EpetraExt::ModelEvaluator::OutArgs
twoD_diffusion_ME::
createOutArgs() const
{
  OutArgsSetup outArgs;
  outArgs.setModelEvalDescription("TwoD Diffusion Model Evaluator");

  // Deterministic OutArgs
  outArgs.set_Np_Ng(1, 1);
  outArgs.setSupports(OUT_ARG_f,true);
  outArgs.setSupports(OUT_ARG_W,true);
  if (precFactory != Teuchos::null)
    outArgs.setSupports(OUT_ARG_WPrec,true);

  // Stochastic OutArgs
  outArgs.setSupports(OUT_ARG_f_sg,true);
  outArgs.setSupports(OUT_ARG_W_sg,true);
  outArgs.setSupports(OUT_ARG_g_sg, 0, true);

  // Multipoint OutArgs
  outArgs.setSupports(OUT_ARG_f_mp,true);
  outArgs.setSupports(OUT_ARG_W_mp,true);
  outArgs.setSupports(OUT_ARG_g_mp, 0, true);

  return outArgs;
}
// Create OutArgs
EpetraExt::ModelEvaluator::OutArgs trilinosModelEvaluator::createOutArgs() const{
  OutArgsSetup outArgs;
  outArgs.setModelEvalDescription(this->description());
  outArgs.set_Np_Ng(0, 0);
  outArgs.setSupports(OUT_ARG_f,true);
  outArgs.setSupports(OUT_ARG_WPrec, true);

  return outArgs;
}
EpetraExt::ModelEvaluator::OutArgs
Stokhos::SGQuadModelEvaluator::
createOutArgs() const
{
  OutArgsSetup outArgs;
  OutArgs me_outargs = me->createOutArgs();

  outArgs.setModelEvalDescription(this->description());
  outArgs.set_Np_Ng(num_p, num_g);
  outArgs.setSupports(OUT_ARG_f, me_outargs.supports(OUT_ARG_f));
  outArgs.setSupports(OUT_ARG_W, me_outargs.supports(OUT_ARG_W));
  for (int j=0; j<num_p; j++)
    outArgs.setSupports(OUT_ARG_DfDp, j, 
			me_outargs.supports(OUT_ARG_DfDp, j));
  for (int i=0; i<num_g; i++) {
    outArgs.setSupports(OUT_ARG_DgDx, i, 
			me_outargs.supports(OUT_ARG_DgDx, i));
    outArgs.setSupports(OUT_ARG_DgDx_dot, i, 
			me_outargs.supports(OUT_ARG_DgDx_dot, i));
    for (int j=0; j<num_p; j++)
      outArgs.setSupports(OUT_ARG_DgDp, i, j, 
			  me_outargs.supports(OUT_ARG_DgDp, i, j));
  }

  outArgs.setSupports(OUT_ARG_f_sg, me_outargs.supports(OUT_ARG_f));
  if (me_outargs.supports(OUT_ARG_W)) {
    outArgs.set_W_properties(me_outargs.get_W_properties());
    outArgs.setSupports(OUT_ARG_W_sg, true);
  }
  for (int j=0; j<num_p; j++) {
    outArgs.setSupports(OUT_ARG_DfDp_sg, j, 
			me_outargs.supports(OUT_ARG_DfDp, j));
  }
  for (int i=0; i<num_g; i++) {
    outArgs.setSupports(OUT_ARG_g_sg, i, true);
    outArgs.setSupports(OUT_ARG_DgDx_sg, i, 
			me_outargs.supports(OUT_ARG_DgDx, i));
    outArgs.setSupports(OUT_ARG_DgDx_dot_sg, i, 
			me_outargs.supports(OUT_ARG_DgDx_dot, i));
    for (int j=0; j<num_p; j++)
      outArgs.setSupports(OUT_ARG_DgDp_sg, i, j, 
			  me_outargs.supports(OUT_ARG_DgDp, i, j));
  }
  
  return outArgs;
}
EpetraExt::ModelEvaluator::OutArgs QCAD::GenEigensolver::createOutArgs() const
{
  //Based on Piro_Epetra_NOXSolver.cpp implementation
  OutArgsSetup outArgs;
  outArgs.setModelEvalDescription("QCAD Generalized Eigensolver Model Evaluator");

  // Ng is 1 bigger then model's Ng so that the solution vector can be an outarg
  outArgs.set_Np_Ng(model_num_p, model_num_g+1);

  //Derivative info 
  EpetraExt::ModelEvaluator::OutArgs model_outArgs = model->createOutArgs();
  for (int i=0; i<model_num_g; i++) {
    for (int j=0; j<model_num_p; j++)
      outArgs.setSupports(OUT_ARG_DgDp, i, j, model_outArgs.supports(OUT_ARG_DgDp, i, j));
  }

  return outArgs;
}
EpetraExt::ModelEvaluator::OutArgs
Stokhos::MPInverseModelEvaluator::createOutArgs() const
{
  OutArgsSetup outArgs;
  OutArgs me_outargs = me->createOutArgs();

  outArgs.setModelEvalDescription(this->description());

  outArgs.set_Np_Ng(num_p, num_g);
  for (int i=0; i<num_g_mp; i++) {
    outArgs.setSupports(OUT_ARG_g_mp, mp_g_index_map[i], true);
    for (int j=0; j<num_p; j++)
      outArgs.setSupports(OUT_ARG_DgDp_mp, mp_g_index_map[i], j, 
			  me_outargs.supports(OUT_ARG_DgDp,i,j));
  }
  
  return outArgs;
}
EpetraExt::ModelEvaluator::OutArgs EpetraExt::MultiPointModelEvaluator::createOutArgs() const
{
  //return underlyingME->createOutArgs();
  OutArgsSetup outArgs;
  outArgs.setModelEvalDescription(this->description());
  outArgs.set_Np_Ng(1, underlyingNg);
  outArgs.setSupports(OUT_ARG_f,true);
  outArgs.setSupports(OUT_ARG_W,true);
  outArgs.set_W_properties(
    DerivativeProperties(
      DERIV_LINEARITY_NONCONST
      ,DERIV_RANK_FULL
      ,true // supportsAdjoint
      )
    );
  outArgs.setSupports(OUT_ARG_DfDp,0,DERIV_MV_BY_COL);
  outArgs.set_DfDp_properties(
    0,DerivativeProperties(
      DERIV_LINEARITY_CONST
      ,DERIV_RANK_DEFICIENT
      ,true // supportsAdjoint
      )
    );

  if (underlyingNg) {
    outArgs.setSupports(OUT_ARG_DgDx,0,DERIV_TRANS_MV_BY_ROW);
    outArgs.set_DgDx_properties(
      0,DerivativeProperties(
        DERIV_LINEARITY_NONCONST
        ,DERIV_RANK_DEFICIENT
        ,true // supportsAdjoint
        )
      );
    outArgs.setSupports(OUT_ARG_DgDp,0,0, orientation_DgDp);
    outArgs.set_DgDp_properties(
      0,0,DerivativeProperties(
        DERIV_LINEARITY_NONCONST
        ,DERIV_RANK_DEFICIENT
        ,true // supportsAdjoint
        )
      );
  }
  return outArgs;
}
Example #7
0
EpetraExt::ModelEvaluator::OutArgs
Albany::ModelEvaluator::createOutArgs() const
{
  OutArgsSetup outArgs;
  outArgs.setModelEvalDescription(this->description());

  int n_g = app->getNumResponses();

  // Deterministic
  outArgs.setSupports(OUT_ARG_f,true);
  outArgs.setSupports(OUT_ARG_W,true);
  outArgs.set_W_properties(
    DerivativeProperties(DERIV_LINEARITY_UNKNOWN, DERIV_RANK_FULL, true));
  if (supplies_prec) outArgs.setSupports(OUT_ARG_WPrec, true);
  outArgs.set_Np_Ng(num_param_vecs+num_dist_param_vecs, n_g);

  for (int i=0; i<num_param_vecs; i++)
    outArgs.setSupports(OUT_ARG_DfDp, i, DerivativeSupport(DERIV_MV_BY_COL));
  for (int i=0; i<num_dist_param_vecs; i++)
    outArgs.setSupports(OUT_ARG_DfDp, i+num_param_vecs,
                        DerivativeSupport(DERIV_LINEAR_OP));
  for (int i=0; i<n_g; i++) {
    if (app->getResponse(i)->isScalarResponse()) {
      outArgs.setSupports(OUT_ARG_DgDx, i,
                          DerivativeSupport(DERIV_TRANS_MV_BY_ROW));
      outArgs.setSupports(OUT_ARG_DgDx_dot, i,
                          DerivativeSupport(DERIV_TRANS_MV_BY_ROW));
      outArgs.setSupports(OUT_ARG_DgDx_dotdot, i,
                          DerivativeSupport(DERIV_TRANS_MV_BY_ROW));
    }
    else {
      outArgs.setSupports(OUT_ARG_DgDx, i,
                          DerivativeSupport(DERIV_LINEAR_OP));
      outArgs.setSupports(OUT_ARG_DgDx_dot, i,
                          DerivativeSupport(DERIV_LINEAR_OP));
      outArgs.setSupports(OUT_ARG_DgDx_dotdot, i,
                          DerivativeSupport(DERIV_LINEAR_OP));
    }

    for (int j=0; j<num_param_vecs; j++)
      outArgs.setSupports(OUT_ARG_DgDp, i, j,
                          DerivativeSupport(DERIV_MV_BY_COL));
    if (app->getResponse(i)->isScalarResponse()) {
      for (int j=0; j<num_dist_param_vecs; j++)
        outArgs.setSupports(OUT_ARG_DgDp, i, j+num_param_vecs,
                            DerivativeSupport(DERIV_TRANS_MV_BY_ROW));
    }
    else {
      for (int j=0; j<num_dist_param_vecs; j++)
        outArgs.setSupports(OUT_ARG_DgDp, i, j+num_param_vecs,
                            DerivativeSupport(DERIV_LINEAR_OP));
    }
  }


#ifdef ALBANY_SG_MP
  // Stochastic
  outArgs.setSupports(OUT_ARG_f_sg,true);
  outArgs.setSupports(OUT_ARG_W_sg,true);
  for (int i=0; i<num_param_vecs; i++)
    outArgs.setSupports(OUT_ARG_DfDp_sg, i, DerivativeSupport(DERIV_MV_BY_COL));
  for (int i=0; i<n_g; i++)
    outArgs.setSupports(OUT_ARG_g_sg, i, true);
  for (int i=0; i<n_g; i++) {
    if (app->getResponse(i)->isScalarResponse()) {
      outArgs.setSupports(OUT_ARG_DgDx_sg, i,
                          DerivativeSupport(DERIV_TRANS_MV_BY_ROW));
      outArgs.setSupports(OUT_ARG_DgDx_dot_sg, i,
                          DerivativeSupport(DERIV_TRANS_MV_BY_ROW));
      outArgs.setSupports(OUT_ARG_DgDx_dotdot_sg, i,
                          DerivativeSupport(DERIV_TRANS_MV_BY_ROW));
    }
    else {
      outArgs.setSupports(OUT_ARG_DgDx_sg, i,
                          DerivativeSupport(DERIV_LINEAR_OP));
      outArgs.setSupports(OUT_ARG_DgDx_dot_sg, i,
                          DerivativeSupport(DERIV_LINEAR_OP));
      outArgs.setSupports(OUT_ARG_DgDx_dotdot_sg, i,
                          DerivativeSupport(DERIV_LINEAR_OP));
    }
    for (int j=0; j<num_param_vecs; j++)
      outArgs.setSupports(OUT_ARG_DgDp_sg, i, j,
                          DerivativeSupport(DERIV_MV_BY_COL));
  }

  // Multi-point
  outArgs.setSupports(OUT_ARG_f_mp,true);
  outArgs.setSupports(OUT_ARG_W_mp,true);
  for (int i=0; i<num_param_vecs; i++)
    outArgs.setSupports(OUT_ARG_DfDp_mp, i, DerivativeSupport(DERIV_MV_BY_COL));
  for (int i=0; i<n_g; i++)
    outArgs.setSupports(OUT_ARG_g_mp, i, true);
  for (int i=0; i<n_g; i++) {
    outArgs.setSupports(OUT_ARG_g_mp, i, true);
    if (app->getResponse(i)->isScalarResponse()) {
      outArgs.setSupports(OUT_ARG_DgDx_mp, i,
                          DerivativeSupport(DERIV_TRANS_MV_BY_ROW));
      outArgs.setSupports(OUT_ARG_DgDx_dot_mp, i,
                          DerivativeSupport(DERIV_TRANS_MV_BY_ROW));
      outArgs.setSupports(OUT_ARG_DgDx_dotdot_mp, i,
                          DerivativeSupport(DERIV_TRANS_MV_BY_ROW));
    }
    else {
      outArgs.setSupports(OUT_ARG_DgDx_mp, i,
                          DerivativeSupport(DERIV_LINEAR_OP));
      outArgs.setSupports(OUT_ARG_DgDx_dot_mp, i,
                          DerivativeSupport(DERIV_LINEAR_OP));
      outArgs.setSupports(OUT_ARG_DgDx_dotdot_mp, i,
                          DerivativeSupport(DERIV_LINEAR_OP));
    }
    for (int j=0; j<num_param_vecs; j++)
      outArgs.setSupports(OUT_ARG_DgDp_mp, i, j,
                          DerivativeSupport(DERIV_MV_BY_COL));
  }
#endif

  return outArgs;
}