void
LOCA::AnasaziOperator::Cayley2Matrix::apply(const NOX::Abstract::MultiVector& input,
                     NOX::Abstract::MultiVector& output) const
{
  std::string callingFunction =
    "LOCA::AnasaziOperator::Cayley2Matrix::apply()";

  NOX::Abstract::Group::ReturnType finalStatus = NOX::Abstract::Group::Ok;
  NOX::Abstract::Group::ReturnType status;

  // Allocate temporary vector
  if (tmp_r == Teuchos::null || tmp_r->numVectors() != input.numVectors())
    tmp_r = input.clone(NOX::ShapeCopy);

  // Compute J-mu*M -- moved to preProcessSeedVector

  // Compute (J-mu*M)*input
  status = grp->applySecondShiftedMatrixMultiVector(input, *tmp_r);
  finalStatus =
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status,
                               finalStatus,
                               callingFunction);

  // Compute J-sigma*M -- moved to preProcessSeedVector

  // Solve (J-sigma*M)*output = (J-mu*M)*input
  status = grp->applyShiftedMatrixInverseMultiVector(*solverParams, *tmp_r,
                             output);

  finalStatus =
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status,
                               finalStatus,
                               callingFunction);
}
LOCA::MultiContinuation::ExtendedMultiVector::ExtendedMultiVector(
		    const Teuchos::RCP<LOCA::GlobalData>& global_data,
		    const NOX::Abstract::MultiVector& xVec, 
		    int nScalarRows) :
  LOCA::Extended::MultiVector(global_data, xVec.numVectors(), 1, nScalarRows)
{
  LOCA::Extended::MultiVector::setMultiVectorPtr(0, xVec.clone(NOX::DeepCopy));
}
void
LOCA::Epetra::AnasaziOperator::Floquet::apply(const NOX::Abstract::MultiVector& input, 
				     NOX::Abstract::MultiVector& output) const
{

  // Apply first part of monodromy operator on input vector
  Teuchos::RCP<NOX::Abstract::MultiVector> tmpVec =  input.clone();
  for (int i=0; i < input.numVectors(); i++) {
    NOX::Abstract::Vector& nAV = tmpVec->operator[](i);
    NOX::Epetra::Vector& nEV = dynamic_cast<NOX::Epetra::Vector&>(nAV);
    Epetra_Vector& eV = nEV.getEpetraVector();

    xyztInterface->beginFloquetOperatorApplication(eV);
  }
    
  // Now apply the main part of the monodromy matrix
  NOX::Abstract::Group::ReturnType status =
    grp->applyJacobianInverseMultiVector(*solverParams, *(tmpVec.get()), output);
  globalData->locaErrorCheck->checkReturnType(status,
                       "LOCA::Epetra::AnasaziOperator::Floquet::apply()");


  for (int i=0; i < input.numVectors(); i++) {
    NOX::Abstract::Vector& nAV = output.operator[](i);
    NOX::Epetra::Vector& nEV = dynamic_cast<NOX::Epetra::Vector&>(nAV);
    Epetra_Vector& eV = nEV.getEpetraVector();

    xyztInterface->finishFloquetOperatorApplication(eV);
  }

// Was this needed?

// TESTING:  Doubling the call to this routine resulted in the
//  squaring of the Floquet multipliers, as they should.
//  Replacing the apply function so the operator is diagonal
//  with entries 1/(i+2) led to the Floquet multipliers.

/*
  std::cout << " Fixing apply so Floquets at 1/2 1/3 1/4 ... " << std::endl;

  Teuchos::RCP<NOX::Abstract::MultiVector> tmpVec =  input.clone();
  for (int i=0; i < input.numVectors(); i++) {
    NOX::Abstract::Vector& nAV = output.operator[](i);
    NOX::Epetra::Vector& nEV = dynamic_cast<NOX::Epetra::Vector&>(nAV);
    Epetra_Vector& oV = nEV.getEpetraVector();

    NOX::Abstract::Vector& nAV2 = tmpVec->operator[](i);
    NOX::Epetra::Vector& nEV2 = dynamic_cast<NOX::Epetra::Vector&>(nAV2);
    Epetra_Vector& iV = nEV2.getEpetraVector();

    for (int j=0; j < iV.MyLength(); j++) {
     oV[j] = iV[j] / (j + 2.0);
    }
  }
*/
}
LOCA::MultiContinuation::ExtendedMultiVector::ExtendedMultiVector(
		     const Teuchos::RCP<LOCA::GlobalData>& global_data,
		     const NOX::Abstract::MultiVector& xVec,
		     const NOX::Abstract::MultiVector::DenseMatrix& params) :
  LOCA::Extended::MultiVector(global_data, xVec.numVectors(), 1, 
			      params.numRows())
{
  LOCA::Extended::MultiVector::setMultiVectorPtr(0, xVec.clone(NOX::DeepCopy));
  LOCA::Extended::MultiVector::getScalars()->assign(params);
}
Exemple #5
0
NOX::Abstract::Group::ReturnType 
LOCA::BorderedSolver::Nested::applyInverseTranspose(
			      Teuchos::ParameterList& params,
			      const NOX::Abstract::MultiVector* F,
			      const NOX::Abstract::MultiVector::DenseMatrix* G,
			      NOX::Abstract::MultiVector& X,
			      NOX::Abstract::MultiVector::DenseMatrix& Y) const
{
  bool isZeroF = (F == NULL);
  bool isZeroG = (G == NULL);

  if (isZeroF && isZeroG) {
    X.init(0.0);
    Y.putScalar(0.0);
  }

  int num_cols = X.numVectors();  
  Teuchos::RCP<NOX::Abstract::MultiVector> FF;
  if (!isZeroF) 
    FF = unbordered_grp->getX().createMultiVector(num_cols);
  NOX::Abstract::MultiVector::DenseMatrix GG(myWidth, num_cols);  
  GG.putScalar(0.0);
  
  if (!isZeroF) {
    NOX::Abstract::MultiVector::DenseMatrix GG1(Teuchos::View, GG,
						underlyingWidth, num_cols, 
						0, 0);
    grp->extractSolutionComponent(*F, *FF);
    grp->extractParameterComponent(false, *F, GG1);
  }
  if (!isZeroG) {
    NOX::Abstract::MultiVector::DenseMatrix GG2(Teuchos::View, GG,
						numConstraints, num_cols, 
						underlyingWidth, 0);
    GG2.assign(*G);
  }

  Teuchos::RCP<NOX::Abstract::MultiVector> XX = 
    unbordered_grp->getX().createMultiVector(num_cols);
  NOX::Abstract::MultiVector::DenseMatrix YY(myWidth, num_cols);
  NOX::Abstract::MultiVector::DenseMatrix YY1(Teuchos::View, YY,
					      underlyingWidth, num_cols, 
					      0, 0);
  NOX::Abstract::MultiVector::DenseMatrix YY2(Teuchos::View, YY,
					      numConstraints, num_cols, 
					      underlyingWidth, 0);

  NOX::Abstract::Group::ReturnType status = 
    solver->applyInverseTranspose(params, FF.get(), &GG, *XX, YY);

  Y.assign(YY2);
  grp->loadNestedComponents(*XX, YY1, X);

  return status;
}
void
LOCA::MultiContinuation::ConstrainedGroup::fillB(
	                                  NOX::Abstract::MultiVector& B) const
{
  std::string callingFunction = 
    "LOCA::MultiContinuation::ConstrainedGroup::fillB";

  bool isZeroB = constraintsPtr->isDXZero();
  Teuchos::RCP<const NOX::Abstract::MultiVector> my_B;

  if (!isZeroB) {
    Teuchos::RCP<const LOCA::MultiContinuation::ConstraintInterfaceMVDX> constraints_mvdx = Teuchos::rcp_dynamic_cast<const LOCA::MultiContinuation::ConstraintInterfaceMVDX>(constraintsPtr);
    if (constraints_mvdx == Teuchos::null)
      globalData->locaErrorCheck->throwError(
				callingFunction,
				std::string("Constraints object must be of type") +
				std::string("ConstraintInterfaceMVDX"));

    my_B = Teuchos::rcp(constraints_mvdx->getDX(),false);
  }

  // If the underlying system isn't bordered, we're done
  if (!isBordered) {
    if (isZeroB)
      B.init(0.0);
    else
      B = *my_B;
    return;
  }

  // Create views for underlying group
  int w = bordered_grp->getBorderedWidth();
  std::vector<int> idx1(w);
  for (int i=0; i<w; i++)
    idx1[i] = i;
  Teuchos::RCP<NOX::Abstract::MultiVector> underlyingB = 
    B.subView(idx1);

  // Combine blocks in underlying group
  bordered_grp->fillB(*underlyingB);

  // Create views for my blocks
  std::vector<int> idx2(numParams);
  for (int i=0; i<numParams; i++)
    idx2[i] = w+i;
  Teuchos::RCP<NOX::Abstract::MultiVector> my_B_x = 
    B.subView(idx2);

  // Extract solution component from my_B and store in B
  if (isZeroB)
    my_B_x->init(0.0);
  else
    bordered_grp->extractSolutionComponent(*my_B, *my_B_x);
}
Exemple #7
0
NOX::Abstract::Group::ReturnType 
LOCA::Epetra::ModelEvaluatorInterface::
computeDfDp(LOCA::MultiContinuation::AbstractGroup& grp, 
	    const vector<int>& param_ids,
	    NOX::Abstract::MultiVector& result,
	    bool isValidF) const
{
  // Break result into f and df/dp
  NOX::Epetra::Vector& f = dynamic_cast<NOX::Epetra::Vector&>(result[0]);
  Epetra_Vector& epetra_f = f.getEpetraVector();

  std::vector<int> dfdp_index(result.numVectors()-1);
  for (unsigned int i=0; i<dfdp_index.size(); i++)
    dfdp_index[i] = i+1;
  Teuchos::RefCountPtr<NOX::Epetra::MultiVector> dfdp =
    Teuchos::rcp_dynamic_cast<NOX::Epetra::MultiVector>(result.subView(dfdp_index));
  Epetra_MultiVector& epetra_dfdp = dfdp->getEpetraMultiVector();

  // Create inargs
  EpetraExt::ModelEvaluator::InArgs inargs = model_->createInArgs();
  const NOX::Epetra::Vector& x = 
    dynamic_cast<const NOX::Epetra::Vector&>(grp.getX());
  const Epetra_Vector& epetra_x = x.getEpetraVector();
  inargs.set_x(Teuchos::rcp(&epetra_x, false));
  inargs.set_p(0, Teuchos::rcp(&param_vec, false));
  if (inargs.supports(EpetraExt::ModelEvaluator::IN_ARG_x_dot)) {
    // Create x_dot, filled with zeros
    if (x_dot == NULL)
      x_dot = new Epetra_Vector(epetra_x.Map());
    inargs.set_x_dot(Teuchos::rcp(x_dot, false));
  }

  // Create outargs
  EpetraExt::ModelEvaluator::OutArgs outargs = model_->createOutArgs();
  if (!isValidF) {
    EpetraExt::ModelEvaluator::Evaluation<Epetra_Vector> eval_f;
    Teuchos::RefCountPtr<Epetra_Vector> F = Teuchos::rcp(&epetra_f, false);
    eval_f.reset(F, EpetraExt::ModelEvaluator::EVAL_TYPE_EXACT); 
    outargs.set_f(eval_f);
  }
  Teuchos::RefCountPtr<Epetra_MultiVector> DfDp = 
    Teuchos::rcp(&epetra_dfdp, false);
  Teuchos::Array<int> param_indexes(param_ids.size());
  for (unsigned int i=0; i<param_ids.size(); i++)
    param_indexes[i] = param_ids[i];
  EpetraExt::ModelEvaluator::DerivativeMultiVector dmv(DfDp, EpetraExt::ModelEvaluator::DERIV_MV_BY_COL,
						       param_indexes);
  EpetraExt::ModelEvaluator::Derivative deriv(dmv);
  outargs.set_DfDp(0, deriv);

  model_->evalModel(inargs, outargs);

  return NOX::Abstract::Group::Ok;
}
NOX::Abstract::Group::ReturnType
LOCA::Epetra::Group::applyComplexMultiVector(
				const NOX::Abstract::MultiVector& input_real,
				const NOX::Abstract::MultiVector& input_imag,
				NOX::Abstract::MultiVector& result_real,
				NOX::Abstract::MultiVector& result_imag) const
{
  std::string callingFunction = 
    "LOCA::Epetra::Group::applyComplexMultiVector()";
  // We must have the time-dependent interface
  if (userInterfaceTime == Teuchos::null)
    return NOX::Abstract::Group::BadDependency;

#ifdef HAVE_NOX_EPETRAEXT
  const NOX::Epetra::MultiVector& epetra_input_real =
    dynamic_cast<const NOX::Epetra::MultiVector&>(input_real);
  const NOX::Epetra::MultiVector& epetra_input_imag =
    dynamic_cast<const NOX::Epetra::MultiVector&>(input_imag);
  NOX::Epetra::MultiVector& epetra_result_real =
    dynamic_cast<NOX::Epetra::MultiVector&>(result_real);
  NOX::Epetra::MultiVector& epetra_result_imag =
    dynamic_cast<NOX::Epetra::MultiVector&>(result_imag);

  // Get Jacobian matrix for row map
  Teuchos::RCP<Epetra_RowMatrix> jac = Teuchos::rcp_dynamic_cast<Epetra_RowMatrix>(sharedLinearSystem.getObject(this)->getJacobianOperator());

  EpetraExt::BlockMultiVector complex_input(jac->RowMatrixRowMap(),
					    complexMatrix->RowMap(),
					    input_real.numVectors());
  complex_input.LoadBlockValues(epetra_input_real.getEpetraMultiVector(), 0);
  complex_input.LoadBlockValues(epetra_input_imag.getEpetraMultiVector(), 1);

  EpetraExt::BlockMultiVector complex_result(jac->RowMatrixRowMap(),
					     complexMatrix->RowMap(),
					     input_real.numVectors());
  complex_result.PutScalar(0.0);

  complexMatrix->Apply(complex_input, complex_result);

  complex_result.ExtractBlockValues(epetra_result_real.getEpetraMultiVector(), 
				    0);
  complex_result.ExtractBlockValues(epetra_result_imag.getEpetraMultiVector(), 
				    1);

  return NOX::Abstract::Group::Ok;
#else

  globalData->locaErrorCheck->throwError(callingFunction, 
					 "Must have EpetraExt support for Hopf tracking.  Configure trilinos with --enable-epetraext");
  return NOX::Abstract::Group::BadDependency;

#endif
}
Exemple #9
0
LOCA::TurningPoint::MooreSpence::ExtendedMultiVector::ExtendedMultiVector(
		  const Teuchos::RCP<LOCA::GlobalData>& global_data,
		  const NOX::Abstract::MultiVector& xVec,
		  const NOX::Abstract::MultiVector& nullVec,
		  const NOX::Abstract::MultiVector::DenseMatrix& bifParams) :
  LOCA::Extended::MultiVector(global_data, xVec.numVectors(), 2, 1)
{
  LOCA::Extended::MultiVector::setMultiVectorPtr(0, xVec.clone(NOX::DeepCopy));
  LOCA::Extended::MultiVector::setMultiVectorPtr(1, 
						 nullVec.clone(NOX::DeepCopy));
  LOCA::Extended::MultiVector::getScalars()->assign(bifParams);
}
Exemple #10
0
NOX::Abstract::Group::ReturnType 
LOCA::DerivUtils::computeDwtJnDx(LOCA::MultiContinuation::AbstractGroup& grp,
				 const NOX::Abstract::MultiVector& w,
				 const NOX::Abstract::Vector& nullVector,
				 NOX::Abstract::MultiVector& result) const
{
  string callingFunction = 
    "LOCA::DerivUtils::computeDwtJnDx()";
  NOX::Abstract::Group::ReturnType status, finalStatus;

  // Vector to store w^T*J
  Teuchos::RCP<NOX::Abstract::MultiVector> wtJ = 
    w.clone(NOX::ShapeCopy);
  
  // Compute base w^T*J
  finalStatus = grp.computeJacobian();
  globalData->locaErrorCheck->checkReturnType(finalStatus, callingFunction);

  status = grp.applyJacobianTransposeMultiVector(w, *wtJ);
  finalStatus = 
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status, finalStatus,
							   callingFunction);
  
  // Copy original solution vector
  Teuchos::RCP<NOX::Abstract::Vector> Xvec = 
    grp.getX().clone(NOX::DeepCopy);

  // Perturb solution vector in direction of nullVector, return perturbation
  double eps = perturbXVec(grp, *Xvec, nullVector);

  // Fill perturbed w^T*J vector
  finalStatus = grp.computeJacobian();
  globalData->locaErrorCheck->checkReturnType(finalStatus, callingFunction);
    
  status = grp.applyJacobianTransposeMultiVector(w, result);
  finalStatus = 
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status, 
							   finalStatus,
							   callingFunction);

  // Difference perturbed and base vector 
  result.update(-1.0, *wtJ, 1.0);
  result.scale(1.0/eps);
  
  // Restore original solution vector
  grp.setX(*Xvec);

  return finalStatus;
}
LOCA::Hopf::MooreSpence::ExtendedMultiVector::ExtendedMultiVector(
		  const Teuchos::RCP<LOCA::GlobalData>& global_data,
		  const NOX::Abstract::MultiVector& xVec,
		  const NOX::Abstract::MultiVector& realEigenVec,
		  const NOX::Abstract::MultiVector& imagEigenVec,
		  const NOX::Abstract::MultiVector::DenseMatrix& freqs,
		  const NOX::Abstract::MultiVector::DenseMatrix& bifParams) :
  LOCA::Extended::MultiVector(global_data, xVec.numVectors(), 3, 2)
{
  LOCA::Extended::MultiVector::setMultiVectorPtr(0, xVec.clone(NOX::DeepCopy));
  LOCA::Extended::MultiVector::setMultiVectorPtr(1, realEigenVec.clone(NOX::DeepCopy));
  LOCA::Extended::MultiVector::setMultiVectorPtr(2, imagEigenVec.clone(NOX::DeepCopy));
  LOCA::Extended::MultiVector::getScalarRows(1,0)->assign(freqs);
  LOCA::Extended::MultiVector::getScalarRows(1,1)->assign(bifParams);
}
Exemple #12
0
LOCA::Pitchfork::MooreSpence::ExtendedMultiVector::ExtendedMultiVector(
		  const Teuchos::RCP<LOCA::GlobalData>& global_data,
		  const NOX::Abstract::MultiVector& xVec,
		  const NOX::Abstract::MultiVector& nullVec,
		  const NOX::Abstract::MultiVector::DenseMatrix& slacks,
		  const NOX::Abstract::MultiVector::DenseMatrix& bifParams) :
  LOCA::Extended::MultiVector(global_data, xVec.numVectors(), 2, 2)
{
  LOCA::Extended::MultiVector::setMultiVectorPtr(0, xVec.clone(NOX::DeepCopy));
  LOCA::Extended::MultiVector::setMultiVectorPtr(1, 
						 nullVec.clone(NOX::DeepCopy));

  LOCA::Extended::MultiVector::getScalarRows(1,0)->assign(slacks);
  LOCA::Extended::MultiVector::getScalarRows(1,1)->assign(bifParams);
}
NOX::Abstract::Group::ReturnType
LOCA::LAPACK::Group::applyShiftedMatrixInverseMultiVector(
			             Teuchos::ParameterList& params, 
				     const NOX::Abstract::MultiVector& input,
				     NOX::Abstract::MultiVector& result) const
{
  // Number of RHS
  int nVecs = input.numVectors();

  int m = shiftedSolver.getMatrix().numRows();

  // Copy all input vectors into one matrix
  NOX::LAPACK::Matrix<double> B(m,nVecs);
  const NOX::LAPACK::Vector* constVecPtr;
  for (int j=0; j<nVecs; j++) {
    constVecPtr = dynamic_cast<const NOX::LAPACK::Vector*>(&(input[j]));
    for (int i=0; i<m; i++)
      B(i,j) = (*constVecPtr)(i);
  }

  bool res = shiftedSolver.solve(false, nVecs, &B(0,0));

  if (!res)
    return NOX::Abstract::Group::Failed;

  // Copy result from matrix
  NOX::LAPACK::Vector* vecPtr;
  for (int j=0; j<nVecs; j++) {
    vecPtr = dynamic_cast<NOX::LAPACK::Vector*>(&(result[j]));
    for (int i=0; i<m; i++)
      (*vecPtr)(i) = B(i,j);
  }
    
  return NOX::Abstract::Group::Ok;
}
NOX::Abstract::Group::ReturnType
LOCA::LAPACK::Group::applyShiftedMatrixMultiVector(
				   const NOX::Abstract::MultiVector& input,
				   NOX::Abstract::MultiVector& result) const
{
  // Number of RHS
  int nVecs = input.numVectors();

  int m = shiftedSolver.getMatrix().numRows();

  // Copy all input vectors into one matrix
  NOX::LAPACK::Matrix<double> B(m,nVecs);
  NOX::LAPACK::Matrix<double> C(m,nVecs);
  const NOX::LAPACK::Vector* constVecPtr;
  for (int j=0; j<nVecs; j++) {
    constVecPtr = dynamic_cast<const NOX::LAPACK::Vector*>(&(input[j]));
    for (int i=0; i<m; i++)
      B(i,j) = (*constVecPtr)(i);
  }

  // Apply shifted matrix
  shiftedSolver.apply(false, nVecs, &B(0,0), &C(0,0));

  // Copy result from matrix
  NOX::LAPACK::Vector* vecPtr;
  for (int j=0; j<nVecs; j++) {
    vecPtr = dynamic_cast<NOX::LAPACK::Vector*>(&(result[j]));
    for (int i=0; i<m; i++)
      (*vecPtr)(i) = C(i,j);
  }
    
  return NOX::Abstract::Group::Ok;
}
void
LOCA::TurningPoint::MooreSpence::ExtendedGroup::lTransNorm(
			const NOX::Abstract::MultiVector& n,
			NOX::Abstract::MultiVector::DenseMatrix& result) const
{
  n.multiply(1.0 / lengthVec->length(), *lengthMultiVec, result);
}
void
LOCA::AnasaziOperator::Cayley2Matrix::preProcessSeedVector(NOX::Abstract::MultiVector& ivec)
{
  // Changes random seed vector ivec:   ivec = (J - sigma*M)^{-1}*M*ivec
  std::string callingFunction =
    "LOCA::AnasaziOperator::Cayley2Matrix::preProcessSeedVector()";

  NOX::Abstract::Group::ReturnType finalStatus = NOX::Abstract::Group::Ok;
  NOX::Abstract::Group::ReturnType status;

  // Allocate temporary vector
  if (tmp_r == Teuchos::null || tmp_r->numVectors() != ivec.numVectors())
    tmp_r = ivec.clone(NOX::ShapeCopy);

  // Compute M
  status = grp->computeShiftedMatrix(0.0, 1.0);
  finalStatus =
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status,
                               finalStatus,
                               callingFunction);

  // Compute M*ivec
  status = grp->applyShiftedMatrixMultiVector(ivec, *tmp_r);
  finalStatus =
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status,
                               finalStatus,
                               callingFunction);

  // Compute J-sigma*M
  status = grp->computeShiftedMatrix(1.0, -sigma);
  finalStatus =
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status,
                               finalStatus,
                               callingFunction);

  // Solve (J-sigma*M)*output = (M)*ivec
  status = grp->applyShiftedMatrixInverseMultiVector(*solverParams, *tmp_r,
                             ivec);

  finalStatus =
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status,
                               finalStatus,
                               callingFunction);

  // Compute J-mu*M
  status = grp->computeSecondShiftedMatrix(1.0, -mu);
}
NOX::Abstract::Group::ReturnType
LOCA::MultiContinuation::ConstraintInterfaceMVDX::addDX(
                      Teuchos::ETransp transb,
                  double alpha,
                      const NOX::Abstract::MultiVector::DenseMatrix& b,
                  double beta,
                  NOX::Abstract::MultiVector& result_x) const
{
  if (!isDXZero()) {
    const NOX::Abstract::MultiVector* dgdx = getDX();
    result_x.update(transb, alpha, *dgdx, b, beta);
  }
  else
    result_x.scale(beta);

  return NOX::Abstract::Group::Ok;
}
NOX::Abstract::Group::ReturnType
LOCA::LAPACK::Group::applyComplexTransposeInverseMultiVector(
				Teuchos::ParameterList& params,
				const NOX::Abstract::MultiVector& input_real,
				const NOX::Abstract::MultiVector& input_imag,
				NOX::Abstract::MultiVector& result_real,
				NOX::Abstract::MultiVector& result_imag) const
{
#ifdef HAVE_TEUCHOS_COMPLEX
   // Check validity of the Jacobian
  if (!isComplex()) 
    return NOX::Abstract::Group::BadDependency;

  int n = complexSolver.getMatrix().numRows();
  int p = input_real.numVectors();

  // Copy inputs into a complex vector
  std::vector< std::complex<double> > input(n*p);
  const NOX::LAPACK::Vector* lapack_input_real;
  const NOX::LAPACK::Vector* lapack_input_imag;
  for (int j=0; j<p; j++) {
    lapack_input_real = 
      dynamic_cast<const NOX::LAPACK::Vector*>(&(input_real[j]));
    lapack_input_imag = 
      dynamic_cast<const NOX::LAPACK::Vector*>(&(input_imag[j]));
    for (int i=0; i<n; i++)
      input[i+n*j] = std::complex<double>((*lapack_input_real)(i),
					  (*lapack_input_imag)(i));
  }

  // Solve complex matrix
  bool res = complexSolver.solve(true, p, &input[0]);

  // Copy result into NOX vectors
  NOX::LAPACK::Vector* lapack_result_real;
  NOX::LAPACK::Vector* lapack_result_imag;
  for (int j=0; j<p; j++) {
    lapack_result_real = 
      dynamic_cast<NOX::LAPACK::Vector*>(&(result_real[j]));
    lapack_result_imag = 
      dynamic_cast<NOX::LAPACK::Vector*>(&(result_imag[j]));
    for (int i=0; i<n; i++) {
      (*lapack_result_real)(i) = input[i+n*j].real();
      (*lapack_result_imag)(i) = input[i+n*j].imag();
    }
  }

  if (res)
    return NOX::Abstract::Group::Ok;
  else
    return NOX::Abstract::Group::Failed;
#else
  globalData->locaErrorCheck->throwError(
    "LOCA::LAPACK::Group::applyComplexTransposeInverseMultiVector()",
    "TEUCHOS_COMPLEX must be enabled for complex support!  Reconfigure with -D Teuchos_ENABLE_COMPLEX");
  return NOX::Abstract::Group::BadDependency;
#endif
}
void
LOCA::AnasaziOperator::ShiftInvert::apply(
				     const NOX::Abstract::MultiVector& input, 
				     NOX::Abstract::MultiVector& output) const
{
  std::string callingFunction = 
    "LOCA::AnasaziOperator::ShiftInvert::apply()";

  NOX::Abstract::Group::ReturnType finalStatus = NOX::Abstract::Group::Ok;
  NOX::Abstract::Group::ReturnType status;

  // Allocate temporary vector
  if (tmp_r == Teuchos::null || tmp_r->numVectors() != input.numVectors())
    tmp_r = input.clone(NOX::ShapeCopy);

  // Compute M
  status = grp->computeShiftedMatrix(0.0, 1.0);
  finalStatus = 
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status, 
							   finalStatus,
							   callingFunction);

  // Compute M*input
  status = grp->applyShiftedMatrixMultiVector(input, *tmp_r);
  finalStatus = 
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status, 
							   finalStatus,
							   callingFunction);

  // Compute J-omega*M
  status = grp->computeShiftedMatrix(1.0, -shift);
  finalStatus = 
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status, 
							   finalStatus,
							   callingFunction);

  // Solve (J-omega*M)*output = M*input
  status = grp->applyShiftedMatrixInverseMultiVector(*solverParams, *tmp_r, 
						     output);
  finalStatus = 
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status, 
							   finalStatus,
							   callingFunction);
}
NOX::Abstract::Group::ReturnType
LOCA::Epetra::Group::applyShiftedMatrixInverseMultiVector(
			        Teuchos::ParameterList& lsParams, 
				const NOX::Abstract::MultiVector& input,
				NOX::Abstract::MultiVector& result) const
{

  if (shiftedSharedLinearSystem != Teuchos::null) {

    NOX::Epetra::LinearSystem::PreconditionerReusePolicyType precPolicy = 
      sharedLinearSystem.getObject(this)->getPreconditionerPolicy();

    if (!isValidShiftedPrec) {

      if (precPolicy == NOX::Epetra::LinearSystem::PRPT_REBUILD) {
	shiftedSharedLinearSystem->getObject(this)->destroyPreconditioner();
	shiftedSharedLinearSystem->getObject(this)->
	  createPreconditioner(xVector, lsParams, false);
	isValidShiftedPrec = true;
      }
      else if (precPolicy == NOX::Epetra::LinearSystem::PRPT_RECOMPUTE) {
	sharedLinearSystem.getObject(this)->recomputePreconditioner(xVector, 
								    lsParams);
      }
      else if (precPolicy == NOX::Epetra::LinearSystem::PRPT_REUSE) {
	// Do Nothing!!!
      }

    }


    const NOX::Epetra::Vector* epetra_input;
    NOX::Epetra::Vector* epetra_result; 
    bool status;
    bool finalStatus = true;
    for (int i=0; i<input.numVectors(); i++) {
      epetra_input = dynamic_cast<const NOX::Epetra::Vector*>(&input[i]);
      epetra_result = dynamic_cast<NOX::Epetra::Vector*>(&result[i]);

      status = 
	shiftedSharedLinearSystem->getObject(this)->applyJacobianInverse(
							      lsParams, 
							      *epetra_input, 
							      *epetra_result);
      finalStatus = finalStatus && status;
    }
    
    if (finalStatus)
      return NOX::Abstract::Group::Ok;
    else
      return NOX::Abstract::Group::NotConverged;
  }

  else 
    return NOX::Abstract::Group::BadDependency;
}
NOX::Abstract::Group::ReturnType 
LOCA::Epetra::Group::applyJacobianTransposeInverseMultiVector(
				    Teuchos::ParameterList& params, 
				    const NOX::Abstract::MultiVector& input, 
				    NOX::Abstract::MultiVector& result) const
{
  std::string callingFunction = 
    "LOCA::Epetra::Group::applyJacobianTransposeInverseMultiVector()";
  NOX::Abstract::Group::ReturnType status;
  NOX::Abstract::Group::ReturnType finalStatus = NOX::Abstract::Group::Ok;

  // Get non-const linsys
  Teuchos::RCP<NOX::Epetra::LinearSystem> linSys = 
    sharedLinearSystem.getObject(this);

  // Get Jacobian operator
  Teuchos::RCP<Epetra_Operator> jac =
    linSys->getJacobianOperator();

  // Instantiate transpose solver
  LOCA::Epetra::TransposeLinearSystem::Factory tls_factory(globalData);
  if (tls_strategy == Teuchos::null)
    tls_strategy = tls_factory.create(Teuchos::rcp(&params, false), linSys);
     
  // Compute Jacobian transpose J^T
  tls_strategy->createJacobianTranspose();

  // Now compute preconditioner for J^T
  tls_strategy->createTransposePreconditioner(xVector, params);

  // Solve for each RHS
  int m = input.numVectors();
  for (int i=0; i<m; i++) {
    bool stat = 
      tls_strategy->applyJacobianTransposeInverse(
			  params, 
			  dynamic_cast<const NOX::Epetra::Vector&>(input[i]),
			  dynamic_cast<NOX::Epetra::Vector&>(result[i]));
    if (stat == true)
      status = NOX::Abstract::Group::Ok;
    else
      status = NOX::Abstract::Group::NotConverged;
    finalStatus = 
      globalData->locaErrorCheck->combineAndCheckReturnTypes(status, 
							     finalStatus,
							     callingFunction);
  }

  // Set original operators in linear system
  jac->SetUseTranspose(false);
  linSys->setJacobianOperatorForSolve(jac);
  linSys->destroyPreconditioner();

  return finalStatus;
}
Exemple #22
0
NOX::Abstract::Group::ReturnType 
LOCA::DerivUtils::computeDCeDxa(
			    LOCA::Hopf::MooreSpence::AbstractGroup& grp,
			    const NOX::Abstract::Vector& yVector,
			    const NOX::Abstract::Vector& zVector,
			    double w,
			    const NOX::Abstract::MultiVector& aVector,
			    const NOX::Abstract::Vector& Ce_real,
			    const NOX::Abstract::Vector& Ce_imag,
			    NOX::Abstract::MultiVector& result_real,
			    NOX::Abstract::MultiVector& result_imag) const
{
  string callingFunction = 
    "LOCA::DerivUtils::computeDCeDxa()";
  NOX::Abstract::Group::ReturnType status, finalStatus = 
    NOX::Abstract::Group::Ok;

  // Copy original solution vector
  Teuchos::RCP<NOX::Abstract::Vector> Xvec = 
    grp.getX().clone(NOX::DeepCopy);

  // Loop over each column of multivector
  for (int i=0; i<aVector.numVectors(); i++) {

    // Perturb solution vector in direction of aVector, return perturbation
    double eps = perturbXVec(grp, *Xvec, aVector[i]);

    // Compute perturbed Ce vectors
    status = grp.computeComplex(w);
    finalStatus = 
      globalData->locaErrorCheck->combineAndCheckReturnTypes(status, 
							     finalStatus,
							     callingFunction);

    status = 
      grp.applyComplex(yVector, zVector, result_real[i], result_imag[i]);
    finalStatus = 
      globalData->locaErrorCheck->combineAndCheckReturnTypes(status, 
							     finalStatus,
							     callingFunction);

    // Difference perturbed and base vector and return approximate derivative
    result_real[i].update(-1.0, Ce_real, 1.0); result_real[i].scale(1.0/eps);
    result_imag[i].update(-1.0, Ce_imag, 1.0); result_imag[i].scale(1.0/eps);

  }

  // Restore original solution vector
  grp.setX(*Xvec);

  return finalStatus;
}
// =============================================================================
// Compute result_p = alpha * dg/dx * input_x.
NOX::Abstract::Group::ReturnType
Ginla::FDM::Constraint::MinDist::
multiplyDX ( double                                    alpha,
             const NOX::Abstract::MultiVector        & input_x,
             NOX::Abstract::MultiVector::DenseMatrix & result_p
           ) const
{ 
  TEUCHOS_ASSERT( komplex_.is_valid_ptr() && !komplex_.is_null() );
  
  TEUCHOS_ASSERT_EQUALITY( result_p.numCols(), input_x.numVectors() );
  
  for ( int k=0; k<input_x.numVectors(); k++ )
  {
      const Epetra_Vector & xE =
              Teuchos::dyn_cast<const NOX::Epetra::Vector>( input_x[0] ).getEpetraVector();
      Teuchos::RCP<ComplexVector> xPsi = komplex_->real2complex( xE );

      result_p(0,k) = alpha * std::imag( psiRef_->dot(*xPsi) );
  }
  
  return NOX::Abstract::Group::Ok;
}
void
LOCA::BorderedSolver::HouseholderQR::applyHouseholderVector(
               const NOX::Abstract::MultiVector::DenseMatrix& V1,
               const NOX::Abstract::MultiVector& V2,
               double beta,
               NOX::Abstract::MultiVector::DenseMatrix& A1,
               NOX::Abstract::MultiVector& A2)
{
  int nColsA = A2.numVectors();

  // Compute u = V2^T * A2
  NOX::Abstract::MultiVector::DenseMatrix u(1, nColsA);
  A2.multiply(1.0, V2, u);

  // Compute u = u + V1^T * A_P
  u.multiply(Teuchos::TRANS, Teuchos::NO_TRANS, 1.0, V1, A1, 1.0);

  // Compute A1 = A1 - b*V1*u
  A1.multiply(Teuchos::NO_TRANS, Teuchos::NO_TRANS, -beta, V1, u, 1.0);

  // Compute A2 = A2 - b*V2*u
  A2.update(Teuchos::NO_TRANS, -beta, V2, u, 1.0);
}
Exemple #25
0
NOX::Abstract::Group::ReturnType
LOCA::Homotopy::DeflatedGroup::
applyJacobianTransposeMultiVector(const NOX::Abstract::MultiVector& input,
				  NOX::Abstract::MultiVector& result) const 
{
  string callingFunction = 
    "LOCA::Homotopy::DeflatedGroup::applyJacobianTransposeMultiVector()";
  
  if (!isJacobian()) {
    globalData->locaErrorCheck->throwError(callingFunction,
					    "Called with invalid Jacobian!");
  }

  // Cast inputs to continuation multivectors
  const LOCA::MultiContinuation::ExtendedMultiVector& c_input = 
    dynamic_cast<const LOCA::MultiContinuation::ExtendedMultiVector&>(input);
  LOCA::MultiContinuation::ExtendedMultiVector& c_result = 
    dynamic_cast<LOCA::MultiContinuation::ExtendedMultiVector&>(result);

  // Get x, param componenets of input vector
  Teuchos::RCP<const NOX::Abstract::MultiVector> input_x = 
    c_input.getXMultiVec();
  Teuchos::RCP<const NOX::Abstract::MultiVector::DenseMatrix> input_param = c_input.getScalars();

  // Get references to x, param components of result vector
  Teuchos::RCP<NOX::Abstract::MultiVector> result_x = 
    c_result.getXMultiVec();
  Teuchos::RCP<NOX::Abstract::MultiVector::DenseMatrix> result_param = 
    c_result.getScalars();

  NOX::Abstract::Group::ReturnType status = 
    grpPtr->applyJacobianTransposeMultiVector(*input_x, *result_x);

  // If the Jacobian is not augmented for homotopy (i.e. using MFNK)
  // then lets augment it here.
  if (augmentJacForHomotopyNotImplemented)
    result_x->update(1.0-conParam, *input_x, conParam/distProd);

  // Add deflated terms
  if (numSolns > 0) {
    NOX::Abstract::MultiVector::DenseMatrix tmp(1, input.numVectors());
    input_x->multiply(1.0, *underlyingF, tmp);
    result_x->update(Teuchos::NO_TRANS, 1.0, *totalDistMultiVec, tmp, 1.0);
  }

  // Zero out parameter component
  result_param->putScalar(0.0);

  return status;
}
Exemple #26
0
void
LOCA::Homotopy::DeflatedGroup::
fillA(NOX::Abstract::MultiVector& A) const
{
  string callingFunction = 
    "LOCA::Homotopy::DeflatedGroup::fillA";

  Teuchos::RCP<const NOX::Abstract::MultiVector> my_A = 
    underlyingF;

  // If the underlying system isn't bordered, we're done
  if (!isBordered) {
    A = *my_A;
    return;
  }

  // Create views for underlying group
  int w = bordered_grp->getBorderedWidth();
  std::vector<int> idx1(w);
  for (int i=0; i<w; i++)
    idx1[i] = i;
  Teuchos::RCP<NOX::Abstract::MultiVector> underlyingA = 
    A.subView(idx1);

  // Fill A block in underlying group
  bordered_grp->fillA(*underlyingA);

  // Create views for my blocks
  std::vector<int> idx2(1);
  for (int i=0; i<1; i++)
    idx2[i] = w+i;
  Teuchos::RCP<NOX::Abstract::MultiVector> my_A_x = 
    A.subView(idx2);

  // Extract solution component from my_A and store in A
  bordered_grp->extractSolutionComponent(*my_A, *my_A_x);
}
Exemple #27
0
void
LOCA::Homotopy::DeflatedGroup::
fillB(NOX::Abstract::MultiVector& B) const
{
  string callingFunction = 
    "LOCA::Homotopy::DeflatedGroup::fillB";

  Teuchos::RCP<const NOX::Abstract::MultiVector> my_B =
    totalDistMultiVec;

  // If the underlying system isn't bordered, we're done
  if (!isBordered) {
    B = *my_B;
    return;
  }

  // Create views for underlying group
  int w = bordered_grp->getBorderedWidth();
  std::vector<int> idx1(w);
  for (int i=0; i<w; i++)
    idx1[i] = i;
  Teuchos::RCP<NOX::Abstract::MultiVector> underlyingB = 
    B.subView(idx1);

  // Combine blocks in underlying group
  bordered_grp->fillB(*underlyingB);

  // Create views for my blocks
  std::vector<int> idx2(2);
  for (int i=0; i<1; i++)
    idx2[i] = w+i;
  Teuchos::RCP<NOX::Abstract::MultiVector> my_B_x = 
    B.subView(idx2);

  // Extract solution component from my_B and store in B
  bordered_grp->extractSolutionComponent(*my_B, *my_B_x);
}
Exemple #28
0
NOX::Abstract::Group::ReturnType
LOCA::Pitchfork::MooreSpence::ExtendedGroup::computeDfDpMulti(
					    const vector<int>& paramIDs, 
					    NOX::Abstract::MultiVector& dfdp, 
					    bool isValid_F)
{
   string callingFunction = 
    "LOCA::Pitchfork::MooreSpence::ExtendedGroup::computeDfDpMulti()";
  NOX::Abstract::Group::ReturnType finalStatus = NOX::Abstract::Group::Ok;
  NOX::Abstract::Group::ReturnType status;

  // Cast dfdp to pitchfork vector
  LOCA::Pitchfork::MooreSpence::ExtendedMultiVector& pf_dfdp = 
    dynamic_cast<LOCA::Pitchfork::MooreSpence::ExtendedMultiVector&>(dfdp);

  // Compute df/dp
  // Note:  the first column of fMultiVec stores f + sigma*psi, not f,
  // so we always need to recompute f.  This changes the first column
  // of fMultiVec back to f
  status = grpPtr->computeDfDpMulti(paramIDs, *pf_dfdp.getXMultiVec(),
				    false);
  finalStatus = 
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status, finalStatus,
							   callingFunction);

  // Change the first column back to f + sigma*psi
  double sigma = xVec->getSlack();
  pf_dfdp.getColumn(0)->getXVec()->update(sigma, *asymVec, 1.0);

  // Compute d(Jn)/dp
  status = grpPtr->computeDJnDpMulti(paramIDs, *(xVec->getNullVec()),
				     *pf_dfdp.getNullMultiVec(), isValid_F);
  finalStatus = 
    globalData->locaErrorCheck->combineAndCheckReturnTypes(status, finalStatus,
							   callingFunction);

  // Set parameter components
  if (!isValid_F) {
    pf_dfdp.getScalar(0,0) = grpPtr->innerProduct(*(xVec->getXVec()), 
						  *asymVec);
    pf_dfdp.getScalar(1,0) = lTransNorm(*(xVec->getNullVec()));
  }
  for (int i=0; i<dfdp.numVectors()-1; i++) {
    pf_dfdp.getScalar(0,i+1) = 0.0;
    pf_dfdp.getScalar(1,i+1) = 0.0;
  }

  return finalStatus;
}
void
LOCA::BorderedSolver::HouseholderQR::applyCompactWY(
                const NOX::Abstract::MultiVector::DenseMatrix& Y1,
                const NOX::Abstract::MultiVector& Y2,
                const NOX::Abstract::MultiVector::DenseMatrix& T,
                NOX::Abstract::MultiVector::DenseMatrix& X1,
                NOX::Abstract::MultiVector& X2,
                bool isZeroX1, bool isZeroX2,
                bool useTranspose) const
{
  if (isZeroX1 && isZeroX2) {
    X1.putScalar(0.0);
    X2.init(0.0);
    return;
  }

  int m = Y2.numVectors();

  Teuchos::ETransp T_flag;
  if (useTranspose)
    T_flag = Teuchos::TRANS;
  else
    T_flag = Teuchos::NO_TRANS;

  NOX::Abstract::MultiVector::DenseMatrix tmp(m, X2.numVectors());

  // Compute Y1^T*X1 + Y2^T*X2
  if (!isZeroX2)
    X2.multiply(1.0, Y2, tmp);

  // Opportunity for optimization here since Y1 is a lower-triangular
  // matrix with unit diagonal
  if (!isZeroX2 && !isZeroX1)
    tmp.multiply(Teuchos::TRANS, Teuchos::NO_TRANS, 1.0, Y1, X1, 1.0);
  else if (!isZeroX1)
    tmp.multiply(Teuchos::TRANS, Teuchos::NO_TRANS, 1.0, Y1, X1, 0.0);

  // Compute op(T)*(Y1^T*X1 + Y2^T*X2)
  dblas.TRMM(Teuchos::LEFT_SIDE, Teuchos::UPPER_TRI, T_flag,
         Teuchos::NON_UNIT_DIAG, tmp.numRows(), tmp.numCols(), 1.0,
         T.values(), T.numRows(), tmp.values(), tmp.numRows());

  // Compute X1 = X1 + Y1*op(T)*(Y1^T*X1 + Y2^T*X2)
  // Opportunity for optimization here since Y1 is a lower-triangular
  // matrix with unit diagonal
  if (isZeroX1)
    X1.multiply(Teuchos::NO_TRANS, Teuchos::NO_TRANS, 1.0, Y1, tmp, 0.0);
  else
    X1.multiply(Teuchos::NO_TRANS, Teuchos::NO_TRANS, 1.0, Y1, tmp, 1.0);

  // Compute X2 = X2 + Y1*op(T)*(Y1^T*X1 + Y2^T*X2)
  if (isZeroX2)
    X2.update(Teuchos::NO_TRANS, 1.0, Y2, tmp, 0.0);
  else
    X2.update(Teuchos::NO_TRANS, 1.0, Y2, tmp, 1.0);
}
Exemple #30
0
NOX::Abstract::Group::ReturnType
LOCA::Homotopy::Group::computeDfDpMulti(const vector<int>& paramIDs, 
					NOX::Abstract::MultiVector& dfdp, 
					bool isValidF)
{
  // g = conParam * f(x) + ((1.0 - conParam) * (x - randomVec))
  // dg/dp = f(x) - (x - randomVec) when p = conParam
  // dg/dp = conParam * df/dp when p != conParam

  // For simplicity, we always recompute g, even if isValidF is true
  // Things get kind of messy otherwise

  // Extract parameter IDs that are not the continuation parameter
  vector<int> pIDs;
  vector<int> idx(1);
  idx[0] = 0; // index 0 corrsponds to f in dfdp
  for (unsigned int i=0; i<paramIDs.size(); i++)
    if (paramIDs[i] != conParamID) {
      pIDs.push_back(paramIDs[i]);
      idx.push_back(i+1);
    }

  // Create view of dfdp for parameters that aren't the continuation parameter
  Teuchos::RCP<NOX::Abstract::MultiVector> fp = 
    dfdp.subView(idx);

  // Compute df/dp for non-continuation parameter parameters
  // We force recomputation of f for simplicity
  NOX::Abstract::Group::ReturnType status = 
    grpPtr->computeDfDpMulti(pIDs, *fp, false);

  // Compute conParam * df/dp
  fp->scale(conParam);

  // Compute g
  double v = 1.0-conParam;
  dfdp[0].update(v, grpPtr->getX(), -v, *randomVecPtr, 1.0);

  // Compute dg/dp for p = conParam
  grpPtr->computeF();
  for (unsigned int i=0; i<paramIDs.size(); i++)
    if (paramIDs[i] == conParamID) {
      dfdp[i+1] = grpPtr->getF();
      dfdp[i+1].update(-1.0, grpPtr->getX(), 1.0, *randomVecPtr, 1.0);
    }

  return status;
}