tempest/resources/3rdparty/eigen/Eigen/src/SparseLU/SparseLU_column_bmod.h


								// This file is part of Eigen, a lightweight C++ template library

								// for linear algebra.

								//

								// Copyright (C) 2012 Désiré Nuentsa-Wakam <desire.nuentsa_wakam@inria.fr>

								// Copyright (C) 2012 Gael Guennebaud <gael.guennebaud@inria.fr>

								//

								// This Source Code Form is subject to the terms of the Mozilla

								// Public License v. 2.0. If a copy of the MPL was not distributed

								// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.


								/*


								 * NOTE: This file is the modified version of xcolumn_bmod.c file in SuperLU


								 * -- SuperLU routine (version 3.0) --

								 * Univ. of California Berkeley, Xerox Palo Alto Research Center,

								 * and Lawrence Berkeley National Lab.

								 * October 15, 2003

								 *

								 * Copyright (c) 1994 by Xerox Corporation.  All rights reserved.

								 *

								 * THIS MATERIAL IS PROVIDED AS IS, WITH ABSOLUTELY NO WARRANTY

								 * EXPRESSED OR IMPLIED.  ANY USE IS AT YOUR OWN RISK.

								 *

								 * Permission is hereby granted to use or copy this program for any

								 * purpose, provided the above notices are retained on all copies.

								 * Permission to modify the code and to distribute modified code is

								 * granted, provided the above notices are retained, and a notice that

								 * the code was modified is included with the above copyright notice.

								 */

								#ifndef SPARSELU_COLUMN_BMOD_H

								#define SPARSELU_COLUMN_BMOD_H


								namespace Eigen {


								namespace internal {

								/**

								 * \brief Performs numeric block updates (sup-col) in topological order

								 *

								 * \param jcol current column to update

								 * \param nseg Number of segments in the U part

								 * \param dense Store the full representation of the column

								 * \param tempv working array

								 * \param segrep segment representative ...

								 * \param repfnz ??? First nonzero column in each row ???  ...

								 * \param fpanelc First column in the current panel

								 * \param glu Global LU data.

								 * \return 0 - successful return

								 *         > 0 - number of bytes allocated when run out of space

								 *

								 */

								template <typename Scalar, typename Index>

								Index SparseLUImpl<Scalar,Index>::column_bmod(const Index jcol, const Index nseg, BlockScalarVector dense, ScalarVector& tempv, BlockIndexVector segrep, BlockIndexVector repfnz, Index fpanelc, GlobalLU_t& glu)

								{

								  Index  jsupno, k, ksub, krep, ksupno;

								  Index lptr, nrow, isub, irow, nextlu, new_next, ufirst;

								  Index fsupc, nsupc, nsupr, luptr, kfnz, no_zeros;

								  /* krep = representative of current k-th supernode

								    * fsupc =  first supernodal column

								    * nsupc = number of columns in a supernode

								    * nsupr = number of rows in a supernode

								    * luptr = location of supernodal LU-block in storage

								    * kfnz = first nonz in the k-th supernodal segment

								    * no_zeros = no lf leading zeros in a supernodal U-segment

								    */


								  jsupno = glu.supno(jcol);

								  // For each nonzero supernode segment of U[*,j] in topological order

								  k = nseg - 1;

								  Index d_fsupc; // distance between the first column of the current panel and the

								               // first column of the current snode

								  Index fst_col; // First column within small LU update

								  Index segsize;

								  for (ksub = 0; ksub < nseg; ksub++)

								  {

								    krep = segrep(k); k--;

								    ksupno = glu.supno(krep);

								    if (jsupno != ksupno )

								    {

								      // outside the rectangular supernode

								      fsupc = glu.xsup(ksupno);

								      fst_col = (std::max)(fsupc, fpanelc);


								      // Distance from the current supernode to the current panel;

								      // d_fsupc = 0 if fsupc > fpanelc

								      d_fsupc = fst_col - fsupc;


								      luptr = glu.xlusup(fst_col) + d_fsupc;

								      lptr = glu.xlsub(fsupc) + d_fsupc;


								      kfnz = repfnz(krep);

								      kfnz = (std::max)(kfnz, fpanelc);


								      segsize = krep - kfnz + 1;

								      nsupc = krep - fst_col + 1;

								      nsupr = glu.xlsub(fsupc+1) - glu.xlsub(fsupc);

								      nrow = nsupr - d_fsupc - nsupc;

								      Index lda = glu.xlusup(fst_col+1) - glu.xlusup(fst_col);


								      // Perform a triangular solver and block update,

								      // then scatter the result of sup-col update to dense

								      no_zeros = kfnz - fst_col;

								      if(segsize==1)

								        LU_kernel_bmod<1>::run(segsize, dense, tempv, glu.lusup, luptr, lda, nrow, glu.lsub, lptr, no_zeros);

								      else

								        LU_kernel_bmod<Dynamic>::run(segsize, dense, tempv, glu.lusup, luptr, lda, nrow, glu.lsub, lptr, no_zeros);

								    } // end if jsupno

								  } // end for each segment


								  // Process the supernodal portion of  L\U[*,j]

								  nextlu = glu.xlusup(jcol);

								  fsupc = glu.xsup(jsupno);


								  // copy the SPA dense into L\U[*,j]

								  Index mem;

								  new_next = nextlu + glu.xlsub(fsupc + 1) - glu.xlsub(fsupc);

								  Index offset = internal::first_multiple<Index>(new_next, internal::packet_traits<Scalar>::size) - new_next;

								  if(offset)

								    new_next += offset;

								  while (new_next > glu.nzlumax )

								  {

								    mem = memXpand<ScalarVector>(glu.lusup, glu.nzlumax, nextlu, LUSUP, glu.num_expansions);

								    if (mem) return mem;

								  }


								  for (isub = glu.xlsub(fsupc); isub < glu.xlsub(fsupc+1); isub++)

								  {

								    irow = glu.lsub(isub);

								    glu.lusup(nextlu) = dense(irow);

								    dense(irow) = Scalar(0.0);

								    ++nextlu;

								  }


								  if(offset)

								  {

								    glu.lusup.segment(nextlu,offset).setZero();

								    nextlu += offset;

								  }

								  glu.xlusup(jcol + 1) = nextlu;  // close L\U(*,jcol);


								  /* For more updates within the panel (also within the current supernode),

								   * should start from the first column of the panel, or the first column

								   * of the supernode, whichever is bigger. There are two cases:

								   *  1) fsupc < fpanelc, then fst_col <-- fpanelc

								   *  2) fsupc >= fpanelc, then fst_col <-- fsupc

								   */

								  fst_col = (std::max)(fsupc, fpanelc);


								  if (fst_col  < jcol)

								  {

								    // Distance between the current supernode and the current panel

								    // d_fsupc = 0 if fsupc >= fpanelc

								    d_fsupc = fst_col - fsupc;


								    lptr = glu.xlsub(fsupc) + d_fsupc;

								    luptr = glu.xlusup(fst_col) + d_fsupc;

								    nsupr = glu.xlsub(fsupc+1) - glu.xlsub(fsupc); // leading dimension

								    nsupc = jcol - fst_col; // excluding jcol

								    nrow = nsupr - d_fsupc - nsupc;


								    // points to the beginning of jcol in snode L\U(jsupno)

								    ufirst = glu.xlusup(jcol) + d_fsupc;

								    Index lda = glu.xlusup(jcol+1) - glu.xlusup(jcol);

								    Map<Matrix<Scalar,Dynamic,Dynamic>, 0,  OuterStride<> > A( &(glu.lusup.data()[luptr]), nsupc, nsupc, OuterStride<>(lda) );

								    VectorBlock<ScalarVector> u(glu.lusup, ufirst, nsupc);

								    u = A.template triangularView<UnitLower>().solve(u);


								    new (&A) Map<Matrix<Scalar,Dynamic,Dynamic>, 0, OuterStride<> > ( &(glu.lusup.data()[luptr+nsupc]), nrow, nsupc, OuterStride<>(lda) );

								    VectorBlock<ScalarVector> l(glu.lusup, ufirst+nsupc, nrow);

								    l.noalias() -= A * u;


								  } // End if fst_col

								  return 0;

								}


								} // end namespace internal

								} // end namespace Eigen


								#endif // SPARSELU_COLUMN_BMOD_H