Stokhos_KLMatrixFreeOperator.cpp

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#include "Stokhos_KLMatrixFreeOperator.hpp"
#include "EpetraExt_BlockMultiVector.h"
#include "EpetraExt_BlockUtility.h"
 
Stokhos::KLMatrixFreeOperator::
KLMatrixFreeOperator(
  const Teuchos::RCP<const EpetraExt::MultiComm>& sg_comm_,
  const Teuchos::RCP<const Stokhos::OrthogPolyBasis<int,double> >& sg_basis_,
  const Teuchos::RCP<const Stokhos::EpetraSparse3Tensor>& epetraCijk_,
  const Teuchos::RCP<const Epetra_Map>& domain_base_map_,
  const Teuchos::RCP<const Epetra_Map>& range_base_map_,
  const Teuchos::RCP<const Epetra_Map>& domain_sg_map_,
  const Teuchos::RCP<const Epetra_Map>& range_sg_map_,
  const Teuchos::RCP<Teuchos::ParameterList>& params) :
  label("Stokhos KL MatrixFree Operator"),
  sg_comm(sg_comm_),
  sg_basis(sg_basis_),
  epetraCijk(epetraCijk_),
  domain_base_map(domain_base_map_),
  range_base_map(range_base_map_),
  domain_sg_map(domain_sg_map_),
  range_sg_map(range_sg_map_),
  is_stoch_parallel(epetraCijk->isStochasticParallel()),
  global_col_map(),
  global_col_map_trans(),
  stoch_col_map(epetraCijk->getStochasticColMap()),
  col_importer(),
  col_importer_trans(),
  Cijk(epetraCijk->getParallelCijk()),
  block_ops(),
  scale_op(true),
  include_mean(true),
  useTranspose(false),
  expansion_size(sg_basis->size()),
  num_blocks(0),
  input_col(),
  input_col_trans(),
  input_block(),
  result_block(),
  tmp(),
  tmp_trans(),
  k_begin(Cijk->k_begin()),
  k_end(Cijk->k_end())
{
  scale_op = params->get("Scale Operator by Inverse Basis Norms", true);
  include_mean = params->get("Include Mean", true);
 
  // Compute maximum number of mat-vec's needed
  if (!include_mean && index(k_begin) == 0)
    ++k_begin;
  int dim = sg_basis->dimension();
  k_end = Cijk->find_k(dim+1);
  max_num_mat_vec = 0;
  for (Cijk_type::k_iterator k=k_begin; k!=k_end; ++k) {
    int nj = Cijk->num_j(k);
    if (max_num_mat_vec < nj)
      max_num_mat_vec = nj;
  }
 
  // Build up column map of SG operator
  int num_col_blocks = expansion_size;
  int num_row_blocks = expansion_size;
  if (is_stoch_parallel) {
 
    // Build column map from base domain map.  This will communicate
    // stochastic components to column map, but not deterministic.  It would
    // be more efficient to do both, but the Epetra_Operator interface
    // doesn't have the concept of a column map.
    global_col_map =
      Teuchos::rcp(EpetraExt::BlockUtility::GenerateBlockMap(*domain_base_map,
                                                             *stoch_col_map,
                                                             *sg_comm));
    global_col_map_trans =
      Teuchos::rcp(EpetraExt::BlockUtility::GenerateBlockMap(*range_base_map,
                                                             *stoch_col_map,
                                                             *sg_comm));
 
    // Build importer from Domain Map to Column Map
    col_importer =
      Teuchos::rcp(new Epetra_Import(*global_col_map, *domain_sg_map));
    col_importer_trans =
      Teuchos::rcp(new Epetra_Import(*global_col_map_trans, *range_sg_map));
 
    num_col_blocks = epetraCijk->numMyCols();
    num_row_blocks = epetraCijk->numMyRows();
  }
 
  input_block.resize(num_col_blocks);
  result_block.resize(num_row_blocks);
}
 
Stokhos::KLMatrixFreeOperator::~KLMatrixFreeOperator()
{
}
 
void
Stokhos::KLMatrixFreeOperator::
setupOperator(
   const Teuchos::RCP<Stokhos::EpetraOperatorOrthogPoly >& ops)
{
  block_ops = ops;
  num_blocks = sg_basis->dimension() + 1;
}
 
Teuchos::RCP< Stokhos::EpetraOperatorOrthogPoly >
Stokhos::KLMatrixFreeOperator::
getSGPolynomial()
{
  return block_ops;
}
 
Teuchos::RCP<const Stokhos::EpetraOperatorOrthogPoly >
Stokhos::KLMatrixFreeOperator::
getSGPolynomial() const
{
  return block_ops;
}
 
int
Stokhos::KLMatrixFreeOperator::
SetUseTranspose(bool UseTheTranspose)
{
  useTranspose = UseTheTranspose;
  for (int i=0; i<num_blocks; i++)
    (*block_ops)[i].SetUseTranspose(useTranspose);
 
  return 0;
}
 
int
Stokhos::KLMatrixFreeOperator::
Apply(const Epetra_MultiVector& Input, Epetra_MultiVector& Result) const
{
  // We have to be careful if Input and Result are the same vector.
  // If this is the case, the only possible solution is to make a copy
  const Epetra_MultiVector *input = &Input;
  bool made_copy = false;
  if (Input.Values() == Result.Values() && !is_stoch_parallel) {
    input = new Epetra_MultiVector(Input);
    made_copy = true;
  }
 
  // Initialize
  Result.PutScalar(0.0);
 
  const Epetra_Map* input_base_map = domain_base_map.get();
  const Epetra_Map* result_base_map = range_base_map.get();
  if (useTranspose == true) {
    input_base_map = range_base_map.get();
    result_base_map = domain_base_map.get();
  }
 
  // Allocate temporary storage
  int m = Input.NumVectors();
  if (useTranspose == false &&
      (tmp == Teuchos::null || tmp->NumVectors() != m*max_num_mat_vec))
    tmp = Teuchos::rcp(new Epetra_MultiVector(*result_base_map,
                                              m*max_num_mat_vec));
  else if (useTranspose == true &&
           (tmp_trans == Teuchos::null ||
            tmp_trans->NumVectors() != m*max_num_mat_vec))
    tmp_trans = Teuchos::rcp(new Epetra_MultiVector(*result_base_map,
                                                    m*max_num_mat_vec));
  Epetra_MultiVector *tmp_result;
  if (useTranspose == false)
    tmp_result = tmp.get();
  else
    tmp_result = tmp_trans.get();
 
  // Map input into column map
  const Epetra_MultiVector *tmp_col;
  if (!is_stoch_parallel)
    tmp_col = input;
  else {
    if (useTranspose == false) {
      if (input_col == Teuchos::null || input_col->NumVectors() != m)
        input_col = Teuchos::rcp(new Epetra_MultiVector(*global_col_map, m));
      input_col->Import(*input, *col_importer, Insert);
      tmp_col = input_col.get();
    }
    else {
      if (input_col_trans == Teuchos::null ||
          input_col_trans->NumVectors() != m)
        input_col_trans =
          Teuchos::rcp(new Epetra_MultiVector(*global_col_map_trans, m));
      input_col_trans->Import(*input, *col_importer_trans, Insert);
      tmp_col = input_col_trans.get();
    }
  }
 
  // Extract blocks
  EpetraExt::BlockMultiVector sg_input(View, *input_base_map, *tmp_col);
  EpetraExt::BlockMultiVector sg_result(View, *result_base_map, Result);
  for (int i=0; i<input_block.size(); i++)
    input_block[i] = sg_input.GetBlock(i);
  for (int i=0; i<result_block.size(); i++)
    result_block[i] = sg_result.GetBlock(i);
  int N = result_block[0]->MyLength();
 
  const Teuchos::Array<double>& norms = sg_basis->norm_squared();
  int d = sg_basis->dimension();
  Teuchos::Array<double> zero(d), one(d);
  for(int j = 0; j<d; j++) {
    zero[j] = 0.0;
    one[j] = 1.0;
  }
  Teuchos::Array< double > phi_0(expansion_size), phi_1(expansion_size);
  sg_basis->evaluateBases(zero, phi_0);
  sg_basis->evaluateBases(one, phi_1);
 
  // k_begin and k_end are initialized in the constructor
  for (Cijk_type::k_iterator k_it=k_begin; k_it!=k_end; ++k_it) {
    Cijk_type::kj_iterator j_begin = Cijk->j_begin(k_it);
    Cijk_type::kj_iterator j_end = Cijk->j_end(k_it);
    int k = index(k_it);
    int nj = Cijk->num_j(k_it);
    if (nj > 0) {
      Teuchos::Array<double*> j_ptr(nj*m);
      Teuchos::Array<int> mj_indices(nj*m);
      int l = 0;
      for (Cijk_type::kj_iterator j_it = j_begin; j_it != j_end; ++j_it) {
        int j = index(j_it);
        for (int mm=0; mm<m; mm++) {
          j_ptr[l*m+mm] = input_block[j]->Values()+mm*N;
          mj_indices[l*m+mm] = l*m+mm;
        }
        l++;
      }
      Epetra_MultiVector input_tmp(View, *input_base_map, &j_ptr[0], nj*m);
      Epetra_MultiVector result_tmp(View, *tmp_result, &mj_indices[0], nj*m);
      (*block_ops)[k].Apply(input_tmp, result_tmp);
      l = 0;
      for (Cijk_type::kj_iterator j_it = j_begin; j_it != j_end; ++j_it) {
        int j = index(j_it);
        int j_gid = epetraCijk->GCID(j);
        for (Cijk_type::kji_iterator i_it = Cijk->i_begin(j_it);
             i_it != Cijk->i_end(j_it); ++i_it) {
          int i = index(i_it);
          int i_gid = epetraCijk->GRID(i);
          double c = value(i_it);
          if (k == 0)
            c /= phi_0[0];
          else {
            c /= phi_1[k];
            if (i_gid == j_gid)
              c -= phi_0[k]/(phi_1[k]*phi_0[0])*norms[i_gid];
          }
          if (scale_op) {
            if (useTranspose)
              c /= norms[j_gid];
            else
              c /= norms[i_gid];
          }
          for (int mm=0; mm<m; mm++)
            (*result_block[i])(mm)->Update(c, *result_tmp(l*m+mm), 1.0);
        }
        l++;
      }
    }
  }
 
  // Destroy blocks
  for (int i=0; i<input_block.size(); i++)
    input_block[i] = Teuchos::null;
  for (int i=0; i<result_block.size(); i++)
    result_block[i] = Teuchos::null;
 
  if (made_copy)
    delete input;
 
  return 0;
}
 
int
Stokhos::KLMatrixFreeOperator::
ApplyInverse(const Epetra_MultiVector& Input, Epetra_MultiVector& Result) const
{
  throw "KLMatrixFreeOperator::ApplyInverse not defined!";
  return -1;
}
 
double
Stokhos::KLMatrixFreeOperator::
NormInf() const
{
  return 1.0;
}
 
 
const char*
Stokhos::KLMatrixFreeOperator::
Label () const
{
  return const_cast<char*>(label.c_str());
}
 
bool
Stokhos::KLMatrixFreeOperator::
UseTranspose() const
{
  return useTranspose;
}
 
bool
Stokhos::KLMatrixFreeOperator::
HasNormInf() const
{
  return false;
}
 
const Epetra_Comm &
Stokhos::KLMatrixFreeOperator::
Comm() const
{
  return *sg_comm;
}
const Epetra_Map&
Stokhos::KLMatrixFreeOperator::
OperatorDomainMap() const
{
  if (useTranspose)
    return *range_sg_map;
  return *domain_sg_map;
}
 
const Epetra_Map&
Stokhos::KLMatrixFreeOperator::
OperatorRangeMap() const
{
  if (useTranspose)
    return *domain_sg_map;
  return *range_sg_map;
}