// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2012 Désiré Nuentsa-Wakam // // 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 [s,d,c,z]column_dfs.c file in SuperLU * -- SuperLU routine (version 2.0) -- * Univ. of California Berkeley, Xerox Palo Alto Research Center, * and Lawrence Berkeley National Lab. * November 15, 1997 * * 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_DFS_H #define SPARSELU_COLUMN_DFS_H template class SparseLUImpl; namespace Eigen { namespace internal { template struct column_dfs_traits : no_assignment_operator { typedef typename ScalarVector::Scalar Scalar; typedef typename IndexVector::Scalar StorageIndex; column_dfs_traits(Index jcol, Index& jsuper, typename SparseLUImpl::GlobalLU_t& glu, SparseLUImpl& luImpl) : m_jcol(jcol), m_jsuper_ref(jsuper), m_glu(glu), m_luImpl(luImpl) {} bool update_segrep(Index /*krep*/, Index /*jj*/) { return true; } void mem_expand(IndexVector& lsub, Index& nextl, Index chmark) { if (nextl >= m_glu.nzlmax) m_luImpl.memXpand(lsub, m_glu.nzlmax, nextl, LSUB, m_glu.num_expansions); if (chmark != (m_jcol-1)) m_jsuper_ref = emptyIdxLU; } enum { ExpandMem = true }; Index m_jcol; Index& m_jsuper_ref; typename SparseLUImpl::GlobalLU_t& m_glu; SparseLUImpl& m_luImpl; }; /** * \brief Performs a symbolic factorization on column jcol and decide the supernode boundary * * A supernode representative is the last column of a supernode. * The nonzeros in U[*,j] are segments that end at supernodes representatives. * The routine returns a list of the supernodal representatives * in topological order of the dfs that generates them. * The location of the first nonzero in each supernodal segment * (supernodal entry location) is also returned. * * \param m number of rows in the matrix * \param jcol Current column * \param perm_r Row permutation * \param maxsuper Maximum number of column allowed in a supernode * \param [in,out] nseg Number of segments in current U[*,j] - new segments appended * \param lsub_col defines the rhs vector to start the dfs * \param [in,out] segrep Segment representatives - new segments appended * \param repfnz First nonzero location in each row * \param xprune * \param marker marker[i] == jj, if i was visited during dfs of current column jj; * \param parent * \param xplore working array * \param glu global LU data * \return 0 success * > 0 number of bytes allocated when run out of space * */ template Index SparseLUImpl::column_dfs(const Index m, const Index jcol, IndexVector& perm_r, Index maxsuper, Index& nseg, BlockIndexVector lsub_col, IndexVector& segrep, BlockIndexVector repfnz, IndexVector& xprune, IndexVector& marker, IndexVector& parent, IndexVector& xplore, GlobalLU_t& glu) { Index jsuper = glu.supno(jcol); Index nextl = glu.xlsub(jcol); VectorBlock marker2(marker, 2*m, m); column_dfs_traits traits(jcol, jsuper, glu, *this); // For each nonzero in A(*,jcol) do dfs for (Index k = 0; ((k < m) ? lsub_col[k] != emptyIdxLU : false) ; k++) { Index krow = lsub_col(k); lsub_col(k) = emptyIdxLU; Index kmark = marker2(krow); // krow was visited before, go to the next nonz; if (kmark == jcol) continue; dfs_kernel(StorageIndex(jcol), perm_r, nseg, glu.lsub, segrep, repfnz, xprune, marker2, parent, xplore, glu, nextl, krow, traits); } // for each nonzero ... Index fsupc; StorageIndex nsuper = glu.supno(jcol); StorageIndex jcolp1 = StorageIndex(jcol) + 1; Index jcolm1 = jcol - 1; // check to see if j belongs in the same supernode as j-1 if ( jcol == 0 ) { // Do nothing for column 0 nsuper = glu.supno(0) = 0 ; } else { fsupc = glu.xsup(nsuper); StorageIndex jptr = glu.xlsub(jcol); // Not yet compressed StorageIndex jm1ptr = glu.xlsub(jcolm1); // Use supernodes of type T2 : see SuperLU paper if ( (nextl-jptr != jptr-jm1ptr-1) ) jsuper = emptyIdxLU; // Make sure the number of columns in a supernode doesn't // exceed threshold if ( (jcol - fsupc) >= maxsuper) jsuper = emptyIdxLU; /* If jcol starts a new supernode, reclaim storage space in * glu.lsub from previous supernode. Note we only store * the subscript set of the first and last columns of * a supernode. (first for num values, last for pruning) */ if (jsuper == emptyIdxLU) { // starts a new supernode if ( (fsupc < jcolm1-1) ) { // >= 3 columns in nsuper StorageIndex ito = glu.xlsub(fsupc+1); glu.xlsub(jcolm1) = ito; StorageIndex istop = ito + jptr - jm1ptr; xprune(jcolm1) = istop; // initialize xprune(jcol-1) glu.xlsub(jcol) = istop; for (StorageIndex ifrom = jm1ptr; ifrom < nextl; ++ifrom, ++ito) glu.lsub(ito) = glu.lsub(ifrom); nextl = ito; // = istop + length(jcol) } nsuper++; glu.supno(jcol) = nsuper; } // if a new supernode } // end else: jcol > 0 // Tidy up the pointers before exit glu.xsup(nsuper+1) = jcolp1; glu.supno(jcolp1) = nsuper; xprune(jcol) = StorageIndex(nextl); // Initialize upper bound for pruning glu.xlsub(jcolp1) = StorageIndex(nextl); return 0; } } // end namespace internal } // end namespace Eigen #endif