fastamgsmoother.hh

// SPDX-FileCopyrightText: Copyright (C) DUNE Project contributors, see file LICENSE.md in module root
// SPDX-License-Identifier: LicenseRef-GPL-2.0-only-with-DUNE-exception
// -*- tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*-
// vi: set et ts=4 sw=2 sts=2:
#ifndef DUNE_ISTL_FASTAMGSMOOTHER_HH
#define DUNE_ISTL_FASTAMGSMOOTHER_HH
 
#include <cstddef>
 
namespace Dune
{
  namespace Amg
  {
 
    template<std::size_t level>
    struct GaussSeidelPresmoothDefect {
 
      template<typename M, typename X, typename Y>
      static void apply(const M& A, X& x, Y& d,
                        const Y& b)
      {
        typedef typename M::ConstRowIterator RowIterator;
        typedef typename M::ConstColIterator ColIterator;
 
        typename Y::iterator dIter=d.begin();
        typename Y::const_iterator bIter=b.begin();
        typename X::iterator xIter=x.begin();
 
        for(RowIterator row=A.begin(), end=A.end(); row != end;
            ++row, ++dIter, ++xIter, ++bIter)
        {
          ColIterator col=(*row).begin();
          *dIter = *bIter;
 
          for (; col.index()<row.index(); ++col)
            (*col).mmv(x[col.index()],*dIter);     // rhs -= sum_{j<i} a_ij * xnew_j
          assert(row.index()==col.index());
          ColIterator diag=col;              // upper diagonal matrix not needed as x was 0 before.
 
          // Not recursive yet. Just solve with the diagonal
          diag->solve(*xIter,*dIter);
          *dIter=0;   //as r=v
 
          // Update residual for the symmetric case
          for(col=(*row).begin(); col.index()<row.index(); ++col)
            col->mmv(*xIter, d[col.index()]);     //d_j-=A_ij x_i
        }
      }
    };
 
    template<std::size_t level>
    struct GaussSeidelPostsmoothDefect {
 
      template<typename M, typename X, typename Y>
      static void apply(const M& A, X& x, Y& d,
                        const Y& b)
      {
        typedef typename M::ConstRowIterator RowIterator;
        typedef typename M::ConstColIterator ColIterator;
        typedef typename Y::block_type YBlock;
 
        typename Y::iterator dIter=d.beforeEnd();
        typename X::iterator xIter=x.beforeEnd();
        typename Y::const_iterator bIter=b.beforeEnd();
 
        for(RowIterator row=A.beforeEnd(), end=A.beforeBegin(); row != end;
            --row, --dIter, --xIter, --bIter)
        {
          ColIterator endCol=(*row).beforeBegin();
          ColIterator col=(*row).beforeEnd();
          *dIter = *bIter;
 
          for (; col.index()>row.index(); --col)
            (*col).mmv(x[col.index()],*dIter);     // rhs -= sum_{i>j} a_ij * xnew_j
          assert(row.index()==col.index());
          ColIterator diag=col;
          YBlock v=*dIter;
          // upper diagonal matrix
          for (--col; col!=endCol; --col)
            (*col).mmv(x[col.index()],v);     // v -= sum_{j<i} a_ij * xold_j
 
          // Not recursive yet. Just solve with the diagonal
          diag->solve(*xIter,v);
 
          *dIter-=v;
 
          // Update residual for the symmetric case
          // Skip residual computation as it is not needed.
          //for(col=(*row).begin();col.index()<row.index(); ++col)
          //col.mmv(*xIter, d[col.index()]); //d_j-=A_ij x_i
        }
      }
    };
  } // end namespace Amg
} // end namespace Dune
#endif