// 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 sp_coletree.c file in SuperLU * -- SuperLU routine (version 3.1) -- * Univ. of California Berkeley, Xerox Palo Alto Research Center, * and Lawrence Berkeley National Lab. * August 1, 2008 * * 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 SPARSE_COLETREE_H #define SPARSE_COLETREE_H // IWYU pragma: private #include "./InternalHeaderCheck.h" namespace Eigen { namespace internal { /** Find the root of the tree/set containing the vertex i : Use Path halving */ template Index etree_find(Index i, IndexVector& pp) { Index p = pp(i); // Parent Index gp = pp(p); // Grand parent while (gp != p) { pp(i) = gp; // Parent pointer on find path is changed to former grand parent i = gp; p = pp(i); gp = pp(p); } return p; } /** Compute the column elimination tree of a sparse matrix * \param mat The matrix in column-major format. * \param parent The elimination tree * \param firstRowElt The column index of the first element in each row * \param perm The permutation to apply to the column of \b mat */ template int coletree(const MatrixType& mat, IndexVector& parent, IndexVector& firstRowElt, typename MatrixType::StorageIndex* perm = 0) { typedef typename MatrixType::StorageIndex StorageIndex; StorageIndex nc = convert_index(mat.cols()); // Number of columns StorageIndex m = convert_index(mat.rows()); StorageIndex diagSize = (std::min)(nc, m); IndexVector root(nc); // root of subtree of etree root.setZero(); IndexVector pp(nc); // disjoint sets pp.setZero(); // Initialize disjoint sets parent.resize(mat.cols()); // Compute first nonzero column in each row firstRowElt.resize(m); firstRowElt.setConstant(nc); firstRowElt.segment(0, diagSize).setLinSpaced(diagSize, 0, diagSize - 1); bool found_diag; for (StorageIndex col = 0; col < nc; col++) { StorageIndex pcol = col; if (perm) pcol = perm[col]; for (typename MatrixType::InnerIterator it(mat, pcol); it; ++it) { Index row = it.row(); firstRowElt(row) = (std::min)(firstRowElt(row), col); } } /* Compute etree by Liu's algorithm for symmetric matrices, except use (firstRowElt[r],c) in place of an edge (r,c) of A. Thus each row clique in A'*A is replaced by a star centered at its first vertex, which has the same fill. */ StorageIndex rset, cset, rroot; for (StorageIndex col = 0; col < nc; col++) { found_diag = col >= m; pp(col) = col; cset = col; root(cset) = col; parent(col) = nc; /* The diagonal element is treated here even if it does not exist in the matrix * hence the loop is executed once more */ StorageIndex pcol = col; if (perm) pcol = perm[col]; for (typename MatrixType::InnerIterator it(mat, pcol); it || !found_diag; ++it) { // A sequence of interleaved find and union is performed Index i = col; if (it) i = it.index(); if (i == col) found_diag = true; StorageIndex row = firstRowElt(i); if (row >= col) continue; rset = internal::etree_find(row, pp); // Find the name of the set containing row rroot = root(rset); if (rroot != col) { parent(rroot) = col; pp(cset) = rset; cset = rset; root(cset) = col; } } } return 0; } /** * Depth-first search from vertex n. No recursion. * This routine was contributed by Cédric Doucet, CEDRAT Group, Meylan, France. */ template void nr_etdfs(typename IndexVector::Scalar n, IndexVector& parent, IndexVector& first_kid, IndexVector& next_kid, IndexVector& post, typename IndexVector::Scalar postnum) { typedef typename IndexVector::Scalar StorageIndex; StorageIndex current = n, first, next; while (postnum != n) { // No kid for the current node first = first_kid(current); // no kid for the current node if (first == -1) { // Numbering this node because it has no kid post(current) = postnum++; // looking for the next kid next = next_kid(current); while (next == -1) { // No more kids : back to the parent node current = parent(current); // numbering the parent node post(current) = postnum++; // Get the next kid next = next_kid(current); } // stopping criterion if (postnum == n + 1) return; // Updating current node current = next; } else { current = first; } } } /** * \brief Post order a tree * \param n the number of nodes * \param parent Input tree * \param post postordered tree */ template void treePostorder(typename IndexVector::Scalar n, IndexVector& parent, IndexVector& post) { typedef typename IndexVector::Scalar StorageIndex; IndexVector first_kid, next_kid; // Linked list of children StorageIndex postnum; // Allocate storage for working arrays and results first_kid.resize(n + 1); next_kid.setZero(n + 1); post.setZero(n + 1); // Set up structure describing children first_kid.setConstant(-1); for (StorageIndex v = n - 1; v >= 0; v--) { StorageIndex dad = parent(v); next_kid(v) = first_kid(dad); first_kid(dad) = v; } // Depth-first search from dummy root vertex #n postnum = 0; internal::nr_etdfs(n, parent, first_kid, next_kid, post, postnum); } } // end namespace internal } // end namespace Eigen #endif // SPARSE_COLETREE_H