示例#1
0
void FELIX::Hydrology::constructNeumannEvaluators (const Teuchos::RCP<Albany::MeshSpecsStruct>& meshSpecs)
{
    // Note: we only enter this function if sidesets are defined in the mesh file
    // i.e. meshSpecs.ssNames.size() > 0

    Albany::BCUtils<Albany::NeumannTraits> nbcUtils;

    // Check to make sure that Neumann BCs are given in the input file
    if (!nbcUtils.haveBCSpecified(this->params))
    {
        return;
    }

    // Construct BC evaluators for all side sets and names
    // Note that the string index sets up the equation offset, so ordering is important

    std::vector<std::string> neumannNames(neq + 1);
    Teuchos::Array<Teuchos::Array<int> > offsets;
    offsets.resize(1);

    neumannNames[0] = "Hydraulic Potential";
    neumannNames[1] = "all";
    offsets[0].resize(1);
    offsets[0][0] = 0;

    // Construct BC evaluators for all possible names of conditions
    std::vector<std::string> condNames(1);
    condNames[0] = "neumann";

    nfm.resize(1); // FELIX problem only has one element block

    nfm[0] = nbcUtils.constructBCEvaluators(meshSpecs, neumannNames, dof_names, false, 0,
                                            condNames, offsets, dl,
                                            this->params, this->paramLib);
}
示例#2
0
//------------------------------------------------------------------------------
void
Albany::MechanicsProblem::
constructDirichletEvaluators(const Albany::MeshSpecsStruct& meshSpecs)
{

  // Construct Dirichlet evaluators for all nodesets and names
  std::vector<std::string> dirichletNames(neq);
  int index = 0;
  if (have_mech_eq_) {
    dirichletNames[index++] = "X";
    if (num_dims_ > 1) dirichletNames[index++] = "Y";
    if (num_dims_ > 2) dirichletNames[index++] = "Z";
  }

  if (have_temperature_eq_) dirichletNames[index++] = "T";
  if (have_pore_pressure_eq_) dirichletNames[index++] = "P";
  if (have_transport_eq_) dirichletNames[index++] = "C";
  if (have_hydrostress_eq_) dirichletNames[index++] = "TAU";
  if (have_damage_eq_) dirichletNames[index++] = "D";
  if (have_stab_pressure_eq_) dirichletNames[index++] = "SP";

  // Pass on the Application as well that is needed for
  // the coupled Schwarz BC. It is just ignored otherwise.
  Teuchos::RCP<Albany::Application> const &
  application = getApplication();

  this->params->set<Teuchos::RCP<Albany::Application>>(
      "Application", application);

  Albany::BCUtils<Albany::DirichletTraits> dirUtils;
  dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
      this->params, this->paramLib);

}
示例#3
0
//------------------------------------------------------------------------------
void
Albany::MechanicsProblem::
constructDirichletEvaluators(const Albany::MeshSpecsStruct& meshSpecs)
{

  // Construct Dirichlet evaluators for all nodesets and names
  std::vector<std::string> dirichletNames(neq);
  int index = 0;
  if (have_mech_eq_) {
    dirichletNames[index++] = "X";
    if (neq > 1) dirichletNames[index++] = "Y";
    if (neq > 2) dirichletNames[index++] = "Z";
  }

  if (have_temperature_eq_) dirichletNames[index++] = "T";
  if (have_pore_pressure_eq_) dirichletNames[index++] = "P";
  if (have_transport_eq_) dirichletNames[index++] = "C";
  if (have_hydrostress_eq_) dirichletNames[index++] = "TAU";
  if (have_damage_eq_) dirichletNames[index++] = "D";
  if (have_stab_pressure_eq_) dirichletNames[index++] = "SP";

  Albany::BCUtils<Albany::DirichletTraits> dirUtils;
  dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
      this->params, this->paramLib);
}
示例#4
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void FELIX::Hydrology::constructDirichletEvaluators (const Albany::MeshSpecsStruct& meshSpecs)
{
    // Construct Dirichlet evaluators for all nodesets and names
    std::vector<std::string> dirichletNames(neq);
    dirichletNames[0] = dof_names[0];

    Albany::BCUtils<Albany::DirichletTraits> dirUtils;
    dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames, this->params, this->paramLib);
}
示例#5
0
//Neumann BCs
void
Albany::PNPProblem::constructNeumannEvaluators(const Teuchos::RCP<Albany::MeshSpecsStruct>& meshSpecs)
{

   // Note: we only enter this function if sidesets are defined in the mesh file
   // i.e. meshSpecs.ssNames.size() > 0
   
    Albany::BCUtils<Albany::NeumannTraits> nbcUtils;

   // Check to make sure that Neumann BCs are given in the input file

   if(!nbcUtils.haveBCSpecified(this->params)) {
      return;
   }

   // Construct BC evaluators for all side sets and names
   // Note that the string index sets up the equation offset, so ordering is important
   //
   // Currently we aren't exactly doing this right.  I think to do this
   // correctly we need different neumann evaluators for each DOF (velocity,
   // pressure, temperature, flux) since velocity is a vector and the 
   // others are scalars.  The dof_names stuff is only used
   // for robin conditions, so at this point, as long as we don't enable
   // robin conditions, this should work.
   
   std::vector<std::string> nbcNames;
   Teuchos::RCP< Teuchos::Array<std::string> > dof_names =
     Teuchos::rcp(new Teuchos::Array<std::string>);
   // TODO: arbitraty numSpecies
   Teuchos::Array<Teuchos::Array<int> > offsets;
   int idx = 0;
     nbcNames.push_back("C1");
     offsets.push_back(Teuchos::Array<int>(1,idx++));
     if (numSpecies>=2) {
       nbcNames.push_back("C2");
       offsets.push_back(Teuchos::Array<int>(1,idx++));
     }
     if (numSpecies==3) {
       nbcNames.push_back("C3");
       offsets.push_back(Teuchos::Array<int>(1,idx++));
     }
     nbcNames.push_back("Phi");
     offsets.push_back(Teuchos::Array<int>(1,idx++));
     dof_names->push_back("Concentration");
     dof_names->push_back("Potential");

   // Construct BC evaluators for all possible names of conditions
   // Should only specify flux vector components (dudx, dudy, dudz), or dudn, not both
   std::vector<std::string> condNames; //dudx, dudy, dudz, dudn, basal 


   nfm[0] = nbcUtils.constructBCEvaluators(meshSpecs, nbcNames,
                                           Teuchos::arcp(dof_names),
                                           true, 0, condNames, offsets, dl,
                                           this->params, this->paramLib);
}
示例#6
0
// Dirichlet BCs
void
Albany::CahnHillProblem::constructDirichletEvaluators(const std::vector<std::string>& nodeSetIDs)
{
   // Construct BC evaluators for all node sets and names
   std::vector<std::string> bcNames(neq);
   bcNames[0] = "rho";
   Albany::BCUtils<Albany::DirichletTraits> bcUtils;
   dfm = bcUtils.constructBCEvaluators(nodeSetIDs, bcNames,
                                          this->params, this->paramLib);
}
示例#7
0
// Dirichlet BCs
void
Albany::PoissonsEquationProblem::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
  // Construct Dirichlet evaluators for all nodesets and names
  std::vector<std::string> dirichletNames(neq);
  dirichletNames[0] = "P";
  Albany::BCUtils<Albany::DirichletTraits> dirUtils;
  dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                       this->params, this->paramLib);
}
示例#8
0
void
Albany::PeridigmProblem::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(neq);
   dirichletNames[0] = "X";
   if (neq>1) dirichletNames[1] = "Y";
   if (neq>2) dirichletNames[2] = "Z";
   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames, this->params, this->paramLib);
}
void
Albany::Helmholtz2DProblem::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(neq);
   dirichletNames[0] = "U";
   dirichletNames[1] = "V";
   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                          this->params, this->paramLib);
   offsets_ = dirUtils.getOffsets(); 
}
示例#10
0
// Dirichlet BCs
void
Albany::HeatProblem::constructDirichletEvaluators(const std::vector<std::string>& nodeSetIDs)
{
   // Construct BC evaluators for all node sets and names
   std::vector<std::string> bcNames(neq);
   bcNames[0] = "T";
   Albany::BCUtils<Albany::DirichletTraits> bcUtils;
   dfm = bcUtils.constructBCEvaluators(nodeSetIDs, bcNames,
                                          this->params, this->paramLib);
   use_sdbcs_ = bcUtils.useSDBCs(); 
   offsets_ = bcUtils.getOffsets(); 
   nodeSetIDs_ = bcUtils.getNodeSetIDs();
}
示例#11
0
// Neumann BCs
void
Albany::HeatProblem::constructNeumannEvaluators(const Teuchos::RCP<Albany::MeshSpecsStruct>& meshSpecs)
{
   // Note: we only enter this function if sidesets are defined in the mesh file
   // i.e. meshSpecs.ssNames.size() > 0

   Albany::BCUtils<Albany::NeumannTraits> bcUtils;

   // Check to make sure that Neumann BCs are given in the input file

   if(!bcUtils.haveBCSpecified(this->params))

      return;

   // Construct BC evaluators for all side sets and names
   // Note that the string index sets up the equation offset, so ordering is important
   std::vector<std::string> bcNames(neq);
   Teuchos::ArrayRCP<std::string> dof_names(neq);
   Teuchos::Array<Teuchos::Array<int> > offsets;
   offsets.resize(neq);

   bcNames[0] = "T";
   dof_names[0] = "Temperature";
   offsets[0].resize(1);
   offsets[0][0] = 0;


   // Construct BC evaluators for all possible names of conditions
   // Should only specify flux vector components (dudx, dudy, dudz), or dudn, not both
   std::vector<std::string> condNames(5);
     //dudx, dudy, dudz, dudn, scaled jump (internal surface), or robin (like DBC plus scaled jump)

   // Note that sidesets are only supported for two and 3D currently
   if(numDim == 2)
    condNames[0] = "(dudx, dudy)";
   else if(numDim == 3)
    condNames[0] = "(dudx, dudy, dudz)";
   else
    TEUCHOS_TEST_FOR_EXCEPTION(true, Teuchos::Exceptions::InvalidParameter,
       std::endl << "Error: Sidesets only supported in 2 and 3D." << std::endl);

   condNames[1] = "dudn";
   condNames[2] = "scaled jump";
   condNames[3] = "robin";
   condNames[4] = "radiate";

   nfm.resize(1); // Heat problem only has one physics set
   nfm[0] = bcUtils.constructBCEvaluators(meshSpecs, bcNames, dof_names, false, 0,
                                  condNames, offsets, dl, this->params, this->paramLib, materialDB);

}
示例#12
0
void
FELIX::StokesFO::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(neq);
   for (int i=0; i<neq; i++) {
     std::stringstream s; s << "U" << i;
     dirichletNames[i] = s.str();
   }
   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                          this->params, this->paramLib);
}
void
Albany::GradientDamageProblem::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
  // Construct Dirichlet evaluators for all nodesets and names
  std::vector<std::string> dirichletNames(neq);
  dirichletNames[X_offset] = "X";
  if (numDim>1) dirichletNames[X_offset+1] = "Y";
  if (numDim>2) dirichletNames[X_offset+2] = "Z";
  dirichletNames[D_offset] = "D";
  Albany::BCUtils<Albany::DirichletTraits> dirUtils;
  dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                       this->params, this->paramLib);
}
示例#14
0
void Hydrology::constructDirichletEvaluators (const Albany::MeshSpecsStruct& meshSpecs)
{
  // Construct Dirichlet evaluators for all nodesets and names
  std::vector<std::string> dirichletNames(neq);
  dirichletNames[0] = dofs_names[0];
  if (!eliminate_h) {
    dirichletNames[1] = dofs_names[1];
  }

  Albany::BCUtils<Albany::DirichletTraits> dirUtils;
  dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames, this->params, this->paramLib);
  offsets_ = dirUtils.getOffsets();
  nodeSetIDs_ = dirUtils.getNodeSetIDs();
}
示例#15
0
void
Albany::ComprNSProblem::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(neq);
   for (int i=0; i<neq; i++) {
     std::stringstream s; s << "qFluct" << i;
     dirichletNames[i] = s.str();
   }
   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                          this->params, this->paramLib);
   offsets_ = dirUtils.getOffsets(); 
}
示例#16
0
// Neumann BCs
void
Albany::PoissonsEquationProblem::constructNeumannEvaluators(
        const Teuchos::RCP<Albany::MeshSpecsStruct>& meshSpecs)
{
   // Note: we only enter this function if sidesets are defined in the mesh file
   // i.e. meshSpecs.ssNames.size() > 0

   Albany::BCUtils<Albany::NeumannTraits> neuUtils;

   // Check to make sure that Neumann BCs are given in the input file

   if(!neuUtils.haveBCSpecified(this->params))

      return;

   // Construct BC evaluators for all side sets and names
   // Note that the string index sets up the equation offset, so ordering is important
   std::vector<std::string> neumannNames(neq);
   Teuchos::Array<Teuchos::Array<int> > offsets;
   offsets.resize(neq);

   neumannNames[0] = "P";
   offsets[0].resize(1);
   offsets[0][0] = 0;

   // Construct BC evaluators for all possible names of conditions
   // Should only specify flux vector components (dudx, dudy, dudz), or dudn, not both
   std::vector<std::string> condNames(2); //dudx, dudy, dudz, dudn, P
   Teuchos::ArrayRCP<std::string> dof_names(1);
     dof_names[0] = "Phi";

   // Note that sidesets are only supported for two and 3D currently
   if(numDim == 2)
    condNames[0] = "(dudx, dudy)";
   else if(numDim == 3)
    condNames[0] = "(dudx, dudy, dudz)";
   else
    TEUCHOS_TEST_FOR_EXCEPTION(true, Teuchos::Exceptions::InvalidParameter,
       std::endl << "Error: Sidesets only supported in 2 and 3D." << std::endl);

   condNames[1] = "dudn";

   nfm.resize(1);
   nfm[0] = neuUtils.constructBCEvaluators(meshSpecs, neumannNames, dof_names, true, 0,
                                           condNames, offsets, dl,
                                           this->params, this->paramLib);

}
示例#17
0
// Dirichlet BCs
void
Albany::HMCProblem::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
  // Construct Dirichlet evaluators for all nodesets and names
  std::vector<std::string> dirichletNames(neq);
  dirichletNames[0] = "X";
  if (neq>1) dirichletNames[1] = "Y";
  if (neq>2) dirichletNames[2] = "Z";
  Albany::BCUtils<Albany::DirichletTraits> dirUtils;
  dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                       this->params, this->paramLib);
  use_sdbcs_ = dirUtils.useSDBCs();
  offsets_ = dirUtils.getOffsets();
  nodeSetIDs_ = dirUtils.getNodeSetIDs();
}
示例#18
0
// Dirichlet BCs
void
Albany::HydrideProblem::constructDirichletEvaluators(const std::vector<std::string>& nodeSetIDs)
{
   // Construct BC evaluators for all node sets and names
   std::vector<std::string> bcNames(neq);
   bcNames[0] = "X";
   if (numDim>1) bcNames[1] = "Y";
   if (numDim>2) bcNames[2] = "Z";
   bcNames[numDim] = "c";
   bcNames[numDim+1] = "w";

   Albany::BCUtils<Albany::DirichletTraits> bcUtils;
   dfm = bcUtils.constructBCEvaluators(nodeSetIDs, bcNames,
                                          this->params, this->paramLib);
   offsets_ = bcUtils.getOffsets(); 
}
示例#19
0
void
Albany::PNPProblem::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(neq);
   int index = 0;
   dirichletNames[index++] = "C1";
   // TODO: arbitraty numSpecies
   if (numSpecies>=2) dirichletNames[index++] = "C2";
   if (numSpecies==3) dirichletNames[index++] = "C3";
   dirichletNames[index++] = "Phi";
   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                          this->params, this->paramLib);
}
//------------------------------------------------------------------------------
void
Albany::ConcurrentMultiscaleProblem::
constructDirichletEvaluators(const Albany::MeshSpecsStruct& meshSpecs)
{

  // Construct Dirichlet evaluators for all nodesets and names
  std::vector<std::string> dirichletNames(neq);
  int index = 0;
  dirichletNames[index++] = "X";
  if (neq>1) dirichletNames[index++] = "Y";
  if (neq>2) dirichletNames[index++] = "Z";

  Albany::BCUtils<Albany::DirichletTraits> dirUtils;
  dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                       this->params, this->paramLib);
}
示例#21
0
void
FELIX::Stokes::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(neq);
   int index = 0;
   if (haveFlowEq) {
     dirichletNames[index++] = "ux";
     if (numDim>=2) dirichletNames[index++] = "uy";
     if (numDim==3) dirichletNames[index++] = "uz";
     dirichletNames[index++] = "p";
   }
   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                          this->params, this->paramLib);
   offsets_ = dirUtils.getOffsets(); 
}
//------------------------------------------------------------------------------
void
Albany::ElectroMechanicsProblem::
constructDirichletEvaluators(const Albany::MeshSpecsStruct& meshSpecs)
{

  // Construct Dirichlet evaluators for all nodesets and names
  std::vector<std::string> dirichletNames(neq);
  int index = 0;
  dirichletNames[index++] = "X";
  if (num_dims_ > 1) dirichletNames[index++] = "Y";
  if (num_dims_ > 2) dirichletNames[index++] = "Z";

  dirichletNames[index++] = "Potential";

  Albany::BCUtils<Albany::DirichletTraits> dirUtils;
  dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
      this->params, this->paramLib);
  offsets_ = dirUtils.getOffsets(); 
}
示例#23
0
void
Albany::NavierStokes::constructDirichletEvaluators(
        const std::vector<std::string>& nodeSetIDs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(neq);
   int index = 0;
   if (haveFlowEq) {
     dirichletNames[index++] = "ux";
     if (numDim>=2) dirichletNames[index++] = "uy";
     if (numDim==3) dirichletNames[index++] = "uz";
     dirichletNames[index++] = "p";
   }
   if (haveHeatEq) dirichletNames[index++] = "T";
   if (haveNeutEq) dirichletNames[index++] = "phi";
   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(nodeSetIDs, dirichletNames,
                                          this->params, this->paramLib);
}
示例#24
0
void
Albany::PNPProblem::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(neq);
   int idx = 0;
   for(idx = 0; idx<numSpecies; idx++) {
     std::stringstream s; s << "C" << (idx+1);
     dirichletNames[idx] = s.str();
   }
   dirichletNames[idx++] = "Phi";
   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                          this->params, this->paramLib);
   use_sdbcs_ = dirUtils.useSDBCs(); 
   offsets_ = dirUtils.getOffsets(); 
   nodeSetIDs_ = dirUtils.getNodeSetIDs();
}
示例#25
0
void
Tsunami::Boussinesq::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(neq);
   int index = 0;
   dirichletNames[index++] = "eta";
   dirichletNames[index++] = "ualpha";
   if (numDim > 1) 
     dirichletNames[index++] = "valpha";
   dirichletNames[index++] = "E1";
   if (numDim > 1) 
     dirichletNames[index++] = "E2";
   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames, dirichletNames,
                                          this->params, this->paramLib);
   use_sdbcs_ = dirUtils.useSDBCs(); 
   offsets_ = dirUtils.getOffsets();
   nodeSetIDs_ = dirUtils.getNodeSetIDs();
}
示例#26
0
void
Aeras::HydrostaticProblem::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(1 + 2*numLevels + numTracers*numLevels);

   int dbc=0;
   std::ostringstream s;
   s << "SPressure";
   dirichletNames[dbc++] = s.str();

   for (int i=0; i<numLevels; ++i) {
     s.str(std::string());
     s << "Velx_"<<i;
     dirichletNames[dbc++] = s.str();
   }
   for (int i=0; i<numLevels; ++i) {
     s.str(std::string());
     s << "Temperature_"<<i;
     dirichletNames[dbc++] = s.str();
   }

   for (int t=0; t<numTracers; ++t) {
     for (int i=0; i<numLevels; ++i) {
       s.str(std::string());
       s << dof_names_tracers[t]<<"_"<<i;
       dirichletNames[dbc++] = s.str();
     }
   }

   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames,
                                        dirichletNames,
                                        this->params,
                                        this->paramLib);
}
void
Aeras::XScalarAdvectionProblem::constructDirichletEvaluators(
        const Albany::MeshSpecsStruct& meshSpecs)
{
   // Construct Dirichlet evaluators for all nodesets and names
   std::vector<std::string> dirichletNames(numLevels*(1+numTracers));
   std::ostringstream s;
   for (int i=0,n=0; i<numLevels; ++i) {
     s.str(std::string());
     s << "rho_"<<i;
     dirichletNames[n++] = s.str();
     for (int j=0; j<numTracers; ++j) {
       s.str(std::string());
       s << dof_names_tracers[j] <<"_"<<i;
       dirichletNames[n++] = s.str();
     }
   }
   Albany::BCUtils<Albany::DirichletTraits> dirUtils;
   dfm = dirUtils.constructBCEvaluators(meshSpecs.nsNames,
                                        dirichletNames,
                                        this->params,
                                        this->paramLib);
   offsets_ = dirUtils.getOffsets();
}
示例#28
0
// Neumann BCs
void
Aeras::HydrostaticProblem::
constructNeumannEvaluators(const Teuchos::RCP<Albany::MeshSpecsStruct>& meshSpecs)
{

   // Note: we only enter this function if sidesets are defined in the mesh file
   // i.e. meshSpecs.ssNames.size() > 0

   Albany::BCUtils<Albany::NeumannTraits> nbcUtils;

   // Check to make sure that Neumann BCs are given in the input file

   if(!nbcUtils.haveBCSpecified(this->params)) {
      return;
   }


   // Construct BC evaluators for all side sets and names
   // Note that the string index sets up the equation offset, so ordering is important

   std::vector<std::string> neumannNames(1 + 1);
   Teuchos::Array<Teuchos::Array<int> > offsets;
   offsets.resize(1 + 1);

   neumannNames[0] = "rho";
   offsets[0].resize(1);
   offsets[0][0] = 0;
   offsets[1].resize(1);
   offsets[1][0] = 0;

   neumannNames[1] = "all";

   // Construct BC evaluators for all possible names of conditions
   // Should only specify flux vector components (dUdx, dUdy, dUdz)
   std::vector<std::string> condNames(1); //(dUdx, dUdy, dUdz)
   Teuchos::ArrayRCP<std::string> dof_names(1);
     dof_names[0] = "rho";

   // Note that sidesets are only supported for two and 3D currently
   if(numDim == 1)
    condNames[0] = "(dFluxdx)";
   else if(numDim == 2)
    condNames[0] = "(dFluxdx, dFluxdy)";
   else if(numDim == 3)
    condNames[0] = "(dFluxdx, dFluxdy, dFluxdz)";
   else
    TEUCHOS_TEST_FOR_EXCEPTION(true, Teuchos::Exceptions::InvalidParameter,
       std::endl << "Error: Sidesets only supported in 2 and 3D." << std::endl);

//   condNames[1] = "dFluxdn";
//   condNames[2] = "basal";
//   condNames[3] = "P";
//   condNames[4] = "lateral";

   nfm.resize(1); // Aeras X scalar advection problem only has one
                  // element block

   nfm[0] = nbcUtils.constructBCEvaluators(meshSpecs,
                                           neumannNames,
                                           dof_names,
                                           true,
                                           0,
                                           condNames,
                                           offsets,
                                           dl,
                                           this->params,
                                           this->paramLib);


}
示例#29
0
//Neumann BCs
void
Tsunami::Boussinesq::constructNeumannEvaluators(const Teuchos::RCP<Albany::MeshSpecsStruct>& meshSpecs)
{

   // Note: we only enter this function if sidesets are defined in the mesh file
   // i.e. meshSpecs.ssNames.size() > 0

    Albany::BCUtils<Albany::NeumannTraits> nbcUtils;

   // Check to make sure that Neumann BCs are given in the input file

   if(!nbcUtils.haveBCSpecified(this->params)) {
      return;
   }

   // Construct BC evaluators for all side sets and names
   // Note that the string index sets up the equation offset, so ordering is important
   //
   // Currently we aren't exactly doing this right.  I think to do this
   // correctly we need different neumann evaluators for each DOF (velocity,
   // pressure, temperature, flux) since velocity is a vector and the
   // others are scalars.  The dof_names stuff is only used
   // for robin conditions, so at this point, as long as we don't enable
   // robin conditions, this should work.

   std::vector<std::string> nbcNames;
   Teuchos::RCP< Teuchos::Array<std::string> > dof_names =
     Teuchos::rcp(new Teuchos::Array<std::string>);
   Teuchos::Array<Teuchos::Array<int> > offsets;
   int idx = 0;
   nbcNames.push_back("eta");
   offsets.push_back(Teuchos::Array<int>(1,idx++));
   nbcNames.push_back("ualpha");
   offsets.push_back(Teuchos::Array<int>(1,idx++));
   if (numDim > 1) {
     nbcNames.push_back("valpha");
     offsets.push_back(Teuchos::Array<int>(1,idx++));
   }
   nbcNames.push_back("E1");
   offsets.push_back(Teuchos::Array<int>(1,idx++));
   if (numDim > 1) {
     nbcNames.push_back("E2");
     offsets.push_back(Teuchos::Array<int>(1,idx++));
   }

   // Construct BC evaluators for all possible names of conditions
   // Should only specify flux vector components (dudx, dudy, dudz), or dudn, not both
   std::vector<std::string> condNames(3); //dudx, dudy, dudz, dudn, basal

   // Note that sidesets are only supported for two and 3D currently
   //
   //IKT, FIXME: the following needs to be changed for Tsunami problem! 
   if(numDim == 2)
    condNames[0] = "(dudx, dudy)";
   else
    TEUCHOS_TEST_FOR_EXCEPTION(true, Teuchos::Exceptions::InvalidParameter,
       std::endl << "Error: Sidesets only supported in 2 and 3D." << std::endl);

   condNames[1] = "dudn";

   condNames[2] = "basal";

   nfm.resize(1);


   nfm[0] = nbcUtils.constructBCEvaluators(meshSpecs, nbcNames,
                                           Teuchos::arcp(dof_names),
                                           true, 0, condNames, offsets, dl,
                                           this->params, this->paramLib);
}
示例#30
0
//------------------------------------------------------------------------------
// Traction BCs
void
Albany::MechanicsProblem::
constructNeumannEvaluators(
    const Teuchos::RCP<Albany::MeshSpecsStruct>& meshSpecs)
{
  // Note: we only enter this function if sidesets are defined in the mesh file
  // i.e. meshSpecs.ssNames.size() > 0

  Albany::BCUtils<Albany::NeumannTraits> neuUtils;

  // Check to make sure that Neumann BCs are given in the input file

  if (!neuUtils.haveBCSpecified(this->params))

  return;

  // Construct BC evaluators for all side sets and names
  // Note that the string index sets up the equation offset,
  // so ordering is important
  
  std::vector<std::string> neumannNames(neq + 1);
  Teuchos::Array<Teuchos::Array<int>> offsets;
  offsets.resize(neq + 1);

  neumannNames[0] = "sig_x";
  offsets[0].resize(1);
  offsets[0][0] = 0;
  // The Neumann BC code uses offsets[neq].size() as num dim, so use num_dims_
  // here rather than neq.
  offsets[neq].resize(num_dims_);
  offsets[neq][0] = 0;

  if (num_dims_ > 1) {
    neumannNames[1] = "sig_y";
    offsets[1].resize(1);
    offsets[1][0] = 1;
    offsets[neq][1] = 1;
  }

  if (num_dims_ > 2) {
    neumannNames[2] = "sig_z";
    offsets[2].resize(1);
    offsets[2][0] = 2;
    offsets[neq][2] = 2;
  }

  neumannNames[neq] = "all";

  // Construct BC evaluators for all possible names of conditions
  // Should only specify flux vector components (dudx, dudy, dudz),
  // or dudn, not both
  std::vector<std::string> condNames(3); //dudx, dudy, dudz, dudn, P
  Teuchos::ArrayRCP<std::string> dof_names(1);
  dof_names[0] = "Displacement";

  // Note that sidesets are only supported for two and 3D currently
  if (num_dims_ == 2)
    condNames[0] = "(t_x, t_y)";
  else if (num_dims_ == 3)
    condNames[0] = "(t_x, t_y, t_z)";
  else
    TEUCHOS_TEST_FOR_EXCEPTION(true, Teuchos::Exceptions::InvalidParameter,
        '\n' << "Error: Sidesets only supported in 2 and 3D." << '\n');

  condNames[1] = "dudn";
  condNames[2] = "P";

  nfm.resize(1); // Elasticity problem only has one element block

  nfm[0] = neuUtils.constructBCEvaluators(
      meshSpecs,
      neumannNames,
      dof_names,
      true,
      0,
      condNames,
      offsets,
      dl_,
      this->params,
      this->paramLib);
}