From f9047c3f8c72f1a15a4c051b507306d308f44646 Mon Sep 17 00:00:00 2001 From: Brecht Van Lommel Date: Tue, 24 Nov 2015 20:42:10 +0100 Subject: Eigen: fold remaining OpenNL code into intern/eigen. Differential Revision: https://developer.blender.org/D1662 --- CMakeLists.txt | 4 - SConstruct | 1 - .../cmake/cmake_static_check_clang_array.py | 1 - build_files/cmake/cmake_static_check_cppcheck.py | 1 - build_files/cmake/cmake_static_check_smatch.py | 1 - build_files/cmake/cmake_static_check_sparse.py | 1 - build_files/cmake/cmake_static_check_splint.py | 1 - build_files/cmake/config/blender_full.cmake | 1 - build_files/cmake/config/blender_lite.cmake | 1 - build_files/cmake/macros.cmake | 5 - doc/doxygen/doxygen.intern.h | 2 +- extern/CMakeLists.txt | 4 - extern/SConscript | 1 - extern/colamd/CMakeLists.txt | 41 - extern/colamd/Doc/ChangeLog | 129 - extern/colamd/Doc/lesser.txt | 504 --- extern/colamd/Include/UFconfig.h | 118 - extern/colamd/Include/colamd.h | 255 -- extern/colamd/README.txt | 127 - extern/colamd/SConscript | 14 - extern/colamd/Source/colamd.c | 3611 -------------------- extern/colamd/Source/colamd_global.c | 24 - intern/CMakeLists.txt | 4 - intern/SConscript | 1 - intern/eigen/CMakeLists.txt | 2 + intern/eigen/eigen_capi.h | 1 + intern/eigen/intern/eigenvalues.cc | 2 +- intern/eigen/intern/eigenvalues.h | 2 +- intern/eigen/intern/linear_solver.cc | 354 ++ intern/eigen/intern/linear_solver.h | 71 + intern/eigen/intern/svd.cc | 2 +- intern/eigen/intern/svd.h | 2 +- intern/opennl/CMakeLists.txt | 58 - intern/opennl/SConscript | 35 - intern/opennl/extern/ONL_opennl.h | 113 - intern/opennl/intern/opennl.cpp | 492 --- source/blender/blenkernel/intern/softbody.c | 9 +- source/blender/blenlib/intern/math_solvers.c | 4 +- source/blender/bmesh/CMakeLists.txt | 8 +- source/blender/bmesh/SConscript | 2 +- .../blender/bmesh/operators/bmo_smooth_laplacian.c | 95 +- source/blender/editors/armature/CMakeLists.txt | 8 +- source/blender/editors/armature/SConscript | 2 +- .../blender/editors/armature/armature_skinning.c | 10 +- source/blender/editors/armature/meshlaplacian.c | 110 +- source/blender/editors/armature/reeb.c | 46 +- source/blender/editors/uvedit/CMakeLists.txt | 8 +- source/blender/editors/uvedit/SConscript | 2 +- .../blender/editors/uvedit/uvedit_parametrizer.c | 167 +- source/blender/modifiers/CMakeLists.txt | 8 +- source/blender/modifiers/SConscript | 2 +- .../blender/modifiers/intern/MOD_laplaciandeform.c | 153 +- .../blender/modifiers/intern/MOD_laplaciansmooth.c | 84 +- source/blender/modifiers/intern/MOD_util.c | 21 - source/blender/modifiers/intern/MOD_util.h | 17 - source/blenderplayer/CMakeLists.txt | 3 - 56 files changed, 681 insertions(+), 6064 deletions(-) delete mode 100644 extern/colamd/CMakeLists.txt delete mode 100644 extern/colamd/Doc/ChangeLog delete mode 100644 extern/colamd/Doc/lesser.txt delete mode 100644 extern/colamd/Include/UFconfig.h delete mode 100644 extern/colamd/Include/colamd.h delete mode 100644 extern/colamd/README.txt delete mode 100644 extern/colamd/SConscript delete mode 100644 extern/colamd/Source/colamd.c delete mode 100644 extern/colamd/Source/colamd_global.c create mode 100644 intern/eigen/intern/linear_solver.cc create mode 100644 intern/eigen/intern/linear_solver.h delete mode 100644 intern/opennl/CMakeLists.txt delete mode 100644 intern/opennl/SConscript delete mode 100644 intern/opennl/extern/ONL_opennl.h delete mode 100644 intern/opennl/intern/opennl.cpp diff --git a/CMakeLists.txt b/CMakeLists.txt index 26e0a3f1379..1cf5d1c4620 100644 --- a/CMakeLists.txt +++ b/CMakeLists.txt @@ -362,7 +362,6 @@ if(WIN32) endif() option(WITH_INPUT_NDOF "Enable NDOF input devices (SpaceNavigator and friends)" ${_init_INPUT_NDOF}) option(WITH_RAYOPTIMIZATION "Enable use of SIMD (SSE) optimizations for the raytracer" ON) -option(WITH_OPENNL "Enable use of Open Numerical Library" ON) if(UNIX AND NOT APPLE) option(WITH_INSTALL_PORTABLE "Install redistributeable runtime, otherwise install into CMAKE_INSTALL_PREFIX" ON) option(WITH_STATIC_LIBS "Try to link with static libraries, as much as possible, to make blender more portable across distributions" OFF) @@ -2983,9 +2982,6 @@ if(FIRST_RUN) info_cfg_option(WITH_GL_ANGLE) endif() - info_cfg_text("Other:") - info_cfg_option(WITH_OPENNL) - # debug message(STATUS "HAVE_STDBOOL_H = ${HAVE_STDBOOL_H}") diff --git a/SConstruct b/SConstruct index a5efed552fe..de265df5b02 100644 --- a/SConstruct +++ b/SConstruct @@ -555,7 +555,6 @@ else: # TODO, make optional (as with CMake) env['CPPFLAGS'].append('-DWITH_AVI') -env['CPPFLAGS'].append('-DWITH_OPENNL') if env['OURPLATFORM'] not in ('win32-vc', 'win64-vc'): env['CPPFLAGS'].append('-DHAVE_STDBOOL_H') diff --git a/build_files/cmake/cmake_static_check_clang_array.py b/build_files/cmake/cmake_static_check_clang_array.py index 45b262a13ce..597d1d2b980 100644 --- a/build_files/cmake/cmake_static_check_clang_array.py +++ b/build_files/cmake/cmake_static_check_clang_array.py @@ -32,7 +32,6 @@ USE_QUIET = (os.environ.get("QUIET", None) is not None) CHECKER_IGNORE_PREFIX = [ "extern", "intern/moto", - "blender/intern/opennl", ] CHECKER_BIN = "python2" diff --git a/build_files/cmake/cmake_static_check_cppcheck.py b/build_files/cmake/cmake_static_check_cppcheck.py index 9f012cb7f6d..3504b005adc 100644 --- a/build_files/cmake/cmake_static_check_cppcheck.py +++ b/build_files/cmake/cmake_static_check_cppcheck.py @@ -32,7 +32,6 @@ USE_QUIET = (os.environ.get("QUIET", None) is not None) CHECKER_IGNORE_PREFIX = [ "extern", "intern/moto", - "blender/intern/opennl", ] CHECKER_BIN = "cppcheck" diff --git a/build_files/cmake/cmake_static_check_smatch.py b/build_files/cmake/cmake_static_check_smatch.py index de13d141276..f525187e22c 100644 --- a/build_files/cmake/cmake_static_check_smatch.py +++ b/build_files/cmake/cmake_static_check_smatch.py @@ -25,7 +25,6 @@ CHECKER_IGNORE_PREFIX = [ "extern", "intern/moto", - "blender/intern/opennl", ] CHECKER_BIN = "smatch" diff --git a/build_files/cmake/cmake_static_check_sparse.py b/build_files/cmake/cmake_static_check_sparse.py index 2ee99925adb..6d1c4e3d6a2 100644 --- a/build_files/cmake/cmake_static_check_sparse.py +++ b/build_files/cmake/cmake_static_check_sparse.py @@ -25,7 +25,6 @@ CHECKER_IGNORE_PREFIX = [ "extern", "intern/moto", - "blender/intern/opennl", ] CHECKER_BIN = "sparse" diff --git a/build_files/cmake/cmake_static_check_splint.py b/build_files/cmake/cmake_static_check_splint.py index 5a967ecc7a3..46d8808e89d 100644 --- a/build_files/cmake/cmake_static_check_splint.py +++ b/build_files/cmake/cmake_static_check_splint.py @@ -25,7 +25,6 @@ CHECKER_IGNORE_PREFIX = [ "extern", "intern/moto", - "blender/intern/opennl", ] CHECKER_BIN = "splint" diff --git a/build_files/cmake/config/blender_full.cmake b/build_files/cmake/config/blender_full.cmake index 0ca980050db..ad8a6815675 100644 --- a/build_files/cmake/config/blender_full.cmake +++ b/build_files/cmake/config/blender_full.cmake @@ -43,7 +43,6 @@ set(WITH_OPENAL ON CACHE BOOL "" FORCE) set(WITH_OPENCOLLADA ON CACHE BOOL "" FORCE) set(WITH_OPENCOLORIO ON CACHE BOOL "" FORCE) set(WITH_OPENMP ON CACHE BOOL "" FORCE) -set(WITH_OPENNL ON CACHE BOOL "" FORCE) set(WITH_PYTHON_INSTALL ON CACHE BOOL "" FORCE) set(WITH_RAYOPTIMIZATION ON CACHE BOOL "" FORCE) set(WITH_SDL ON CACHE BOOL "" FORCE) diff --git a/build_files/cmake/config/blender_lite.cmake b/build_files/cmake/config/blender_lite.cmake index 9e7b4dcf39b..99e90caf793 100644 --- a/build_files/cmake/config/blender_lite.cmake +++ b/build_files/cmake/config/blender_lite.cmake @@ -47,7 +47,6 @@ set(WITH_OPENCOLLADA OFF CACHE BOOL "" FORCE) set(WITH_OPENCOLORIO OFF CACHE BOOL "" FORCE) set(WITH_OPENIMAGEIO OFF CACHE BOOL "" FORCE) set(WITH_OPENMP OFF CACHE BOOL "" FORCE) -set(WITH_OPENNL OFF CACHE BOOL "" FORCE) set(WITH_RAYOPTIMIZATION OFF CACHE BOOL "" FORCE) set(WITH_SDL OFF CACHE BOOL "" FORCE) set(WITH_X11_XINPUT OFF CACHE BOOL "" FORCE) diff --git a/build_files/cmake/macros.cmake b/build_files/cmake/macros.cmake index 39c12f2c4d9..4ba15c72677 100644 --- a/build_files/cmake/macros.cmake +++ b/build_files/cmake/macros.cmake @@ -596,7 +596,6 @@ function(SETUP_BLENDER_SORTED_LIBS) ge_phys_bullet bf_intern_smoke extern_lzma - extern_colamd ge_logic_ketsji extern_recastnavigation ge_logic @@ -698,10 +697,6 @@ function(SETUP_BLENDER_SORTED_LIBS) list(APPEND BLENDER_SORTED_LIBS bf_intern_locale) endif() - if(WITH_OPENNL) - list_insert_after(BLENDER_SORTED_LIBS "bf_render" "bf_intern_opennl") - endif() - if(WITH_BULLET) list_insert_after(BLENDER_SORTED_LIBS "bf_blenkernel" "bf_intern_rigidbody") endif() diff --git a/doc/doxygen/doxygen.intern.h b/doc/doxygen/doxygen.intern.h index 2c8ecae0ead..e3cc11b3404 100644 --- a/doc/doxygen/doxygen.intern.h +++ b/doc/doxygen/doxygen.intern.h @@ -38,7 +38,7 @@ * \ingroup intern */ -/** \defgroup opennl opennl +/** \defgroup eigen eigen * \ingroup intern */ diff --git a/extern/CMakeLists.txt b/extern/CMakeLists.txt index d0c587b80e4..640de9d80e7 100644 --- a/extern/CMakeLists.txt +++ b/extern/CMakeLists.txt @@ -30,10 +30,6 @@ add_subdirectory(rangetree) add_subdirectory(wcwidth) add_subdirectory(libmv) -if(WITH_OPENNL) - add_subdirectory(colamd) -endif() - if(WITH_BULLET) if(NOT WITH_SYSTEM_BULLET) add_subdirectory(bullet2) diff --git a/extern/SConscript b/extern/SConscript index 46c177c5bcb..a5d8c1f078e 100644 --- a/extern/SConscript +++ b/extern/SConscript @@ -7,7 +7,6 @@ if env['WITH_BF_GLEW_ES']: else: SConscript(['glew/SConscript']) -SConscript(['colamd/SConscript']) SConscript(['rangetree/SConscript']) SConscript(['wcwidth/SConscript']) SConscript(['libmv/SConscript']) diff --git a/extern/colamd/CMakeLists.txt b/extern/colamd/CMakeLists.txt deleted file mode 100644 index 3019ee5904e..00000000000 --- a/extern/colamd/CMakeLists.txt +++ /dev/null @@ -1,41 +0,0 @@ -# ***** BEGIN GPL LICENSE BLOCK ***** -# -# This program is free software; you can redistribute it and/or -# modify it under the terms of the GNU General Public License -# as published by the Free Software Foundation; either version 2 -# of the License, or (at your option) any later version. -# -# This program is distributed in the hope that it will be useful, -# but WITHOUT ANY WARRANTY; without even the implied warranty of -# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -# GNU General Public License for more details. -# -# You should have received a copy of the GNU General Public License -# along with this program; if not, write to the Free Software Foundation, -# Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. -# -# The Original Code is Copyright (C) 2011, Blender Foundation -# All rights reserved. -# -# Contributor(s): Blender Foundation, -# Sergey Sharybin -# -# ***** END GPL LICENSE BLOCK ***** - -set(INC - Include -) - -set(INC_SYS - -) - -set(SRC - Source/colamd.c - Source/colamd_global.c - - Include/colamd.h - Include/UFconfig.h -) - -blender_add_lib(extern_colamd "${SRC}" "${INC}" "${INC_SYS}") diff --git a/extern/colamd/Doc/ChangeLog b/extern/colamd/Doc/ChangeLog deleted file mode 100644 index 29308e9ad01..00000000000 --- a/extern/colamd/Doc/ChangeLog +++ /dev/null @@ -1,129 +0,0 @@ -May 31, 2007: version 2.7.0 - - * ported to 64-bit MATLAB - - * subdirectories added (Source/, Include/, Lib/, Doc/, MATLAB/, Demo/) - -Dec 12, 2006, version 2.5.2 - - * minor MATLAB cleanup. MATLAB functions renamed colamd2 and symamd2, - so that they do not conflict with the built-in versions. Note that - the MATLAB built-in functions colamd and symamd are identical to - the colamd and symamd functions here. - -Aug 31, 2006: Version 2.5.1 - - * minor change to colamd.m and symamd.m, to use etree instead - of sparsfun. - -Apr. 30, 2006: Version 2.5 - - * colamd_recommended modified, to do more careful integer overflow - checking. It now returns size_t, not int. colamd_l_recommended - also returns size_t. A zero is returned if an error occurs. A - postive return value denotes success. In v2.4 and earlier, - -1 was returned on error (an int or long). - - * long replaced with UF_long integer, which is long except on WIN64. - -Nov 15, 2005: - - * minor editting of comments; version number (2.4) unchanged. - -Changes from Version 2.3 to 2.4 (Aug 30, 2005) - - * Makefile now relies on ../UFconfig/UFconfig.mk - - * changed the dense row/col detection. The meaning of the knobs - has thus changed. - - * added an option to turn off aggressive absorption. It was - always on in versions 2.3 and earlier. - - * added a #define'd version number - - * added a function pointer (colamd_printf) for COLAMD's printing. - - * added a -DNPRINT option, to turn off printing at compile-time. - - * added a check for integer overflow in colamd_recommended - - * minor changes to allow for more simpler 100% test coverage - - * bug fix. If symamd v2.3 fails to allocate its copy of the input - matrix, then it erroneously frees a calloc'd workspace twice. - This bug has no effect on the MATLAB symamd mexFunction, since - mxCalloc terminates the mexFunction if it fails to allocate - memory. Similarly, UMFPACK is not affected because it does not - use symamd. The bug has no effect on the colamd ordering - routine in v2.3. - -Changes from Version 2.2 to 2.3 (Sept. 8, 2003) - - * removed the call to the MATLAB spparms ('spumoni') function. - This can take a lot of time if you are ordering many small - matrices. Only affects the MATLAB interface (colamdmex.c, - symamdmex.c, colamdtestmex.c, and symamdtestmex.c). The - usage of the optional 2nd argument to the colamd and symamd - mexFunctions was changed accordingly. - -Changes from Version 2.1 to 2.2 (Sept. 23, 2002) - - * extensive testing routines added (colamd_test.m, colamdtestmex.c, - and symamdtestmex.c), and the Makefile modified accordingly. - - * a few typos in the comments corrected - - * use of the MATLAB "flops" command removed from colamd_demo, and an - m-file routine luflops.m added. - - * an explicit typecast from unsigned to int added, for COLAMD_C and - COLAMD_R in colamd.h. - - * #include added to colamd_example.c - - -Changes from Version 2.0 to 2.1 (May 4, 2001) - - * TRUE and FALSE are predefined on some systems, so they are defined - here only if not already defined. - - * web site changed - - * UNIX Makefile modified, to handle the case if "." is not in your path. - - -Changes from Version 1.0 to 2.0 (January 31, 2000) - - No bugs were found in version 1.1. These changes merely add new - functionality. - - * added the COLAMD_RECOMMENDED (nnz, n_row, n_col) macro. - - * moved the output statistics, from A, to a separate output argument. - The arguments changed for the C-callable routines. - - * added colamd_report and symamd_report. - - * added a C-callable symamd routine. Formerly, symamd was only - available as a mexFunction from MATLAB. - - * added error-checking to symamd. Formerly, it assumed its input - was error-free. - - * added the optional stats and knobs arguments to the symamd mexFunction - - * deleted colamd_help. A help message is still available from - "help colamd" and "help symamd" in MATLAB. - - * deleted colamdtree.m and symamdtree.m. Now, colamd.m and symamd.m - also do the elimination tree post-ordering. The Version 1.1 - colamd and symamd mexFunctions, which do not do the post- - ordering, are now visible as colamdmex and symamdmex from - MATLAB. Essentialy, the post-ordering is now the default - behavior of colamd.m and symamd.m, to match the behavior of - colmmd and symmmd. The post-ordering is only available in the - MATLAB interface, not the C-callable interface. - - * made a slight change to the dense row/column detection in symamd, - to match the stated specifications. diff --git a/extern/colamd/Doc/lesser.txt b/extern/colamd/Doc/lesser.txt deleted file mode 100644 index 8add30ad590..00000000000 --- a/extern/colamd/Doc/lesser.txt +++ /dev/null @@ -1,504 +0,0 @@ - GNU LESSER GENERAL PUBLIC LICENSE - Version 2.1, February 1999 - - Copyright (C) 1991, 1999 Free Software Foundation, Inc. - 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - Everyone is permitted to copy and distribute verbatim copies - of this license document, but changing it is not allowed. - -[This is the first released version of the Lesser GPL. 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On most systems, - * a C program can be compiled in LP64 mode, in which long's and pointers are - * both 64-bits, and int's are 32-bits. Windows 64, however, uses the LLP64 - * model, in which int's and long's are 32-bits, and long long's and pointers - * are 64-bits. - * - * SuiteSparse packages that include long integer versions are - * intended for the LP64 mode. However, as a workaround for Windows 64 - * (and perhaps other systems), the long integer can be redefined. - * - * If _WIN64 is defined, then the __int64 type is used instead of long. - * - * The long integer can also be defined at compile time. For example, this - * could be added to UFconfig.mk: - * - * CFLAGS = -O -D'UF_long=long long' -D'UF_long_max=9223372036854775801' \ - * -D'UF_long_id="%lld"' - * - * This file defines UF_long as either long (on all but _WIN64) or - * __int64 on Windows 64. The intent is that a UF_long is always a 64-bit - * integer in a 64-bit code. ptrdiff_t might be a better choice than long; - * it is always the same size as a pointer. - * - * This file also defines the SUITESPARSE_VERSION and related definitions. - * - * Copyright (c) 2007, University of Florida. No licensing restrictions - * apply to this file or to the UFconfig directory. Author: Timothy A. Davis. - */ - -#ifndef _UFCONFIG_H -#define _UFCONFIG_H - -#ifdef __cplusplus -extern "C" { -#endif - -#include - -/* ========================================================================== */ -/* === UF_long ============================================================== */ -/* ========================================================================== */ - -#ifndef UF_long - -#ifdef _WIN64 - -#define UF_long __int64 -#define UF_long_max _I64_MAX -#define UF_long_id "%I64d" - -#else - -#define UF_long long -#define UF_long_max LONG_MAX -#define UF_long_id "%ld" - -#endif -#endif - -/* ========================================================================== */ -/* === SuiteSparse version ================================================== */ -/* ========================================================================== */ - -/* SuiteSparse is not a package itself, but a collection of packages, some of - * which must be used together (UMFPACK requires AMD, CHOLMOD requires AMD, - * COLAMD, CAMD, and CCOLAMD, etc). A version number is provided here for the - * collection itself. The versions of packages within each version of - * SuiteSparse are meant to work together. Combining one packge from one - * version of SuiteSparse, with another package from another version of - * SuiteSparse, may or may not work. - * - * SuiteSparse Version 3.4.0 contains the following packages: - * - * AMD version 2.2.0 - * CAMD version 2.2.0 - * COLAMD version 2.7.1 - * CCOLAMD version 2.7.1 - * CHOLMOD version 1.7.1 - * CSparse version 2.2.3 - * CXSparse version 2.2.3 - * KLU version 1.1.0 - * BTF version 1.1.0 - * LDL version 2.0.1 - * UFconfig version number is the same as SuiteSparse - * UMFPACK version 5.4.0 - * RBio version 1.1.2 - * UFcollection version 1.2.0 - * LINFACTOR version 1.1.0 - * MESHND version 1.1.1 - * SSMULT version 2.0.0 - * MATLAB_Tools no specific version number - * SuiteSparseQR version 1.1.2 - * - * Other package dependencies: - * BLAS required by CHOLMOD and UMFPACK - * LAPACK required by CHOLMOD - * METIS 4.0.1 required by CHOLMOD (optional) and KLU (optional) - */ - -#define SUITESPARSE_DATE "May 20, 2009" -#define SUITESPARSE_VER_CODE(main,sub) ((main) * 1000 + (sub)) -#define SUITESPARSE_MAIN_VERSION 3 -#define SUITESPARSE_SUB_VERSION 4 -#define SUITESPARSE_SUBSUB_VERSION 0 -#define SUITESPARSE_VERSION \ - SUITESPARSE_VER_CODE(SUITESPARSE_MAIN_VERSION,SUITESPARSE_SUB_VERSION) - -#ifdef __cplusplus -} -#endif -#endif diff --git a/extern/colamd/Include/colamd.h b/extern/colamd/Include/colamd.h deleted file mode 100644 index 26372d8fa96..00000000000 --- a/extern/colamd/Include/colamd.h +++ /dev/null @@ -1,255 +0,0 @@ -/* ========================================================================== */ -/* === colamd/symamd prototypes and definitions ============================= */ -/* ========================================================================== */ - -/* COLAMD / SYMAMD include file - - You must include this file (colamd.h) in any routine that uses colamd, - symamd, or the related macros and definitions. - - Authors: - - The authors of the code itself are Stefan I. Larimore and Timothy A. - Davis (davis at cise.ufl.edu), University of Florida. The algorithm was - developed in collaboration with John Gilbert, Xerox PARC, and Esmond - Ng, Oak Ridge National Laboratory. - - Acknowledgements: - - This work was supported by the National Science Foundation, under - grants DMS-9504974 and DMS-9803599. - - Notice: - - Copyright (c) 1998-2007, Timothy A. Davis, 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, copy, modify, and/or distribute - this program, provided that the Copyright, this License, and the - Availability of the original version is retained on all copies and made - accessible to the end-user of any code or package that includes COLAMD - or any modified version of COLAMD. - - Availability: - - The colamd/symamd library is available at - - http://www.cise.ufl.edu/research/sparse/colamd/ - - This is the http://www.cise.ufl.edu/research/sparse/colamd/colamd.h - file. It is required by the colamd.c, colamdmex.c, and symamdmex.c - files, and by any C code that calls the routines whose prototypes are - listed below, or that uses the colamd/symamd definitions listed below. - -*/ - -#ifndef COLAMD_H -#define COLAMD_H - -/* make it easy for C++ programs to include COLAMD */ -#ifdef __cplusplus -extern "C" { -#endif - -/* ========================================================================== */ -/* === Include files ======================================================== */ -/* ========================================================================== */ - -#include - -/* ========================================================================== */ -/* === COLAMD version ======================================================= */ -/* ========================================================================== */ - -/* COLAMD Version 2.4 and later will include the following definitions. - * As an example, to test if the version you are using is 2.4 or later: - * - * #ifdef COLAMD_VERSION - * if (COLAMD_VERSION >= COLAMD_VERSION_CODE (2,4)) ... - * #endif - * - * This also works during compile-time: - * - * #if defined(COLAMD_VERSION) && (COLAMD_VERSION >= COLAMD_VERSION_CODE (2,4)) - * printf ("This is version 2.4 or later\n") ; - * #else - * printf ("This is an early version\n") ; - * #endif - * - * Versions 2.3 and earlier of COLAMD do not include a #define'd version number. - */ - -#define COLAMD_DATE "Nov 1, 2007" -#define COLAMD_VERSION_CODE(main,sub) ((main) * 1000 + (sub)) -#define COLAMD_MAIN_VERSION 2 -#define COLAMD_SUB_VERSION 7 -#define COLAMD_SUBSUB_VERSION 1 -#define COLAMD_VERSION \ - COLAMD_VERSION_CODE(COLAMD_MAIN_VERSION,COLAMD_SUB_VERSION) - -/* ========================================================================== */ -/* === Knob and statistics definitions ====================================== */ -/* ========================================================================== */ - -/* size of the knobs [ ] array. Only knobs [0..1] are currently used. */ -#define COLAMD_KNOBS 20 - -/* number of output statistics. Only stats [0..6] are currently used. */ -#define COLAMD_STATS 20 - -/* knobs [0] and stats [0]: dense row knob and output statistic. */ -#define COLAMD_DENSE_ROW 0 - -/* knobs [1] and stats [1]: dense column knob and output statistic. */ -#define COLAMD_DENSE_COL 1 - -/* knobs [2]: aggressive absorption */ -#define COLAMD_AGGRESSIVE 2 - -/* stats [2]: memory defragmentation count output statistic */ -#define COLAMD_DEFRAG_COUNT 2 - -/* stats [3]: colamd status: zero OK, > 0 warning or notice, < 0 error */ -#define COLAMD_STATUS 3 - -/* stats [4..6]: error info, or info on jumbled columns */ -#define COLAMD_INFO1 4 -#define COLAMD_INFO2 5 -#define COLAMD_INFO3 6 - -/* error codes returned in stats [3]: */ -#define COLAMD_OK (0) -#define COLAMD_OK_BUT_JUMBLED (1) -#define COLAMD_ERROR_A_not_present (-1) -#define COLAMD_ERROR_p_not_present (-2) -#define COLAMD_ERROR_nrow_negative (-3) -#define COLAMD_ERROR_ncol_negative (-4) -#define COLAMD_ERROR_nnz_negative (-5) -#define COLAMD_ERROR_p0_nonzero (-6) -#define COLAMD_ERROR_A_too_small (-7) -#define COLAMD_ERROR_col_length_negative (-8) -#define COLAMD_ERROR_row_index_out_of_bounds (-9) -#define COLAMD_ERROR_out_of_memory (-10) -#define COLAMD_ERROR_internal_error (-999) - - -/* ========================================================================== */ -/* === Prototypes of user-callable routines ================================= */ -/* ========================================================================== */ - -/* define UF_long */ -#include "UFconfig.h" - -size_t colamd_recommended /* returns recommended value of Alen, */ - /* or 0 if input arguments are erroneous */ -( - int nnz, /* nonzeros in A */ - int n_row, /* number of rows in A */ - int n_col /* number of columns in A */ -) ; - -size_t colamd_l_recommended /* returns recommended value of Alen, */ - /* or 0 if input arguments are erroneous */ -( - UF_long nnz, /* nonzeros in A */ - UF_long n_row, /* number of rows in A */ - UF_long n_col /* number of columns in A */ -) ; - -void colamd_set_defaults /* sets default parameters */ -( /* knobs argument is modified on output */ - double knobs [COLAMD_KNOBS] /* parameter settings for colamd */ -) ; - -void colamd_l_set_defaults /* sets default parameters */ -( /* knobs argument is modified on output */ - double knobs [COLAMD_KNOBS] /* parameter settings for colamd */ -) ; - -int colamd /* returns (1) if successful, (0) otherwise*/ -( /* A and p arguments are modified on output */ - int n_row, /* number of rows in A */ - int n_col, /* number of columns in A */ - int Alen, /* size of the array A */ - int A [], /* row indices of A, of size Alen */ - int p [], /* column pointers of A, of size n_col+1 */ - double knobs [COLAMD_KNOBS],/* parameter settings for colamd */ - int stats [COLAMD_STATS] /* colamd output statistics and error codes */ -) ; - -UF_long colamd_l /* returns (1) if successful, (0) otherwise*/ -( /* A and p arguments are modified on output */ - UF_long n_row, /* number of rows in A */ - UF_long n_col, /* number of columns in A */ - UF_long Alen, /* size of the array A */ - UF_long A [], /* row indices of A, of size Alen */ - UF_long p [], /* column pointers of A, of size n_col+1 */ - double knobs [COLAMD_KNOBS],/* parameter settings for colamd */ - UF_long stats [COLAMD_STATS]/* colamd output statistics and error codes */ -) ; - -int symamd /* return (1) if OK, (0) otherwise */ -( - int n, /* number of rows and columns of A */ - int A [], /* row indices of A */ - int p [], /* column pointers of A */ - int perm [], /* output permutation, size n_col+1 */ - double knobs [COLAMD_KNOBS], /* parameters (uses defaults if NULL) */ - int stats [COLAMD_STATS], /* output statistics and error codes */ - void * (*allocate) (size_t, size_t), - /* pointer to calloc (ANSI C) or */ - /* mxCalloc (for MATLAB mexFunction) */ - void (*release) (void *) - /* pointer to free (ANSI C) or */ - /* mxFree (for MATLAB mexFunction) */ -) ; - -UF_long symamd_l /* return (1) if OK, (0) otherwise */ -( - UF_long n, /* number of rows and columns of A */ - UF_long A [], /* row indices of A */ - UF_long p [], /* column pointers of A */ - UF_long perm [], /* output permutation, size n_col+1 */ - double knobs [COLAMD_KNOBS], /* parameters (uses defaults if NULL) */ - UF_long stats [COLAMD_STATS], /* output statistics and error codes */ - void * (*allocate) (size_t, size_t), - /* pointer to calloc (ANSI C) or */ - /* mxCalloc (for MATLAB mexFunction) */ - void (*release) (void *) - /* pointer to free (ANSI C) or */ - /* mxFree (for MATLAB mexFunction) */ -) ; - -void colamd_report -( - int stats [COLAMD_STATS] -) ; - -void colamd_l_report -( - UF_long stats [COLAMD_STATS] -) ; - -void symamd_report -( - int stats [COLAMD_STATS] -) ; - -void symamd_l_report -( - UF_long stats [COLAMD_STATS] -) ; - -#ifndef EXTERN -#define EXTERN extern -#endif - -EXTERN int (*colamd_printf) (const char *, ...) ; - -#ifdef __cplusplus -} -#endif - -#endif /* COLAMD_H */ diff --git a/extern/colamd/README.txt b/extern/colamd/README.txt deleted file mode 100644 index 5ed81c71d02..00000000000 --- a/extern/colamd/README.txt +++ /dev/null @@ -1,127 +0,0 @@ -The COLAMD ordering method - Version 2.7 -------------------------------------------------------------------------------- - -The COLAMD column approximate minimum degree ordering algorithm computes -a permutation vector P such that the LU factorization of A (:,P) -tends to be sparser than that of A. The Cholesky factorization of -(A (:,P))'*(A (:,P)) will also tend to be sparser than that of A'*A. -SYMAMD is a symmetric minimum degree ordering method based on COLAMD, -available as a MATLAB-callable function. It constructs a matrix M such -that M'*M has the same pattern as A, and then uses COLAMD to compute a column -ordering of M. Colamd and symamd tend to be faster and generate better -orderings than their MATLAB counterparts, colmmd and symmmd. - -To compile and test the colamd m-files and mexFunctions, just unpack the -COLAMD/ directory from the COLAMD.tar.gz file, and run MATLAB from -within that directory. Next, type colamd_test to compile and test colamd -and symamd. This will work on any computer with MATLAB (Unix, PC, or Mac). -Alternatively, type "make" (in Unix) to compile and run a simple example C -code, without using MATLAB. - -To compile and install the colamd m-files and mexFunctions, just cd to -COLAMD/MATLAB and type colamd_install in the MATLAB command window. -A short demo will run. Optionally, type colamd_test to run an extensive tests. -Type "make" in Unix in the COLAMD directory to compile the C-callable -library and to run a short demo. - -If you have MATLAB 7.2 or earlier, you must first edit UFconfig/UFconfig.h to -remove the "-largeArrayDims" option from the MEX command (or just use -colamd_make.m inside MATLAB). - -Colamd is a built-in routine in MATLAB, available from The -Mathworks, Inc. Under most cases, the compiled COLAMD from Versions 2.0 to the -current version do not differ. Colamd Versions 2.2 and 2.3 differ only in their -mexFunction interaces to MATLAB. v2.4 fixes a bug in the symamd routine in -v2.3. The bug (in v2.3 and earlier) has no effect on the MATLAB symamd -mexFunction. v2.5 adds additional checks for integer overflow, so that -the "int" version can be safely used with 64-bit pointers. Refer to the -ChangeLog for more details. - -To use colamd and symamd within an application written in C, all you need are -colamd.c, colamd_global.c, and colamd.h, which are the C-callable -colamd/symamd codes. See colamd.c for more information on how to call -colamd from a C program. - -Requires UFconfig, in the ../UFconfig directory relative to this directory. - - Copyright (c) 1998-2007, Timothy A. Davis, All Rights Reserved. - - See http://www.cise.ufl.edu/research/sparse/colamd (the colamd.c - file) for the License. - - -Related papers: - - T. A. Davis, J. R. Gilbert, S. Larimore, E. Ng, An approximate column - minimum degree ordering algorithm, ACM Transactions on Mathematical - Software, vol. 30, no. 3., pp. 353-376, 2004. - - T. A. Davis, J. R. Gilbert, S. Larimore, E. Ng, Algorithm 836: COLAMD, - an approximate column minimum degree ordering algorithm, ACM - Transactions on Mathematical Software, vol. 30, no. 3., pp. 377-380, - 2004. - - "An approximate minimum degree column ordering algorithm", - S. I. Larimore, MS Thesis, Dept. of Computer and Information - Science and Engineering, University of Florida, Gainesville, FL, - 1998. CISE Tech Report TR-98-016. Available at - ftp://ftp.cise.ufl.edu/cis/tech-reports/tr98/tr98-016.ps - via anonymous ftp. - - Approximate Deficiency for Ordering the Columns of a Matrix, - J. L. Kern, Senior Thesis, Dept. of Computer and Information - Science and Engineering, University of Florida, Gainesville, FL, - 1999. Available at http://www.cise.ufl.edu/~davis/Kern/kern.ps - - -Authors: Stefan I. Larimore and Timothy A. Davis, University of Florida, -in collaboration with John Gilbert, Xerox PARC (now at UC Santa Barbara), -and Esmong Ng, Lawrence Berkeley National Laboratory (much of this work -he did while at Oak Ridge National Laboratory). - -COLAMD files: - - Demo simple demo - Doc additional documentation (see colamd.c for more) - Include include file - Lib compiled C-callable library - Makefile primary Unix Makefile - MATLAB MATLAB functions - README.txt this file - Source C source code - - ./Demo: - colamd_example.c simple example - colamd_example.out output of colamd_example.c - colamd_l_example.c simple example, long integers - colamd_l_example.out output of colamd_l_example.c - Makefile Makefile for C demos - - ./Doc: - ChangeLog change log - lesser.txt license - - ./Include: - colamd.h include file - - ./Lib: - Makefile Makefile for C-callable library - - ./MATLAB: - colamd2.m MATLAB interface for colamd2 - colamd_demo.m simple demo - colamd_install.m compile and install colamd2 and symamd2 - colamd_make.m compile colamd2 and symamd2 - colamdmex.ca MATLAB mexFunction for colamd2 - colamd_test.m extensive test - colamdtestmex.c test function for colamd - Contents.m contents of the MATLAB directory - luflops.m test code - Makefile Makefile for MATLAB functions - symamd2.m MATLAB interface for symamd2 - symamdmex.c MATLAB mexFunction for symamd2 - symamdtestmex.c test function for symamd - - ./Source: - colamd.c primary source code - colamd_global.c globally defined function pointers (malloc, free, ...) diff --git a/extern/colamd/SConscript b/extern/colamd/SConscript deleted file mode 100644 index 7930e3ace2d..00000000000 --- a/extern/colamd/SConscript +++ /dev/null @@ -1,14 +0,0 @@ -#!/usr/bin/python -import sys -import os - -Import('env') - -defs = '' -cflags = [] - -src = env.Glob('Source/*.c') - -incs = './Include' - -env.BlenderLib ( libname = 'extern_colamd', sources=src, includes=Split(incs), defines=Split(defs), libtype=['extern', 'player'], priority=[20,137], compileflags=cflags ) diff --git a/extern/colamd/Source/colamd.c b/extern/colamd/Source/colamd.c deleted file mode 100644 index 5fe20d62822..00000000000 --- a/extern/colamd/Source/colamd.c +++ /dev/null @@ -1,3611 +0,0 @@ -/* ========================================================================== */ -/* === colamd/symamd - a sparse matrix column ordering algorithm ============ */ -/* ========================================================================== */ - -/* COLAMD / SYMAMD - - colamd: an approximate minimum degree column ordering algorithm, - for LU factorization of symmetric or unsymmetric matrices, - QR factorization, least squares, interior point methods for - linear programming problems, and other related problems. - - symamd: an approximate minimum degree ordering algorithm for Cholesky - factorization of symmetric matrices. - - Purpose: - - Colamd computes a permutation Q such that the Cholesky factorization of - (AQ)'(AQ) has less fill-in and requires fewer floating point operations - than A'A. This also provides a good ordering for sparse partial - pivoting methods, P(AQ) = LU, where Q is computed prior to numerical - factorization, and P is computed during numerical factorization via - conventional partial pivoting with row interchanges. Colamd is the - column ordering method used in SuperLU, part of the ScaLAPACK library. - It is also available as built-in function in MATLAB Version 6, - available from MathWorks, Inc. (http://www.mathworks.com). This - routine can be used in place of colmmd in MATLAB. - - Symamd computes a permutation P of a symmetric matrix A such that the - Cholesky factorization of PAP' has less fill-in and requires fewer - floating point operations than A. Symamd constructs a matrix M such - that M'M has the same nonzero pattern of A, and then orders the columns - of M using colmmd. The column ordering of M is then returned as the - row and column ordering P of A. - - Authors: - - The authors of the code itself are Stefan I. Larimore and Timothy A. - Davis (davis at cise.ufl.edu), University of Florida. The algorithm was - developed in collaboration with John Gilbert, Xerox PARC, and Esmond - Ng, Oak Ridge National Laboratory. - - Acknowledgements: - - This work was supported by the National Science Foundation, under - grants DMS-9504974 and DMS-9803599. - - Copyright and License: - - Copyright (c) 1998-2007, Timothy A. Davis, All Rights Reserved. - COLAMD is also available under alternate licenses, contact T. Davis - for details. - - This library is free software; you can redistribute it and/or - modify it under the terms of the GNU Lesser General Public - License as published by the Free Software Foundation; either - version 2.1 of the License, or (at your option) any later version. - - This library is distributed in the hope that it will be useful, - but WITHOUT ANY WARRANTY; without even the implied warranty of - MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU - Lesser General Public License for more details. - - You should have received a copy of the GNU Lesser General Public - License along with this library; if not, write to the Free Software - Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 - USA - - Permission is hereby granted to use or copy this program under the - terms of the GNU LGPL, provided that the Copyright, this License, - and the Availability of the original version is retained on all copies. - User documentation of any code that uses this code or any modified - version of this code must cite the Copyright, this License, the - Availability note, and "Used by permission." Permission to modify - the code and to distribute modified code is granted, provided the - Copyright, this License, and the Availability note are retained, - and a notice that the code was modified is included. - - Availability: - - The colamd/symamd library is available at - - http://www.cise.ufl.edu/research/sparse/colamd/ - - This is the http://www.cise.ufl.edu/research/sparse/colamd/colamd.c - file. It requires the colamd.h file. It is required by the colamdmex.c - and symamdmex.c files, for the MATLAB interface to colamd and symamd. - Appears as ACM Algorithm 836. - - See the ChangeLog file for changes since Version 1.0. - - References: - - T. A. Davis, J. R. Gilbert, S. Larimore, E. Ng, An approximate column - minimum degree ordering algorithm, ACM Transactions on Mathematical - Software, vol. 30, no. 3., pp. 353-376, 2004. - - T. A. Davis, J. R. Gilbert, S. Larimore, E. Ng, Algorithm 836: COLAMD, - an approximate column minimum degree ordering algorithm, ACM - Transactions on Mathematical Software, vol. 30, no. 3., pp. 377-380, - 2004. - -*/ - -/* ========================================================================== */ -/* === Description of user-callable routines ================================ */ -/* ========================================================================== */ - -/* COLAMD includes both int and UF_long versions of all its routines. The - * description below is for the int version. For UF_long, all int arguments - * become UF_long. UF_long is normally defined as long, except for WIN64. - - ---------------------------------------------------------------------------- - colamd_recommended: - ---------------------------------------------------------------------------- - - C syntax: - - #include "colamd.h" - size_t colamd_recommended (int nnz, int n_row, int n_col) ; - size_t colamd_l_recommended (UF_long nnz, UF_long n_row, - UF_long n_col) ; - - Purpose: - - Returns recommended value of Alen for use by colamd. Returns 0 - if any input argument is negative. The use of this routine - is optional. Not needed for symamd, which dynamically allocates - its own memory. - - Note that in v2.4 and earlier, these routines returned int or long. - They now return a value of type size_t. - - Arguments (all input arguments): - - int nnz ; Number of nonzeros in the matrix A. This must - be the same value as p [n_col] in the call to - colamd - otherwise you will get a wrong value - of the recommended memory to use. - - int n_row ; Number of rows in the matrix A. - - int n_col ; Number of columns in the matrix A. - - ---------------------------------------------------------------------------- - colamd_set_defaults: - ---------------------------------------------------------------------------- - - C syntax: - - #include "colamd.h" - colamd_set_defaults (double knobs [COLAMD_KNOBS]) ; - colamd_l_set_defaults (double knobs [COLAMD_KNOBS]) ; - - Purpose: - - Sets the default parameters. The use of this routine is optional. - - Arguments: - - double knobs [COLAMD_KNOBS] ; Output only. - - NOTE: the meaning of the dense row/col knobs has changed in v2.4 - - knobs [0] and knobs [1] control dense row and col detection: - - Colamd: rows with more than - max (16, knobs [COLAMD_DENSE_ROW] * sqrt (n_col)) - entries are removed prior to ordering. Columns with more than - max (16, knobs [COLAMD_DENSE_COL] * sqrt (MIN (n_row,n_col))) - entries are removed prior to - ordering, and placed last in the output column ordering. - - Symamd: uses only knobs [COLAMD_DENSE_ROW], which is knobs [0]. - Rows and columns with more than - max (16, knobs [COLAMD_DENSE_ROW] * sqrt (n)) - entries are removed prior to ordering, and placed last in the - output ordering. - - COLAMD_DENSE_ROW and COLAMD_DENSE_COL are defined as 0 and 1, - respectively, in colamd.h. Default values of these two knobs - are both 10. Currently, only knobs [0] and knobs [1] are - used, but future versions may use more knobs. If so, they will - be properly set to their defaults by the future version of - colamd_set_defaults, so that the code that calls colamd will - not need to change, assuming that you either use - colamd_set_defaults, or pass a (double *) NULL pointer as the - knobs array to colamd or symamd. - - knobs [2]: aggressive absorption - - knobs [COLAMD_AGGRESSIVE] controls whether or not to do - aggressive absorption during the ordering. Default is TRUE. - - - ---------------------------------------------------------------------------- - colamd: - ---------------------------------------------------------------------------- - - C syntax: - - #include "colamd.h" - int colamd (int n_row, int n_col, int Alen, int *A, int *p, - double knobs [COLAMD_KNOBS], int stats [COLAMD_STATS]) ; - UF_long colamd_l (UF_long n_row, UF_long n_col, UF_long Alen, - UF_long *A, UF_long *p, double knobs [COLAMD_KNOBS], - UF_long stats [COLAMD_STATS]) ; - - Purpose: - - Computes a column ordering (Q) of A such that P(AQ)=LU or - (AQ)'AQ=LL' have less fill-in and require fewer floating point - operations than factorizing the unpermuted matrix A or A'A, - respectively. - - Returns: - - TRUE (1) if successful, FALSE (0) otherwise. - - Arguments: - - int n_row ; Input argument. - - Number of rows in the matrix A. - Restriction: n_row >= 0. - Colamd returns FALSE if n_row is negative. - - int n_col ; Input argument. - - Number of columns in the matrix A. - Restriction: n_col >= 0. - Colamd returns FALSE if n_col is negative. - - int Alen ; Input argument. - - Restriction (see note): - Alen >= 2*nnz + 6*(n_col+1) + 4*(n_row+1) + n_col - Colamd returns FALSE if these conditions are not met. - - Note: this restriction makes an modest assumption regarding - the size of the two typedef's structures in colamd.h. - We do, however, guarantee that - - Alen >= colamd_recommended (nnz, n_row, n_col) - - will be sufficient. Note: the macro version does not check - for integer overflow, and thus is not recommended. Use - the colamd_recommended routine instead. - - int A [Alen] ; Input argument, undefined on output. - - A is an integer array of size Alen. Alen must be at least as - large as the bare minimum value given above, but this is very - low, and can result in excessive run time. For best - performance, we recommend that Alen be greater than or equal to - colamd_recommended (nnz, n_row, n_col), which adds - nnz/5 to the bare minimum value given above. - - On input, the row indices of the entries in column c of the - matrix are held in A [(p [c]) ... (p [c+1]-1)]. The row indices - in a given column c need not be in ascending order, and - duplicate row indices may be be present. However, colamd will - work a little faster if both of these conditions are met - (Colamd puts the matrix into this format, if it finds that the - the conditions are not met). - - The matrix is 0-based. That is, rows are in the range 0 to - n_row-1, and columns are in the range 0 to n_col-1. Colamd - returns FALSE if any row index is out of range. - - The contents of A are modified during ordering, and are - undefined on output. - - int p [n_col+1] ; Both input and output argument. - - p is an integer array of size n_col+1. On input, it holds the - "pointers" for the column form of the matrix A. Column c of - the matrix A is held in A [(p [c]) ... (p [c+1]-1)]. The first - entry, p [0], must be zero, and p [c] <= p [c+1] must hold - for all c in the range 0 to n_col-1. The value p [n_col] is - thus the total number of entries in the pattern of the matrix A. - Colamd returns FALSE if these conditions are not met. - - On output, if colamd returns TRUE, the array p holds the column - permutation (Q, for P(AQ)=LU or (AQ)'(AQ)=LL'), where p [0] is - the first column index in the new ordering, and p [n_col-1] is - the last. That is, p [k] = j means that column j of A is the - kth pivot column, in AQ, where k is in the range 0 to n_col-1 - (p [0] = j means that column j of A is the first column in AQ). - - If colamd returns FALSE, then no permutation is returned, and - p is undefined on output. - - double knobs [COLAMD_KNOBS] ; Input argument. - - See colamd_set_defaults for a description. - - int stats [COLAMD_STATS] ; Output argument. - - Statistics on the ordering, and error status. - See colamd.h for related definitions. - Colamd returns FALSE if stats is not present. - - stats [0]: number of dense or empty rows ignored. - - stats [1]: number of dense or empty columns ignored (and - ordered last in the output permutation p) - Note that a row can become "empty" if it - contains only "dense" and/or "empty" columns, - and similarly a column can become "empty" if it - only contains "dense" and/or "empty" rows. - - stats [2]: number of garbage collections performed. - This can be excessively high if Alen is close - to the minimum required value. - - stats [3]: status code. < 0 is an error code. - > 1 is a warning or notice. - - 0 OK. Each column of the input matrix contained - row indices in increasing order, with no - duplicates. - - 1 OK, but columns of input matrix were jumbled - (unsorted columns or duplicate entries). Colamd - had to do some extra work to sort the matrix - first and remove duplicate entries, but it - still was able to return a valid permutation - (return value of colamd was TRUE). - - stats [4]: highest numbered column that - is unsorted or has duplicate - entries. - stats [5]: last seen duplicate or - unsorted row index. - stats [6]: number of duplicate or - unsorted row indices. - - -1 A is a null pointer - - -2 p is a null pointer - - -3 n_row is negative - - stats [4]: n_row - - -4 n_col is negative - - stats [4]: n_col - - -5 number of nonzeros in matrix is negative - - stats [4]: number of nonzeros, p [n_col] - - -6 p [0] is nonzero - - stats [4]: p [0] - - -7 A is too small - - stats [4]: required size - stats [5]: actual size (Alen) - - -8 a column has a negative number of entries - - stats [4]: column with < 0 entries - stats [5]: number of entries in col - - -9 a row index is out of bounds - - stats [4]: column with bad row index - stats [5]: bad row index - stats [6]: n_row, # of rows of matrx - - -10 (unused; see symamd.c) - - -999 (unused; see symamd.c) - - Future versions may return more statistics in the stats array. - - Example: - - See http://www.cise.ufl.edu/research/sparse/colamd/example.c - for a complete example. - - To order the columns of a 5-by-4 matrix with 11 nonzero entries in - the following nonzero pattern - - x 0 x 0 - x 0 x x - 0 x x 0 - 0 0 x x - x x 0 0 - - with default knobs and no output statistics, do the following: - - #include "colamd.h" - #define ALEN 100 - int A [ALEN] = {0, 1, 4, 2, 4, 0, 1, 2, 3, 1, 3} ; - int p [ ] = {0, 3, 5, 9, 11} ; - int stats [COLAMD_STATS] ; - colamd (5, 4, ALEN, A, p, (double *) NULL, stats) ; - - The permutation is returned in the array p, and A is destroyed. - - ---------------------------------------------------------------------------- - symamd: - ---------------------------------------------------------------------------- - - C syntax: - - #include "colamd.h" - int symamd (int n, int *A, int *p, int *perm, - double knobs [COLAMD_KNOBS], int stats [COLAMD_STATS], - void (*allocate) (size_t, size_t), void (*release) (void *)) ; - UF_long symamd_l (UF_long n, UF_long *A, UF_long *p, UF_long *perm, - double knobs [COLAMD_KNOBS], UF_long stats [COLAMD_STATS], - void (*allocate) (size_t, size_t), void (*release) (void *)) ; - - Purpose: - - The symamd routine computes an ordering P of a symmetric sparse - matrix A such that the Cholesky factorization PAP' = LL' remains - sparse. It is based on a column ordering of a matrix M constructed - so that the nonzero pattern of M'M is the same as A. The matrix A - is assumed to be symmetric; only the strictly lower triangular part - is accessed. You must pass your selected memory allocator (usually - calloc/free or mxCalloc/mxFree) to symamd, for it to allocate - memory for the temporary matrix M. - - Returns: - - TRUE (1) if successful, FALSE (0) otherwise. - - Arguments: - - int n ; Input argument. - - Number of rows and columns in the symmetrix matrix A. - Restriction: n >= 0. - Symamd returns FALSE if n is negative. - - int A [nnz] ; Input argument. - - A is an integer array of size nnz, where nnz = p [n]. - - The row indices of the entries in column c of the matrix are - held in A [(p [c]) ... (p [c+1]-1)]. The row indices in a - given column c need not be in ascending order, and duplicate - row indices may be present. However, symamd will run faster - if the columns are in sorted order with no duplicate entries. - - The matrix is 0-based. That is, rows are in the range 0 to - n-1, and columns are in the range 0 to n-1. Symamd - returns FALSE if any row index is out of range. - - The contents of A are not modified. - - int p [n+1] ; Input argument. - - p is an integer array of size n+1. On input, it holds the - "pointers" for the column form of the matrix A. Column c of - the matrix A is held in A [(p [c]) ... (p [c+1]-1)]. The first - entry, p [0], must be zero, and p [c] <= p [c+1] must hold - for all c in the range 0 to n-1. The value p [n] is - thus the total number of entries in the pattern of the matrix A. - Symamd returns FALSE if these conditions are not met. - - The contents of p are not modified. - - int perm [n+1] ; Output argument. - - On output, if symamd returns TRUE, the array perm holds the - permutation P, where perm [0] is the first index in the new - ordering, and perm [n-1] is the last. That is, perm [k] = j - means that row and column j of A is the kth column in PAP', - where k is in the range 0 to n-1 (perm [0] = j means - that row and column j of A are the first row and column in - PAP'). The array is used as a workspace during the ordering, - which is why it must be of length n+1, not just n. - - double knobs [COLAMD_KNOBS] ; Input argument. - - See colamd_set_defaults for a description. - - int stats [COLAMD_STATS] ; Output argument. - - Statistics on the ordering, and error status. - See colamd.h for related definitions. - Symamd returns FALSE if stats is not present. - - stats [0]: number of dense or empty row and columns ignored - (and ordered last in the output permutation - perm). Note that a row/column can become - "empty" if it contains only "dense" and/or - "empty" columns/rows. - - stats [1]: (same as stats [0]) - - stats [2]: number of garbage collections performed. - - stats [3]: status code. < 0 is an error code. - > 1 is a warning or notice. - - 0 OK. Each column of the input matrix contained - row indices in increasing order, with no - duplicates. - - 1 OK, but columns of input matrix were jumbled - (unsorted columns or duplicate entries). Symamd - had to do some extra work to sort the matrix - first and remove duplicate entries, but it - still was able to return a valid permutation - (return value of symamd was TRUE). - - stats [4]: highest numbered column that - is unsorted or has duplicate - entries. - stats [5]: last seen duplicate or - unsorted row index. - stats [6]: number of duplicate or - unsorted row indices. - - -1 A is a null pointer - - -2 p is a null pointer - - -3 (unused, see colamd.c) - - -4 n is negative - - stats [4]: n - - -5 number of nonzeros in matrix is negative - - stats [4]: # of nonzeros (p [n]). - - -6 p [0] is nonzero - - stats [4]: p [0] - - -7 (unused) - - -8 a column has a negative number of entries - - stats [4]: column with < 0 entries - stats [5]: number of entries in col - - -9 a row index is out of bounds - - stats [4]: column with bad row index - stats [5]: bad row index - stats [6]: n_row, # of rows of matrx - - -10 out of memory (unable to allocate temporary - workspace for M or count arrays using the - "allocate" routine passed into symamd). - - Future versions may return more statistics in the stats array. - - void * (*allocate) (size_t, size_t) - - A pointer to a function providing memory allocation. The - allocated memory must be returned initialized to zero. For a - C application, this argument should normally be a pointer to - calloc. For a MATLAB mexFunction, the routine mxCalloc is - passed instead. - - void (*release) (size_t, size_t) - - A pointer to a function that frees memory allocated by the - memory allocation routine above. For a C application, this - argument should normally be a pointer to free. For a MATLAB - mexFunction, the routine mxFree is passed instead. - - - ---------------------------------------------------------------------------- - colamd_report: - ---------------------------------------------------------------------------- - - C syntax: - - #include "colamd.h" - colamd_report (int stats [COLAMD_STATS]) ; - colamd_l_report (UF_long stats [COLAMD_STATS]) ; - - Purpose: - - Prints the error status and statistics recorded in the stats - array on the standard error output (for a standard C routine) - or on the MATLAB output (for a mexFunction). - - Arguments: - - int stats [COLAMD_STATS] ; Input only. Statistics from colamd. - - - ---------------------------------------------------------------------------- - symamd_report: - ---------------------------------------------------------------------------- - - C syntax: - - #include "colamd.h" - symamd_report (int stats [COLAMD_STATS]) ; - symamd_l_report (UF_long stats [COLAMD_STATS]) ; - - Purpose: - - Prints the error status and statistics recorded in the stats - array on the standard error output (for a standard C routine) - or on the MATLAB output (for a mexFunction). - - Arguments: - - int stats [COLAMD_STATS] ; Input only. Statistics from symamd. - - -*/ - -/* ========================================================================== */ -/* === Scaffolding code definitions ======================================== */ -/* ========================================================================== */ - -/* Ensure that debugging is turned off: */ -#ifndef NDEBUG -#define NDEBUG -#endif - -/* turn on debugging by uncommenting the following line - #undef NDEBUG -*/ - -/* - Our "scaffolding code" philosophy: In our opinion, well-written library - code should keep its "debugging" code, and just normally have it turned off - by the compiler so as not to interfere with performance. This serves - several purposes: - - (1) assertions act as comments to the reader, telling you what the code - expects at that point. All assertions will always be true (unless - there really is a bug, of course). - - (2) leaving in the scaffolding code assists anyone who would like to modify - the code, or understand the algorithm (by reading the debugging output, - one can get a glimpse into what the code is doing). - - (3) (gasp!) for actually finding bugs. This code has been heavily tested - and "should" be fully functional and bug-free ... but you never know... - - The code will become outrageously slow when debugging is - enabled. To control the level of debugging output, set an environment - variable D to 0 (little), 1 (some), 2, 3, or 4 (lots). When debugging, - you should see the following message on the standard output: - - colamd: debug version, D = 1 (THIS WILL BE SLOW!) - - or a similar message for symamd. If you don't, then debugging has not - been enabled. - -*/ - -/* ========================================================================== */ -/* === Include files ======================================================== */ -/* ========================================================================== */ - -#include "colamd.h" -#include -#include - -#ifdef MATLAB_MEX_FILE -#include "mex.h" -#include "matrix.h" -#endif /* MATLAB_MEX_FILE */ - -#if !defined (NPRINT) || !defined (NDEBUG) -#include -#endif - -#ifndef NULL -#define NULL ((void *) 0) -#endif - -/* ========================================================================== */ -/* === int or UF_long ======================================================= */ -/* ========================================================================== */ - -/* define UF_long */ -#include "UFconfig.h" - -#ifdef DLONG - -#define Int UF_long -#define ID UF_long_id -#define Int_MAX UF_long_max - -#define COLAMD_recommended colamd_l_recommended -#define COLAMD_set_defaults colamd_l_set_defaults -#define COLAMD_MAIN colamd_l -#define SYMAMD_MAIN symamd_l -#define COLAMD_report colamd_l_report -#define SYMAMD_report symamd_l_report - -#else - -#define Int int -#define ID "%d" -#define Int_MAX INT_MAX - -#define COLAMD_recommended colamd_recommended -#define COLAMD_set_defaults colamd_set_defaults -#define COLAMD_MAIN colamd -#define SYMAMD_MAIN symamd -#define COLAMD_report colamd_report -#define SYMAMD_report symamd_report - -#endif - -/* ========================================================================== */ -/* === Row and Column structures ============================================ */ -/* ========================================================================== */ - -/* User code that makes use of the colamd/symamd routines need not directly */ -/* reference these structures. They are used only for colamd_recommended. */ - -typedef struct Colamd_Col_struct -{ - Int start ; /* index for A of first row in this column, or DEAD */ - /* if column is dead */ - Int length ; /* number of rows in this column */ - union - { - Int thickness ; /* number of original columns represented by this */ - /* col, if the column is alive */ - Int parent ; /* parent in parent tree super-column structure, if */ - /* the column is dead */ - } shared1 ; - union - { - Int score ; /* the score used to maintain heap, if col is alive */ - Int order ; /* pivot ordering of this column, if col is dead */ - } shared2 ; - union - { - Int headhash ; /* head of a hash bucket, if col is at the head of */ - /* a degree list */ - Int hash ; /* hash value, if col is not in a degree list */ - Int prev ; /* previous column in degree list, if col is in a */ - /* degree list (but not at the head of a degree list) */ - } shared3 ; - union - { - Int degree_next ; /* next column, if col is in a degree list */ - Int hash_next ; /* next column, if col is in a hash list */ - } shared4 ; - -} Colamd_Col ; - -typedef struct Colamd_Row_struct -{ - Int start ; /* index for A of first col in this row */ - Int length ; /* number of principal columns in this row */ - union - { - Int degree ; /* number of principal & non-principal columns in row */ - Int p ; /* used as a row pointer in init_rows_cols () */ - } shared1 ; - union - { - Int mark ; /* for computing set differences and marking dead rows*/ - Int first_column ;/* first column in row (used in garbage collection) */ - } shared2 ; - -} Colamd_Row ; - -/* ========================================================================== */ -/* === Definitions ========================================================== */ -/* ========================================================================== */ - -/* Routines are either PUBLIC (user-callable) or PRIVATE (not user-callable) */ -#define PUBLIC -#define PRIVATE static - -#define DENSE_DEGREE(alpha,n) \ - ((Int) MAX (16.0, (alpha) * sqrt ((double) (n)))) - -#define MAX(a,b) (((a) > (b)) ? (a) : (b)) -#define MIN(a,b) (((a) < (b)) ? (a) : (b)) - -#define ONES_COMPLEMENT(r) (-(r)-1) - -/* -------------------------------------------------------------------------- */ -/* Change for version 2.1: define TRUE and FALSE only if not yet defined */ -/* -------------------------------------------------------------------------- */ - -#ifndef TRUE -#define TRUE (1) -#endif - -#ifndef FALSE -#define FALSE (0) -#endif - -/* -------------------------------------------------------------------------- */ - -#define EMPTY (-1) - -/* Row and column status */ -#define ALIVE (0) -#define DEAD (-1) - -/* Column status */ -#define DEAD_PRINCIPAL (-1) -#define DEAD_NON_PRINCIPAL (-2) - -/* Macros for row and column status update and checking. */ -#define ROW_IS_DEAD(r) ROW_IS_MARKED_DEAD (Row[r].shared2.mark) -#define ROW_IS_MARKED_DEAD(row_mark) (row_mark < ALIVE) -#define ROW_IS_ALIVE(r) (Row [r].shared2.mark >= ALIVE) -#define COL_IS_DEAD(c) (Col [c].start < ALIVE) -#define COL_IS_ALIVE(c) (Col [c].start >= ALIVE) -#define COL_IS_DEAD_PRINCIPAL(c) (Col [c].start == DEAD_PRINCIPAL) -#define KILL_ROW(r) { Row [r].shared2.mark = DEAD ; } -#define KILL_PRINCIPAL_COL(c) { Col [c].start = DEAD_PRINCIPAL ; } -#define KILL_NON_PRINCIPAL_COL(c) { Col [c].start = DEAD_NON_PRINCIPAL ; } - -/* ========================================================================== */ -/* === Colamd reporting mechanism =========================================== */ -/* ========================================================================== */ - -#if defined (MATLAB_MEX_FILE) || defined (MATHWORKS) -/* In MATLAB, matrices are 1-based to the user, but 0-based internally */ -#define INDEX(i) ((i)+1) -#else -/* In C, matrices are 0-based and indices are reported as such in *_report */ -#define INDEX(i) (i) -#endif - -/* All output goes through the PRINTF macro. */ -#define PRINTF(params) { if (colamd_printf != NULL) (void) colamd_printf params ; } - -/* ========================================================================== */ -/* === Prototypes of PRIVATE routines ======================================= */ -/* ========================================================================== */ - -PRIVATE Int init_rows_cols -( - Int n_row, - Int n_col, - Colamd_Row Row [], - Colamd_Col Col [], - Int A [], - Int p [], - Int stats [COLAMD_STATS] -) ; - -PRIVATE void init_scoring -( - Int n_row, - Int n_col, - Colamd_Row Row [], - Colamd_Col Col [], - Int A [], - Int head [], - double knobs [COLAMD_KNOBS], - Int *p_n_row2, - Int *p_n_col2, - Int *p_max_deg -) ; - -PRIVATE Int find_ordering -( - Int n_row, - Int n_col, - Int Alen, - Colamd_Row Row [], - Colamd_Col Col [], - Int A [], - Int head [], - Int n_col2, - Int max_deg, - Int pfree, - Int aggressive -) ; - -PRIVATE void order_children -( - Int n_col, - Colamd_Col Col [], - Int p [] -) ; - -PRIVATE void detect_super_cols -( - -#ifndef NDEBUG - Int n_col, - Colamd_Row Row [], -#endif /* NDEBUG */ - - Colamd_Col Col [], - Int A [], - Int head [], - Int row_start, - Int row_length -) ; - -PRIVATE Int garbage_collection -( - Int n_row, - Int n_col, - Colamd_Row Row [], - Colamd_Col Col [], - Int A [], - Int *pfree -) ; - -PRIVATE Int clear_mark -( - Int tag_mark, - Int max_mark, - Int n_row, - Colamd_Row Row [] -) ; - -PRIVATE void print_report -( - char *method, - Int stats [COLAMD_STATS] -) ; - -/* ========================================================================== */ -/* === Debugging prototypes and definitions ================================= */ -/* ========================================================================== */ - -#ifndef NDEBUG - -#include - -/* colamd_debug is the *ONLY* global variable, and is only */ -/* present when debugging */ - -PRIVATE Int colamd_debug = 0 ; /* debug print level */ - -#define DEBUG0(params) { PRINTF (params) ; } -#define DEBUG1(params) { if (colamd_debug >= 1) PRINTF (params) ; } -#define DEBUG2(params) { if (colamd_debug >= 2) PRINTF (params) ; } -#define DEBUG3(params) { if (colamd_debug >= 3) PRINTF (params) ; } -#define DEBUG4(params) { if (colamd_debug >= 4) PRINTF (params) ; } - -#ifdef MATLAB_MEX_FILE -#define ASSERT(expression) (mxAssert ((expression), "")) -#else -#define ASSERT(expression) (assert (expression)) -#endif /* MATLAB_MEX_FILE */ - -PRIVATE void colamd_get_debug /* gets the debug print level from getenv */ -( - char *method -) ; - -PRIVATE void debug_deg_lists -( - Int n_row, - Int n_col, - Colamd_Row Row [], - Colamd_Col Col [], - Int head [], - Int min_score, - Int should, - Int max_deg -) ; - -PRIVATE void debug_mark -( - Int n_row, - Colamd_Row Row [], - Int tag_mark, - Int max_mark -) ; - -PRIVATE void debug_matrix -( - Int n_row, - Int n_col, - Colamd_Row Row [], - Colamd_Col Col [], - Int A [] -) ; - -PRIVATE void debug_structures -( - Int n_row, - Int n_col, - Colamd_Row Row [], - Colamd_Col Col [], - Int A [], - Int n_col2 -) ; - -#else /* NDEBUG */ - -/* === No debugging ========================================================= */ - -#define DEBUG0(params) ; -#define DEBUG1(params) ; -#define DEBUG2(params) ; -#define DEBUG3(params) ; -#define DEBUG4(params) ; - -#define ASSERT(expression) - -#endif /* NDEBUG */ - -/* ========================================================================== */ -/* === USER-CALLABLE ROUTINES: ============================================== */ -/* ========================================================================== */ - -/* ========================================================================== */ -/* === colamd_recommended =================================================== */ -/* ========================================================================== */ - -/* - The colamd_recommended routine returns the suggested size for Alen. This - value has been determined to provide good balance between the number of - garbage collections and the memory requirements for colamd. If any - argument is negative, or if integer overflow occurs, a 0 is returned as an - error condition. 2*nnz space is required for the row and column - indices of the matrix. COLAMD_C (n_col) + COLAMD_R (n_row) space is - required for the Col and Row arrays, respectively, which are internal to - colamd (roughly 6*n_col + 4*n_row). An additional n_col space is the - minimal amount of "elbow room", and nnz/5 more space is recommended for - run time efficiency. - - Alen is approximately 2.2*nnz + 7*n_col + 4*n_row + 10. - - This function is not needed when using symamd. -*/ - -/* add two values of type size_t, and check for integer overflow */ -static size_t t_add (size_t a, size_t b, int *ok) -{ - (*ok) = (*ok) && ((a + b) >= MAX (a,b)) ; - return ((*ok) ? (a + b) : 0) ; -} - -/* compute a*k where k is a small integer, and check for integer overflow */ -static size_t t_mult (size_t a, size_t k, int *ok) -{ - size_t i, s = 0 ; - for (i = 0 ; i < k ; i++) - { - s = t_add (s, a, ok) ; - } - return (s) ; -} - -/* size of the Col and Row structures */ -#define COLAMD_C(n_col,ok) \ - ((t_mult (t_add (n_col, 1, ok), sizeof (Colamd_Col), ok) / sizeof (Int))) - -#define COLAMD_R(n_row,ok) \ - ((t_mult (t_add (n_row, 1, ok), sizeof (Colamd_Row), ok) / sizeof (Int))) - - -PUBLIC size_t COLAMD_recommended /* returns recommended value of Alen. */ -( - /* === Parameters ======================================================= */ - - Int nnz, /* number of nonzeros in A */ - Int n_row, /* number of rows in A */ - Int n_col /* number of columns in A */ -) -{ - size_t s, c, r ; - int ok = TRUE ; - if (nnz < 0 || n_row < 0 || n_col < 0) - { - return (0) ; - } - s = t_mult (nnz, 2, &ok) ; /* 2*nnz */ - c = COLAMD_C (n_col, &ok) ; /* size of column structures */ - r = COLAMD_R (n_row, &ok) ; /* size of row structures */ - s = t_add (s, c, &ok) ; - s = t_add (s, r, &ok) ; - s = t_add (s, n_col, &ok) ; /* elbow room */ - s = t_add (s, nnz/5, &ok) ; /* elbow room */ - ok = ok && (s < Int_MAX) ; - return (ok ? s : 0) ; -} - - -/* ========================================================================== */ -/* === colamd_set_defaults ================================================== */ -/* ========================================================================== */ - -/* - The colamd_set_defaults routine sets the default values of the user- - controllable parameters for colamd and symamd: - - Colamd: rows with more than max (16, knobs [0] * sqrt (n_col)) - entries are removed prior to ordering. Columns with more than - max (16, knobs [1] * sqrt (MIN (n_row,n_col))) entries are removed - prior to ordering, and placed last in the output column ordering. - - Symamd: Rows and columns with more than max (16, knobs [0] * sqrt (n)) - entries are removed prior to ordering, and placed last in the - output ordering. - - knobs [0] dense row control - - knobs [1] dense column control - - knobs [2] if nonzero, do aggresive absorption - - knobs [3..19] unused, but future versions might use this - -*/ - -PUBLIC void COLAMD_set_defaults -( - /* === Parameters ======================================================= */ - - double knobs [COLAMD_KNOBS] /* knob array */ -) -{ - /* === Local variables ================================================== */ - - Int i ; - - if (!knobs) - { - return ; /* no knobs to initialize */ - } - for (i = 0 ; i < COLAMD_KNOBS ; i++) - { - knobs [i] = 0 ; - } - knobs [COLAMD_DENSE_ROW] = 10 ; - knobs [COLAMD_DENSE_COL] = 10 ; - knobs [COLAMD_AGGRESSIVE] = TRUE ; /* default: do aggressive absorption*/ -} - - -/* ========================================================================== */ -/* === symamd =============================================================== */ -/* ========================================================================== */ - -PUBLIC Int SYMAMD_MAIN /* return TRUE if OK, FALSE otherwise */ -( - /* === Parameters ======================================================= */ - - Int n, /* number of rows and columns of A */ - Int A [], /* row indices of A */ - Int p [], /* column pointers of A */ - Int perm [], /* output permutation, size n+1 */ - double knobs [COLAMD_KNOBS], /* parameters (uses defaults if NULL) */ - Int stats [COLAMD_STATS], /* output statistics and error codes */ - void * (*allocate) (size_t, size_t), - /* pointer to calloc (ANSI C) or */ - /* mxCalloc (for MATLAB mexFunction) */ - void (*release) (void *) - /* pointer to free (ANSI C) or */ - /* mxFree (for MATLAB mexFunction) */ -) -{ - /* === Local variables ================================================== */ - - Int *count ; /* length of each column of M, and col pointer*/ - Int *mark ; /* mark array for finding duplicate entries */ - Int *M ; /* row indices of matrix M */ - size_t Mlen ; /* length of M */ - Int n_row ; /* number of rows in M */ - Int nnz ; /* number of entries in A */ - Int i ; /* row index of A */ - Int j ; /* column index of A */ - Int k ; /* row index of M */ - Int mnz ; /* number of nonzeros in M */ - Int pp ; /* index into a column of A */ - Int last_row ; /* last row seen in the current column */ - Int length ; /* number of nonzeros in a column */ - - double cknobs [COLAMD_KNOBS] ; /* knobs for colamd */ - double default_knobs [COLAMD_KNOBS] ; /* default knobs for colamd */ - -#ifndef NDEBUG - colamd_get_debug ("symamd") ; -#endif /* NDEBUG */ - - /* === Check the input arguments ======================================== */ - - if (!stats) - { - DEBUG0 (("symamd: stats not present\n")) ; - return (FALSE) ; - } - for (i = 0 ; i < COLAMD_STATS ; i++) - { - stats [i] = 0 ; - } - stats [COLAMD_STATUS] = COLAMD_OK ; - stats [COLAMD_INFO1] = -1 ; - stats [COLAMD_INFO2] = -1 ; - - if (!A) - { - stats [COLAMD_STATUS] = COLAMD_ERROR_A_not_present ; - DEBUG0 (("symamd: A not present\n")) ; - return (FALSE) ; - } - - if (!p) /* p is not present */ - { - stats [COLAMD_STATUS] = COLAMD_ERROR_p_not_present ; - DEBUG0 (("symamd: p not present\n")) ; - return (FALSE) ; - } - - if (n < 0) /* n must be >= 0 */ - { - stats [COLAMD_STATUS] = COLAMD_ERROR_ncol_negative ; - stats [COLAMD_INFO1] = n ; - DEBUG0 (("symamd: n negative %d\n", n)) ; - return (FALSE) ; - } - - nnz = p [n] ; - if (nnz < 0) /* nnz must be >= 0 */ - { - stats [COLAMD_STATUS] = COLAMD_ERROR_nnz_negative ; - stats [COLAMD_INFO1] = nnz ; - DEBUG0 (("symamd: number of entries negative %d\n", nnz)) ; - return (FALSE) ; - } - - if (p [0] != 0) - { - stats [COLAMD_STATUS] = COLAMD_ERROR_p0_nonzero ; - stats [COLAMD_INFO1] = p [0] ; - DEBUG0 (("symamd: p[0] not zero %d\n", p [0])) ; - return (FALSE) ; - } - - /* === If no knobs, set default knobs =================================== */ - - if (!knobs) - { - COLAMD_set_defaults (default_knobs) ; - knobs = default_knobs ; - } - - /* === Allocate count and mark ========================================== */ - - count = (Int *) ((*allocate) (n+1, sizeof (Int))) ; - if (!count) - { - stats [COLAMD_STATUS] = COLAMD_ERROR_out_of_memory ; - DEBUG0 (("symamd: allocate count (size %d) failed\n", n+1)) ; - return (FALSE) ; - } - - mark = (Int *) ((*allocate) (n+1, sizeof (Int))) ; - if (!mark) - { - stats [COLAMD_STATUS] = COLAMD_ERROR_out_of_memory ; - (*release) ((void *) count) ; - DEBUG0 (("symamd: allocate mark (size %d) failed\n", n+1)) ; - return (FALSE) ; - } - - /* === Compute column counts of M, check if A is valid ================== */ - - stats [COLAMD_INFO3] = 0 ; /* number of duplicate or unsorted row indices*/ - - for (i = 0 ; i < n ; i++) - { - mark [i] = -1 ; - } - - for (j = 0 ; j < n ; j++) - { - last_row = -1 ; - - length = p [j+1] - p [j] ; - if (length < 0) - { - /* column pointers must be non-decreasing */ - stats [COLAMD_STATUS] = COLAMD_ERROR_col_length_negative ; - stats [COLAMD_INFO1] = j ; - stats [COLAMD_INFO2] = length ; - (*release) ((void *) count) ; - (*release) ((void *) mark) ; - DEBUG0 (("symamd: col %d negative length %d\n", j, length)) ; - return (FALSE) ; - } - - for (pp = p [j] ; pp < p [j+1] ; pp++) - { - i = A [pp] ; - if (i < 0 || i >= n) - { - /* row index i, in column j, is out of bounds */ - stats [COLAMD_STATUS] = COLAMD_ERROR_row_index_out_of_bounds ; - stats [COLAMD_INFO1] = j ; - stats [COLAMD_INFO2] = i ; - stats [COLAMD_INFO3] = n ; - (*release) ((void *) count) ; - (*release) ((void *) mark) ; - DEBUG0 (("symamd: row %d col %d out of bounds\n", i, j)) ; - return (FALSE) ; - } - - if (i <= last_row || mark [i] == j) - { - /* row index is unsorted or repeated (or both), thus col */ - /* is jumbled. This is a notice, not an error condition. */ - stats [COLAMD_STATUS] = COLAMD_OK_BUT_JUMBLED ; - stats [COLAMD_INFO1] = j ; - stats [COLAMD_INFO2] = i ; - (stats [COLAMD_INFO3]) ++ ; - DEBUG1 (("symamd: row %d col %d unsorted/duplicate\n", i, j)) ; - } - - if (i > j && mark [i] != j) - { - /* row k of M will contain column indices i and j */ - count [i]++ ; - count [j]++ ; - } - - /* mark the row as having been seen in this column */ - mark [i] = j ; - - last_row = i ; - } - } - - /* v2.4: removed free(mark) */ - - /* === Compute column pointers of M ===================================== */ - - /* use output permutation, perm, for column pointers of M */ - perm [0] = 0 ; - for (j = 1 ; j <= n ; j++) - { - perm [j] = perm [j-1] + count [j-1] ; - } - for (j = 0 ; j < n ; j++) - { - count [j] = perm [j] ; - } - - /* === Construct M ====================================================== */ - - mnz = perm [n] ; - n_row = mnz / 2 ; - Mlen = COLAMD_recommended (mnz, n_row, n) ; - M = (Int *) ((*allocate) (Mlen, sizeof (Int))) ; - DEBUG0 (("symamd: M is %d-by-%d with %d entries, Mlen = %g\n", - n_row, n, mnz, (double) Mlen)) ; - - if (!M) - { - stats [COLAMD_STATUS] = COLAMD_ERROR_out_of_memory ; - (*release) ((void *) count) ; - (*release) ((void *) mark) ; - DEBUG0 (("symamd: allocate M (size %g) failed\n", (double) Mlen)) ; - return (FALSE) ; - } - - k = 0 ; - - if (stats [COLAMD_STATUS] == COLAMD_OK) - { - /* Matrix is OK */ - for (j = 0 ; j < n ; j++) - { - ASSERT (p [j+1] - p [j] >= 0) ; - for (pp = p [j] ; pp < p [j+1] ; pp++) - { - i = A [pp] ; - ASSERT (i >= 0 && i < n) ; - if (i > j) - { - /* row k of M contains column indices i and j */ - M [count [i]++] = k ; - M [count [j]++] = k ; - k++ ; - } - } - } - } - else - { - /* Matrix is jumbled. Do not add duplicates to M. Unsorted cols OK. */ - DEBUG0 (("symamd: Duplicates in A.\n")) ; - for (i = 0 ; i < n ; i++) - { - mark [i] = -1 ; - } - for (j = 0 ; j < n ; j++) - { - ASSERT (p [j+1] - p [j] >= 0) ; - for (pp = p [j] ; pp < p [j+1] ; pp++) - { - i = A [pp] ; - ASSERT (i >= 0 && i < n) ; - if (i > j && mark [i] != j) - { - /* row k of M contains column indices i and j */ - M [count [i]++] = k ; - M [count [j]++] = k ; - k++ ; - mark [i] = j ; - } - } - } - /* v2.4: free(mark) moved below */ - } - - /* count and mark no longer needed */ - (*release) ((void *) count) ; - (*release) ((void *) mark) ; /* v2.4: free (mark) moved here */ - ASSERT (k == n_row) ; - - /* === Adjust the knobs for M =========================================== */ - - for (i = 0 ; i < COLAMD_KNOBS ; i++) - { - cknobs [i] = knobs [i] ; - } - - /* there are no dense rows in M */ - cknobs [COLAMD_DENSE_ROW] = -1 ; - cknobs [COLAMD_DENSE_COL] = knobs [COLAMD_DENSE_ROW] ; - - /* === Order the columns of M =========================================== */ - - /* v2.4: colamd cannot fail here, so the error check is removed */ - (void) COLAMD_MAIN (n_row, n, (Int) Mlen, M, perm, cknobs, stats) ; - - /* Note that the output permutation is now in perm */ - - /* === get the statistics for symamd from colamd ======================== */ - - /* a dense column in colamd means a dense row and col in symamd */ - stats [COLAMD_DENSE_ROW] = stats [COLAMD_DENSE_COL] ; - - /* === Free M =========================================================== */ - - (*release) ((void *) M) ; - DEBUG0 (("symamd: done.\n")) ; - return (TRUE) ; - -} - -/* ========================================================================== */ -/* === colamd =============================================================== */ -/* ========================================================================== */ - -/* - The colamd routine computes a column ordering Q of a sparse matrix - A such that the LU factorization P(AQ) = LU remains sparse, where P is - selected via partial pivoting. The routine can also be viewed as - providing a permutation Q such that the Cholesky factorization - (AQ)'(AQ) = LL' remains sparse. -*/ - -PUBLIC Int COLAMD_MAIN /* returns TRUE if successful, FALSE otherwise*/ -( - /* === Parameters ======================================================= */ - - Int n_row, /* number of rows in A */ - Int n_col, /* number of columns in A */ - Int Alen, /* length of A */ - Int A [], /* row indices of A */ - Int p [], /* pointers to columns in A */ - double knobs [COLAMD_KNOBS],/* parameters (uses defaults if NULL) */ - Int stats [COLAMD_STATS] /* output statistics and error codes */ -) -{ - /* === Local variables ================================================== */ - - Int i ; /* loop index */ - Int nnz ; /* nonzeros in A */ - size_t Row_size ; /* size of Row [], in integers */ - size_t Col_size ; /* size of Col [], in integers */ - size_t need ; /* minimum required length of A */ - Colamd_Row *Row ; /* pointer into A of Row [0..n_row] array */ - Colamd_Col *Col ; /* pointer into A of Col [0..n_col] array */ - Int n_col2 ; /* number of non-dense, non-empty columns */ - Int n_row2 ; /* number of non-dense, non-empty rows */ - Int ngarbage ; /* number of garbage collections performed */ - Int max_deg ; /* maximum row degree */ - double default_knobs [COLAMD_KNOBS] ; /* default knobs array */ - Int aggressive ; /* do aggressive absorption */ - int ok ; - -#ifndef NDEBUG - colamd_get_debug ("colamd") ; -#endif /* NDEBUG */ - - /* === Check the input arguments ======================================== */ - - if (!stats) - { - DEBUG0 (("colamd: stats not present\n")) ; - return (FALSE) ; - } - for (i = 0 ; i < COLAMD_STATS ; i++) - { - stats [i] = 0 ; - } - stats [COLAMD_STATUS] = COLAMD_OK ; - stats [COLAMD_INFO1] = -1 ; - stats [COLAMD_INFO2] = -1 ; - - if (!A) /* A is not present */ - { - stats [COLAMD_STATUS] = COLAMD_ERROR_A_not_present ; - DEBUG0 (("colamd: A not present\n")) ; - return (FALSE) ; - } - - if (!p) /* p is not present */ - { - stats [COLAMD_STATUS] = COLAMD_ERROR_p_not_present ; - DEBUG0 (("colamd: p not present\n")) ; - return (FALSE) ; - } - - if (n_row < 0) /* n_row must be >= 0 */ - { - stats [COLAMD_STATUS] = COLAMD_ERROR_nrow_negative ; - stats [COLAMD_INFO1] = n_row ; - DEBUG0 (("colamd: nrow negative %d\n", n_row)) ; - return (FALSE) ; - } - - if (n_col < 0) /* n_col must be >= 0 */ - { - stats [COLAMD_STATUS] = COLAMD_ERROR_ncol_negative ; - stats [COLAMD_INFO1] = n_col ; - DEBUG0 (("colamd: ncol negative %d\n", n_col)) ; - return (FALSE) ; - } - - nnz = p [n_col] ; - if (nnz < 0) /* nnz must be >= 0 */ - { - stats [COLAMD_STATUS] = COLAMD_ERROR_nnz_negative ; - stats [COLAMD_INFO1] = nnz ; - DEBUG0 (("colamd: number of entries negative %d\n", nnz)) ; - return (FALSE) ; - } - - if (p [0] != 0) - { - stats [COLAMD_STATUS] = COLAMD_ERROR_p0_nonzero ; - stats [COLAMD_INFO1] = p [0] ; - DEBUG0 (("colamd: p[0] not zero %d\n", p [0])) ; - return (FALSE) ; - } - - /* === If no knobs, set default knobs =================================== */ - - if (!knobs) - { - COLAMD_set_defaults (default_knobs) ; - knobs = default_knobs ; - } - - aggressive = (knobs [COLAMD_AGGRESSIVE] != FALSE) ; - - /* === Allocate the Row and Col arrays from array A ===================== */ - - ok = TRUE ; - Col_size = COLAMD_C (n_col, &ok) ; /* size of Col array of structs */ - Row_size = COLAMD_R (n_row, &ok) ; /* size of Row array of structs */ - - /* need = 2*nnz + n_col + Col_size + Row_size ; */ - need = t_mult (nnz, 2, &ok) ; - need = t_add (need, n_col, &ok) ; - need = t_add (need, Col_size, &ok) ; - need = t_add (need, Row_size, &ok) ; - - if (!ok || need > (size_t) Alen || need > Int_MAX) - { - /* not enough space in array A to perform the ordering */ - stats [COLAMD_STATUS] = COLAMD_ERROR_A_too_small ; - stats [COLAMD_INFO1] = need ; - stats [COLAMD_INFO2] = Alen ; - DEBUG0 (("colamd: Need Alen >= %d, given only Alen = %d\n", need,Alen)); - return (FALSE) ; - } - - Alen -= Col_size + Row_size ; - Col = (Colamd_Col *) &A [Alen] ; - Row = (Colamd_Row *) &A [Alen + Col_size] ; - - /* === Construct the row and column data structures ===================== */ - - if (!init_rows_cols (n_row, n_col, Row, Col, A, p, stats)) - { - /* input matrix is invalid */ - DEBUG0 (("colamd: Matrix invalid\n")) ; - return (FALSE) ; - } - - /* === Initialize scores, kill dense rows/columns ======================= */ - - init_scoring (n_row, n_col, Row, Col, A, p, knobs, - &n_row2, &n_col2, &max_deg) ; - - /* === Order the supercolumns =========================================== */ - - ngarbage = find_ordering (n_row, n_col, Alen, Row, Col, A, p, - n_col2, max_deg, 2*nnz, aggressive) ; - - /* === Order the non-principal columns ================================== */ - - order_children (n_col, Col, p) ; - - /* === Return statistics in stats ======================================= */ - - stats [COLAMD_DENSE_ROW] = n_row - n_row2 ; - stats [COLAMD_DENSE_COL] = n_col - n_col2 ; - stats [COLAMD_DEFRAG_COUNT] = ngarbage ; - DEBUG0 (("colamd: done.\n")) ; - return (TRUE) ; -} - - -/* ========================================================================== */ -/* === colamd_report ======================================================== */ -/* ========================================================================== */ - -PUBLIC void COLAMD_report -( - Int stats [COLAMD_STATS] -) -{ - print_report ("colamd", stats) ; -} - - -/* ========================================================================== */ -/* === symamd_report ======================================================== */ -/* ========================================================================== */ - -PUBLIC void SYMAMD_report -( - Int stats [COLAMD_STATS] -) -{ - print_report ("symamd", stats) ; -} - - - -/* ========================================================================== */ -/* === NON-USER-CALLABLE ROUTINES: ========================================== */ -/* ========================================================================== */ - -/* There are no user-callable routines beyond this point in the file */ - - -/* ========================================================================== */ -/* === init_rows_cols ======================================================= */ -/* ========================================================================== */ - -/* - Takes the column form of the matrix in A and creates the row form of the - matrix. Also, row and column attributes are stored in the Col and Row - structs. If the columns are un-sorted or contain duplicate row indices, - this routine will also sort and remove duplicate row indices from the - column form of the matrix. Returns FALSE if the matrix is invalid, - TRUE otherwise. Not user-callable. -*/ - -PRIVATE Int init_rows_cols /* returns TRUE if OK, or FALSE otherwise */ -( - /* === Parameters ======================================================= */ - - Int n_row, /* number of rows of A */ - Int n_col, /* number of columns of A */ - Colamd_Row Row [], /* of size n_row+1 */ - Colamd_Col Col [], /* of size n_col+1 */ - Int A [], /* row indices of A, of size Alen */ - Int p [], /* pointers to columns in A, of size n_col+1 */ - Int stats [COLAMD_STATS] /* colamd statistics */ -) -{ - /* === Local variables ================================================== */ - - Int col ; /* a column index */ - Int row ; /* a row index */ - Int *cp ; /* a column pointer */ - Int *cp_end ; /* a pointer to the end of a column */ - Int *rp ; /* a row pointer */ - Int *rp_end ; /* a pointer to the end of a row */ - Int last_row ; /* previous row */ - - /* === Initialize columns, and check column pointers ==================== */ - - for (col = 0 ; col < n_col ; col++) - { - Col [col].start = p [col] ; - Col [col].length = p [col+1] - p [col] ; - - if (Col [col].length < 0) - { - /* column pointers must be non-decreasing */ - stats [COLAMD_STATUS] = COLAMD_ERROR_col_length_negative ; - stats [COLAMD_INFO1] = col ; - stats [COLAMD_INFO2] = Col [col].length ; - DEBUG0 (("colamd: col %d length %d < 0\n", col, Col [col].length)) ; - return (FALSE) ; - } - - Col [col].shared1.thickness = 1 ; - Col [col].shared2.score = 0 ; - Col [col].shared3.prev = EMPTY ; - Col [col].shared4.degree_next = EMPTY ; - } - - /* p [0..n_col] no longer needed, used as "head" in subsequent routines */ - - /* === Scan columns, compute row degrees, and check row indices ========= */ - - stats [COLAMD_INFO3] = 0 ; /* number of duplicate or unsorted row indices*/ - - for (row = 0 ; row < n_row ; row++) - { - Row [row].length = 0 ; - Row [row].shared2.mark = -1 ; - } - - for (col = 0 ; col < n_col ; col++) - { - last_row = -1 ; - - cp = &A [p [col]] ; - cp_end = &A [p [col+1]] ; - - while (cp < cp_end) - { - row = *cp++ ; - - /* make sure row indices within range */ - if (row < 0 || row >= n_row) - { - stats [COLAMD_STATUS] = COLAMD_ERROR_row_index_out_of_bounds ; - stats [COLAMD_INFO1] = col ; - stats [COLAMD_INFO2] = row ; - stats [COLAMD_INFO3] = n_row ; - DEBUG0 (("colamd: row %d col %d out of bounds\n", row, col)) ; - return (FALSE) ; - } - - if (row <= last_row || Row [row].shared2.mark == col) - { - /* row index are unsorted or repeated (or both), thus col */ - /* is jumbled. This is a notice, not an error condition. */ - stats [COLAMD_STATUS] = COLAMD_OK_BUT_JUMBLED ; - stats [COLAMD_INFO1] = col ; - stats [COLAMD_INFO2] = row ; - (stats [COLAMD_INFO3]) ++ ; - DEBUG1 (("colamd: row %d col %d unsorted/duplicate\n",row,col)); - } - - if (Row [row].shared2.mark != col) - { - Row [row].length++ ; - } - else - { - /* this is a repeated entry in the column, */ - /* it will be removed */ - Col [col].length-- ; - } - - /* mark the row as having been seen in this column */ - Row [row].shared2.mark = col ; - - last_row = row ; - } - } - - /* === Compute row pointers ============================================= */ - - /* row form of the matrix starts directly after the column */ - /* form of matrix in A */ - Row [0].start = p [n_col] ; - Row [0].shared1.p = Row [0].start ; - Row [0].shared2.mark = -1 ; - for (row = 1 ; row < n_row ; row++) - { - Row [row].start = Row [row-1].start + Row [row-1].length ; - Row [row].shared1.p = Row [row].start ; - Row [row].shared2.mark = -1 ; - } - - /* === Create row form ================================================== */ - - if (stats [COLAMD_STATUS] == COLAMD_OK_BUT_JUMBLED) - { - /* if cols jumbled, watch for repeated row indices */ - for (col = 0 ; col < n_col ; col++) - { - cp = &A [p [col]] ; - cp_end = &A [p [col+1]] ; - while (cp < cp_end) - { - row = *cp++ ; - if (Row [row].shared2.mark != col) - { - A [(Row [row].shared1.p)++] = col ; - Row [row].shared2.mark = col ; - } - } - } - } - else - { - /* if cols not jumbled, we don't need the mark (this is faster) */ - for (col = 0 ; col < n_col ; col++) - { - cp = &A [p [col]] ; - cp_end = &A [p [col+1]] ; - while (cp < cp_end) - { - A [(Row [*cp++].shared1.p)++] = col ; - } - } - } - - /* === Clear the row marks and set row degrees ========================== */ - - for (row = 0 ; row < n_row ; row++) - { - Row [row].shared2.mark = 0 ; - Row [row].shared1.degree = Row [row].length ; - } - - /* === See if we need to re-create columns ============================== */ - - if (stats [COLAMD_STATUS] == COLAMD_OK_BUT_JUMBLED) - { - DEBUG0 (("colamd: reconstructing column form, matrix jumbled\n")) ; - -#ifndef NDEBUG - /* make sure column lengths are correct */ - for (col = 0 ; col < n_col ; col++) - { - p [col] = Col [col].length ; - } - for (row = 0 ; row < n_row ; row++) - { - rp = &A [Row [row].start] ; - rp_end = rp + Row [row].length ; - while (rp < rp_end) - { - p [*rp++]-- ; - } - } - for (col = 0 ; col < n_col ; col++) - { - ASSERT (p [col] == 0) ; - } - /* now p is all zero (different than when debugging is turned off) */ -#endif /* NDEBUG */ - - /* === Compute col pointers ========================================= */ - - /* col form of the matrix starts at A [0]. */ - /* Note, we may have a gap between the col form and the row */ - /* form if there were duplicate entries, if so, it will be */ - /* removed upon the first garbage collection */ - Col [0].start = 0 ; - p [0] = Col [0].start ; - for (col = 1 ; col < n_col ; col++) - { - /* note that the lengths here are for pruned columns, i.e. */ - /* no duplicate row indices will exist for these columns */ - Col [col].start = Col [col-1].start + Col [col-1].length ; - p [col] = Col [col].start ; - } - - /* === Re-create col form =========================================== */ - - for (row = 0 ; row < n_row ; row++) - { - rp = &A [Row [row].start] ; - rp_end = rp + Row [row].length ; - while (rp < rp_end) - { - A [(p [*rp++])++] = row ; - } - } - } - - /* === Done. Matrix is not (or no longer) jumbled ====================== */ - - return (TRUE) ; -} - - -/* ========================================================================== */ -/* === init_scoring ========================================================= */ -/* ========================================================================== */ - -/* - Kills dense or empty columns and rows, calculates an initial score for - each column, and places all columns in the degree lists. Not user-callable. -*/ - -PRIVATE void init_scoring -( - /* === Parameters ======================================================= */ - - Int n_row, /* number of rows of A */ - Int n_col, /* number of columns of A */ - Colamd_Row Row [], /* of size n_row+1 */ - Colamd_Col Col [], /* of size n_col+1 */ - Int A [], /* column form and row form of A */ - Int head [], /* of size n_col+1 */ - double knobs [COLAMD_KNOBS],/* parameters */ - Int *p_n_row2, /* number of non-dense, non-empty rows */ - Int *p_n_col2, /* number of non-dense, non-empty columns */ - Int *p_max_deg /* maximum row degree */ -) -{ - /* === Local variables ================================================== */ - - Int c ; /* a column index */ - Int r, row ; /* a row index */ - Int *cp ; /* a column pointer */ - Int deg ; /* degree of a row or column */ - Int *cp_end ; /* a pointer to the end of a column */ - Int *new_cp ; /* new column pointer */ - Int col_length ; /* length of pruned column */ - Int score ; /* current column score */ - Int n_col2 ; /* number of non-dense, non-empty columns */ - Int n_row2 ; /* number of non-dense, non-empty rows */ - Int dense_row_count ; /* remove rows with more entries than this */ - Int dense_col_count ; /* remove cols with more entries than this */ - Int min_score ; /* smallest column score */ - Int max_deg ; /* maximum row degree */ - Int next_col ; /* Used to add to degree list.*/ - -#ifndef NDEBUG - Int debug_count ; /* debug only. */ -#endif /* NDEBUG */ - - /* === Extract knobs ==================================================== */ - - /* Note: if knobs contains a NaN, this is undefined: */ - if (knobs [COLAMD_DENSE_ROW] < 0) - { - /* only remove completely dense rows */ - dense_row_count = n_col-1 ; - } - else - { - dense_row_count = DENSE_DEGREE (knobs [COLAMD_DENSE_ROW], n_col) ; - } - if (knobs [COLAMD_DENSE_COL] < 0) - { - /* only remove completely dense columns */ - dense_col_count = n_row-1 ; - } - else - { - dense_col_count = - DENSE_DEGREE (knobs [COLAMD_DENSE_COL], MIN (n_row, n_col)) ; - } - - DEBUG1 (("colamd: densecount: %d %d\n", dense_row_count, dense_col_count)) ; - max_deg = 0 ; - n_col2 = n_col ; - n_row2 = n_row ; - - /* === Kill empty columns =============================================== */ - - /* Put the empty columns at the end in their natural order, so that LU */ - /* factorization can proceed as far as possible. */ - for (c = n_col-1 ; c >= 0 ; c--) - { - deg = Col [c].length ; - if (deg == 0) - { - /* this is a empty column, kill and order it last */ - Col [c].shared2.order = --n_col2 ; - KILL_PRINCIPAL_COL (c) ; - } - } - DEBUG1 (("colamd: null columns killed: %d\n", n_col - n_col2)) ; - - /* === Kill dense columns =============================================== */ - - /* Put the dense columns at the end, in their natural order */ - for (c = n_col-1 ; c >= 0 ; c--) - { - /* skip any dead columns */ - if (COL_IS_DEAD (c)) - { - continue ; - } - deg = Col [c].length ; - if (deg > dense_col_count) - { - /* this is a dense column, kill and order it last */ - Col [c].shared2.order = --n_col2 ; - /* decrement the row degrees */ - cp = &A [Col [c].start] ; - cp_end = cp + Col [c].length ; - while (cp < cp_end) - { - Row [*cp++].shared1.degree-- ; - } - KILL_PRINCIPAL_COL (c) ; - } - } - DEBUG1 (("colamd: Dense and null columns killed: %d\n", n_col - n_col2)) ; - - /* === Kill dense and empty rows ======================================== */ - - for (r = 0 ; r < n_row ; r++) - { - deg = Row [r].shared1.degree ; - ASSERT (deg >= 0 && deg <= n_col) ; - if (deg > dense_row_count || deg == 0) - { - /* kill a dense or empty row */ - KILL_ROW (r) ; - --n_row2 ; - } - else - { - /* keep track of max degree of remaining rows */ - max_deg = MAX (max_deg, deg) ; - } - } - DEBUG1 (("colamd: Dense and null rows killed: %d\n", n_row - n_row2)) ; - - /* === Compute initial column scores ==================================== */ - - /* At this point the row degrees are accurate. They reflect the number */ - /* of "live" (non-dense) columns in each row. No empty rows exist. */ - /* Some "live" columns may contain only dead rows, however. These are */ - /* pruned in the code below. */ - - /* now find the initial matlab score for each column */ - for (c = n_col-1 ; c >= 0 ; c--) - { - /* skip dead column */ - if (COL_IS_DEAD (c)) - { - continue ; - } - score = 0 ; - cp = &A [Col [c].start] ; - new_cp = cp ; - cp_end = cp + Col [c].length ; - while (cp < cp_end) - { - /* get a row */ - row = *cp++ ; - /* skip if dead */ - if (ROW_IS_DEAD (row)) - { - continue ; - } - /* compact the column */ - *new_cp++ = row ; - /* add row's external degree */ - score += Row [row].shared1.degree - 1 ; - /* guard against integer overflow */ - score = MIN (score, n_col) ; - } - /* determine pruned column length */ - col_length = (Int) (new_cp - &A [Col [c].start]) ; - if (col_length == 0) - { - /* a newly-made null column (all rows in this col are "dense" */ - /* and have already been killed) */ - DEBUG2 (("Newly null killed: %d\n", c)) ; - Col [c].shared2.order = --n_col2 ; - KILL_PRINCIPAL_COL (c) ; - } - else - { - /* set column length and set score */ - ASSERT (score >= 0) ; - ASSERT (score <= n_col) ; - Col [c].length = col_length ; - Col [c].shared2.score = score ; - } - } - DEBUG1 (("colamd: Dense, null, and newly-null columns killed: %d\n", - n_col-n_col2)) ; - - /* At this point, all empty rows and columns are dead. All live columns */ - /* are "clean" (containing no dead rows) and simplicial (no supercolumns */ - /* yet). Rows may contain dead columns, but all live rows contain at */ - /* least one live column. */ - -#ifndef NDEBUG - debug_structures (n_row, n_col, Row, Col, A, n_col2) ; -#endif /* NDEBUG */ - - /* === Initialize degree lists ========================================== */ - -#ifndef NDEBUG - debug_count = 0 ; -#endif /* NDEBUG */ - - /* clear the hash buckets */ - for (c = 0 ; c <= n_col ; c++) - { - head [c] = EMPTY ; - } - min_score = n_col ; - /* place in reverse order, so low column indices are at the front */ - /* of the lists. This is to encourage natural tie-breaking */ - for (c = n_col-1 ; c >= 0 ; c--) - { - /* only add principal columns to degree lists */ - if (COL_IS_ALIVE (c)) - { - DEBUG4 (("place %d score %d minscore %d ncol %d\n", - c, Col [c].shared2.score, min_score, n_col)) ; - - /* === Add columns score to DList =============================== */ - - score = Col [c].shared2.score ; - - ASSERT (min_score >= 0) ; - ASSERT (min_score <= n_col) ; - ASSERT (score >= 0) ; - ASSERT (score <= n_col) ; - ASSERT (head [score] >= EMPTY) ; - - /* now add this column to dList at proper score location */ - next_col = head [score] ; - Col [c].shared3.prev = EMPTY ; - Col [c].shared4.degree_next = next_col ; - - /* if there already was a column with the same score, set its */ - /* previous pointer to this new column */ - if (next_col != EMPTY) - { - Col [next_col].shared3.prev = c ; - } - head [score] = c ; - - /* see if this score is less than current min */ - min_score = MIN (min_score, score) ; - -#ifndef NDEBUG - debug_count++ ; -#endif /* NDEBUG */ - - } - } - -#ifndef NDEBUG - DEBUG1 (("colamd: Live cols %d out of %d, non-princ: %d\n", - debug_count, n_col, n_col-debug_count)) ; - ASSERT (debug_count == n_col2) ; - debug_deg_lists (n_row, n_col, Row, Col, head, min_score, n_col2, max_deg) ; -#endif /* NDEBUG */ - - /* === Return number of remaining columns, and max row degree =========== */ - - *p_n_col2 = n_col2 ; - *p_n_row2 = n_row2 ; - *p_max_deg = max_deg ; -} - - -/* ========================================================================== */ -/* === find_ordering ======================================================== */ -/* ========================================================================== */ - -/* - Order the principal columns of the supercolumn form of the matrix - (no supercolumns on input). Uses a minimum approximate column minimum - degree ordering method. Not user-callable. -*/ - -PRIVATE Int find_ordering /* return the number of garbage collections */ -( - /* === Parameters ======================================================= */ - - Int n_row, /* number of rows of A */ - Int n_col, /* number of columns of A */ - Int Alen, /* size of A, 2*nnz + n_col or larger */ - Colamd_Row Row [], /* of size n_row+1 */ - Colamd_Col Col [], /* of size n_col+1 */ - Int A [], /* column form and row form of A */ - Int head [], /* of size n_col+1 */ - Int n_col2, /* Remaining columns to order */ - Int max_deg, /* Maximum row degree */ - Int pfree, /* index of first free slot (2*nnz on entry) */ - Int aggressive -) -{ - /* === Local variables ================================================== */ - - Int k ; /* current pivot ordering step */ - Int pivot_col ; /* current pivot column */ - Int *cp ; /* a column pointer */ - Int *rp ; /* a row pointer */ - Int pivot_row ; /* current pivot row */ - Int *new_cp ; /* modified column pointer */ - Int *new_rp ; /* modified row pointer */ - Int pivot_row_start ; /* pointer to start of pivot row */ - Int pivot_row_degree ; /* number of columns in pivot row */ - Int pivot_row_length ; /* number of supercolumns in pivot row */ - Int pivot_col_score ; /* score of pivot column */ - Int needed_memory ; /* free space needed for pivot row */ - Int *cp_end ; /* pointer to the end of a column */ - Int *rp_end ; /* pointer to the end of a row */ - Int row ; /* a row index */ - Int col ; /* a column index */ - Int max_score ; /* maximum possible score */ - Int cur_score ; /* score of current column */ - unsigned Int hash ; /* hash value for supernode detection */ - Int head_column ; /* head of hash bucket */ - Int first_col ; /* first column in hash bucket */ - Int tag_mark ; /* marker value for mark array */ - Int row_mark ; /* Row [row].shared2.mark */ - Int set_difference ; /* set difference size of row with pivot row */ - Int min_score ; /* smallest column score */ - Int col_thickness ; /* "thickness" (no. of columns in a supercol) */ - Int max_mark ; /* maximum value of tag_mark */ - Int pivot_col_thickness ; /* number of columns represented by pivot col */ - Int prev_col ; /* Used by Dlist operations. */ - Int next_col ; /* Used by Dlist operations. */ - Int ngarbage ; /* number of garbage collections performed */ - -#ifndef NDEBUG - Int debug_d ; /* debug loop counter */ - Int debug_step = 0 ; /* debug loop counter */ -#endif /* NDEBUG */ - - /* === Initialization and clear mark ==================================== */ - - max_mark = INT_MAX - n_col ; /* INT_MAX defined in */ - tag_mark = clear_mark (0, max_mark, n_row, Row) ; - min_score = 0 ; - ngarbage = 0 ; - DEBUG1 (("colamd: Ordering, n_col2=%d\n", n_col2)) ; - - /* === Order the columns ================================================ */ - - for (k = 0 ; k < n_col2 ; /* 'k' is incremented below */) - { - -#ifndef NDEBUG - if (debug_step % 100 == 0) - { - DEBUG2 (("\n... Step k: %d out of n_col2: %d\n", k, n_col2)) ; - } - else - { - DEBUG3 (("\n----------Step k: %d out of n_col2: %d\n", k, n_col2)) ; - } - debug_step++ ; - debug_deg_lists (n_row, n_col, Row, Col, head, - min_score, n_col2-k, max_deg) ; - debug_matrix (n_row, n_col, Row, Col, A) ; -#endif /* NDEBUG */ - - /* === Select pivot column, and order it ============================ */ - - /* make sure degree list isn't empty */ - ASSERT (min_score >= 0) ; - ASSERT (min_score <= n_col) ; - ASSERT (head [min_score] >= EMPTY) ; - -#ifndef NDEBUG - for (debug_d = 0 ; debug_d < min_score ; debug_d++) - { - ASSERT (head [debug_d] == EMPTY) ; - } -#endif /* NDEBUG */ - - /* get pivot column from head of minimum degree list */ - while (head [min_score] == EMPTY && min_score < n_col) - { - min_score++ ; - } - pivot_col = head [min_score] ; - ASSERT (pivot_col >= 0 && pivot_col <= n_col) ; - next_col = Col [pivot_col].shared4.degree_next ; - head [min_score] = next_col ; - if (next_col != EMPTY) - { - Col [next_col].shared3.prev = EMPTY ; - } - - ASSERT (COL_IS_ALIVE (pivot_col)) ; - - /* remember score for defrag check */ - pivot_col_score = Col [pivot_col].shared2.score ; - - /* the pivot column is the kth column in the pivot order */ - Col [pivot_col].shared2.order = k ; - - /* increment order count by column thickness */ - pivot_col_thickness = Col [pivot_col].shared1.thickness ; - k += pivot_col_thickness ; - ASSERT (pivot_col_thickness > 0) ; - DEBUG3 (("Pivot col: %d thick %d\n", pivot_col, pivot_col_thickness)) ; - - /* === Garbage_collection, if necessary ============================= */ - - needed_memory = MIN (pivot_col_score, n_col - k) ; - if (pfree + needed_memory >= Alen) - { - pfree = garbage_collection (n_row, n_col, Row, Col, A, &A [pfree]) ; - ngarbage++ ; - /* after garbage collection we will have enough */ - ASSERT (pfree + needed_memory < Alen) ; - /* garbage collection has wiped out the Row[].shared2.mark array */ - tag_mark = clear_mark (0, max_mark, n_row, Row) ; - -#ifndef NDEBUG - debug_matrix (n_row, n_col, Row, Col, A) ; -#endif /* NDEBUG */ - } - - /* === Compute pivot row pattern ==================================== */ - - /* get starting location for this new merged row */ - pivot_row_start = pfree ; - - /* initialize new row counts to zero */ - pivot_row_degree = 0 ; - - /* tag pivot column as having been visited so it isn't included */ - /* in merged pivot row */ - Col [pivot_col].shared1.thickness = -pivot_col_thickness ; - - /* pivot row is the union of all rows in the pivot column pattern */ - cp = &A [Col [pivot_col].start] ; - cp_end = cp + Col [pivot_col].length ; - while (cp < cp_end) - { - /* get a row */ - row = *cp++ ; - DEBUG4 (("Pivot col pattern %d %d\n", ROW_IS_ALIVE (row), row)) ; - /* skip if row is dead */ - if (ROW_IS_ALIVE (row)) - { - rp = &A [Row [row].start] ; - rp_end = rp + Row [row].length ; - while (rp < rp_end) - { - /* get a column */ - col = *rp++ ; - /* add the column, if alive and untagged */ - col_thickness = Col [col].shared1.thickness ; - if (col_thickness > 0 && COL_IS_ALIVE (col)) - { - /* tag column in pivot row */ - Col [col].shared1.thickness = -col_thickness ; - ASSERT (pfree < Alen) ; - /* place column in pivot row */ - A [pfree++] = col ; - pivot_row_degree += col_thickness ; - } - } - } - } - - /* clear tag on pivot column */ - Col [pivot_col].shared1.thickness = pivot_col_thickness ; - max_deg = MAX (max_deg, pivot_row_degree) ; - -#ifndef NDEBUG - DEBUG3 (("check2\n")) ; - debug_mark (n_row, Row, tag_mark, max_mark) ; -#endif /* NDEBUG */ - - /* === Kill all rows used to construct pivot row ==================== */ - - /* also kill pivot row, temporarily */ - cp = &A [Col [pivot_col].start] ; - cp_end = cp + Col [pivot_col].length ; - while (cp < cp_end) - { - /* may be killing an already dead row */ - row = *cp++ ; - DEBUG3 (("Kill row in pivot col: %d\n", row)) ; - KILL_ROW (row) ; - } - - /* === Select a row index to use as the new pivot row =============== */ - - pivot_row_length = pfree - pivot_row_start ; - if (pivot_row_length > 0) - { - /* pick the "pivot" row arbitrarily (first row in col) */ - pivot_row = A [Col [pivot_col].start] ; - DEBUG3 (("Pivotal row is %d\n", pivot_row)) ; - } - else - { - /* there is no pivot row, since it is of zero length */ - pivot_row = EMPTY ; - ASSERT (pivot_row_length == 0) ; - } - ASSERT (Col [pivot_col].length > 0 || pivot_row_length == 0) ; - - /* === Approximate degree computation =============================== */ - - /* Here begins the computation of the approximate degree. The column */ - /* score is the sum of the pivot row "length", plus the size of the */ - /* set differences of each row in the column minus the pattern of the */ - /* pivot row itself. The column ("thickness") itself is also */ - /* excluded from the column score (we thus use an approximate */ - /* external degree). */ - - /* The time taken by the following code (compute set differences, and */ - /* add them up) is proportional to the size of the data structure */ - /* being scanned - that is, the sum of the sizes of each column in */ - /* the pivot row. Thus, the amortized time to compute a column score */ - /* is proportional to the size of that column (where size, in this */ - /* context, is the column "length", or the number of row indices */ - /* in that column). The number of row indices in a column is */ - /* monotonically non-decreasing, from the length of the original */ - /* column on input to colamd. */ - - /* === Compute set differences ====================================== */ - - DEBUG3 (("** Computing set differences phase. **\n")) ; - - /* pivot row is currently dead - it will be revived later. */ - - DEBUG3 (("Pivot row: ")) ; - /* for each column in pivot row */ - rp = &A [pivot_row_start] ; - rp_end = rp + pivot_row_length ; - while (rp < rp_end) - { - col = *rp++ ; - ASSERT (COL_IS_ALIVE (col) && col != pivot_col) ; - DEBUG3 (("Col: %d\n", col)) ; - - /* clear tags used to construct pivot row pattern */ - col_thickness = -Col [col].shared1.thickness ; - ASSERT (col_thickness > 0) ; - Col [col].shared1.thickness = col_thickness ; - - /* === Remove column from degree list =========================== */ - - cur_score = Col [col].shared2.score ; - prev_col = Col [col].shared3.prev ; - next_col = Col [col].shared4.degree_next ; - ASSERT (cur_score >= 0) ; - ASSERT (cur_score <= n_col) ; - ASSERT (cur_score >= EMPTY) ; - if (prev_col == EMPTY) - { - head [cur_score] = next_col ; - } - else - { - Col [prev_col].shared4.degree_next = next_col ; - } - if (next_col != EMPTY) - { - Col [next_col].shared3.prev = prev_col ; - } - - /* === Scan the column ========================================== */ - - cp = &A [Col [col].start] ; - cp_end = cp + Col [col].length ; - while (cp < cp_end) - { - /* get a row */ - row = *cp++ ; - row_mark = Row [row].shared2.mark ; - /* skip if dead */ - if (ROW_IS_MARKED_DEAD (row_mark)) - { - continue ; - } - ASSERT (row != pivot_row) ; - set_difference = row_mark - tag_mark ; - /* check if the row has been seen yet */ - if (set_difference < 0) - { - ASSERT (Row [row].shared1.degree <= max_deg) ; - set_difference = Row [row].shared1.degree ; - } - /* subtract column thickness from this row's set difference */ - set_difference -= col_thickness ; - ASSERT (set_difference >= 0) ; - /* absorb this row if the set difference becomes zero */ - if (set_difference == 0 && aggressive) - { - DEBUG3 (("aggressive absorption. Row: %d\n", row)) ; - KILL_ROW (row) ; - } - else - { - /* save the new mark */ - Row [row].shared2.mark = set_difference + tag_mark ; - } - } - } - -#ifndef NDEBUG - debug_deg_lists (n_row, n_col, Row, Col, head, - min_score, n_col2-k-pivot_row_degree, max_deg) ; -#endif /* NDEBUG */ - - /* === Add up set differences for each column ======================= */ - - DEBUG3 (("** Adding set differences phase. **\n")) ; - - /* for each column in pivot row */ - rp = &A [pivot_row_start] ; - rp_end = rp + pivot_row_length ; - while (rp < rp_end) - { - /* get a column */ - col = *rp++ ; - ASSERT (COL_IS_ALIVE (col) && col != pivot_col) ; - hash = 0 ; - cur_score = 0 ; - cp = &A [Col [col].start] ; - /* compact the column */ - new_cp = cp ; - cp_end = cp + Col [col].length ; - - DEBUG4 (("Adding set diffs for Col: %d.\n", col)) ; - - while (cp < cp_end) - { - /* get a row */ - row = *cp++ ; - ASSERT(row >= 0 && row < n_row) ; - row_mark = Row [row].shared2.mark ; - /* skip if dead */ - if (ROW_IS_MARKED_DEAD (row_mark)) - { - DEBUG4 ((" Row %d, dead\n", row)) ; - continue ; - } - DEBUG4 ((" Row %d, set diff %d\n", row, row_mark-tag_mark)); - ASSERT (row_mark >= tag_mark) ; - /* compact the column */ - *new_cp++ = row ; - /* compute hash function */ - hash += row ; - /* add set difference */ - cur_score += row_mark - tag_mark ; - /* integer overflow... */ - cur_score = MIN (cur_score, n_col) ; - } - - /* recompute the column's length */ - Col [col].length = (Int) (new_cp - &A [Col [col].start]) ; - - /* === Further mass elimination ================================= */ - - if (Col [col].length == 0) - { - DEBUG4 (("further mass elimination. Col: %d\n", col)) ; - /* nothing left but the pivot row in this column */ - KILL_PRINCIPAL_COL (col) ; - pivot_row_degree -= Col [col].shared1.thickness ; - ASSERT (pivot_row_degree >= 0) ; - /* order it */ - Col [col].shared2.order = k ; - /* increment order count by column thickness */ - k += Col [col].shared1.thickness ; - } - else - { - /* === Prepare for supercolumn detection ==================== */ - - DEBUG4 (("Preparing supercol detection for Col: %d.\n", col)) ; - - /* save score so far */ - Col [col].shared2.score = cur_score ; - - /* add column to hash table, for supercolumn detection */ - hash %= n_col + 1 ; - - DEBUG4 ((" Hash = %d, n_col = %d.\n", hash, n_col)) ; - ASSERT (((Int) hash) <= n_col) ; - - head_column = head [hash] ; - if (head_column > EMPTY) - { - /* degree list "hash" is non-empty, use prev (shared3) of */ - /* first column in degree list as head of hash bucket */ - first_col = Col [head_column].shared3.headhash ; - Col [head_column].shared3.headhash = col ; - } - else - { - /* degree list "hash" is empty, use head as hash bucket */ - first_col = - (head_column + 2) ; - head [hash] = - (col + 2) ; - } - Col [col].shared4.hash_next = first_col ; - - /* save hash function in Col [col].shared3.hash */ - Col [col].shared3.hash = (Int) hash ; - ASSERT (COL_IS_ALIVE (col)) ; - } - } - - /* The approximate external column degree is now computed. */ - - /* === Supercolumn detection ======================================== */ - - DEBUG3 (("** Supercolumn detection phase. **\n")) ; - - detect_super_cols ( - -#ifndef NDEBUG - n_col, Row, -#endif /* NDEBUG */ - - Col, A, head, pivot_row_start, pivot_row_length) ; - - /* === Kill the pivotal column ====================================== */ - - KILL_PRINCIPAL_COL (pivot_col) ; - - /* === Clear mark =================================================== */ - - tag_mark = clear_mark (tag_mark+max_deg+1, max_mark, n_row, Row) ; - -#ifndef NDEBUG - DEBUG3 (("check3\n")) ; - debug_mark (n_row, Row, tag_mark, max_mark) ; -#endif /* NDEBUG */ - - /* === Finalize the new pivot row, and column scores ================ */ - - DEBUG3 (("** Finalize scores phase. **\n")) ; - - /* for each column in pivot row */ - rp = &A [pivot_row_start] ; - /* compact the pivot row */ - new_rp = rp ; - rp_end = rp + pivot_row_length ; - while (rp < rp_end) - { - col = *rp++ ; - /* skip dead columns */ - if (COL_IS_DEAD (col)) - { - continue ; - } - *new_rp++ = col ; - /* add new pivot row to column */ - A [Col [col].start + (Col [col].length++)] = pivot_row ; - - /* retrieve score so far and add on pivot row's degree. */ - /* (we wait until here for this in case the pivot */ - /* row's degree was reduced due to mass elimination). */ - cur_score = Col [col].shared2.score + pivot_row_degree ; - - /* calculate the max possible score as the number of */ - /* external columns minus the 'k' value minus the */ - /* columns thickness */ - max_score = n_col - k - Col [col].shared1.thickness ; - - /* make the score the external degree of the union-of-rows */ - cur_score -= Col [col].shared1.thickness ; - - /* make sure score is less or equal than the max score */ - cur_score = MIN (cur_score, max_score) ; - ASSERT (cur_score >= 0) ; - - /* store updated score */ - Col [col].shared2.score = cur_score ; - - /* === Place column back in degree list ========================= */ - - ASSERT (min_score >= 0) ; - ASSERT (min_score <= n_col) ; - ASSERT (cur_score >= 0) ; - ASSERT (cur_score <= n_col) ; - ASSERT (head [cur_score] >= EMPTY) ; - next_col = head [cur_score] ; - Col [col].shared4.degree_next = next_col ; - Col [col].shared3.prev = EMPTY ; - if (next_col != EMPTY) - { - Col [next_col].shared3.prev = col ; - } - head [cur_score] = col ; - - /* see if this score is less than current min */ - min_score = MIN (min_score, cur_score) ; - - } - -#ifndef NDEBUG - debug_deg_lists (n_row, n_col, Row, Col, head, - min_score, n_col2-k, max_deg) ; -#endif /* NDEBUG */ - - /* === Resurrect the new pivot row ================================== */ - - if (pivot_row_degree > 0) - { - /* update pivot row length to reflect any cols that were killed */ - /* during super-col detection and mass elimination */ - Row [pivot_row].start = pivot_row_start ; - Row [pivot_row].length = (Int) (new_rp - &A[pivot_row_start]) ; - ASSERT (Row [pivot_row].length > 0) ; - Row [pivot_row].shared1.degree = pivot_row_degree ; - Row [pivot_row].shared2.mark = 0 ; - /* pivot row is no longer dead */ - - DEBUG1 (("Resurrect Pivot_row %d deg: %d\n", - pivot_row, pivot_row_degree)) ; - } - } - - /* === All principal columns have now been ordered ====================== */ - - return (ngarbage) ; -} - - -/* ========================================================================== */ -/* === order_children ======================================================= */ -/* ========================================================================== */ - -/* - The find_ordering routine has ordered all of the principal columns (the - representatives of the supercolumns). The non-principal columns have not - yet been ordered. This routine orders those columns by walking up the - parent tree (a column is a child of the column which absorbed it). The - final permutation vector is then placed in p [0 ... n_col-1], with p [0] - being the first column, and p [n_col-1] being the last. It doesn't look - like it at first glance, but be assured that this routine takes time linear - in the number of columns. Although not immediately obvious, the time - taken by this routine is O (n_col), that is, linear in the number of - columns. Not user-callable. -*/ - -PRIVATE void order_children -( - /* === Parameters ======================================================= */ - - Int n_col, /* number of columns of A */ - Colamd_Col Col [], /* of size n_col+1 */ - Int p [] /* p [0 ... n_col-1] is the column permutation*/ -) -{ - /* === Local variables ================================================== */ - - Int i ; /* loop counter for all columns */ - Int c ; /* column index */ - Int parent ; /* index of column's parent */ - Int order ; /* column's order */ - - /* === Order each non-principal column ================================== */ - - for (i = 0 ; i < n_col ; i++) - { - /* find an un-ordered non-principal column */ - ASSERT (COL_IS_DEAD (i)) ; - if (!COL_IS_DEAD_PRINCIPAL (i) && Col [i].shared2.order == EMPTY) - { - parent = i ; - /* once found, find its principal parent */ - do - { - parent = Col [parent].shared1.parent ; - } while (!COL_IS_DEAD_PRINCIPAL (parent)) ; - - /* now, order all un-ordered non-principal columns along path */ - /* to this parent. collapse tree at the same time */ - c = i ; - /* get order of parent */ - order = Col [parent].shared2.order ; - - do - { - ASSERT (Col [c].shared2.order == EMPTY) ; - - /* order this column */ - Col [c].shared2.order = order++ ; - /* collaps tree */ - Col [c].shared1.parent = parent ; - - /* get immediate parent of this column */ - c = Col [c].shared1.parent ; - - /* continue until we hit an ordered column. There are */ - /* guarranteed not to be anymore unordered columns */ - /* above an ordered column */ - } while (Col [c].shared2.order == EMPTY) ; - - /* re-order the super_col parent to largest order for this group */ - Col [parent].shared2.order = order ; - } - } - - /* === Generate the permutation ========================================= */ - - for (c = 0 ; c < n_col ; c++) - { - p [Col [c].shared2.order] = c ; - } -} - - -/* ========================================================================== */ -/* === detect_super_cols ==================================================== */ -/* ========================================================================== */ - -/* - Detects supercolumns by finding matches between columns in the hash buckets. - Check amongst columns in the set A [row_start ... row_start + row_length-1]. - The columns under consideration are currently *not* in the degree lists, - and have already been placed in the hash buckets. - - The hash bucket for columns whose hash function is equal to h is stored - as follows: - - if head [h] is >= 0, then head [h] contains a degree list, so: - - head [h] is the first column in degree bucket h. - Col [head [h]].headhash gives the first column in hash bucket h. - - otherwise, the degree list is empty, and: - - -(head [h] + 2) is the first column in hash bucket h. - - For a column c in a hash bucket, Col [c].shared3.prev is NOT a "previous - column" pointer. Col [c].shared3.hash is used instead as the hash number - for that column. The value of Col [c].shared4.hash_next is the next column - in the same hash bucket. - - Assuming no, or "few" hash collisions, the time taken by this routine is - linear in the sum of the sizes (lengths) of each column whose score has - just been computed in the approximate degree computation. - Not user-callable. -*/ - -PRIVATE void detect_super_cols -( - /* === Parameters ======================================================= */ - -#ifndef NDEBUG - /* these two parameters are only needed when debugging is enabled: */ - Int n_col, /* number of columns of A */ - Colamd_Row Row [], /* of size n_row+1 */ -#endif /* NDEBUG */ - - Colamd_Col Col [], /* of size n_col+1 */ - Int A [], /* row indices of A */ - Int head [], /* head of degree lists and hash buckets */ - Int row_start, /* pointer to set of columns to check */ - Int row_length /* number of columns to check */ -) -{ - /* === Local variables ================================================== */ - - Int hash ; /* hash value for a column */ - Int *rp ; /* pointer to a row */ - Int c ; /* a column index */ - Int super_c ; /* column index of the column to absorb into */ - Int *cp1 ; /* column pointer for column super_c */ - Int *cp2 ; /* column pointer for column c */ - Int length ; /* length of column super_c */ - Int prev_c ; /* column preceding c in hash bucket */ - Int i ; /* loop counter */ - Int *rp_end ; /* pointer to the end of the row */ - Int col ; /* a column index in the row to check */ - Int head_column ; /* first column in hash bucket or degree list */ - Int first_col ; /* first column in hash bucket */ - - /* === Consider each column in the row ================================== */ - - rp = &A [row_start] ; - rp_end = rp + row_length ; - while (rp < rp_end) - { - col = *rp++ ; - if (COL_IS_DEAD (col)) - { - continue ; - } - - /* get hash number for this column */ - hash = Col [col].shared3.hash ; - ASSERT (hash <= n_col) ; - - /* === Get the first column in this hash bucket ===================== */ - - head_column = head [hash] ; - if (head_column > EMPTY) - { - first_col = Col [head_column].shared3.headhash ; - } - else - { - first_col = - (head_column + 2) ; - } - - /* === Consider each column in the hash bucket ====================== */ - - for (super_c = first_col ; super_c != EMPTY ; - super_c = Col [super_c].shared4.hash_next) - { - ASSERT (COL_IS_ALIVE (super_c)) ; - ASSERT (Col [super_c].shared3.hash == hash) ; - length = Col [super_c].length ; - - /* prev_c is the column preceding column c in the hash bucket */ - prev_c = super_c ; - - /* === Compare super_c with all columns after it ================ */ - - for (c = Col [super_c].shared4.hash_next ; - c != EMPTY ; c = Col [c].shared4.hash_next) - { - ASSERT (c != super_c) ; - ASSERT (COL_IS_ALIVE (c)) ; - ASSERT (Col [c].shared3.hash == hash) ; - - /* not identical if lengths or scores are different */ - if (Col [c].length != length || - Col [c].shared2.score != Col [super_c].shared2.score) - { - prev_c = c ; - continue ; - } - - /* compare the two columns */ - cp1 = &A [Col [super_c].start] ; - cp2 = &A [Col [c].start] ; - - for (i = 0 ; i < length ; i++) - { - /* the columns are "clean" (no dead rows) */ - ASSERT (ROW_IS_ALIVE (*cp1)) ; - ASSERT (ROW_IS_ALIVE (*cp2)) ; - /* row indices will same order for both supercols, */ - /* no gather scatter nessasary */ - if (*cp1++ != *cp2++) - { - break ; - } - } - - /* the two columns are different if the for-loop "broke" */ - if (i != length) - { - prev_c = c ; - continue ; - } - - /* === Got it! two columns are identical =================== */ - - ASSERT (Col [c].shared2.score == Col [super_c].shared2.score) ; - - Col [super_c].shared1.thickness += Col [c].shared1.thickness ; - Col [c].shared1.parent = super_c ; - KILL_NON_PRINCIPAL_COL (c) ; - /* order c later, in order_children() */ - Col [c].shared2.order = EMPTY ; - /* remove c from hash bucket */ - Col [prev_c].shared4.hash_next = Col [c].shared4.hash_next ; - } - } - - /* === Empty this hash bucket ======================================= */ - - if (head_column > EMPTY) - { - /* corresponding degree list "hash" is not empty */ - Col [head_column].shared3.headhash = EMPTY ; - } - else - { - /* corresponding degree list "hash" is empty */ - head [hash] = EMPTY ; - } - } -} - - -/* ========================================================================== */ -/* === garbage_collection =================================================== */ -/* ========================================================================== */ - -/* - Defragments and compacts columns and rows in the workspace A. Used when - all avaliable memory has been used while performing row merging. Returns - the index of the first free position in A, after garbage collection. The - time taken by this routine is linear is the size of the array A, which is - itself linear in the number of nonzeros in the input matrix. - Not user-callable. -*/ - -PRIVATE Int garbage_collection /* returns the new value of pfree */ -( - /* === Parameters ======================================================= */ - - Int n_row, /* number of rows */ - Int n_col, /* number of columns */ - Colamd_Row Row [], /* row info */ - Colamd_Col Col [], /* column info */ - Int A [], /* A [0 ... Alen-1] holds the matrix */ - Int *pfree /* &A [0] ... pfree is in use */ -) -{ - /* === Local variables ================================================== */ - - Int *psrc ; /* source pointer */ - Int *pdest ; /* destination pointer */ - Int j ; /* counter */ - Int r ; /* a row index */ - Int c ; /* a column index */ - Int length ; /* length of a row or column */ - -#ifndef NDEBUG - Int debug_rows ; - DEBUG2 (("Defrag..\n")) ; - for (psrc = &A[0] ; psrc < pfree ; psrc++) ASSERT (*psrc >= 0) ; - debug_rows = 0 ; -#endif /* NDEBUG */ - - /* === Defragment the columns =========================================== */ - - pdest = &A[0] ; - for (c = 0 ; c < n_col ; c++) - { - if (COL_IS_ALIVE (c)) - { - psrc = &A [Col [c].start] ; - - /* move and compact the column */ - ASSERT (pdest <= psrc) ; - Col [c].start = (Int) (pdest - &A [0]) ; - length = Col [c].length ; - for (j = 0 ; j < length ; j++) - { - r = *psrc++ ; - if (ROW_IS_ALIVE (r)) - { - *pdest++ = r ; - } - } - Col [c].length = (Int) (pdest - &A [Col [c].start]) ; - } - } - - /* === Prepare to defragment the rows =================================== */ - - for (r = 0 ; r < n_row ; r++) - { - if (ROW_IS_DEAD (r) || (Row [r].length == 0)) - { - /* This row is already dead, or is of zero length. Cannot compact - * a row of zero length, so kill it. NOTE: in the current version, - * there are no zero-length live rows. Kill the row (for the first - * time, or again) just to be safe. */ - KILL_ROW (r) ; - } - else - { - /* save first column index in Row [r].shared2.first_column */ - psrc = &A [Row [r].start] ; - Row [r].shared2.first_column = *psrc ; - ASSERT (ROW_IS_ALIVE (r)) ; - /* flag the start of the row with the one's complement of row */ - *psrc = ONES_COMPLEMENT (r) ; -#ifndef NDEBUG - debug_rows++ ; -#endif /* NDEBUG */ - } - } - - /* === Defragment the rows ============================================== */ - - psrc = pdest ; - while (psrc < pfree) - { - /* find a negative number ... the start of a row */ - if (*psrc++ < 0) - { - psrc-- ; - /* get the row index */ - r = ONES_COMPLEMENT (*psrc) ; - ASSERT (r >= 0 && r < n_row) ; - /* restore first column index */ - *psrc = Row [r].shared2.first_column ; - ASSERT (ROW_IS_ALIVE (r)) ; - ASSERT (Row [r].length > 0) ; - /* move and compact the row */ - ASSERT (pdest <= psrc) ; - Row [r].start = (Int) (pdest - &A [0]) ; - length = Row [r].length ; - for (j = 0 ; j < length ; j++) - { - c = *psrc++ ; - if (COL_IS_ALIVE (c)) - { - *pdest++ = c ; - } - } - Row [r].length = (Int) (pdest - &A [Row [r].start]) ; - ASSERT (Row [r].length > 0) ; -#ifndef NDEBUG - debug_rows-- ; -#endif /* NDEBUG */ - } - } - /* ensure we found all the rows */ - ASSERT (debug_rows == 0) ; - - /* === Return the new value of pfree ==================================== */ - - return ((Int) (pdest - &A [0])) ; -} - - -/* ========================================================================== */ -/* === clear_mark =========================================================== */ -/* ========================================================================== */ - -/* - Clears the Row [].shared2.mark array, and returns the new tag_mark. - Return value is the new tag_mark. Not user-callable. -*/ - -PRIVATE Int clear_mark /* return the new value for tag_mark */ -( - /* === Parameters ======================================================= */ - - Int tag_mark, /* new value of tag_mark */ - Int max_mark, /* max allowed value of tag_mark */ - - Int n_row, /* number of rows in A */ - Colamd_Row Row [] /* Row [0 ... n_row-1].shared2.mark is set to zero */ -) -{ - /* === Local variables ================================================== */ - - Int r ; - - if (tag_mark <= 0 || tag_mark >= max_mark) - { - for (r = 0 ; r < n_row ; r++) - { - if (ROW_IS_ALIVE (r)) - { - Row [r].shared2.mark = 0 ; - } - } - tag_mark = 1 ; - } - - return (tag_mark) ; -} - - -/* ========================================================================== */ -/* === print_report ========================================================= */ -/* ========================================================================== */ - -PRIVATE void print_report -( - char *method, - Int stats [COLAMD_STATS] -) -{ - - Int i1, i2, i3 ; - - PRINTF (("\n%s version %d.%d, %s: ", method, - COLAMD_MAIN_VERSION, COLAMD_SUB_VERSION, COLAMD_DATE)) ; - - if (!stats) - { - PRINTF (("No statistics available.\n")) ; - return ; - } - - i1 = stats [COLAMD_INFO1] ; - i2 = stats [COLAMD_INFO2] ; - i3 = stats [COLAMD_INFO3] ; - - if (stats [COLAMD_STATUS] >= 0) - { - PRINTF (("OK. ")) ; - } - else - { - PRINTF (("ERROR. ")) ; - } - - switch (stats [COLAMD_STATUS]) - { - - case COLAMD_OK_BUT_JUMBLED: - - PRINTF(("Matrix has unsorted or duplicate row indices.\n")) ; - - PRINTF(("%s: number of duplicate or out-of-order row indices: %d\n", - method, i3)) ; - - PRINTF(("%s: last seen duplicate or out-of-order row index: %d\n", - method, INDEX (i2))) ; - - PRINTF(("%s: last seen in column: %d", - method, INDEX (i1))) ; - - /* no break - fall through to next case instead */ - - case COLAMD_OK: - - PRINTF(("\n")) ; - - PRINTF(("%s: number of dense or empty rows ignored: %d\n", - method, stats [COLAMD_DENSE_ROW])) ; - - PRINTF(("%s: number of dense or empty columns ignored: %d\n", - method, stats [COLAMD_DENSE_COL])) ; - - PRINTF(("%s: number of garbage collections performed: %d\n", - method, stats [COLAMD_DEFRAG_COUNT])) ; - break ; - - case COLAMD_ERROR_A_not_present: - - PRINTF(("Array A (row indices of matrix) not present.\n")) ; - break ; - - case COLAMD_ERROR_p_not_present: - - PRINTF(("Array p (column pointers for matrix) not present.\n")) ; - break ; - - case COLAMD_ERROR_nrow_negative: - - PRINTF(("Invalid number of rows (%d).\n", i1)) ; - break ; - - case COLAMD_ERROR_ncol_negative: - - PRINTF(("Invalid number of columns (%d).\n", i1)) ; - break ; - - case COLAMD_ERROR_nnz_negative: - - PRINTF(("Invalid number of nonzero entries (%d).\n", i1)) ; - break ; - - case COLAMD_ERROR_p0_nonzero: - - PRINTF(("Invalid column pointer, p [0] = %d, must be zero.\n", i1)); - break ; - - case COLAMD_ERROR_A_too_small: - - PRINTF(("Array A too small.\n")) ; - PRINTF((" Need Alen >= %d, but given only Alen = %d.\n", - i1, i2)) ; - break ; - - case COLAMD_ERROR_col_length_negative: - - PRINTF - (("Column %d has a negative number of nonzero entries (%d).\n", - INDEX (i1), i2)) ; - break ; - - case COLAMD_ERROR_row_index_out_of_bounds: - - PRINTF - (("Row index (row %d) out of bounds (%d to %d) in column %d.\n", - INDEX (i2), INDEX (0), INDEX (i3-1), INDEX (i1))) ; - break ; - - case COLAMD_ERROR_out_of_memory: - - PRINTF(("Out of memory.\n")) ; - break ; - - /* v2.4: internal-error case deleted */ - } -} - - - - -/* ========================================================================== */ -/* === colamd debugging routines ============================================ */ -/* ========================================================================== */ - -/* When debugging is disabled, the remainder of this file is ignored. */ - -#ifndef NDEBUG - - -/* ========================================================================== */ -/* === debug_structures ===================================================== */ -/* ========================================================================== */ - -/* - At this point, all empty rows and columns are dead. All live columns - are "clean" (containing no dead rows) and simplicial (no supercolumns - yet). Rows may contain dead columns, but all live rows contain at - least one live column. -*/ - -PRIVATE void debug_structures -( - /* === Parameters ======================================================= */ - - Int n_row, - Int n_col, - Colamd_Row Row [], - Colamd_Col Col [], - Int A [], - Int n_col2 -) -{ - /* === Local variables ================================================== */ - - Int i ; - Int c ; - Int *cp ; - Int *cp_end ; - Int len ; - Int score ; - Int r ; - Int *rp ; - Int *rp_end ; - Int deg ; - - /* === Check A, Row, and Col ============================================ */ - - for (c = 0 ; c < n_col ; c++) - { - if (COL_IS_ALIVE (c)) - { - len = Col [c].length ; - score = Col [c].shared2.score ; - DEBUG4 (("initial live col %5d %5d %5d\n", c, len, score)) ; - ASSERT (len > 0) ; - ASSERT (score >= 0) ; - ASSERT (Col [c].shared1.thickness == 1) ; - cp = &A [Col [c].start] ; - cp_end = cp + len ; - while (cp < cp_end) - { - r = *cp++ ; - ASSERT (ROW_IS_ALIVE (r)) ; - } - } - else - { - i = Col [c].shared2.order ; - ASSERT (i >= n_col2 && i < n_col) ; - } - } - - for (r = 0 ; r < n_row ; r++) - { - if (ROW_IS_ALIVE (r)) - { - i = 0 ; - len = Row [r].length ; - deg = Row [r].shared1.degree ; - ASSERT (len > 0) ; - ASSERT (deg > 0) ; - rp = &A [Row [r].start] ; - rp_end = rp + len ; - while (rp < rp_end) - { - c = *rp++ ; - if (COL_IS_ALIVE (c)) - { - i++ ; - } - } - ASSERT (i > 0) ; - } - } -} - - -/* ========================================================================== */ -/* === debug_deg_lists ====================================================== */ -/* ========================================================================== */ - -/* - Prints the contents of the degree lists. Counts the number of columns - in the degree list and compares it to the total it should have. Also - checks the row degrees. -*/ - -PRIVATE void debug_deg_lists -( - /* === Parameters ======================================================= */ - - Int n_row, - Int n_col, - Colamd_Row Row [], - Colamd_Col Col [], - Int head [], - Int min_score, - Int should, - Int max_deg -) -{ - /* === Local variables ================================================== */ - - Int deg ; - Int col ; - Int have ; - Int row ; - - /* === Check the degree lists =========================================== */ - - if (n_col > 10000 && colamd_debug <= 0) - { - return ; - } - have = 0 ; - DEBUG4 (("Degree lists: %d\n", min_score)) ; - for (deg = 0 ; deg <= n_col ; deg++) - { - col = head [deg] ; - if (col == EMPTY) - { - continue ; - } - DEBUG4 (("%d:", deg)) ; - while (col != EMPTY) - { - DEBUG4 ((" %d", col)) ; - have += Col [col].shared1.thickness ; - ASSERT (COL_IS_ALIVE (col)) ; - col = Col [col].shared4.degree_next ; - } - DEBUG4 (("\n")) ; - } - DEBUG4 (("should %d have %d\n", should, have)) ; - ASSERT (should == have) ; - - /* === Check the row degrees ============================================ */ - - if (n_row > 10000 && colamd_debug <= 0) - { - return ; - } - for (row = 0 ; row < n_row ; row++) - { - if (ROW_IS_ALIVE (row)) - { - ASSERT (Row [row].shared1.degree <= max_deg) ; - } - } -} - - -/* ========================================================================== */ -/* === debug_mark =========================================================== */ -/* ========================================================================== */ - -/* - Ensures that the tag_mark is less that the maximum and also ensures that - each entry in the mark array is less than the tag mark. -*/ - -PRIVATE void debug_mark -( - /* === Parameters ======================================================= */ - - Int n_row, - Colamd_Row Row [], - Int tag_mark, - Int max_mark -) -{ - /* === Local variables ================================================== */ - - Int r ; - - /* === Check the Row marks ============================================== */ - - ASSERT (tag_mark > 0 && tag_mark <= max_mark) ; - if (n_row > 10000 && colamd_debug <= 0) - { - return ; - } - for (r = 0 ; r < n_row ; r++) - { - ASSERT (Row [r].shared2.mark < tag_mark) ; - } -} - - -/* ========================================================================== */ -/* === debug_matrix ========================================================= */ -/* ========================================================================== */ - -/* - Prints out the contents of the columns and the rows. -*/ - -PRIVATE void debug_matrix -( - /* === Parameters ======================================================= */ - - Int n_row, - Int n_col, - Colamd_Row Row [], - Colamd_Col Col [], - Int A [] -) -{ - /* === Local variables ================================================== */ - - Int r ; - Int c ; - Int *rp ; - Int *rp_end ; - Int *cp ; - Int *cp_end ; - - /* === Dump the rows and columns of the matrix ========================== */ - - if (colamd_debug < 3) - { - return ; - } - DEBUG3 (("DUMP MATRIX:\n")) ; - for (r = 0 ; r < n_row ; r++) - { - DEBUG3 (("Row %d alive? %d\n", r, ROW_IS_ALIVE (r))) ; - if (ROW_IS_DEAD (r)) - { - continue ; - } - DEBUG3 (("start %d length %d degree %d\n", - Row [r].start, Row [r].length, Row [r].shared1.degree)) ; - rp = &A [Row [r].start] ; - rp_end = rp + Row [r].length ; - while (rp < rp_end) - { - c = *rp++ ; - DEBUG4 ((" %d col %d\n", COL_IS_ALIVE (c), c)) ; - } - } - - for (c = 0 ; c < n_col ; c++) - { - DEBUG3 (("Col %d alive? %d\n", c, COL_IS_ALIVE (c))) ; - if (COL_IS_DEAD (c)) - { - continue ; - } - DEBUG3 (("start %d length %d shared1 %d shared2 %d\n", - Col [c].start, Col [c].length, - Col [c].shared1.thickness, Col [c].shared2.score)) ; - cp = &A [Col [c].start] ; - cp_end = cp + Col [c].length ; - while (cp < cp_end) - { - r = *cp++ ; - DEBUG4 ((" %d row %d\n", ROW_IS_ALIVE (r), r)) ; - } - } -} - -PRIVATE void colamd_get_debug -( - char *method -) -{ - FILE *f ; - colamd_debug = 0 ; /* no debug printing */ - f = fopen ("debug", "r") ; - if (f == (FILE *) NULL) - { - colamd_debug = 0 ; - } - else - { - fscanf (f, "%d", &colamd_debug) ; - fclose (f) ; - } - DEBUG0 (("%s: debug version, D = %d (THIS WILL BE SLOW!)\n", - method, colamd_debug)) ; -} - -#endif /* NDEBUG */ diff --git a/extern/colamd/Source/colamd_global.c b/extern/colamd/Source/colamd_global.c deleted file mode 100644 index 4d1ae22300c..00000000000 --- a/extern/colamd/Source/colamd_global.c +++ /dev/null @@ -1,24 +0,0 @@ -/* ========================================================================== */ -/* === colamd_global.c ====================================================== */ -/* ========================================================================== */ - -/* ---------------------------------------------------------------------------- - * COLAMD, Copyright (C) 2007, Timothy A. Davis. - * See License.txt for the Version 2.1 of the GNU Lesser General Public License - * http://www.cise.ufl.edu/research/sparse - * -------------------------------------------------------------------------- */ - -/* Global variables for COLAMD */ - -#ifndef NPRINT -#ifdef MATLAB_MEX_FILE -#include "mex.h" -int (*colamd_printf) (const char *, ...) = mexPrintf ; -#else -#include -int (*colamd_printf) (const char *, ...) = printf ; -#endif -#else -int (*colamd_printf) (const char *, ...) = ((void *) 0) ; -#endif - diff --git a/intern/CMakeLists.txt b/intern/CMakeLists.txt index 9b0f2de22f2..275524f788f 100644 --- a/intern/CMakeLists.txt +++ b/intern/CMakeLists.txt @@ -74,10 +74,6 @@ if(WITH_BULLET) add_subdirectory(rigidbody) endif() -if(WITH_OPENNL) - add_subdirectory(opennl) -endif() - if(WITH_OPENSUBDIV) add_subdirectory(opensubdiv) endif() diff --git a/intern/SConscript b/intern/SConscript index 3b855d60ac8..736242102cc 100644 --- a/intern/SConscript +++ b/intern/SConscript @@ -37,7 +37,6 @@ SConscript(['string/SConscript', 'itasc/SConscript', 'eigen/SConscript', 'opencolorio/SConscript', - 'opennl/SConscript', 'mikktspace/SConscript', 'smoke/SConscript', 'raskter/SConscript']) diff --git a/intern/eigen/CMakeLists.txt b/intern/eigen/CMakeLists.txt index 58964e43224..5811b71de94 100644 --- a/intern/eigen/CMakeLists.txt +++ b/intern/eigen/CMakeLists.txt @@ -35,9 +35,11 @@ set(SRC eigen_capi.h intern/eigenvalues.cc + intern/linear_solver.cc intern/svd.cc intern/eigenvalues.h + intern/linear_solver.h intern/svd.h ) diff --git a/intern/eigen/eigen_capi.h b/intern/eigen/eigen_capi.h index 45ee1c015ec..be42e340274 100644 --- a/intern/eigen/eigen_capi.h +++ b/intern/eigen/eigen_capi.h @@ -28,6 +28,7 @@ #define __EIGEN_C_API_H__ #include "intern/eigenvalues.h" +#include "intern/linear_solver.h" #include "intern/svd.h" #endif /* __EIGEN_C_API_H__ */ diff --git a/intern/eigen/intern/eigenvalues.cc b/intern/eigen/intern/eigenvalues.cc index dcaaee8e9c2..57942a4dc55 100644 --- a/intern/eigen/intern/eigenvalues.cc +++ b/intern/eigen/intern/eigenvalues.cc @@ -45,7 +45,7 @@ using Eigen::Map; using Eigen::Success; -bool EG3_self_adjoint_eigen_solve(const int size, const float *matrix, float *r_eigen_values, float *r_eigen_vectors) +bool EIG_self_adjoint_eigen_solve(const int size, const float *matrix, float *r_eigen_values, float *r_eigen_vectors) { SelfAdjointEigenSolver eigen_solver; diff --git a/intern/eigen/intern/eigenvalues.h b/intern/eigen/intern/eigenvalues.h index 93fc06c2339..5c08ab5be39 100644 --- a/intern/eigen/intern/eigenvalues.h +++ b/intern/eigen/intern/eigenvalues.h @@ -31,7 +31,7 @@ extern "C" { #endif -bool EG3_self_adjoint_eigen_solve(const int size, const float *matrix, float *r_eigen_values, float *r_eigen_vectors); +bool EIG_self_adjoint_eigen_solve(const int size, const float *matrix, float *r_eigen_values, float *r_eigen_vectors); #ifdef __cplusplus } diff --git a/intern/eigen/intern/linear_solver.cc b/intern/eigen/intern/linear_solver.cc new file mode 100644 index 00000000000..181b278b9c0 --- /dev/null +++ b/intern/eigen/intern/linear_solver.cc @@ -0,0 +1,354 @@ +/* + * Sparse linear solver. + * Copyright (C) 2004 Bruno Levy + * Copyright (C) 2005-2015 Blender Foundation + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; either version 2 of the License, or + * (at your option) any later version. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. + * + * If you modify this software, you should include a notice giving the + * name of the person performing the modification, the date of modification, + * and the reason for such modification. + */ + +#include "linear_solver.h" + +#include + +#include +#include +#include +#include +#include + +/* Eigen data structures */ + +typedef Eigen::SparseMatrix EigenSparseMatrix; +typedef Eigen::SparseLU EigenSparseLU; +typedef Eigen::VectorXd EigenVectorX; +typedef Eigen::Triplet EigenTriplet; + +/* Linear Solver data structure */ + +struct LinearSolver +{ + struct Coeff + { + Coeff() + { + index = 0; + value = 0.0; + } + + int index; + double value; + }; + + struct Variable + { + Variable() + { + memset(value, 0, sizeof(value)); + locked = false; + index = 0; + } + + double value[4]; + bool locked; + int index; + std::vector a; + }; + + enum State + { + STATE_VARIABLES_CONSTRUCT, + STATE_MATRIX_CONSTRUCT, + STATE_MATRIX_SOLVED + }; + + LinearSolver(int num_rows_, int num_variables_, int num_rhs_, bool lsq_) + { + assert(num_variables_ > 0); + assert(num_rhs_ <= 4); + + state = STATE_VARIABLES_CONSTRUCT; + m = 0; + n = 0; + sparseLU = NULL; + num_variables = num_variables_; + num_rhs = num_rhs_; + num_rows = num_rows_; + least_squares = lsq_; + + variable.resize(num_variables); + } + + ~LinearSolver() + { + delete sparseLU; + } + + State state; + + int n; + int m; + + std::vector Mtriplets; + EigenSparseMatrix M; + EigenSparseMatrix MtM; + std::vector b; + std::vector x; + + EigenSparseLU *sparseLU; + + int num_variables; + std::vector variable; + + int num_rows; + int num_rhs; + + bool least_squares; +}; + +LinearSolver *EIG_linear_solver_new(int num_rows, int num_columns, int num_rhs) +{ + return new LinearSolver(num_rows, num_columns, num_rhs, false); +} + +LinearSolver *EIG_linear_least_squares_solver_new(int num_rows, int num_columns, int num_rhs) +{ + return new LinearSolver(num_rows, num_columns, num_rhs, true); +} + +void EIG_linear_solver_delete(LinearSolver *solver) +{ + delete solver; +} + +/* Variables */ + +void EIG_linear_solver_variable_set(LinearSolver *solver, int rhs, int index, double value) +{ + solver->variable[index].value[rhs] = value; +} + +double EIG_linear_solver_variable_get(LinearSolver *solver, int rhs, int index) +{ + return solver->variable[index].value[rhs]; +} + +void EIG_linear_solver_variable_lock(LinearSolver *solver, int index) +{ + if (!solver->variable[index].locked) { + assert(solver->state == LinearSolver::STATE_VARIABLES_CONSTRUCT); + solver->variable[index].locked = true; + } +} + +static void linear_solver_variables_to_vector(LinearSolver *solver) +{ + int num_rhs = solver->num_rhs; + + for (int i = 0; i < solver->num_variables; i++) { + LinearSolver::Variable* v = &solver->variable[i]; + if (!v->locked) { + for (int j = 0; j < num_rhs; j++) + solver->x[j][v->index] = v->value[j]; + } + } +} + +static void linear_solver_vector_to_variables(LinearSolver *solver) +{ + int num_rhs = solver->num_rhs; + + for (int i = 0; i < solver->num_variables; i++) { + LinearSolver::Variable* v = &solver->variable[i]; + if (!v->locked) { + for (int j = 0; j < num_rhs; j++) + v->value[j] = solver->x[j][v->index]; + } + } +} + +/* Matrix */ + +static void linear_solver_ensure_matrix_construct(LinearSolver *solver) +{ + /* transition to matrix construction if necessary */ + if (solver->state == LinearSolver::STATE_VARIABLES_CONSTRUCT) { + int n = 0; + + for (int i = 0; i < solver->num_variables; i++) { + if (solver->variable[i].locked) + solver->variable[i].index = ~0; + else + solver->variable[i].index = n++; + } + + int m = (solver->num_rows == 0)? n: solver->num_rows; + + solver->m = m; + solver->n = n; + + assert(solver->least_squares || m == n); + + /* reserve reasonable estimate */ + solver->Mtriplets.clear(); + solver->Mtriplets.reserve(std::max(m, n)*3); + + solver->b.resize(solver->num_rhs); + solver->x.resize(solver->num_rhs); + + for (int i = 0; i < solver->num_rhs; i++) { + solver->b[i].setZero(m); + solver->x[i].setZero(n); + } + + linear_solver_variables_to_vector(solver); + + solver->state = LinearSolver::STATE_MATRIX_CONSTRUCT; + } +} + +void EIG_linear_solver_matrix_add(LinearSolver *solver, int row, int col, double value) +{ + if (solver->state == LinearSolver::STATE_MATRIX_SOLVED) + return; + + linear_solver_ensure_matrix_construct(solver); + + if (!solver->least_squares && solver->variable[row].locked); + else if (solver->variable[col].locked) { + if (!solver->least_squares) + row = solver->variable[row].index; + + LinearSolver::Coeff coeff; + coeff.index = row; + coeff.value = value; + solver->variable[col].a.push_back(coeff); + } + else { + if (!solver->least_squares) + row = solver->variable[row].index; + col = solver->variable[col].index; + + /* direct insert into matrix is too slow, so use triplets */ + EigenTriplet triplet(row, col, value); + solver->Mtriplets.push_back(triplet); + } +} + +/* Right hand side */ + +void EIG_linear_solver_right_hand_side_add(LinearSolver *solver, int rhs, int index, double value) +{ + linear_solver_ensure_matrix_construct(solver); + + if (solver->least_squares) { + solver->b[rhs][index] += value; + } + else if (!solver->variable[index].locked) { + index = solver->variable[index].index; + solver->b[rhs][index] += value; + } +} + +/* Solve */ + +bool EIG_linear_solver_solve(LinearSolver *solver) +{ + bool result = true; + + assert(solver->state != LinearSolver::STATE_VARIABLES_CONSTRUCT); + + if (solver->state == LinearSolver::STATE_MATRIX_CONSTRUCT) { + /* create matrix from triplets */ + solver->M.resize(solver->m, solver->n); + solver->M.setFromTriplets(solver->Mtriplets.begin(), solver->Mtriplets.end()); + solver->Mtriplets.clear(); + + /* create least squares matrix */ + if (solver->least_squares) + solver->MtM = solver->M.transpose() * solver->M; + + /* convert M to compressed column format */ + EigenSparseMatrix& M = (solver->least_squares)? solver->MtM: solver->M; + M.makeCompressed(); + + /* perform sparse LU factorization */ + EigenSparseLU *sparseLU = new EigenSparseLU(); + solver->sparseLU = sparseLU; + + sparseLU->compute(M); + result = (sparseLU->info() == Eigen::Success); + + solver->state = LinearSolver::STATE_MATRIX_SOLVED; + } + + if (result) { + /* solve for each right hand side */ + for (int rhs = 0; rhs < solver->num_rhs; rhs++) { + /* modify for locked variables */ + EigenVectorX& b = solver->b[rhs]; + + for (int i = 0; i < solver->num_variables; i++) { + LinearSolver::Variable *variable = &solver->variable[i]; + + if (variable->locked) { + std::vector& a = variable->a; + + for (int j = 0; j < a.size(); j++) + b[a[j].index] -= a[j].value*variable->value[rhs]; + } + } + + /* solve */ + if (solver->least_squares) { + EigenVectorX Mtb = solver->M.transpose() * b; + solver->x[rhs] = solver->sparseLU->solve(Mtb); + } + else { + EigenVectorX& b = solver->b[rhs]; + solver->x[rhs] = solver->sparseLU->solve(b); + } + + if (solver->sparseLU->info() != Eigen::Success) + result = false; + } + + if (result) + linear_solver_vector_to_variables(solver); + } + + /* clear for next solve */ + for (int rhs = 0; rhs < solver->num_rhs; rhs++) + solver->b[rhs].setZero(solver->m); + + return result; +} + +/* Debugging */ + +void EIG_linear_solver_print_matrix(LinearSolver *solver) +{ + std::cout << "A:" << solver->M << std::endl; + + for (int rhs = 0; rhs < solver->num_rhs; rhs++) + std::cout << "b " << rhs << ":" << solver->b[rhs] << std::endl; + + if (solver->MtM.rows() && solver->MtM.cols()) + std::cout << "AtA:" << solver->MtM << std::endl; +} + diff --git a/intern/eigen/intern/linear_solver.h b/intern/eigen/intern/linear_solver.h new file mode 100644 index 00000000000..2dbea4d6f68 --- /dev/null +++ b/intern/eigen/intern/linear_solver.h @@ -0,0 +1,71 @@ +/* + * Sparse linear solver. + * Copyright (C) 2004 Bruno Levy + * Copyright (C) 2005-2015 Blender Foundation + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; either version 2 of the License, or + * (at your option) any later version. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. + * + * If you modify this software, you should include a notice giving the + * name of the person performing the modification, the date of modification, + * and the reason for such modification. + */ + +#pragma once + +#include + +#ifdef __cplusplus +extern "C" { +#endif + +/* Solvers for Ax = b and AtAx = Atb */ + +typedef struct LinearSolver LinearSolver; + +LinearSolver *EIG_linear_solver_new( + int num_rows, + int num_columns, + int num_right_hand_sides); + +LinearSolver *EIG_linear_least_squares_solver_new( + int num_rows, + int num_columns, + int num_right_hand_sides); + +void EIG_linear_solver_delete(LinearSolver *solver); + +/* Variables (x). Any locking must be done before matrix construction. */ + +void EIG_linear_solver_variable_set(LinearSolver *solver, int rhs, int index, double value); +double EIG_linear_solver_variable_get(LinearSolver *solver, int rhs, int index); +void EIG_linear_solver_variable_lock(LinearSolver *solver, int index); + +/* Matrix (A) and right hand side (b) */ + +void EIG_linear_solver_matrix_add(LinearSolver *solver, int row, int col, double value); +void EIG_linear_solver_right_hand_side_add(LinearSolver *solver, int rhs, int index, double value); + +/* Solve. Repeated solves are supported, by changing b between solves. */ + +bool EIG_linear_solver_solve(LinearSolver *solver); + +/* Debugging */ + +void EIG_linear_solver_print_matrix(LinearSolver *solver); + +#ifdef __cplusplus +} +#endif + diff --git a/intern/eigen/intern/svd.cc b/intern/eigen/intern/svd.cc index e39a8261edb..4ed65af2a8f 100644 --- a/intern/eigen/intern/svd.cc +++ b/intern/eigen/intern/svd.cc @@ -48,7 +48,7 @@ using Eigen::MatrixXf; using Eigen::VectorXf; using Eigen::Map; -void EG3_svd_square_matrix(const int size, const float *matrix, float *r_U, float *r_S, float *r_V) +void EIG_svd_square_matrix(const int size, const float *matrix, float *r_U, float *r_S, float *r_V) { /* Since our matrix is squared, we can use thinU/V. */ unsigned int flags = (r_U ? ComputeThinU : 0) | (r_V ? ComputeThinV : 0); diff --git a/intern/eigen/intern/svd.h b/intern/eigen/intern/svd.h index 0ac51108977..feadcc3520a 100644 --- a/intern/eigen/intern/svd.h +++ b/intern/eigen/intern/svd.h @@ -31,7 +31,7 @@ extern "C" { #endif -void EG3_svd_square_matrix(const int size, const float *matrix, float *r_U, float *r_S, float *r_V); +void EIG_svd_square_matrix(const int size, const float *matrix, float *r_U, float *r_S, float *r_V); #ifdef __cplusplus } diff --git a/intern/opennl/CMakeLists.txt b/intern/opennl/CMakeLists.txt deleted file mode 100644 index 9416bc2b9ea..00000000000 --- a/intern/opennl/CMakeLists.txt +++ /dev/null @@ -1,58 +0,0 @@ -# ***** BEGIN GPL LICENSE BLOCK ***** -# -# This program is free software; you can redistribute it and/or -# modify it under the terms of the GNU General Public License -# as published by the Free Software Foundation; either version 2 -# of the License, or (at your option) any later version. -# -# This program is distributed in the hope that it will be useful, -# but WITHOUT ANY WARRANTY; without even the implied warranty of -# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -# GNU General Public License for more details. -# -# You should have received a copy of the GNU General Public License -# along with this program; if not, write to the Free Software Foundation, -# Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. -# -# The Original Code is Copyright (C) 2006, Blender Foundation -# All rights reserved. -# -# The Original Code is: all of this file. -# -# Contributor(s): Jacques Beaurain. -# -# ***** END GPL LICENSE BLOCK ***** - -# External project, better not fix warnings. -remove_strict_flags() - -# remove debug flag here since this is not a blender maintained library -# and debug gives a lot of prints on UV unwrapping. developers can enable if they need to. -if(MSVC) - remove_definitions(-DDEBUG) -else() - add_definitions(-UDEBUG) -endif() - - -# quiet compiler warnings about undefined defines -add_definitions( - -DDEBUGlevel=0 - -DPRNTlevel=0 -) - -set(INC - extern -) - -set(INC_SYS - ../../extern/colamd/Include - ../../extern/Eigen3 -) - -set(SRC - intern/opennl.cpp - extern/ONL_opennl.h -) - -blender_add_lib(bf_intern_opennl "${SRC}" "${INC}" "${INC_SYS}") diff --git a/intern/opennl/SConscript b/intern/opennl/SConscript deleted file mode 100644 index 99df29b780a..00000000000 --- a/intern/opennl/SConscript +++ /dev/null @@ -1,35 +0,0 @@ -#!/usr/bin/env python -# -# ***** BEGIN GPL LICENSE BLOCK ***** -# -# This program is free software; you can redistribute it and/or -# modify it under the terms of the GNU General Public License -# as published by the Free Software Foundation; either version 2 -# of the License, or (at your option) any later version. -# -# This program is distributed in the hope that it will be useful, -# but WITHOUT ANY WARRANTY; without even the implied warranty of -# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -# GNU General Public License for more details. -# -# You should have received a copy of the GNU General Public License -# along with this program; if not, write to the Free Software Foundation, -# Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. -# -# The Original Code is Copyright (C) 2006, Blender Foundation -# All rights reserved. -# -# The Original Code is: all of this file. -# -# Contributor(s): Nathan Letwory. -# -# ***** END GPL LICENSE BLOCK ***** - -Import ('env') - -sources = env.Glob('intern/*.cpp') - -incs = 'extern ../../extern/colamd/Include ../../extern/Eigen3' - -env.BlenderLib ('bf_intern_opennl', sources, Split(incs), [], libtype=['intern','player'], priority=[100,90] ) - diff --git a/intern/opennl/extern/ONL_opennl.h b/intern/opennl/extern/ONL_opennl.h deleted file mode 100644 index a414f40824b..00000000000 --- a/intern/opennl/extern/ONL_opennl.h +++ /dev/null @@ -1,113 +0,0 @@ -/** \file opennl/extern/ONL_opennl.h - * \ingroup opennlextern - */ -/* - * OpenNL: Numerical Library - * Copyright (C) 2004 Bruno Levy - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; either version 2 of the License, or - * (at your option) any later version. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. - * - * If you modify this software, you should include a notice giving the - * name of the person performing the modification, the date of modification, - * and the reason for such modification. - * - * Contact: Bruno Levy - * - * levy@loria.fr - * - * ISA Project - * LORIA, INRIA Lorraine, - * Campus Scientifique, BP 239 - * 54506 VANDOEUVRE LES NANCY CEDEX - * FRANCE - * - * Note that the GNU General Public License does not permit incorporating - * the Software into proprietary programs. - */ - -#ifndef nlOPENNL_H -#define nlOPENNL_H - -#ifdef __cplusplus -extern "C" { -#endif - -/* Datatypes */ - -typedef unsigned int NLenum; -typedef unsigned char NLboolean; -typedef int NLint; /* 4-byte signed */ -typedef unsigned int NLuint; /* 4-byte unsigned */ -typedef double NLdouble; /* double precision float */ - -typedef struct NLContext NLContext; - -/* Constants */ - -#define NL_FALSE 0x0 -#define NL_TRUE 0x1 - -/* Primitives */ - -#define NL_SYSTEM 0x0 -#define NL_MATRIX 0x1 - -/* Solver Parameters */ - -#define NL_SOLVER 0x100 -#define NL_NB_VARIABLES 0x101 -#define NL_LEAST_SQUARES 0x102 -#define NL_ERROR 0x108 -#define NL_NB_ROWS 0x110 -#define NL_NB_RIGHT_HAND_SIDES 0x112 /* 4 max */ - -/* Contexts */ - -NLContext *nlNewContext(void); -void nlDeleteContext(NLContext *context); - -/* State get/set */ - -void nlSolverParameteri(NLContext *context, NLenum pname, NLint param); - -/* Variables */ - -void nlSetVariable(NLContext *context, NLuint rhsindex, NLuint index, NLdouble value); -NLdouble nlGetVariable(NLContext *context, NLuint rhsindex, NLuint index); -void nlLockVariable(NLContext *context, NLuint index); -void nlUnlockVariable(NLContext *context, NLuint index); - -/* Begin/End */ - -void nlBegin(NLContext *context, NLenum primitive); -void nlEnd(NLContext *context, NLenum primitive); - -/* Setting elements in matrix/vector */ - -void nlMatrixAdd(NLContext *context, NLuint row, NLuint col, NLdouble value); -void nlRightHandSideAdd(NLContext *context, NLuint rhsindex, NLuint index, NLdouble value); -void nlRightHandSideSet(NLContext *context, NLuint rhsindex, NLuint index, NLdouble value); - -/* Solve */ - -void nlPrintMatrix(NLContext *context); -NLboolean nlSolve(NLContext *context, NLboolean solveAgain); - -#ifdef __cplusplus -} -#endif - -#endif - diff --git a/intern/opennl/intern/opennl.cpp b/intern/opennl/intern/opennl.cpp deleted file mode 100644 index 331291e790a..00000000000 --- a/intern/opennl/intern/opennl.cpp +++ /dev/null @@ -1,492 +0,0 @@ -/** \file opennl/intern/opennl.c - * \ingroup opennlintern - */ -/* - * - * OpenNL: Numerical Library - * Copyright (C) 2004 Bruno Levy - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; either version 2 of the License, or - * (at your option) any later version. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. - * - * If you modify this software, you should include a notice giving the - * name of the person performing the modification, the date of modification, - * and the reason for such modification. - * - * Contact: Bruno Levy - * - * levy@loria.fr - * - * ISA Project - * LORIA, INRIA Lorraine, - * Campus Scientifique, BP 239 - * 54506 VANDOEUVRE LES NANCY CEDEX - * FRANCE - * - * Note that the GNU General Public License does not permit incorporating - * the Software into proprietary programs. - */ - -#include "ONL_opennl.h" - -#include - -#include -#include -#include -#include -#include - -/* Eigen data structures */ - -typedef Eigen::SparseMatrix EigenSparseMatrix; -typedef Eigen::SparseLU EigenSparseSolver; -typedef Eigen::VectorXd EigenVectorX; -typedef Eigen::Triplet EigenTriplet; - -/* NLContext data structure */ - -struct NLCoeff { - NLCoeff() - { - index = 0; - value = 0.0; - } - NLuint index; - NLdouble value; -}; - -struct NLVariable { - NLVariable() - { - memset(value, 0, sizeof(value)); - locked = false; - index = 0; - } - NLdouble value[4]; - NLboolean locked; - NLuint index; - std::vector a; -}; - -#define NL_STATE_INITIAL 0 -#define NL_STATE_SYSTEM 1 -#define NL_STATE_MATRIX 2 -#define NL_STATE_MATRIX_CONSTRUCTED 3 -#define NL_STATE_SYSTEM_CONSTRUCTED 4 -#define NL_STATE_SYSTEM_SOLVED 5 - -struct NLContext { - NLContext() - { - state = NL_STATE_INITIAL; - n = 0; - m = 0; - sparse_solver = NULL; - nb_variables = 0; - nb_rhs = 1; - nb_rows = 0; - least_squares = false; - solve_again = false; - } - - ~NLContext() - { - delete sparse_solver; - } - - NLenum state; - - NLuint n; - NLuint m; - - std::vector Mtriplets; - EigenSparseMatrix M; - EigenSparseMatrix MtM; - std::vector b; - std::vector Mtb; - std::vector x; - - EigenSparseSolver *sparse_solver; - - NLuint nb_variables; - std::vector variable; - - NLuint nb_rows; - NLuint nb_rhs; - - NLboolean least_squares; - NLboolean solve_again; -}; - -NLContext *nlNewContext(void) -{ - return new NLContext(); -} - -void nlDeleteContext(NLContext *context) -{ - delete context; -} - -static void __nlCheckState(NLContext *context, NLenum state) -{ - assert(context->state == state); -} - -static void __nlTransition(NLContext *context, NLenum from_state, NLenum to_state) -{ - __nlCheckState(context, from_state); - context->state = to_state; -} - -/* Get/Set parameters */ - -void nlSolverParameteri(NLContext *context, NLenum pname, NLint param) -{ - __nlCheckState(context, NL_STATE_INITIAL); - switch(pname) { - case NL_NB_VARIABLES: { - assert(param > 0); - context->nb_variables = (NLuint)param; - } break; - case NL_NB_ROWS: { - assert(param > 0); - context->nb_rows = (NLuint)param; - } break; - case NL_LEAST_SQUARES: { - context->least_squares = (NLboolean)param; - } break; - case NL_NB_RIGHT_HAND_SIDES: { - context->nb_rhs = (NLuint)param; - } break; - default: { - assert(0); - } break; - } -} - -/* Get/Set Lock/Unlock variables */ - -void nlSetVariable(NLContext *context, NLuint rhsindex, NLuint index, NLdouble value) -{ - __nlCheckState(context, NL_STATE_SYSTEM); - context->variable[index].value[rhsindex] = value; -} - -NLdouble nlGetVariable(NLContext *context, NLuint rhsindex, NLuint index) -{ - assert(context->state != NL_STATE_INITIAL); - return context->variable[index].value[rhsindex]; -} - -void nlLockVariable(NLContext *context, NLuint index) -{ - __nlCheckState(context, NL_STATE_SYSTEM); - context->variable[index].locked = true; -} - -void nlUnlockVariable(NLContext *context, NLuint index) -{ - __nlCheckState(context, NL_STATE_SYSTEM); - context->variable[index].locked = false; -} - -/* System construction */ - -static void __nlVariablesToVector(NLContext *context) -{ - NLuint i, j, nb_rhs; - - nb_rhs= context->nb_rhs; - - for(i=0; inb_variables; i++) { - NLVariable* v = &(context->variable[i]); - if(!v->locked) { - for(j=0; jx[j][v->index] = v->value[j]; - } - } -} - -static void __nlVectorToVariables(NLContext *context) -{ - NLuint i, j, nb_rhs; - - nb_rhs= context->nb_rhs; - - for(i=0; inb_variables; i++) { - NLVariable* v = &(context->variable[i]); - if(!v->locked) { - for(j=0; jvalue[j] = context->x[j][v->index]; - } - } -} - -static void __nlBeginSystem(NLContext *context) -{ - assert(context->nb_variables > 0); - - if (context->solve_again) - __nlTransition(context, NL_STATE_SYSTEM_SOLVED, NL_STATE_SYSTEM); - else { - __nlTransition(context, NL_STATE_INITIAL, NL_STATE_SYSTEM); - - context->variable.resize(context->nb_variables); - } -} - -static void __nlEndSystem(NLContext *context) -{ - __nlTransition(context, NL_STATE_MATRIX_CONSTRUCTED, NL_STATE_SYSTEM_CONSTRUCTED); -} - -static void __nlBeginMatrix(NLContext *context) -{ - NLuint i; - NLuint m = 0, n = 0; - - __nlTransition(context, NL_STATE_SYSTEM, NL_STATE_MATRIX); - - if (!context->solve_again) { - for(i=0; inb_variables; i++) { - if(context->variable[i].locked) - context->variable[i].index = ~0; - else - context->variable[i].index = n++; - } - - m = (context->nb_rows == 0)? n: context->nb_rows; - - context->m = m; - context->n = n; - - /* reserve reasonable estimate */ - context->Mtriplets.clear(); - context->Mtriplets.reserve(std::max(m, n)*3); - - context->b.resize(context->nb_rhs); - context->x.resize(context->nb_rhs); - - for (i=0; inb_rhs; i++) { - context->b[i].setZero(m); - context->x[i].setZero(n); - } - } - else { - /* need to recompute b only, A is not constructed anymore */ - for (i=0; inb_rhs; i++) - context->b[i].setZero(context->m); - } - - __nlVariablesToVector(context); -} - -static void __nlEndMatrixRHS(NLContext *context, NLuint rhs) -{ - NLVariable *variable; - NLuint i, j; - - EigenVectorX& b = context->b[rhs]; - - for(i=0; inb_variables; i++) { - variable = &(context->variable[i]); - - if(variable->locked) { - std::vector& a = variable->a; - - for(j=0; jvalue[rhs]; - } - } - } - - if(context->least_squares) - context->Mtb[rhs] = context->M.transpose() * b; -} - -static void __nlEndMatrix(NLContext *context) -{ - __nlTransition(context, NL_STATE_MATRIX, NL_STATE_MATRIX_CONSTRUCTED); - - if(!context->solve_again) { - context->M.resize(context->m, context->n); - context->M.setFromTriplets(context->Mtriplets.begin(), context->Mtriplets.end()); - context->Mtriplets.clear(); - - if(context->least_squares) { - context->MtM = context->M.transpose() * context->M; - - context->Mtb.resize(context->nb_rhs); - for (NLuint rhs=0; rhsnb_rhs; rhs++) - context->Mtb[rhs].setZero(context->n); - } - } - - for (NLuint rhs=0; rhsnb_rhs; rhs++) - __nlEndMatrixRHS(context, rhs); -} - -void nlMatrixAdd(NLContext *context, NLuint row, NLuint col, NLdouble value) -{ - __nlCheckState(context, NL_STATE_MATRIX); - - if(context->solve_again) - return; - - if (!context->least_squares && context->variable[row].locked); - else if (context->variable[col].locked) { - if(!context->least_squares) - row = context->variable[row].index; - - NLCoeff coeff; - coeff.index = row; - coeff.value = value; - context->variable[col].a.push_back(coeff); - } - else { - if(!context->least_squares) - row = context->variable[row].index; - col = context->variable[col].index; - - // direct insert into matrix is too slow, so use triplets - EigenTriplet triplet(row, col, value); - context->Mtriplets.push_back(triplet); - } -} - -void nlRightHandSideAdd(NLContext *context, NLuint rhsindex, NLuint index, NLdouble value) -{ - __nlCheckState(context, NL_STATE_MATRIX); - - if(context->least_squares) { - context->b[rhsindex][index] += value; - } - else { - if(!context->variable[index].locked) { - index = context->variable[index].index; - context->b[rhsindex][index] += value; - } - } -} - -void nlRightHandSideSet(NLContext *context, NLuint rhsindex, NLuint index, NLdouble value) -{ - __nlCheckState(context, NL_STATE_MATRIX); - - if(context->least_squares) { - context->b[rhsindex][index] = value; - } - else { - if(!context->variable[index].locked) { - index = context->variable[index].index; - context->b[rhsindex][index] = value; - } - } -} - -void nlBegin(NLContext *context, NLenum prim) -{ - switch(prim) { - case NL_SYSTEM: { - __nlBeginSystem(context); - } break; - case NL_MATRIX: { - __nlBeginMatrix(context); - } break; - default: { - assert(0); - } - } -} - -void nlEnd(NLContext *context, NLenum prim) -{ - switch(prim) { - case NL_SYSTEM: { - __nlEndSystem(context); - } break; - case NL_MATRIX: { - __nlEndMatrix(context); - } break; - default: { - assert(0); - } - } -} - -void nlPrintMatrix(NLContext *context) -{ - std::cout << "A:" << context->M << std::endl; - - for(NLuint rhs=0; rhsnb_rhs; rhs++) - std::cout << "b " << rhs << ":" << context->b[rhs] << std::endl; - - if (context->MtM.rows() && context->MtM.cols()) - std::cout << "AtA:" << context->MtM << std::endl; -} - -/* Solving */ - -NLboolean nlSolve(NLContext *context, NLboolean solveAgain) -{ - NLboolean result = true; - - __nlCheckState(context, NL_STATE_SYSTEM_CONSTRUCTED); - - if (!context->solve_again) { - EigenSparseMatrix& M = (context->least_squares)? context->MtM: context->M; - - assert(M.rows() == M.cols()); - - /* Convert M to compressed column format */ - M.makeCompressed(); - - /* Perform sparse LU factorization */ - EigenSparseSolver *sparse_solver = new EigenSparseSolver(); - context->sparse_solver = sparse_solver; - - sparse_solver->analyzePattern(M); - sparse_solver->factorize(M); - - result = (sparse_solver->info() == Eigen::Success); - - /* Free M, don't need it anymore at this point */ - M.resize(0, 0); - } - - if (result) { - /* Solve each right hand side */ - for(NLuint rhs=0; rhsnb_rhs; rhs++) { - EigenVectorX& b = (context->least_squares)? context->Mtb[rhs]: context->b[rhs]; - context->x[rhs] = context->sparse_solver->solve(b); - - if (context->sparse_solver->info() != Eigen::Success) - result = false; - } - - if (result) { - __nlVectorToVariables(context); - - if (solveAgain) - context->solve_again = true; - - __nlTransition(context, NL_STATE_SYSTEM_CONSTRUCTED, NL_STATE_SYSTEM_SOLVED); - } - } - - return result; -} - diff --git a/source/blender/blenkernel/intern/softbody.c b/source/blender/blenkernel/intern/softbody.c index 86ffb541bf8..1c3ff3d3e02 100644 --- a/source/blender/blenkernel/intern/softbody.c +++ b/source/blender/blenkernel/intern/softbody.c @@ -81,7 +81,6 @@ variables on the UI for now #include "BKE_scene.h" #include "PIL_time.h" -// #include "ONL_opennl.h" remove linking to ONL for now /* callbacks for errors and interrupts and some goo */ static int (*SB_localInterruptCallBack)(void) = NULL; @@ -1811,14 +1810,14 @@ static void dfdx_spring(int ia, int ic, int op, float dir[3], float L, float len for (j=0;j<3;j++) { delta_ij = (i==j ? (1.0f): (0.0f)); m=factor*(dir[i]*dir[j] + (1-L/len)*(delta_ij - dir[i]*dir[j])); - nlMatrixAdd(ia+i, op+ic+j, m); + EIG_linear_solver_matrix_add(ia+i, op+ic+j, m); } } else { for (i=0;i<3;i++) for (j=0;j<3;j++) { m=factor*dir[i]*dir[j]; - nlMatrixAdd(ia+i, op+ic+j, m); + EIG_linear_solver_matrix_add(ia+i, op+ic+j, m); } } } @@ -1827,13 +1826,13 @@ static void dfdx_spring(int ia, int ic, int op, float dir[3], float L, float len static void dfdx_goal(int ia, int ic, int op, float factor) { int i; - for (i=0;i<3;i++) nlMatrixAdd(ia+i, op+ic+i, factor); + for (i=0;i<3;i++) EIG_linear_solver_matrix_add(ia+i, op+ic+i, factor); } static void dfdv_goal(int ia, int ic, float factor) { int i; - for (i=0;i<3;i++) nlMatrixAdd(ia+i, ic+i, factor); + for (i=0;i<3;i++) EIG_linear_solver_matrix_add(ia+i, ic+i, factor); } */ static void sb_spring_force(Object *ob, int bpi, BodySpring *bs, float iks, float UNUSED(forcetime)) diff --git a/source/blender/blenlib/intern/math_solvers.c b/source/blender/blenlib/intern/math_solvers.c index c27c6bea160..641e50c9bde 100644 --- a/source/blender/blenlib/intern/math_solvers.c +++ b/source/blender/blenlib/intern/math_solvers.c @@ -57,7 +57,7 @@ bool BLI_eigen_solve_selfadjoint_m3(const float m3[3][3], float r_eigen_values[3 } #endif - return EG3_self_adjoint_eigen_solve(3, (const float *)m3, r_eigen_values, (float *)r_eigen_vectors); + return EIG_self_adjoint_eigen_solve(3, (const float *)m3, r_eigen_values, (float *)r_eigen_vectors); } /** @@ -70,5 +70,5 @@ bool BLI_eigen_solve_selfadjoint_m3(const float m3[3][3], float r_eigen_values[3 */ void BLI_svd_m3(const float m3[3][3], float r_U[3][3], float r_S[3], float r_V[3][3]) { - EG3_svd_square_matrix(3, (const float *)m3, (float *)r_U, (float *)r_S, (float *)r_V); + EIG_svd_square_matrix(3, (const float *)m3, (float *)r_U, (float *)r_S, (float *)r_V); } diff --git a/source/blender/bmesh/CMakeLists.txt b/source/blender/bmesh/CMakeLists.txt index 686b8507291..d13d3e1cd0f 100644 --- a/source/blender/bmesh/CMakeLists.txt +++ b/source/blender/bmesh/CMakeLists.txt @@ -30,6 +30,7 @@ set(INC ../blentranslation ../makesdna ../../../intern/guardedalloc + ../../../intern/eigen ../../../extern/rangetree ) @@ -176,13 +177,6 @@ if(WITH_INTERNATIONAL) add_definitions(-DWITH_INTERNATIONAL) endif() -if(WITH_OPENNL) - add_definitions(-DWITH_OPENNL) - list(APPEND INC_SYS - ../../../intern/opennl/extern - ) -endif() - if(WITH_FREESTYLE) add_definitions(-DWITH_FREESTYLE) endif() diff --git a/source/blender/bmesh/SConscript b/source/blender/bmesh/SConscript index c53974be1a7..6bf4fdf7c78 100644 --- a/source/blender/bmesh/SConscript +++ b/source/blender/bmesh/SConscript @@ -40,9 +40,9 @@ incs = [ '../makesdna', '../blenkernel', '#/intern/guardedalloc', + '#/intern/eigen', '#/extern/bullet2/src', '#/extern/rangetree', - '#/intern/opennl/extern' ] defs = [] diff --git a/source/blender/bmesh/operators/bmo_smooth_laplacian.c b/source/blender/bmesh/operators/bmo_smooth_laplacian.c index 624fbd93818..95ff3eb4858 100644 --- a/source/blender/bmesh/operators/bmo_smooth_laplacian.c +++ b/source/blender/bmesh/operators/bmo_smooth_laplacian.c @@ -28,18 +28,15 @@ #include "MEM_guardedalloc.h" - #include "BLI_math.h" +#include "eigen_capi.h" + #include "bmesh.h" #include "intern/bmesh_operators_private.h" /* own include */ -#ifdef WITH_OPENNL - -#include "ONL_opennl.h" - // #define SMOOTH_LAPLACIAN_AREA_FACTOR 4.0f /* UNUSED */ // #define SMOOTH_LAPLACIAN_EDGE_FACTOR 2.0f /* UNUSED */ #define SMOOTH_LAPLACIAN_MAX_EDGE_PERCENTAGE 1.8f @@ -59,7 +56,7 @@ struct BLaplacianSystem { /* Pointers to data*/ BMesh *bm; BMOperator *op; - NLContext *context; + LinearSolver *context; /*Data*/ float min_area; @@ -92,7 +89,7 @@ static void delete_laplacian_system(LaplacianSystem *sys) delete_void_pointer(sys->vweights); delete_void_pointer(sys->zerola); if (sys->context) { - nlDeleteContext(sys->context); + EIG_linear_solver_delete(sys->context); } sys->bm = NULL; sys->op = NULL; @@ -333,9 +330,9 @@ static void fill_laplacian_matrix(LaplacianSystem *sys) w4 = w4 / 4.0f; if (!vert_is_boundary(vf[j]) && sys->zerola[idv1] == 0) { - nlMatrixAdd(sys->context, idv1, idv2, w2 * sys->vweights[idv1]); - nlMatrixAdd(sys->context, idv1, idv3, w3 * sys->vweights[idv1]); - nlMatrixAdd(sys->context, idv1, idv4, w4 * sys->vweights[idv1]); + EIG_linear_solver_matrix_add(sys->context, idv1, idv2, w2 * sys->vweights[idv1]); + EIG_linear_solver_matrix_add(sys->context, idv1, idv3, w3 * sys->vweights[idv1]); + EIG_linear_solver_matrix_add(sys->context, idv1, idv4, w4 * sys->vweights[idv1]); } } } @@ -346,16 +343,16 @@ static void fill_laplacian_matrix(LaplacianSystem *sys) /* Is ring if number of faces == number of edges around vertice*/ i = BM_elem_index_get(f); if (!vert_is_boundary(vf[0]) && sys->zerola[idv1] == 0) { - nlMatrixAdd(sys->context, idv1, idv2, sys->fweights[i][2] * sys->vweights[idv1]); - nlMatrixAdd(sys->context, idv1, idv3, sys->fweights[i][1] * sys->vweights[idv1]); + EIG_linear_solver_matrix_add(sys->context, idv1, idv2, sys->fweights[i][2] * sys->vweights[idv1]); + EIG_linear_solver_matrix_add(sys->context, idv1, idv3, sys->fweights[i][1] * sys->vweights[idv1]); } if (!vert_is_boundary(vf[1]) && sys->zerola[idv2] == 0) { - nlMatrixAdd(sys->context, idv2, idv1, sys->fweights[i][2] * sys->vweights[idv2]); - nlMatrixAdd(sys->context, idv2, idv3, sys->fweights[i][0] * sys->vweights[idv2]); + EIG_linear_solver_matrix_add(sys->context, idv2, idv1, sys->fweights[i][2] * sys->vweights[idv2]); + EIG_linear_solver_matrix_add(sys->context, idv2, idv3, sys->fweights[i][0] * sys->vweights[idv2]); } if (!vert_is_boundary(vf[2]) && sys->zerola[idv3] == 0) { - nlMatrixAdd(sys->context, idv3, idv1, sys->fweights[i][1] * sys->vweights[idv3]); - nlMatrixAdd(sys->context, idv3, idv2, sys->fweights[i][0] * sys->vweights[idv3]); + EIG_linear_solver_matrix_add(sys->context, idv3, idv1, sys->fweights[i][1] * sys->vweights[idv3]); + EIG_linear_solver_matrix_add(sys->context, idv3, idv2, sys->fweights[i][0] * sys->vweights[idv3]); } } } @@ -368,8 +365,8 @@ static void fill_laplacian_matrix(LaplacianSystem *sys) idv2 = BM_elem_index_get(e->v2); if (sys->zerola[idv1] == 0 && sys->zerola[idv2] == 0) { i = BM_elem_index_get(e); - nlMatrixAdd(sys->context, idv1, idv2, sys->eweights[i] * sys->vlengths[idv1]); - nlMatrixAdd(sys->context, idv2, idv1, sys->eweights[i] * sys->vlengths[idv2]); + EIG_linear_solver_matrix_add(sys->context, idv1, idv2, sys->eweights[i] * sys->vlengths[idv1]); + EIG_linear_solver_matrix_add(sys->context, idv2, idv1, sys->eweights[i] * sys->vlengths[idv2]); } } } @@ -434,12 +431,12 @@ static void validate_solution(LaplacianSystem *sys, int usex, int usey, int usez idv2 = BM_elem_index_get(e->v2); vi1 = e->v1->co; vi2 = e->v2->co; - ve1[0] = nlGetVariable(sys->context, 0, idv1); - ve1[1] = nlGetVariable(sys->context, 1, idv1); - ve1[2] = nlGetVariable(sys->context, 2, idv1); - ve2[0] = nlGetVariable(sys->context, 0, idv2); - ve2[1] = nlGetVariable(sys->context, 1, idv2); - ve2[2] = nlGetVariable(sys->context, 2, idv2); + ve1[0] = EIG_linear_solver_variable_get(sys->context, 0, idv1); + ve1[1] = EIG_linear_solver_variable_get(sys->context, 1, idv1); + ve1[2] = EIG_linear_solver_variable_get(sys->context, 2, idv1); + ve2[0] = EIG_linear_solver_variable_get(sys->context, 0, idv2); + ve2[1] = EIG_linear_solver_variable_get(sys->context, 1, idv2); + ve2[2] = EIG_linear_solver_variable_get(sys->context, 2, idv2); leni = len_v3v3(vi1, vi2); lene = len_v3v3(ve1, ve2); if (lene > leni * SMOOTH_LAPLACIAN_MAX_EDGE_PERCENTAGE || lene < leni * SMOOTH_LAPLACIAN_MIN_EDGE_PERCENTAGE) { @@ -455,13 +452,13 @@ static void validate_solution(LaplacianSystem *sys, int usex, int usey, int usez m_vertex_id = BM_elem_index_get(v); if (sys->zerola[m_vertex_id] == 0) { if (usex) { - v->co[0] = nlGetVariable(sys->context, 0, m_vertex_id); + v->co[0] = EIG_linear_solver_variable_get(sys->context, 0, m_vertex_id); } if (usey) { - v->co[1] = nlGetVariable(sys->context, 1, m_vertex_id); + v->co[1] = EIG_linear_solver_variable_get(sys->context, 1, m_vertex_id); } if (usez) { - v->co[2] = nlGetVariable(sys->context, 2, m_vertex_id); + v->co[2] = EIG_linear_solver_variable_get(sys->context, 2, m_vertex_id); } } } @@ -501,32 +498,24 @@ void bmo_smooth_laplacian_vert_exec(BMesh *bm, BMOperator *op) preserve_volume = BMO_slot_bool_get(op->slots_in, "preserve_volume"); - sys->context = nlNewContext(); - - nlSolverParameteri(sys->context, NL_NB_VARIABLES, bm->totvert); - nlSolverParameteri(sys->context, NL_LEAST_SQUARES, NL_TRUE); - nlSolverParameteri(sys->context, NL_NB_ROWS, bm->totvert); - nlSolverParameteri(sys->context, NL_NB_RIGHT_HAND_SIDES, 3); + sys->context = EIG_linear_least_squares_solver_new(bm->totvert, bm->totvert, 3); - nlBegin(sys->context, NL_SYSTEM); for (i = 0; i < bm->totvert; i++) { - nlLockVariable(sys->context, i); + EIG_linear_solver_variable_lock(sys->context, i); } BMO_ITER (v, &siter, op->slots_in, "verts", BM_VERT) { m_vertex_id = BM_elem_index_get(v); - nlUnlockVariable(sys->context, m_vertex_id); - nlSetVariable(sys->context, 0, m_vertex_id, v->co[0]); - nlSetVariable(sys->context, 1, m_vertex_id, v->co[1]); - nlSetVariable(sys->context, 2, m_vertex_id, v->co[2]); + EIG_linear_solver_variable_set(sys->context, 0, m_vertex_id, v->co[0]); + EIG_linear_solver_variable_set(sys->context, 1, m_vertex_id, v->co[1]); + EIG_linear_solver_variable_set(sys->context, 2, m_vertex_id, v->co[2]); } - nlBegin(sys->context, NL_MATRIX); init_laplacian_matrix(sys); BMO_ITER (v, &siter, op->slots_in, "verts", BM_VERT) { m_vertex_id = BM_elem_index_get(v); - nlRightHandSideAdd(sys->context, 0, m_vertex_id, v->co[0]); - nlRightHandSideAdd(sys->context, 1, m_vertex_id, v->co[1]); - nlRightHandSideAdd(sys->context, 2, m_vertex_id, v->co[2]); + EIG_linear_solver_right_hand_side_add(sys->context, 0, m_vertex_id, v->co[0]); + EIG_linear_solver_right_hand_side_add(sys->context, 1, m_vertex_id, v->co[1]); + EIG_linear_solver_right_hand_side_add(sys->context, 2, m_vertex_id, v->co[2]); i = m_vertex_id; if (sys->zerola[i] == 0) { w = sys->vweights[i] * sys->ring_areas[i]; @@ -535,34 +524,22 @@ void bmo_smooth_laplacian_vert_exec(BMesh *bm, BMOperator *op) sys->vlengths[i] = (w == 0.0f) ? 0.0f : -lambda_border * 2.0f / w; if (!vert_is_boundary(v)) { - nlMatrixAdd(sys->context, i, i, 1.0f + lambda_factor / (4.0f * sys->ring_areas[i])); + EIG_linear_solver_matrix_add(sys->context, i, i, 1.0f + lambda_factor / (4.0f * sys->ring_areas[i])); } else { - nlMatrixAdd(sys->context, i, i, 1.0f + lambda_border * 2.0f); + EIG_linear_solver_matrix_add(sys->context, i, i, 1.0f + lambda_border * 2.0f); } } else { - nlMatrixAdd(sys->context, i, i, 1.0f); + EIG_linear_solver_matrix_add(sys->context, i, i, 1.0f); } } fill_laplacian_matrix(sys); - nlEnd(sys->context, NL_MATRIX); - nlEnd(sys->context, NL_SYSTEM); - - if (nlSolve(sys->context, NL_TRUE) ) { + if (EIG_linear_solver_solve(sys->context) ) { validate_solution(sys, usex, usey, usez, preserve_volume); } delete_laplacian_system(sys); } -#else /* WITH_OPENNL */ - -#ifdef __GNUC__ -# pragma GCC diagnostic ignored "-Wunused-parameter" -#endif - -void bmo_smooth_laplacian_vert_exec(BMesh *bm, BMOperator *op) {} - -#endif /* WITH_OPENNL */ diff --git a/source/blender/editors/armature/CMakeLists.txt b/source/blender/editors/armature/CMakeLists.txt index 1ed70b3cd98..b213aca478f 100644 --- a/source/blender/editors/armature/CMakeLists.txt +++ b/source/blender/editors/armature/CMakeLists.txt @@ -28,6 +28,7 @@ set(INC ../../makesrna ../../windowmanager ../../../../intern/guardedalloc + ../../../../intern/eigen ../../../../intern/glew-mx ) @@ -68,13 +69,6 @@ if(WITH_INTERNATIONAL) add_definitions(-DWITH_INTERNATIONAL) endif() -if(WITH_OPENNL) - add_definitions(-DWITH_OPENNL) - list(APPEND INC_SYS - ../../../../intern/opennl/extern - ) -endif() - add_definitions(${GL_DEFINITIONS}) blender_add_lib(bf_editor_armature "${SRC}" "${INC}" "${INC_SYS}") diff --git a/source/blender/editors/armature/SConscript b/source/blender/editors/armature/SConscript index 9c3959ecb5b..850834d2cd4 100644 --- a/source/blender/editors/armature/SConscript +++ b/source/blender/editors/armature/SConscript @@ -31,9 +31,9 @@ sources = env.Glob('*.c') incs = [ '#/intern/guardedalloc', + '#/intern/eigen', env['BF_GLEW_INC'], '#/intern/glew-mx', - '#/intern/opennl/extern', '../include', '../../blenkernel', '../../blenlib', diff --git a/source/blender/editors/armature/armature_skinning.c b/source/blender/editors/armature/armature_skinning.c index ea1a94fbba6..c621d6f99c0 100644 --- a/source/blender/editors/armature/armature_skinning.c +++ b/source/blender/editors/armature/armature_skinning.c @@ -51,12 +51,10 @@ #include "ED_armature.h" #include "ED_mesh.h" +#include "eigen_capi.h" #include "armature_intern.h" - -#ifdef WITH_OPENNL -# include "meshlaplacian.h" -#endif +#include "meshlaplacian.h" #if 0 #include "reeb.h" @@ -401,12 +399,8 @@ static void add_verts_to_dgroups(ReportList *reports, Scene *scene, Object *ob, if (heat) { const char *error = NULL; -#ifdef WITH_OPENNL heat_bone_weighting(ob, mesh, verts, numbones, dgrouplist, dgroupflip, root, tip, selected, &error); -#else - error = "Built without OpenNL"; -#endif if (error) { BKE_report(reports, RPT_WARNING, error); } diff --git a/source/blender/editors/armature/meshlaplacian.c b/source/blender/editors/armature/meshlaplacian.c index 3f27a58930d..6bf75413e81 100644 --- a/source/blender/editors/armature/meshlaplacian.c +++ b/source/blender/editors/armature/meshlaplacian.c @@ -46,11 +46,9 @@ #include "ED_mesh.h" #include "ED_armature.h" -#include "meshlaplacian.h" - -#ifdef WITH_OPENNL +#include "eigen_capi.h" -#include "ONL_opennl.h" +#include "meshlaplacian.h" /* ************* XXX *************** */ static void waitcursor(int UNUSED(val)) {} @@ -64,7 +62,7 @@ static void error(const char *str) { printf("error: %s\n", str); } /************************** Laplacian System *****************************/ struct LaplacianSystem { - NLContext *context; /* opennl context */ + LinearSolver *context; /* linear solver */ int totvert, totface; @@ -76,7 +74,7 @@ struct LaplacianSystem { int areaweights; /* use area in cotangent weights? */ int storeweights; /* store cotangent weights in fweights */ - int nlbegun; /* nlBegin(NL_SYSTEM/NL_MATRIX) done */ + bool variablesdone; /* variables set in linear system */ EdgeHash *edgehash; /* edge hash for construction */ @@ -182,18 +180,18 @@ static void laplacian_triangle_weights(LaplacianSystem *sys, int f, int i1, int t2 = cotangent_tri_weight_v3(v2, v3, v1) / laplacian_edge_count(sys->edgehash, i3, i1); t3 = cotangent_tri_weight_v3(v3, v1, v2) / laplacian_edge_count(sys->edgehash, i1, i2); - nlMatrixAdd(sys->context, i1, i1, (t2 + t3) * varea[i1]); - nlMatrixAdd(sys->context, i2, i2, (t1 + t3) * varea[i2]); - nlMatrixAdd(sys->context, i3, i3, (t1 + t2) * varea[i3]); + EIG_linear_solver_matrix_add(sys->context, i1, i1, (t2 + t3) * varea[i1]); + EIG_linear_solver_matrix_add(sys->context, i2, i2, (t1 + t3) * varea[i2]); + EIG_linear_solver_matrix_add(sys->context, i3, i3, (t1 + t2) * varea[i3]); - nlMatrixAdd(sys->context, i1, i2, -t3 * varea[i1]); - nlMatrixAdd(sys->context, i2, i1, -t3 * varea[i2]); + EIG_linear_solver_matrix_add(sys->context, i1, i2, -t3 * varea[i1]); + EIG_linear_solver_matrix_add(sys->context, i2, i1, -t3 * varea[i2]); - nlMatrixAdd(sys->context, i2, i3, -t1 * varea[i2]); - nlMatrixAdd(sys->context, i3, i2, -t1 * varea[i3]); + EIG_linear_solver_matrix_add(sys->context, i2, i3, -t1 * varea[i2]); + EIG_linear_solver_matrix_add(sys->context, i3, i2, -t1 * varea[i3]); - nlMatrixAdd(sys->context, i3, i1, -t2 * varea[i3]); - nlMatrixAdd(sys->context, i1, i3, -t2 * varea[i1]); + EIG_linear_solver_matrix_add(sys->context, i3, i1, -t2 * varea[i3]); + EIG_linear_solver_matrix_add(sys->context, i1, i3, -t2 * varea[i1]); if (sys->storeweights) { sys->fweights[f][0] = t1 * varea[i1]; @@ -218,11 +216,11 @@ static LaplacianSystem *laplacian_system_construct_begin(int totvert, int totfac sys->areaweights = 1; sys->storeweights = 0; - /* create opennl context */ - sys->context = nlNewContext(); - nlSolverParameteri(sys->context, NL_NB_VARIABLES, totvert); + /* create linear solver */ if (lsq) - nlSolverParameteri(sys->context, NL_LEAST_SQUARES, NL_TRUE); + sys->context = EIG_linear_least_squares_solver_new(0, totvert, 1); + else + sys->context = EIG_linear_solver_new(0, totvert, 1); return sys; } @@ -272,7 +270,7 @@ static void laplacian_system_construct_end(LaplacianSystem *sys) /* for heat weighting */ if (sys->heat.H) - nlMatrixAdd(sys->context, a, a, sys->heat.H[a]); + EIG_linear_solver_matrix_add(sys->context, a, a, sys->heat.H[a]); } if (sys->storeweights) @@ -301,7 +299,7 @@ static void laplacian_system_delete(LaplacianSystem *sys) if (sys->faces) MEM_freeN(sys->faces); if (sys->fweights) MEM_freeN(sys->fweights); - nlDeleteContext(sys->context); + EIG_linear_solver_delete(sys->context); MEM_freeN(sys); } @@ -309,42 +307,37 @@ void laplacian_begin_solve(LaplacianSystem *sys, int index) { int a; - if (!sys->nlbegun) { - nlBegin(sys->context, NL_SYSTEM); - + if (!sys->variablesdone) { if (index >= 0) { for (a = 0; a < sys->totvert; a++) { if (sys->vpinned[a]) { - nlSetVariable(sys->context, 0, a, sys->verts[a][index]); - nlLockVariable(sys->context, a); + EIG_linear_solver_variable_set(sys->context, 0, a, sys->verts[a][index]); + EIG_linear_solver_variable_lock(sys->context, a); } } } - nlBegin(sys->context, NL_MATRIX); - sys->nlbegun = 1; + sys->variablesdone = true; } } void laplacian_add_right_hand_side(LaplacianSystem *sys, int v, float value) { - nlRightHandSideAdd(sys->context, 0, v, value); + EIG_linear_solver_right_hand_side_add(sys->context, 0, v, value); } int laplacian_system_solve(LaplacianSystem *sys) { - nlEnd(sys->context, NL_MATRIX); - nlEnd(sys->context, NL_SYSTEM); - sys->nlbegun = 0; + sys->variablesdone = false; - //nlPrintMatrix(sys->context, ); + //EIG_linear_solver_print_matrix(sys->context, ); - return nlSolve(sys->context, NL_TRUE); + return EIG_linear_solver_solve(sys->context); } float laplacian_system_get_solution(LaplacianSystem *sys, int v) { - return nlGetVariable(sys->context, 0, v); + return EIG_linear_solver_variable_get(sys->context, 0, v); } /************************* Heat Bone Weighting ******************************/ @@ -1284,7 +1277,7 @@ static float meshdeform_boundary_total_weight(MeshDeformBind *mdb, int x, int y, return totweight; } -static void meshdeform_matrix_add_cell(MeshDeformBind *mdb, NLContext *context, int x, int y, int z) +static void meshdeform_matrix_add_cell(MeshDeformBind *mdb, LinearSolver *context, int x, int y, int z) { MDefBoundIsect *isect; float weight, totweight; @@ -1294,7 +1287,7 @@ static void meshdeform_matrix_add_cell(MeshDeformBind *mdb, NLContext *context, if (mdb->tag[acenter] == MESHDEFORM_TAG_EXTERIOR) return; - nlMatrixAdd(context, mdb->varidx[acenter], mdb->varidx[acenter], 1.0f); + EIG_linear_solver_matrix_add(context, mdb->varidx[acenter], mdb->varidx[acenter], 1.0f); totweight = meshdeform_boundary_total_weight(mdb, x, y, z); for (i = 1; i <= 6; i++) { @@ -1305,12 +1298,12 @@ static void meshdeform_matrix_add_cell(MeshDeformBind *mdb, NLContext *context, isect = mdb->boundisect[acenter][i - 1]; if (!isect) { weight = (1.0f / mdb->width[0]) / totweight; - nlMatrixAdd(context, mdb->varidx[acenter], mdb->varidx[a], -weight); + EIG_linear_solver_matrix_add(context, mdb->varidx[acenter], mdb->varidx[a], -weight); } } } -static void meshdeform_matrix_add_rhs(MeshDeformBind *mdb, NLContext *context, int x, int y, int z, int cagevert) +static void meshdeform_matrix_add_rhs(MeshDeformBind *mdb, LinearSolver *context, int x, int y, int z, int cagevert) { MDefBoundIsect *isect; float rhs, weight, totweight; @@ -1331,7 +1324,7 @@ static void meshdeform_matrix_add_rhs(MeshDeformBind *mdb, NLContext *context, i if (isect) { weight = (1.0f / isect->len) / totweight; rhs = weight * meshdeform_boundary_phi(mdb, isect, cagevert); - nlRightHandSideAdd(context, 0, mdb->varidx[acenter], rhs); + EIG_linear_solver_right_hand_side_add(context, 0, mdb->varidx[acenter], rhs); } } } @@ -1386,7 +1379,7 @@ static void meshdeform_matrix_add_exterior_phi(MeshDeformBind *mdb, int x, int y static void meshdeform_matrix_solve(MeshDeformModifierData *mmd, MeshDeformBind *mdb) { - NLContext *context; + LinearSolver *context; float vec[3], gridvec[3]; int a, b, x, y, z, totvar; char message[256]; @@ -1403,15 +1396,8 @@ static void meshdeform_matrix_solve(MeshDeformModifierData *mmd, MeshDeformBind progress_bar(0, "Starting mesh deform solve"); - /* setup opennl solver */ - context = nlNewContext(); - - nlSolverParameteri(context, NL_NB_VARIABLES, totvar); - nlSolverParameteri(context, NL_NB_ROWS, totvar); - nlSolverParameteri(context, NL_NB_RIGHT_HAND_SIDES, 1); - - nlBegin(context, NL_SYSTEM); - nlBegin(context, NL_MATRIX); + /* setup linear solver */ + context = EIG_linear_solver_new(totvar, totvar, 1); /* build matrix */ for (z = 0; z < mdb->size; z++) @@ -1421,21 +1407,13 @@ static void meshdeform_matrix_solve(MeshDeformModifierData *mmd, MeshDeformBind /* solve for each cage vert */ for (a = 0; a < mdb->totcagevert; a++) { - if (a != 0) { - nlBegin(context, NL_SYSTEM); - nlBegin(context, NL_MATRIX); - } - /* fill in right hand side and solve */ for (z = 0; z < mdb->size; z++) for (y = 0; y < mdb->size; y++) for (x = 0; x < mdb->size; x++) meshdeform_matrix_add_rhs(mdb, context, x, y, z, a); - nlEnd(context, NL_MATRIX); - nlEnd(context, NL_SYSTEM); - - if (nlSolve(context, NL_TRUE)) { + if (EIG_linear_solver_solve(context)) { for (z = 0; z < mdb->size; z++) for (y = 0; y < mdb->size; y++) for (x = 0; x < mdb->size; x++) @@ -1448,7 +1426,7 @@ static void meshdeform_matrix_solve(MeshDeformModifierData *mmd, MeshDeformBind for (b = 0; b < mdb->size3; b++) { if (mdb->tag[b] != MESHDEFORM_TAG_EXTERIOR) - mdb->phi[b] = nlGetVariable(context, 0, mdb->varidx[b]); + mdb->phi[b] = EIG_linear_solver_variable_get(context, 0, mdb->varidx[b]); mdb->totalphi[b] += mdb->phi[b]; } @@ -1502,7 +1480,7 @@ static void meshdeform_matrix_solve(MeshDeformModifierData *mmd, MeshDeformBind /* free */ MEM_freeN(mdb->varidx); - nlDeleteContext(context); + EIG_linear_solver_delete(context); } static void harmonic_coordinates_bind(Scene *UNUSED(scene), MeshDeformModifierData *mmd, MeshDeformBind *mdb) @@ -1705,13 +1683,3 @@ void mesh_deform_bind(Scene *scene, MeshDeformModifierData *mmd, float *vertexco waitcursor(0); } -#else /* WITH_OPENNL */ - -#ifdef __GNUC__ -# pragma GCC diagnostic ignored "-Wunused-parameter" -#endif - -void mesh_deform_bind(Scene *scene, MeshDeformModifierData *mmd, float *vertexcos, int totvert, float cagemat[4][4]) {} -void *modifier_mdef_compact_influences_link_kludge = modifier_mdef_compact_influences; - -#endif /* WITH_OPENNL */ diff --git a/source/blender/editors/armature/reeb.c b/source/blender/editors/armature/reeb.c index d53e5b857a0..a1c1f4f115e 100644 --- a/source/blender/editors/armature/reeb.c +++ b/source/blender/editors/armature/reeb.c @@ -2497,7 +2497,7 @@ int weightFromLoc(EditMesh *em, int axis) return 1; } -static void addTriangle(NLContext *context, EditVert *v1, EditVert *v2, EditVert *v3, int e1, int e2, int e3) +static void addTriangle(LinearSolver *context, EditVert *v1, EditVert *v2, EditVert *v3, int e1, int e2, int e3) { /* Angle opposite e1 */ float t1 = cotangent_tri_weight_v3(v1->co, v2->co, v3->co) / e2; @@ -2512,23 +2512,23 @@ static void addTriangle(NLContext *context, EditVert *v1, EditVert *v2, EditVert int i2 = indexData(v2); int i3 = indexData(v3); - nlMatrixAdd(context, i1, i1, t2 + t3); - nlMatrixAdd(context, i2, i2, t1 + t3); - nlMatrixAdd(context, i3, i3, t1 + t2); + EIG_linear_solver_matrix_add(context, i1, i1, t2 + t3); + EIG_linear_solver_matrix_add(context, i2, i2, t1 + t3); + EIG_linear_solver_matrix_add(context, i3, i3, t1 + t2); - nlMatrixAdd(context, i1, i2, -t3); - nlMatrixAdd(context, i2, i1, -t3); + EIG_linear_solver_matrix_add(context, i1, i2, -t3); + EIG_linear_solver_matrix_add(context, i2, i1, -t3); - nlMatrixAdd(context, i2, i3, -t1); - nlMatrixAdd(context, i3, i2, -t1); + EIG_linear_solver_matrix_add(context, i2, i3, -t1); + EIG_linear_solver_matrix_add(context, i3, i2, -t1); - nlMatrixAdd(context, i3, i1, -t2); - nlMatrixAdd(context, i1, i3, -t2); + EIG_linear_solver_matrix_add(context, i3, i1, -t2); + EIG_linear_solver_matrix_add(context, i1, i3, -t2); } int weightToHarmonic(EditMesh *em, EdgeIndex *indexed_edges) { - NLContext *context; + LinearSolver *context; NLboolean success; EditVert *eve; EditEdge *eed; @@ -2542,14 +2542,10 @@ int weightToHarmonic(EditMesh *em, EdgeIndex *indexed_edges) totvert++; } - /* Solve with openNL */ + /* Solve */ - context = nlNewContext(); + context = EIG_linear_solver_new(, 0, totvert, 1); - nlSolverParameteri(context, NL_NB_VARIABLES, totvert); - - nlBegin(context, NL_SYSTEM); - /* Find local extrema */ for (index = 0, eve = em->verts.first; eve; index++, eve = eve->next) { if (eve->h == 0) { @@ -2583,8 +2579,8 @@ int weightToHarmonic(EditMesh *em, EdgeIndex *indexed_edges) if (maximum || minimum) { float w = weightData(eve); eve->f1 = 0; - nlSetVariable(context, 0, index, w); - nlLockVariable(context, index); + EIG_linear_solver_variable_set(context, 0, index, w); + EIG_linear_solver_variable_lock(context, index); } else { eve->f1 = 1; @@ -2592,8 +2588,6 @@ int weightToHarmonic(EditMesh *em, EdgeIndex *indexed_edges) } } - nlBegin(context, NL_MATRIX); - /* Zero edge weight */ for (eed = em->edges.first; eed; eed = eed->next) { eed->tmp.l = 0; @@ -2625,23 +2619,19 @@ int weightToHarmonic(EditMesh *em, EdgeIndex *indexed_edges) } } - nlEnd(context, NL_MATRIX); - - nlEnd(context, NL_SYSTEM); - - success = nlSolve(context, NL_TRUE); + success = EIG_linear_solver_solve(context); if (success) { rval = 1; for (index = 0, eve = em->verts.first; eve; index++, eve = eve->next) { - weightSetData(eve, nlGetVariable(context, 0, index)); + weightSetData(eve, EIG_linear_solver_variable_get(context, 0, index)); } } else { rval = 0; } - nlDeleteContext(context); + EIG_linear_solver_delete(context); return rval; } diff --git a/source/blender/editors/uvedit/CMakeLists.txt b/source/blender/editors/uvedit/CMakeLists.txt index a90763eed4e..543ef0e0663 100644 --- a/source/blender/editors/uvedit/CMakeLists.txt +++ b/source/blender/editors/uvedit/CMakeLists.txt @@ -29,6 +29,7 @@ set(INC ../../makesrna ../../windowmanager ../../../../intern/guardedalloc + ../../../../intern/eigen ../../../../intern/glew-mx ) @@ -52,13 +53,6 @@ if(WITH_INTERNATIONAL) add_definitions(-DWITH_INTERNATIONAL) endif() -if(WITH_OPENNL) - add_definitions(-DWITH_OPENNL) - list(APPEND INC_SYS - ../../../../intern/opennl/extern - ) -endif() - add_definitions(${GL_DEFINITIONS}) blender_add_lib(bf_editor_uvedit "${SRC}" "${INC}" "${INC_SYS}") diff --git a/source/blender/editors/uvedit/SConscript b/source/blender/editors/uvedit/SConscript index b5cccab4002..85ea7f45536 100644 --- a/source/blender/editors/uvedit/SConscript +++ b/source/blender/editors/uvedit/SConscript @@ -34,9 +34,9 @@ sources = env.Glob('*.c') incs = [ '#/intern/guardedalloc', + '#/intern/eigen', env['BF_GLEW_INC'], '#/intern/glew-mx', - '#/intern/opennl/extern', '../include', '../../blenkernel', '../../blenlib', diff --git a/source/blender/editors/uvedit/uvedit_parametrizer.c b/source/blender/editors/uvedit/uvedit_parametrizer.c index 311c152a239..e1495b617f8 100644 --- a/source/blender/editors/uvedit/uvedit_parametrizer.c +++ b/source/blender/editors/uvedit/uvedit_parametrizer.c @@ -44,9 +44,7 @@ #include "BLI_sys_types.h" /* for intptr_t support */ -#ifdef WITH_OPENNL - -#include "ONL_opennl.h" +#include "eigen_capi.h" /* Utils */ @@ -193,7 +191,7 @@ typedef struct PChart { union PChartUnion { struct PChartLscm { - NLContext *context; + LinearSolver *context; float *abf_alpha; PVert *pin1, *pin2; } lscm; @@ -2471,17 +2469,12 @@ static PBool p_abf_matrix_invert(PAbfSystem *sys, PChart *chart) PEdge *e; int i, j, ninterior = sys->ninterior, nvar = 2 * sys->ninterior; PBool success; - NLContext *context; - - context = nlNewContext(); - nlSolverParameteri(context, NL_NB_VARIABLES, nvar); + LinearSolver *context; - nlBegin(context, NL_SYSTEM); - - nlBegin(context, NL_MATRIX); + context = EIG_linear_solver_new(0, nvar, 1); for (i = 0; i < nvar; i++) - nlRightHandSideAdd(context, 0, i, sys->bInterior[i]); + EIG_linear_solver_right_hand_side_add(context, 0, i, sys->bInterior[i]); for (f = chart->faces; f; f = f->nextlink) { float wi1, wi2, wi3, b, si, beta[3], j2[3][3], W[3][3]; @@ -2527,8 +2520,8 @@ static PBool p_abf_matrix_invert(PAbfSystem *sys, PChart *chart) sys->J2dt[e2->u.id][0] = j2[1][0] = p_abf_compute_sin_product(sys, v1, e2->u.id) * wi2; sys->J2dt[e3->u.id][0] = j2[2][0] = p_abf_compute_sin_product(sys, v1, e3->u.id) * wi3; - nlRightHandSideAdd(context, 0, v1->u.id, j2[0][0] * beta[0]); - nlRightHandSideAdd(context, 0, ninterior + v1->u.id, j2[1][0] * beta[1] + j2[2][0] * beta[2]); + EIG_linear_solver_right_hand_side_add(context, 0, v1->u.id, j2[0][0] * beta[0]); + EIG_linear_solver_right_hand_side_add(context, 0, ninterior + v1->u.id, j2[1][0] * beta[1] + j2[2][0] * beta[2]); row1[0] = j2[0][0] * W[0][0]; row2[0] = j2[0][0] * W[1][0]; @@ -2547,8 +2540,8 @@ static PBool p_abf_matrix_invert(PAbfSystem *sys, PChart *chart) sys->J2dt[e2->u.id][1] = j2[1][1] = 1.0f * wi2; sys->J2dt[e3->u.id][1] = j2[2][1] = p_abf_compute_sin_product(sys, v2, e3->u.id) * wi3; - nlRightHandSideAdd(context, 0, v2->u.id, j2[1][1] * beta[1]); - nlRightHandSideAdd(context, 0, ninterior + v2->u.id, j2[0][1] * beta[0] + j2[2][1] * beta[2]); + EIG_linear_solver_right_hand_side_add(context, 0, v2->u.id, j2[1][1] * beta[1]); + EIG_linear_solver_right_hand_side_add(context, 0, ninterior + v2->u.id, j2[0][1] * beta[0] + j2[2][1] * beta[2]); row1[1] = j2[1][1] * W[0][1]; row2[1] = j2[1][1] * W[1][1]; @@ -2567,8 +2560,8 @@ static PBool p_abf_matrix_invert(PAbfSystem *sys, PChart *chart) sys->J2dt[e2->u.id][2] = j2[1][2] = p_abf_compute_sin_product(sys, v3, e2->u.id) * wi2; sys->J2dt[e3->u.id][2] = j2[2][2] = 1.0f * wi3; - nlRightHandSideAdd(context, 0, v3->u.id, j2[2][2] * beta[2]); - nlRightHandSideAdd(context, 0, ninterior + v3->u.id, j2[0][2] * beta[0] + j2[1][2] * beta[1]); + EIG_linear_solver_right_hand_side_add(context, 0, v3->u.id, j2[2][2] * beta[2]); + EIG_linear_solver_right_hand_side_add(context, 0, ninterior + v3->u.id, j2[0][2] * beta[0] + j2[1][2] * beta[1]); row1[2] = j2[2][2] * W[0][2]; row2[2] = j2[2][2] * W[1][2]; @@ -2592,29 +2585,25 @@ static PBool p_abf_matrix_invert(PAbfSystem *sys, PChart *chart) continue; if (i == 0) - nlMatrixAdd(context, r, c, j2[0][i] * row1[j]); + EIG_linear_solver_matrix_add(context, r, c, j2[0][i] * row1[j]); else - nlMatrixAdd(context, r + ninterior, c, j2[0][i] * row1[j]); + EIG_linear_solver_matrix_add(context, r + ninterior, c, j2[0][i] * row1[j]); if (i == 1) - nlMatrixAdd(context, r, c, j2[1][i] * row2[j]); + EIG_linear_solver_matrix_add(context, r, c, j2[1][i] * row2[j]); else - nlMatrixAdd(context, r + ninterior, c, j2[1][i] * row2[j]); + EIG_linear_solver_matrix_add(context, r + ninterior, c, j2[1][i] * row2[j]); if (i == 2) - nlMatrixAdd(context, r, c, j2[2][i] * row3[j]); + EIG_linear_solver_matrix_add(context, r, c, j2[2][i] * row3[j]); else - nlMatrixAdd(context, r + ninterior, c, j2[2][i] * row3[j]); + EIG_linear_solver_matrix_add(context, r + ninterior, c, j2[2][i] * row3[j]); } } } - nlEnd(context, NL_MATRIX); - - nlEnd(context, NL_SYSTEM); - - success = nlSolve(context, NL_FALSE); + success = EIG_linear_solver_solve(context); if (success) { for (f = chart->faces; f; f = f->nextlink) { @@ -2625,24 +2614,24 @@ static PBool p_abf_matrix_invert(PAbfSystem *sys, PChart *chart) pre[0] = pre[1] = pre[2] = 0.0; if (v1->flag & PVERT_INTERIOR) { - float x = nlGetVariable(context, 0, v1->u.id); - float x2 = nlGetVariable(context, 0, ninterior + v1->u.id); + float x = EIG_linear_solver_variable_get(context, 0, v1->u.id); + float x2 = EIG_linear_solver_variable_get(context, 0, ninterior + v1->u.id); pre[0] += sys->J2dt[e1->u.id][0] * x; pre[1] += sys->J2dt[e2->u.id][0] * x2; pre[2] += sys->J2dt[e3->u.id][0] * x2; } if (v2->flag & PVERT_INTERIOR) { - float x = nlGetVariable(context, 0, v2->u.id); - float x2 = nlGetVariable(context, 0, ninterior + v2->u.id); + float x = EIG_linear_solver_variable_get(context, 0, v2->u.id); + float x2 = EIG_linear_solver_variable_get(context, 0, ninterior + v2->u.id); pre[0] += sys->J2dt[e1->u.id][1] * x2; pre[1] += sys->J2dt[e2->u.id][1] * x; pre[2] += sys->J2dt[e3->u.id][1] * x2; } if (v3->flag & PVERT_INTERIOR) { - float x = nlGetVariable(context, 0, v3->u.id); - float x2 = nlGetVariable(context, 0, ninterior + v3->u.id); + float x = EIG_linear_solver_variable_get(context, 0, v3->u.id); + float x2 = EIG_linear_solver_variable_get(context, 0, ninterior + v3->u.id); pre[0] += sys->J2dt[e1->u.id][2] * x2; pre[1] += sys->J2dt[e2->u.id][2] * x2; pre[2] += sys->J2dt[e3->u.id][2] * x; @@ -2673,12 +2662,12 @@ static PBool p_abf_matrix_invert(PAbfSystem *sys, PChart *chart) } for (i = 0; i < ninterior; i++) { - sys->lambdaPlanar[i] += (float)nlGetVariable(context, 0, i); - sys->lambdaLength[i] += (float)nlGetVariable(context, 0, ninterior + i); + sys->lambdaPlanar[i] += (float)EIG_linear_solver_variable_get(context, 0, i); + sys->lambdaLength[i] += (float)EIG_linear_solver_variable_get(context, 0, ninterior + i); } } - nlDeleteContext(context); + EIG_linear_solver_delete(context); return success; } @@ -3004,12 +2993,12 @@ static void p_chart_extrema_verts(PChart *chart, PVert **pin1, PVert **pin2) static void p_chart_lscm_load_solution(PChart *chart) { - NLContext *context = chart->u.lscm.context; + LinearSolver *context = chart->u.lscm.context; PVert *v; for (v = chart->verts; v; v = v->nextlink) { - v->uv[0] = nlGetVariable(context, 0, 2 * v->u.id); - v->uv[1] = nlGetVariable(context, 0, 2 * v->u.id + 1); + v->uv[0] = EIG_linear_solver_variable_get(context, 0, 2 * v->u.id); + v->uv[1] = EIG_linear_solver_variable_get(context, 0, 2 * v->u.id + 1); } } @@ -3064,16 +3053,13 @@ static void p_chart_lscm_begin(PChart *chart, PBool live, PBool abf) for (v = chart->verts; v; v = v->nextlink) v->u.id = id++; - chart->u.lscm.context = nlNewContext(); - nlSolverParameteri(chart->u.lscm.context, NL_NB_VARIABLES, 2 * chart->nverts); - nlSolverParameteri(chart->u.lscm.context, NL_NB_ROWS, 2 * chart->nfaces); - nlSolverParameteri(chart->u.lscm.context, NL_LEAST_SQUARES, NL_TRUE); + chart->u.lscm.context = EIG_linear_least_squares_solver_new(2 * chart->nfaces, 2 * chart->nverts, 1); } } static PBool p_chart_lscm_solve(PHandle *handle, PChart *chart) { - NLContext *context = chart->u.lscm.context; + LinearSolver *context = chart->u.lscm.context; PVert *v, *pin1 = chart->u.lscm.pin1, *pin2 = chart->u.lscm.pin2; PFace *f; float *alpha = chart->u.lscm.abf_alpha; @@ -3081,8 +3067,6 @@ static PBool p_chart_lscm_solve(PHandle *handle, PChart *chart) bool flip_faces; int row; - nlBegin(context, NL_SYSTEM); - #if 0 /* TODO: make loading pins work for simplify/complexify. */ #endif @@ -3092,25 +3076,25 @@ static PBool p_chart_lscm_solve(PHandle *handle, PChart *chart) p_vert_load_pin_select_uvs(handle, v); /* reload for live */ if (chart->u.lscm.pin1) { - nlLockVariable(context, 2 * pin1->u.id); - nlLockVariable(context, 2 * pin1->u.id + 1); - nlLockVariable(context, 2 * pin2->u.id); - nlLockVariable(context, 2 * pin2->u.id + 1); + EIG_linear_solver_variable_lock(context, 2 * pin1->u.id); + EIG_linear_solver_variable_lock(context, 2 * pin1->u.id + 1); + EIG_linear_solver_variable_lock(context, 2 * pin2->u.id); + EIG_linear_solver_variable_lock(context, 2 * pin2->u.id + 1); - nlSetVariable(context, 0, 2 * pin1->u.id, pin1->uv[0]); - nlSetVariable(context, 0, 2 * pin1->u.id + 1, pin1->uv[1]); - nlSetVariable(context, 0, 2 * pin2->u.id, pin2->uv[0]); - nlSetVariable(context, 0, 2 * pin2->u.id + 1, pin2->uv[1]); + EIG_linear_solver_variable_set(context, 0, 2 * pin1->u.id, pin1->uv[0]); + EIG_linear_solver_variable_set(context, 0, 2 * pin1->u.id + 1, pin1->uv[1]); + EIG_linear_solver_variable_set(context, 0, 2 * pin2->u.id, pin2->uv[0]); + EIG_linear_solver_variable_set(context, 0, 2 * pin2->u.id + 1, pin2->uv[1]); } else { /* set and lock the pins */ for (v = chart->verts; v; v = v->nextlink) { if (v->flag & PVERT_PIN) { - nlLockVariable(context, 2 * v->u.id); - nlLockVariable(context, 2 * v->u.id + 1); + EIG_linear_solver_variable_lock(context, 2 * v->u.id); + EIG_linear_solver_variable_lock(context, 2 * v->u.id + 1); - nlSetVariable(context, 0, 2 * v->u.id, v->uv[0]); - nlSetVariable(context, 0, 2 * v->u.id + 1, v->uv[1]); + EIG_linear_solver_variable_set(context, 0, 2 * v->u.id, v->uv[0]); + EIG_linear_solver_variable_set(context, 0, 2 * v->u.id + 1, v->uv[1]); } } } @@ -3137,8 +3121,6 @@ static PBool p_chart_lscm_solve(PHandle *handle, PChart *chart) /* construct matrix */ - nlBegin(context, NL_MATRIX); - row = 0; for (f = chart->faces; f; f = f->nextlink) { PEdge *e1 = f->edge, *e2 = e1->next, *e3 = e2->next; @@ -3185,26 +3167,22 @@ static PBool p_chart_lscm_solve(PHandle *handle, PChart *chart) cosine = cosf(a1) * ratio; sine = sina1 * ratio; - nlMatrixAdd(context, row, 2 * v1->u.id, cosine - 1.0f); - nlMatrixAdd(context, row, 2 * v1->u.id + 1, -sine); - nlMatrixAdd(context, row, 2 * v2->u.id, -cosine); - nlMatrixAdd(context, row, 2 * v2->u.id + 1, sine); - nlMatrixAdd(context, row, 2 * v3->u.id, 1.0); + EIG_linear_solver_matrix_add(context, row, 2 * v1->u.id, cosine - 1.0f); + EIG_linear_solver_matrix_add(context, row, 2 * v1->u.id + 1, -sine); + EIG_linear_solver_matrix_add(context, row, 2 * v2->u.id, -cosine); + EIG_linear_solver_matrix_add(context, row, 2 * v2->u.id + 1, sine); + EIG_linear_solver_matrix_add(context, row, 2 * v3->u.id, 1.0); row++; - nlMatrixAdd(context, row, 2 * v1->u.id, sine); - nlMatrixAdd(context, row, 2 * v1->u.id + 1, cosine - 1.0f); - nlMatrixAdd(context, row, 2 * v2->u.id, -sine); - nlMatrixAdd(context, row, 2 * v2->u.id + 1, -cosine); - nlMatrixAdd(context, row, 2 * v3->u.id + 1, 1.0); + EIG_linear_solver_matrix_add(context, row, 2 * v1->u.id, sine); + EIG_linear_solver_matrix_add(context, row, 2 * v1->u.id + 1, cosine - 1.0f); + EIG_linear_solver_matrix_add(context, row, 2 * v2->u.id, -sine); + EIG_linear_solver_matrix_add(context, row, 2 * v2->u.id + 1, -cosine); + EIG_linear_solver_matrix_add(context, row, 2 * v3->u.id + 1, 1.0); row++; } - nlEnd(context, NL_MATRIX); - - nlEnd(context, NL_SYSTEM); - - if (nlSolve(context, NL_TRUE)) { + if (EIG_linear_solver_solve(context)) { p_chart_lscm_load_solution(chart); return P_TRUE; } @@ -3221,7 +3199,7 @@ static PBool p_chart_lscm_solve(PHandle *handle, PChart *chart) static void p_chart_lscm_end(PChart *chart) { if (chart->u.lscm.context) - nlDeleteContext(chart->u.lscm.context); + EIG_linear_solver_delete(chart->u.lscm.context); if (chart->u.lscm.abf_alpha) { MEM_freeN(chart->u.lscm.abf_alpha); @@ -4700,36 +4678,3 @@ void param_flush_restore(ParamHandle *handle) } } -#else /* WITH_OPENNL */ - -#ifdef __GNUC__ -# pragma GCC diagnostic ignored "-Wunused-parameter" -#endif - -/* stubs */ -void param_face_add(ParamHandle *handle, ParamKey key, int nverts, - ParamKey *vkeys, float **co, float **uv, - ParamBool *pin, ParamBool *select, float normal[3]) {} -void param_edge_set_seam(ParamHandle *handle, - ParamKey *vkeys) {} -void param_aspect_ratio(ParamHandle *handle, float aspx, float aspy) {} -ParamHandle *param_construct_begin(void) { return NULL; } -void param_construct_end(ParamHandle *handle, ParamBool fill, ParamBool impl) {} -void param_delete(ParamHandle *handle) {} - -void param_stretch_begin(ParamHandle *handle) {} -void param_stretch_blend(ParamHandle *handle, float blend) {} -void param_stretch_iter(ParamHandle *handle) {} -void param_stretch_end(ParamHandle *handle) {} - -void param_pack(ParamHandle *handle, float margin, bool do_rotate) {} -void param_average(ParamHandle *handle) {} - -void param_flush(ParamHandle *handle) {} -void param_flush_restore(ParamHandle *handle) {} - -void param_lscm_begin(ParamHandle *handle, ParamBool live, ParamBool abf) {} -void param_lscm_solve(ParamHandle *handle) {} -void param_lscm_end(ParamHandle *handle) {} - -#endif /* WITH_OPENNL */ diff --git a/source/blender/modifiers/CMakeLists.txt b/source/blender/modifiers/CMakeLists.txt index ad230dede24..0de7676e8f8 100644 --- a/source/blender/modifiers/CMakeLists.txt +++ b/source/blender/modifiers/CMakeLists.txt @@ -37,6 +37,7 @@ set(INC ../render/extern/include ../../../intern/elbeem/extern ../../../intern/guardedalloc + ../../../intern/eigen ) set(INC_SYS @@ -144,13 +145,6 @@ if(WITH_INTERNATIONAL) add_definitions(-DWITH_INTERNATIONAL) endif() -if(WITH_OPENNL) - add_definitions(-DWITH_OPENNL) - list(APPEND INC_SYS - ../../../intern/opennl/extern - ) -endif() - if(WITH_OPENSUBDIV) add_definitions(-DWITH_OPENSUBDIV) endif() diff --git a/source/blender/modifiers/SConscript b/source/blender/modifiers/SConscript index 7be295aa1a0..30007118562 100644 --- a/source/blender/modifiers/SConscript +++ b/source/blender/modifiers/SConscript @@ -33,8 +33,8 @@ incs = [ '.', './intern', '#/intern/guardedalloc', + '#/intern/eigen', '#/intern/elbeem/extern', - '#/intern/opennl/extern', '../render/extern/include', '../bmesh', '../include', diff --git a/source/blender/modifiers/intern/MOD_laplaciandeform.c b/source/blender/modifiers/intern/MOD_laplaciandeform.c index fdaacc7cd9e..d4f02d923d3 100644 --- a/source/blender/modifiers/intern/MOD_laplaciandeform.c +++ b/source/blender/modifiers/intern/MOD_laplaciandeform.c @@ -42,6 +42,7 @@ #include "MOD_util.h" +#include "eigen_capi.h" enum { LAPDEFORM_SYSTEM_NOT_CHANGE = 0, @@ -54,10 +55,6 @@ enum { LAPDEFORM_SYSTEM_CHANGE_NOT_VALID_GROUP, }; -#ifdef WITH_OPENNL - -#include "ONL_opennl.h" - typedef struct LaplacianSystem { bool is_matrix_computed; bool has_solution; @@ -75,7 +72,7 @@ typedef struct LaplacianSystem { int *unit_verts; /* Unit vectors of projected edges onto the plane orthogonal to n */ int *ringf_indices; /* Indices of faces per vertex */ int *ringv_indices; /* Indices of neighbors(vertex) per vertex */ - NLContext *context; /* System for solve general implicit rotations */ + LinearSolver *context; /* System for solve general implicit rotations */ MeshElemMap *ringf_map; /* Map of faces per vertex */ MeshElemMap *ringv_map; /* Map of vertex per vertex */ } LaplacianSystem; @@ -134,7 +131,7 @@ static void deleteLaplacianSystem(LaplacianSystem *sys) MEM_SAFE_FREE(sys->ringv_map); if (sys->context) { - nlDeleteContext(sys->context); + EIG_linear_solver_delete(sys->context); } MEM_SAFE_FREE(sys); } @@ -283,9 +280,9 @@ static void initLaplacianMatrix(LaplacianSystem *sys) sys->delta[idv[0]][1] -= v3[1] * w3; sys->delta[idv[0]][2] -= v3[2] * w3; - nlMatrixAdd(sys->context, idv[0], idv[1], -w2); - nlMatrixAdd(sys->context, idv[0], idv[2], -w3); - nlMatrixAdd(sys->context, idv[0], idv[0], w2 + w3); + EIG_linear_solver_matrix_add(sys->context, idv[0], idv[1], -w2); + EIG_linear_solver_matrix_add(sys->context, idv[0], idv[2], -w3); + EIG_linear_solver_matrix_add(sys->context, idv[0], idv[0], w2 + w3); } } } @@ -338,9 +335,9 @@ static void rotateDifferentialCoordinates(LaplacianSystem *sys) beta = dot_v3v3(uij, di); gamma = dot_v3v3(e2, di); - pi[0] = nlGetVariable(sys->context, 0, i); - pi[1] = nlGetVariable(sys->context, 1, i); - pi[2] = nlGetVariable(sys->context, 2, i); + pi[0] = EIG_linear_solver_variable_get(sys->context, 0, i); + pi[1] = EIG_linear_solver_variable_get(sys->context, 1, i); + pi[2] = EIG_linear_solver_variable_get(sys->context, 2, i); zero_v3(ni); num_fni = 0; num_fni = sys->ringf_map[i].count; @@ -349,9 +346,9 @@ static void rotateDifferentialCoordinates(LaplacianSystem *sys) fidn = sys->ringf_map[i].indices; vin = sys->tris[fidn[fi]]; for (j = 0; j < 3; j++) { - vn[j][0] = nlGetVariable(sys->context, 0, vin[j]); - vn[j][1] = nlGetVariable(sys->context, 1, vin[j]); - vn[j][2] = nlGetVariable(sys->context, 2, vin[j]); + vn[j][0] = EIG_linear_solver_variable_get(sys->context, 0, vin[j]); + vn[j][1] = EIG_linear_solver_variable_get(sys->context, 1, vin[j]); + vn[j][2] = EIG_linear_solver_variable_get(sys->context, 2, vin[j]); if (vin[j] == sys->unit_verts[i]) { copy_v3_v3(pj, vn[j]); } @@ -372,14 +369,14 @@ static void rotateDifferentialCoordinates(LaplacianSystem *sys) fni[2] = alpha * ni[2] + beta * uij[2] + gamma * e2[2]; if (len_squared_v3(fni) > FLT_EPSILON) { - nlRightHandSideSet(sys->context, 0, i, fni[0]); - nlRightHandSideSet(sys->context, 1, i, fni[1]); - nlRightHandSideSet(sys->context, 2, i, fni[2]); + EIG_linear_solver_right_hand_side_add(sys->context, 0, i, fni[0]); + EIG_linear_solver_right_hand_side_add(sys->context, 1, i, fni[1]); + EIG_linear_solver_right_hand_side_add(sys->context, 2, i, fni[2]); } else { - nlRightHandSideSet(sys->context, 0, i, sys->delta[i][0]); - nlRightHandSideSet(sys->context, 1, i, sys->delta[i][1]); - nlRightHandSideSet(sys->context, 2, i, sys->delta[i][2]); + EIG_linear_solver_right_hand_side_add(sys->context, 0, i, sys->delta[i][0]); + EIG_linear_solver_right_hand_side_add(sys->context, 1, i, sys->delta[i][1]); + EIG_linear_solver_right_hand_side_add(sys->context, 2, i, sys->delta[i][2]); } } } @@ -390,75 +387,59 @@ static void laplacianDeformPreview(LaplacianSystem *sys, float (*vertexCos)[3]) n = sys->total_verts; na = sys->total_anchors; -#ifdef OPENNL_THREADING_HACK - modifier_opennl_lock(); -#endif - if (!sys->is_matrix_computed) { - sys->context = nlNewContext(); + sys->context = EIG_linear_least_squares_solver_new(n + na, n, 3); - nlSolverParameteri(sys->context, NL_NB_VARIABLES, n); - nlSolverParameteri(sys->context, NL_LEAST_SQUARES, NL_TRUE); - nlSolverParameteri(sys->context, NL_NB_ROWS, n + na); - nlSolverParameteri(sys->context, NL_NB_RIGHT_HAND_SIDES, 3); - nlBegin(sys->context, NL_SYSTEM); for (i = 0; i < n; i++) { - nlSetVariable(sys->context, 0, i, sys->co[i][0]); - nlSetVariable(sys->context, 1, i, sys->co[i][1]); - nlSetVariable(sys->context, 2, i, sys->co[i][2]); + EIG_linear_solver_variable_set(sys->context, 0, i, sys->co[i][0]); + EIG_linear_solver_variable_set(sys->context, 1, i, sys->co[i][1]); + EIG_linear_solver_variable_set(sys->context, 2, i, sys->co[i][2]); } for (i = 0; i < na; i++) { vid = sys->index_anchors[i]; - nlSetVariable(sys->context, 0, vid, vertexCos[vid][0]); - nlSetVariable(sys->context, 1, vid, vertexCos[vid][1]); - nlSetVariable(sys->context, 2, vid, vertexCos[vid][2]); + EIG_linear_solver_variable_set(sys->context, 0, vid, vertexCos[vid][0]); + EIG_linear_solver_variable_set(sys->context, 1, vid, vertexCos[vid][1]); + EIG_linear_solver_variable_set(sys->context, 2, vid, vertexCos[vid][2]); } - nlBegin(sys->context, NL_MATRIX); initLaplacianMatrix(sys); computeImplictRotations(sys); for (i = 0; i < n; i++) { - nlRightHandSideSet(sys->context, 0, i, sys->delta[i][0]); - nlRightHandSideSet(sys->context, 1, i, sys->delta[i][1]); - nlRightHandSideSet(sys->context, 2, i, sys->delta[i][2]); + EIG_linear_solver_right_hand_side_add(sys->context, 0, i, sys->delta[i][0]); + EIG_linear_solver_right_hand_side_add(sys->context, 1, i, sys->delta[i][1]); + EIG_linear_solver_right_hand_side_add(sys->context, 2, i, sys->delta[i][2]); } for (i = 0; i < na; i++) { vid = sys->index_anchors[i]; - nlRightHandSideSet(sys->context, 0, n + i, vertexCos[vid][0]); - nlRightHandSideSet(sys->context, 1, n + i, vertexCos[vid][1]); - nlRightHandSideSet(sys->context, 2, n + i, vertexCos[vid][2]); - nlMatrixAdd(sys->context, n + i, vid, 1.0f); + EIG_linear_solver_right_hand_side_add(sys->context, 0, n + i, vertexCos[vid][0]); + EIG_linear_solver_right_hand_side_add(sys->context, 1, n + i, vertexCos[vid][1]); + EIG_linear_solver_right_hand_side_add(sys->context, 2, n + i, vertexCos[vid][2]); + EIG_linear_solver_matrix_add(sys->context, n + i, vid, 1.0f); } - nlEnd(sys->context, NL_MATRIX); - nlEnd(sys->context, NL_SYSTEM); - if (nlSolve(sys->context, NL_TRUE)) { + if (EIG_linear_solver_solve(sys->context)) { sys->has_solution = true; for (j = 1; j <= sys->repeat; j++) { - nlBegin(sys->context, NL_SYSTEM); - nlBegin(sys->context, NL_MATRIX); rotateDifferentialCoordinates(sys); for (i = 0; i < na; i++) { vid = sys->index_anchors[i]; - nlRightHandSideSet(sys->context, 0, n + i, vertexCos[vid][0]); - nlRightHandSideSet(sys->context, 1, n + i, vertexCos[vid][1]); - nlRightHandSideSet(sys->context, 2, n + i, vertexCos[vid][2]); + EIG_linear_solver_right_hand_side_add(sys->context, 0, n + i, vertexCos[vid][0]); + EIG_linear_solver_right_hand_side_add(sys->context, 1, n + i, vertexCos[vid][1]); + EIG_linear_solver_right_hand_side_add(sys->context, 2, n + i, vertexCos[vid][2]); } - nlEnd(sys->context, NL_MATRIX); - nlEnd(sys->context, NL_SYSTEM); - if (!nlSolve(sys->context, NL_FALSE)) { + if (!EIG_linear_solver_solve(sys->context)) { sys->has_solution = false; break; } } if (sys->has_solution) { for (vid = 0; vid < sys->total_verts; vid++) { - vertexCos[vid][0] = nlGetVariable(sys->context, 0, vid); - vertexCos[vid][1] = nlGetVariable(sys->context, 1, vid); - vertexCos[vid][2] = nlGetVariable(sys->context, 2, vid); + vertexCos[vid][0] = EIG_linear_solver_variable_get(sys->context, 0, vid); + vertexCos[vid][1] = EIG_linear_solver_variable_get(sys->context, 1, vid); + vertexCos[vid][2] = EIG_linear_solver_variable_get(sys->context, 2, vid); } } else { @@ -473,49 +454,40 @@ static void laplacianDeformPreview(LaplacianSystem *sys, float (*vertexCos)[3]) } else if (sys->has_solution) { - nlBegin(sys->context, NL_SYSTEM); - nlBegin(sys->context, NL_MATRIX); - for (i = 0; i < n; i++) { - nlRightHandSideSet(sys->context, 0, i, sys->delta[i][0]); - nlRightHandSideSet(sys->context, 1, i, sys->delta[i][1]); - nlRightHandSideSet(sys->context, 2, i, sys->delta[i][2]); + EIG_linear_solver_right_hand_side_add(sys->context, 0, i, sys->delta[i][0]); + EIG_linear_solver_right_hand_side_add(sys->context, 1, i, sys->delta[i][1]); + EIG_linear_solver_right_hand_side_add(sys->context, 2, i, sys->delta[i][2]); } for (i = 0; i < na; i++) { vid = sys->index_anchors[i]; - nlRightHandSideSet(sys->context, 0, n + i, vertexCos[vid][0]); - nlRightHandSideSet(sys->context, 1, n + i, vertexCos[vid][1]); - nlRightHandSideSet(sys->context, 2, n + i, vertexCos[vid][2]); - nlMatrixAdd(sys->context, n + i, vid, 1.0f); + EIG_linear_solver_right_hand_side_add(sys->context, 0, n + i, vertexCos[vid][0]); + EIG_linear_solver_right_hand_side_add(sys->context, 1, n + i, vertexCos[vid][1]); + EIG_linear_solver_right_hand_side_add(sys->context, 2, n + i, vertexCos[vid][2]); + EIG_linear_solver_matrix_add(sys->context, n + i, vid, 1.0f); } - nlEnd(sys->context, NL_MATRIX); - nlEnd(sys->context, NL_SYSTEM); - if (nlSolve(sys->context, NL_FALSE)) { + if (EIG_linear_solver_solve(sys->context)) { sys->has_solution = true; for (j = 1; j <= sys->repeat; j++) { - nlBegin(sys->context, NL_SYSTEM); - nlBegin(sys->context, NL_MATRIX); rotateDifferentialCoordinates(sys); for (i = 0; i < na; i++) { vid = sys->index_anchors[i]; - nlRightHandSideSet(sys->context, 0, n + i, vertexCos[vid][0]); - nlRightHandSideSet(sys->context, 1, n + i, vertexCos[vid][1]); - nlRightHandSideSet(sys->context, 2, n + i, vertexCos[vid][2]); + EIG_linear_solver_right_hand_side_add(sys->context, 0, n + i, vertexCos[vid][0]); + EIG_linear_solver_right_hand_side_add(sys->context, 1, n + i, vertexCos[vid][1]); + EIG_linear_solver_right_hand_side_add(sys->context, 2, n + i, vertexCos[vid][2]); } - nlEnd(sys->context, NL_MATRIX); - nlEnd(sys->context, NL_SYSTEM); - if (!nlSolve(sys->context, NL_FALSE)) { + if (!EIG_linear_solver_solve(sys->context)) { sys->has_solution = false; break; } } if (sys->has_solution) { for (vid = 0; vid < sys->total_verts; vid++) { - vertexCos[vid][0] = nlGetVariable(sys->context, 0, vid); - vertexCos[vid][1] = nlGetVariable(sys->context, 1, vid); - vertexCos[vid][2] = nlGetVariable(sys->context, 2, vid); + vertexCos[vid][0] = EIG_linear_solver_variable_get(sys->context, 0, vid); + vertexCos[vid][1] = EIG_linear_solver_variable_get(sys->context, 1, vid); + vertexCos[vid][2] = EIG_linear_solver_variable_get(sys->context, 2, vid); } } else { @@ -526,10 +498,6 @@ static void laplacianDeformPreview(LaplacianSystem *sys, float (*vertexCos)[3]) sys->has_solution = false; } } - -#ifdef OPENNL_THREADING_HACK - modifier_opennl_unlock(); -#endif } static bool isValidVertexGroup(LaplacianDeformModifierData *lmd, Object *ob, DerivedMesh *dm) @@ -720,15 +688,6 @@ static void LaplacianDeformModifier_do( } } -#else /* WITH_OPENNL */ -static void LaplacianDeformModifier_do( - LaplacianDeformModifierData *lmd, Object *ob, DerivedMesh *dm, - float (*vertexCos)[3], int numVerts) -{ - UNUSED_VARS(lmd, ob, dm, vertexCos, numVerts); -} -#endif /* WITH_OPENNL */ - static void initData(ModifierData *md) { LaplacianDeformModifierData *lmd = (LaplacianDeformModifierData *)md; @@ -792,12 +751,10 @@ static void deformVertsEM( static void freeData(ModifierData *md) { LaplacianDeformModifierData *lmd = (LaplacianDeformModifierData *)md; -#ifdef WITH_OPENNL LaplacianSystem *sys = (LaplacianSystem *)lmd->cache_system; if (sys) { deleteLaplacianSystem(sys); } -#endif MEM_SAFE_FREE(lmd->vertexco); lmd->total_verts = 0; } diff --git a/source/blender/modifiers/intern/MOD_laplaciansmooth.c b/source/blender/modifiers/intern/MOD_laplaciansmooth.c index 189ceb11d08..f1216ff462a 100644 --- a/source/blender/modifiers/intern/MOD_laplaciansmooth.c +++ b/source/blender/modifiers/intern/MOD_laplaciansmooth.c @@ -43,9 +43,7 @@ #include "MOD_util.h" -#ifdef WITH_OPENNL - -#include "ONL_opennl.h" +#include "eigen_capi.h" #if 0 #define MOD_LAPLACIANSMOOTH_MAX_EDGE_PERCENTAGE 1.8f @@ -71,7 +69,7 @@ struct BLaplacianSystem { const MPoly *mpoly; const MLoop *mloop; const MEdge *medges; - NLContext *context; + LinearSolver *context; /*Data*/ float min_area; @@ -104,7 +102,7 @@ static void delete_laplacian_system(LaplacianSystem *sys) MEM_SAFE_FREE(sys->zerola); if (sys->context) { - nlDeleteContext(sys->context); + EIG_linear_solver_delete(sys->context); } sys->vertexCos = NULL; sys->mpoly = NULL; @@ -300,16 +298,16 @@ static void fill_laplacian_matrix(LaplacianSystem *sys) /* Is ring if number of faces == number of edges around vertice*/ if (sys->numNeEd[l_curr->v] == sys->numNeFa[l_curr->v] && sys->zerola[l_curr->v] == 0) { - nlMatrixAdd(sys->context, l_curr->v, l_next->v, sys->fweights[l_curr_index][2] * sys->vweights[l_curr->v]); - nlMatrixAdd(sys->context, l_curr->v, l_prev->v, sys->fweights[l_curr_index][1] * sys->vweights[l_curr->v]); + EIG_linear_solver_matrix_add(sys->context, l_curr->v, l_next->v, sys->fweights[l_curr_index][2] * sys->vweights[l_curr->v]); + EIG_linear_solver_matrix_add(sys->context, l_curr->v, l_prev->v, sys->fweights[l_curr_index][1] * sys->vweights[l_curr->v]); } if (sys->numNeEd[l_next->v] == sys->numNeFa[l_next->v] && sys->zerola[l_next->v] == 0) { - nlMatrixAdd(sys->context, l_next->v, l_curr->v, sys->fweights[l_curr_index][2] * sys->vweights[l_next->v]); - nlMatrixAdd(sys->context, l_next->v, l_prev->v, sys->fweights[l_curr_index][0] * sys->vweights[l_next->v]); + EIG_linear_solver_matrix_add(sys->context, l_next->v, l_curr->v, sys->fweights[l_curr_index][2] * sys->vweights[l_next->v]); + EIG_linear_solver_matrix_add(sys->context, l_next->v, l_prev->v, sys->fweights[l_curr_index][0] * sys->vweights[l_next->v]); } if (sys->numNeEd[l_prev->v] == sys->numNeFa[l_prev->v] && sys->zerola[l_prev->v] == 0) { - nlMatrixAdd(sys->context, l_prev->v, l_curr->v, sys->fweights[l_curr_index][1] * sys->vweights[l_prev->v]); - nlMatrixAdd(sys->context, l_prev->v, l_next->v, sys->fweights[l_curr_index][0] * sys->vweights[l_prev->v]); + EIG_linear_solver_matrix_add(sys->context, l_prev->v, l_curr->v, sys->fweights[l_curr_index][1] * sys->vweights[l_prev->v]); + EIG_linear_solver_matrix_add(sys->context, l_prev->v, l_next->v, sys->fweights[l_curr_index][0] * sys->vweights[l_prev->v]); } } } @@ -323,8 +321,8 @@ static void fill_laplacian_matrix(LaplacianSystem *sys) sys->zerola[idv1] == 0 && sys->zerola[idv2] == 0) { - nlMatrixAdd(sys->context, idv1, idv2, sys->eweights[i] * sys->vlengths[idv1]); - nlMatrixAdd(sys->context, idv2, idv1, sys->eweights[i] * sys->vlengths[idv2]); + EIG_linear_solver_matrix_add(sys->context, idv1, idv2, sys->eweights[i] * sys->vlengths[idv1]); + EIG_linear_solver_matrix_add(sys->context, idv2, idv1, sys->eweights[i] * sys->vlengths[idv2]); } } } @@ -342,13 +340,13 @@ static void validate_solution(LaplacianSystem *sys, short flag, float lambda, fl if (sys->zerola[i] == 0) { lam = sys->numNeEd[i] == sys->numNeFa[i] ? (lambda >= 0.0f ? 1.0f : -1.0f) : (lambda_border >= 0.0f ? 1.0f : -1.0f); if (flag & MOD_LAPLACIANSMOOTH_X) { - sys->vertexCos[i][0] += lam * ((float)nlGetVariable(sys->context, 0, i) - sys->vertexCos[i][0]); + sys->vertexCos[i][0] += lam * ((float)EIG_linear_solver_variable_get(sys->context, 0, i) - sys->vertexCos[i][0]); } if (flag & MOD_LAPLACIANSMOOTH_Y) { - sys->vertexCos[i][1] += lam * ((float)nlGetVariable(sys->context, 1, i) - sys->vertexCos[i][1]); + sys->vertexCos[i][1] += lam * ((float)EIG_linear_solver_variable_get(sys->context, 1, i) - sys->vertexCos[i][1]); } if (flag & MOD_LAPLACIANSMOOTH_Z) { - sys->vertexCos[i][2] += lam * ((float)nlGetVariable(sys->context, 2, i) - sys->vertexCos[i][2]); + sys->vertexCos[i][2] += lam * ((float)EIG_linear_solver_variable_get(sys->context, 2, i) - sys->vertexCos[i][2]); } } } @@ -386,24 +384,15 @@ static void laplaciansmoothModifier_do( sys->vert_centroid[2] = 0.0f; memset_laplacian_system(sys, 0); -#ifdef OPENNL_THREADING_HACK - modifier_opennl_lock(); -#endif - - sys->context = nlNewContext(); - nlSolverParameteri(sys->context, NL_NB_VARIABLES, numVerts); - nlSolverParameteri(sys->context, NL_LEAST_SQUARES, NL_TRUE); - nlSolverParameteri(sys->context, NL_NB_ROWS, numVerts); - nlSolverParameteri(sys->context, NL_NB_RIGHT_HAND_SIDES, 3); + sys->context = EIG_linear_least_squares_solver_new(numVerts, numVerts, 3); init_laplacian_matrix(sys); for (iter = 0; iter < smd->repeat; iter++) { - nlBegin(sys->context, NL_SYSTEM); for (i = 0; i < numVerts; i++) { - nlSetVariable(sys->context, 0, i, vertexCos[i][0]); - nlSetVariable(sys->context, 1, i, vertexCos[i][1]); - nlSetVariable(sys->context, 2, i, vertexCos[i][2]); + EIG_linear_solver_variable_set(sys->context, 0, i, vertexCos[i][0]); + EIG_linear_solver_variable_set(sys->context, 1, i, vertexCos[i][1]); + EIG_linear_solver_variable_set(sys->context, 2, i, vertexCos[i][2]); if (iter == 0) { add_v3_v3(sys->vert_centroid, vertexCos[i]); } @@ -412,12 +401,11 @@ static void laplaciansmoothModifier_do( mul_v3_fl(sys->vert_centroid, 1.0f / (float)numVerts); } - nlBegin(sys->context, NL_MATRIX); dv = dvert; for (i = 0; i < numVerts; i++) { - nlRightHandSideSet(sys->context, 0, i, vertexCos[i][0]); - nlRightHandSideSet(sys->context, 1, i, vertexCos[i][1]); - nlRightHandSideSet(sys->context, 2, i, vertexCos[i][2]); + EIG_linear_solver_right_hand_side_add(sys->context, 0, i, vertexCos[i][0]); + EIG_linear_solver_right_hand_side_add(sys->context, 1, i, vertexCos[i][1]); + EIG_linear_solver_right_hand_side_add(sys->context, 2, i, vertexCos[i][2]); if (iter == 0) { if (dv) { wpaint = defvert_find_weight(dv, defgrp_index); @@ -434,10 +422,10 @@ static void laplaciansmoothModifier_do( w = sys->vlengths[i]; sys->vlengths[i] = (w == 0.0f) ? 0.0f : -fabsf(smd->lambda_border) * wpaint * 2.0f / w; if (sys->numNeEd[i] == sys->numNeFa[i]) { - nlMatrixAdd(sys->context, i, i, 1.0f + fabsf(smd->lambda) * wpaint); + EIG_linear_solver_matrix_add(sys->context, i, i, 1.0f + fabsf(smd->lambda) * wpaint); } else { - nlMatrixAdd(sys->context, i, i, 1.0f + fabsf(smd->lambda_border) * wpaint * 2.0f); + EIG_linear_solver_matrix_add(sys->context, i, i, 1.0f + fabsf(smd->lambda_border) * wpaint * 2.0f); } } else { @@ -447,15 +435,15 @@ static void laplaciansmoothModifier_do( sys->vlengths[i] = (w == 0.0f) ? 0.0f : -fabsf(smd->lambda_border) * wpaint * 2.0f / w; if (sys->numNeEd[i] == sys->numNeFa[i]) { - nlMatrixAdd(sys->context, i, i, 1.0f + fabsf(smd->lambda) * wpaint / (4.0f * sys->ring_areas[i])); + EIG_linear_solver_matrix_add(sys->context, i, i, 1.0f + fabsf(smd->lambda) * wpaint / (4.0f * sys->ring_areas[i])); } else { - nlMatrixAdd(sys->context, i, i, 1.0f + fabsf(smd->lambda_border) * wpaint * 2.0f); + EIG_linear_solver_matrix_add(sys->context, i, i, 1.0f + fabsf(smd->lambda_border) * wpaint * 2.0f); } } } else { - nlMatrixAdd(sys->context, i, i, 1.0f); + EIG_linear_solver_matrix_add(sys->context, i, i, 1.0f); } } } @@ -464,32 +452,16 @@ static void laplaciansmoothModifier_do( fill_laplacian_matrix(sys); } - nlEnd(sys->context, NL_MATRIX); - nlEnd(sys->context, NL_SYSTEM); - - if (nlSolve(sys->context, NL_TRUE)) { + if (EIG_linear_solver_solve(sys->context)) { validate_solution(sys, smd->flag, smd->lambda, smd->lambda_border); } } - nlDeleteContext(sys->context); + EIG_linear_solver_delete(sys->context); sys->context = NULL; -#ifdef OPENNL_THREADING_HACK - modifier_opennl_unlock(); -#endif - delete_laplacian_system(sys); } -#else /* WITH_OPENNL */ -static void laplaciansmoothModifier_do( - LaplacianSmoothModifierData *smd, Object *ob, DerivedMesh *dm, - float (*vertexCos)[3], int numVerts) -{ - UNUSED_VARS(smd, ob, dm, vertexCos, numVerts); -} -#endif /* WITH_OPENNL */ - static void init_data(ModifierData *md) { LaplacianSmoothModifierData *smd = (LaplacianSmoothModifierData *) md; diff --git a/source/blender/modifiers/intern/MOD_util.c b/source/blender/modifiers/intern/MOD_util.c index be6f7af7791..f9291fb077f 100644 --- a/source/blender/modifiers/intern/MOD_util.c +++ b/source/blender/modifiers/intern/MOD_util.c @@ -55,10 +55,6 @@ #include "MEM_guardedalloc.h" -#ifdef OPENNL_THREADING_HACK -#include "BLI_threads.h" -#endif - void modifier_init_texture(const Scene *scene, Tex *tex) { if (!tex) @@ -234,23 +230,6 @@ void modifier_get_vgroup(Object *ob, DerivedMesh *dm, const char *name, MDeformV } -#ifdef OPENNL_THREADING_HACK - -static ThreadMutex opennl_context_mutex = BLI_MUTEX_INITIALIZER; - -void modifier_opennl_lock(void) -{ - BLI_mutex_lock(&opennl_context_mutex); -} - -void modifier_opennl_unlock(void) -{ - BLI_mutex_unlock(&opennl_context_mutex); -} - -#endif - - /* only called by BKE_modifier.h/modifier.c */ void modifier_type_init(ModifierTypeInfo *types[]) { diff --git a/source/blender/modifiers/intern/MOD_util.h b/source/blender/modifiers/intern/MOD_util.h index b74ff9c2a25..095d7c278df 100644 --- a/source/blender/modifiers/intern/MOD_util.h +++ b/source/blender/modifiers/intern/MOD_util.h @@ -52,21 +52,4 @@ struct DerivedMesh *get_dm_for_modifier(struct Object *ob, ModifierApplyFlag fla void modifier_get_vgroup(struct Object *ob, struct DerivedMesh *dm, const char *name, struct MDeformVert **dvert, int *defgrp_index); -/* XXX workaround for non-threadsafe context in OpenNL (T38403) - * OpenNL uses global pointer for "current context", which causes - * conflict when multiple modifiers get evaluated in threaded depgraph. - * This is just a stupid hack to prevent assert failure / crash, - * otherwise we'd have to modify OpenNL on a large scale. - * OpenNL should be replaced eventually, there are other options (eigen, ceres). - * - lukas_t - */ -#ifdef WITH_OPENNL -#define OPENNL_THREADING_HACK -#endif - -#ifdef OPENNL_THREADING_HACK -void modifier_opennl_lock(void); -void modifier_opennl_unlock(void); -#endif - #endif /* __MOD_UTIL_H__ */ diff --git a/source/blenderplayer/CMakeLists.txt b/source/blenderplayer/CMakeLists.txt index f3a65c4d75e..deb702f005c 100644 --- a/source/blenderplayer/CMakeLists.txt +++ b/source/blenderplayer/CMakeLists.txt @@ -169,7 +169,6 @@ endif() extern_recastnavigation bf_intern_raskter bf_intern_opencolorio - bf_intern_opennl bf_intern_glew_mx bf_intern_eigen extern_rangetree @@ -195,8 +194,6 @@ endif() list(APPEND BLENDER_SORTED_LIBS extern_ceres) endif() - list(APPEND BLENDER_SORTED_LIBS extern_colamd) - if(WITH_MOD_BOOLEAN) list(APPEND BLENDER_SORTED_LIBS extern_carve) endif() -- cgit v1.2.3