
            }
            else
            {
                MultiRegions::ExpList2DSharedPtr Exp2D;
                Exp2D = MemoryManager<MultiRegions::ExpList2D>::AllocateSharedPtr(vSession,graphShPt);
                Exp[0] =  Exp2D;
            }
            break;
        }
        case 3:
        {
            MultiRegions::ExpList3DSharedPtr Exp3D;
            Exp3D = MemoryManager<MultiRegions::ExpList3D>::AllocateSharedPtr(vSession,graphShPt);
            Exp[0] =  Exp3D;
            break;
        }
        default:
            ASSERTL0(false,"Expansion dimension not recognised");
            break;
    }

    //-----------------------------------------------

    //----------------------------------------------
    // Write solution  depending on #define
    string   outfile(strtok(argv[argc-1],"."));
    outfile +=  ".dat";
    ofstream outstrm(outfile.c_str());

    Exp[0]->WriteTecplotHeader(outstrm);

    if (vSession->DefinesCmdLineArgument("multi-zone"))
    {
        int nExp = Exp[0]->GetExpSize();

        for (int i = 0; i < nExp; ++i)
        {
            Exp[0]->WriteTecplotZone        (outstrm, i);
            Exp[0]->WriteTecplotConnectivity(outstrm, i);
        }
    }
    else
    {
        Exp[0]->WriteTecplotZone        (outstrm);
        Exp[0]->WriteTecplotConnectivity(outstrm);
    }

    outstrm.close();
    //----------------------------------------------
    return 0;
}
Exemple #3
0
int main(int argc, char *argv[])
{
    LibUtilities::SessionReaderSharedPtr vSession
            = LibUtilities::SessionReader::CreateInstance(argc, argv);

    LibUtilities::CommSharedPtr vComm = vSession->GetComm();
    MultiRegions::ContField1DSharedPtr Exp,Fce;
    int     i, nq,  coordim;
    Array<OneD,NekDouble>  fce;
    Array<OneD,NekDouble>  xc0,xc1,xc2;
    StdRegions::ConstFactorMap factors;

    if( (argc != 2) && (argc != 3) && (argc != 4))
    {
        fprintf(stderr,"Usage: Helmholtz1D  meshfile \n");
        exit(1);
    }

    try
    {
        LibUtilities::FieldIOSharedPtr fld =
            MemoryManager<LibUtilities::FieldIO>::AllocateSharedPtr(vComm);

        //----------------------------------------------
        // Read in mesh from input file
        SpatialDomains::MeshGraphSharedPtr graph1D =
            SpatialDomains::MeshGraph::Read(vSession);
        //----------------------------------------------

        //----------------------------------------------
        // Print summary of solution details
        factors[StdRegions::eFactorLambda] = vSession->GetParameter("Lambda");
        const SpatialDomains::ExpansionMap &expansions = graph1D->GetExpansions();
        LibUtilities::BasisKey bkey0 = expansions.begin()->second->m_basisKeyVector[0];

        if (vComm->GetRank() ==0)
        {
            cout << "Solving 1D Helmholtz: "  << endl;
            cout << "       Communication: " << vComm->GetType() << endl;
            cout << "       Solver type  : " << vSession->GetSolverInfo("GlobalSysSoln") << endl;
            cout << "       Lambda       : " << factors[StdRegions::eFactorLambda] << endl;
            cout << "       No. modes    : " << bkey0.GetNumModes() << endl;
        }
        //----------------------------------------------

        //----------------------------------------------
        // Define Expansion
        Exp = MemoryManager<MultiRegions::ContField1D>::
            AllocateSharedPtr(vSession,graph1D,vSession->GetVariable(0));
        //----------------------------------------------

        //----------------------------------------------
        // Set up coordinates of mesh for Forcing function evaluation
        coordim = Exp->GetCoordim(0);
        nq      = Exp->GetTotPoints();

        xc0 = Array<OneD,NekDouble>(nq);
        xc1 = Array<OneD,NekDouble>(nq);
        xc2 = Array<OneD,NekDouble>(nq);

        switch(coordim)
        {
        case 1:
            Exp->GetCoords(xc0);
            Vmath::Zero(nq,&xc1[0],1);
            Vmath::Zero(nq,&xc2[0],1);
            break;
        case 2:
            Exp->GetCoords(xc0,xc1);
            Vmath::Zero(nq,&xc2[0],1);
            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);

        ffunc->Evaluate(xc0,xc1,xc2, fce);

        //----------------------------------------------

        //----------------------------------------------
        // Setup expansion containing the  forcing function
        Fce = MemoryManager<MultiRegions::ContField1D>::AllocateSharedPtr(*Exp);
        Fce->SetPhys(fce);
        //----------------------------------------------

        //----------------------------------------------
        //Helmholtz solution taking physical forcing after setting
        //initial condition to zero
        Vmath::Zero(Exp->GetNcoeffs(),Exp->UpdateCoeffs(),1);
        Exp->HelmSolve(Fce->GetPhys(), Exp->UpdateCoeffs(), NullFlagList, factors);
        //----------------------------------------------

        //----------------------------------------------
        // Backward Transform Solution to get solved values at
        Exp->BwdTrans(Exp->GetCoeffs(), Exp->UpdatePhys());
        //----------------------------------------------

        //----------------------------------------------
        // Write solution
        string   out(strtok(argv[1],"."));
        string   endfile(".fld");
        out += endfile;
        std::vector<LibUtilities::FieldDefinitionsSharedPtr> FieldDef
            = Exp->GetFieldDefinitions();
        std::vector<std::vector<NekDouble> > FieldData(FieldDef.size());
        for(i = 0; i < FieldDef.size(); ++i)
        {
            FieldDef[i]->m_fields.push_back("u");
            Exp->AppendFieldData(FieldDef[i], FieldData[i]);
        }
        fld->Write(out, FieldDef, FieldData);
        //----------------------------------------------

        //----------------------------------------------
        // See if there is an exact solution, if so
        // evaluate and plot errors
        LibUtilities::EquationSharedPtr ex_sol
                                = vSession->GetFunction("ExactSolution", 0);


        if(ex_sol)
        {
            //----------------------------------------------
            // evaluate exact solution

            ex_sol->Evaluate(xc0,xc1,xc2, fce);

            Fce->SetPhys(fce);
            //----------------------------------------------

            //--------------------------------------------
            // Calculate errors
            NekDouble vLinfError = Exp->Linf(Exp->GetPhys(), Fce->GetPhys());
            NekDouble vL2Error   = Exp->L2(Exp->GetPhys(), Fce->GetPhys());
            NekDouble vH1Error   = Exp->H1(Exp->GetPhys(), Fce->GetPhys());
            if (vComm->GetRank() == 0)
            {
                cout << "L infinity error: " << vLinfError << endl;
                cout << "L 2 error:        " << vL2Error << endl;
                cout << "H 1 error:        " << vH1Error << endl;
            }
            //--------------------------------------------
        }
        //----------------------------------------------
    }
    catch (const std::runtime_error&)
    {
        cerr << "Caught exception." << endl;
        return 1;
    }

    vComm->Finalise();

    return 0;
}