/* ========================================================================== */ /* === UMFPACK_report_control =============================================== */ /* ========================================================================== */ /* -------------------------------------------------------------------------- */ /* Copyright (c) 2005-2012 by Timothy A. Davis, http://www.suitesparse.com. */ /* All Rights Reserved. See ../Doc/License.txt for License. */ /* -------------------------------------------------------------------------- */ /* User-callable. Prints the control settings. See umfpack_report_control.h for details. */ #include "umf_internal.h" GLOBAL void UMFPACK_report_control ( const double Control [UMFPACK_CONTROL] ) { double drow, dcol, relpt, relpt2, alloc_init, front_alloc_init, amd_alpha, force_fixQ, droptol, aggr ; Int prl, nb, irstep, strategy, scale, s ; Int do_singletons, ordering_option ; prl = GET_CONTROL (UMFPACK_PRL, UMFPACK_DEFAULT_PRL) ; if (prl < 2) { /* default is to print nothing */ return ; } PRINTF (("UMFPACK V%d.%d.%d (%s), Control:\n", UMFPACK_MAIN_VERSION, UMFPACK_SUB_VERSION, UMFPACK_SUBSUB_VERSION, UMFPACK_DATE)) ; /* ---------------------------------------------------------------------- */ /* run-time options */ /* ---------------------------------------------------------------------- */ /* This is a "run-time" option because all four umfpack_* versions */ /* compiled into the UMFPACK library. */ #ifdef DINT PRINTF ((" Matrix entry defined as: double\n")) ; PRINTF ((" Int (generic integer) defined as: int\n")) ; #endif #ifdef DLONG PRINTF ((" Matrix entry defined as: double\n")) ; PRINTF ((" Int (generic integer) defined as: SuiteSparse_long\n")) ; #endif #ifdef ZINT PRINTF ((" Matrix entry defined as: double complex\n")) ; PRINTF ((" Int (generic integer) defined as: int\n")) ; #endif #ifdef ZLONG PRINTF ((" Matrix entry defined as: double complex\n")) ; PRINTF ((" Int (generic integer) defined as: SuiteSparse_long\n")) ; #endif /* ---------------------------------------------------------------------- */ /* printing level */ /* ---------------------------------------------------------------------- */ PRINTF (("\n "ID": print level: "ID"\n", (Int) INDEX (UMFPACK_PRL), prl)) ; /* ---------------------------------------------------------------------- */ /* dense row/col parameters */ /* ---------------------------------------------------------------------- */ drow = GET_CONTROL (UMFPACK_DENSE_ROW, UMFPACK_DEFAULT_DENSE_ROW) ; dcol = GET_CONTROL (UMFPACK_DENSE_COL, UMFPACK_DEFAULT_DENSE_COL) ; PRINTF ((" "ID": dense row parameter: %g\n", (Int) INDEX (UMFPACK_DENSE_ROW), drow)) ; PRINTF ((" \"dense\" rows have > max (16, (%g)*16*sqrt(n_col)" " entries)\n", drow)) ; PRINTF ((" "ID": dense column parameter: %g\n", (Int) INDEX (UMFPACK_DENSE_COL), dcol)) ; PRINTF ((" \"dense\" columns have > max (16, (%g)*16*sqrt(n_row)" " entries)\n", dcol)) ; /* ---------------------------------------------------------------------- */ /* pivot tolerance */ /* ---------------------------------------------------------------------- */ relpt = GET_CONTROL (UMFPACK_PIVOT_TOLERANCE, UMFPACK_DEFAULT_PIVOT_TOLERANCE) ; relpt = MAX (0.0, MIN (relpt, 1.0)) ; PRINTF ((" "ID": pivot tolerance: %g\n", (Int) INDEX (UMFPACK_PIVOT_TOLERANCE), relpt)) ; /* ---------------------------------------------------------------------- */ /* block size */ /* ---------------------------------------------------------------------- */ nb = GET_CONTROL (UMFPACK_BLOCK_SIZE, UMFPACK_DEFAULT_BLOCK_SIZE) ; nb = MAX (1, nb) ; PRINTF ((" "ID": block size for dense matrix kernels: "ID"\n", (Int) INDEX (UMFPACK_BLOCK_SIZE), nb)) ; /* ---------------------------------------------------------------------- */ /* strategy */ /* ---------------------------------------------------------------------- */ strategy = GET_CONTROL (UMFPACK_STRATEGY, UMFPACK_DEFAULT_STRATEGY) ; if (strategy < UMFPACK_STRATEGY_AUTO || strategy > UMFPACK_STRATEGY_SYMMETRIC) { strategy = UMFPACK_STRATEGY_AUTO ; } PRINTF ((" "ID": strategy: "ID, (Int) INDEX (UMFPACK_STRATEGY), strategy)) ; if (strategy == UMFPACK_STRATEGY_SYMMETRIC) { PRINTF ((" (symmetric)\n" " Q = AMD (A+A'), Q not refined during numerical\n" " factorization, and diagonal pivoting (P=Q') attempted.\n")) ; } else if (strategy == UMFPACK_STRATEGY_UNSYMMETRIC) { PRINTF ((" (unsymmetric)\n" " Q = COLAMD (A), Q refined during numerical\n" " factorization, and no attempt at diagonal pivoting.\n")) ; } else /* auto strategy */ { strategy = UMFPACK_STRATEGY_AUTO ; PRINTF ((" (auto)\n")) ; } /* ---------------------------------------------------------------------- */ /* ordering */ /* ---------------------------------------------------------------------- */ ordering_option = GET_CONTROL (UMFPACK_ORDERING, UMFPACK_DEFAULT_ORDERING) ; if (ordering_option < 0 || ordering_option > UMFPACK_ORDERING_USER) { ordering_option = UMFPACK_DEFAULT_ORDERING ; } PRINTF ((" "ID": ordering: "ID, (Int) INDEX (UMFPACK_ORDERING), ordering_option)) ; if (ordering_option == UMFPACK_ORDERING_CHOLMOD) { PRINTF ((" CHOLMOD: AMD/COLAMD, then try METIS, and select best\n")) ; } else if (ordering_option == UMFPACK_ORDERING_AMD) { PRINTF ((" AMD/COLAMD\n")) ; } else if (ordering_option == UMFPACK_ORDERING_GIVEN) { PRINTF ((" user-provided permutation vector\n")) ; } else if (ordering_option == UMFPACK_ORDERING_NONE) { PRINTF ((" none\n")) ; } else if (ordering_option == UMFPACK_ORDERING_METIS) { PRINTF ((" METIS\n")) ; } else if (ordering_option == UMFPACK_ORDERING_BEST) { PRINTF ((" best effort. Try AMD/COLAMD and METIS, select best\n")) ; } else if (ordering_option == UMFPACK_ORDERING_USER) { PRINTF ((" user-provided ordering function\n")) ; } /* ---------------------------------------------------------------------- */ /* disable singletons (default is FALSE) */ /* ---------------------------------------------------------------------- */ do_singletons = GET_CONTROL (UMFPACK_SINGLETONS,UMFPACK_DEFAULT_SINGLETONS); PRINTF ((" "ID": singleton filter:", (Int) INDEX (UMFPACK_SINGLETONS))) ; if (do_singletons) { PRINTF ((" enabled\n")) ; } else { PRINTF ((" disabled\n")) ; } /* ---------------------------------------------------------------------- */ /* initial allocation parameter */ /* ---------------------------------------------------------------------- */ alloc_init = GET_CONTROL (UMFPACK_ALLOC_INIT, UMFPACK_DEFAULT_ALLOC_INIT) ; if (alloc_init >= 0) { PRINTF ((" "ID": initial allocation ratio: %g\n", (Int) INDEX (UMFPACK_ALLOC_INIT), alloc_init)) ; } else { s = -alloc_init ; s = MAX (1, s) ; PRINTF ((" "ID": initial allocation (in Units): "ID"\n", (Int) INDEX (UMFPACK_ALLOC_INIT), s)) ; } /* ---------------------------------------------------------------------- */ /* maximum iterative refinement steps */ /* ---------------------------------------------------------------------- */ irstep = GET_CONTROL (UMFPACK_IRSTEP, UMFPACK_DEFAULT_IRSTEP) ; irstep = MAX (0, irstep) ; PRINTF ((" "ID": max iterative refinement steps: "ID"\n", (Int) INDEX (UMFPACK_IRSTEP), irstep)) ; /* ---------------------------------------------------------------------- */ /* force fixQ */ /* ---------------------------------------------------------------------- */ force_fixQ = GET_CONTROL (UMFPACK_FIXQ, UMFPACK_DEFAULT_FIXQ) ; PRINTF ((" "ID": Q fixed during numerical factorization: %g ", (Int) INDEX (UMFPACK_FIXQ), force_fixQ)) ; if (force_fixQ > 0) { PRINTF (("(yes)\n")) ; } else if (force_fixQ < 0) { PRINTF (("(no)\n")) ; } else { PRINTF (("(auto)\n")) ; } /* ---------------------------------------------------------------------- */ /* AMD parameters */ /* ---------------------------------------------------------------------- */ amd_alpha = GET_CONTROL (UMFPACK_AMD_DENSE, UMFPACK_DEFAULT_AMD_DENSE) ; PRINTF ((" "ID": AMD dense row/col parameter: %g\n", (Int) INDEX (UMFPACK_AMD_DENSE), amd_alpha)) ; if (amd_alpha < 0) { PRINTF ((" no \"dense\" rows/columns\n")) ; } else { PRINTF ((" \"dense\" rows/columns have > max (16, (%g)*sqrt(n))" " entries\n", amd_alpha)) ; } PRINTF ((" Only used if the AMD ordering is used.\n")) ; /* ---------------------------------------------------------------------- */ /* pivot tolerance for symmetric pivoting */ /* ---------------------------------------------------------------------- */ relpt2 = GET_CONTROL (UMFPACK_SYM_PIVOT_TOLERANCE, UMFPACK_DEFAULT_SYM_PIVOT_TOLERANCE) ; relpt2 = MAX (0.0, MIN (relpt2, 1.0)) ; PRINTF ((" "ID": diagonal pivot tolerance: %g\n" " Only used if diagonal pivoting is attempted.\n", (Int) INDEX (UMFPACK_SYM_PIVOT_TOLERANCE), relpt2)) ; /* ---------------------------------------------------------------------- */ /* scaling */ /* ---------------------------------------------------------------------- */ scale = GET_CONTROL (UMFPACK_SCALE, UMFPACK_DEFAULT_SCALE) ; if (scale != UMFPACK_SCALE_NONE && scale != UMFPACK_SCALE_MAX) { scale = UMFPACK_DEFAULT_SCALE ; } PRINTF ((" "ID": scaling: "ID, (Int) INDEX (UMFPACK_SCALE), scale)) ; if (scale == UMFPACK_SCALE_NONE) { PRINTF ((" (no)")) ; } else if (scale == UMFPACK_SCALE_SUM) { PRINTF ((" (divide each row by sum of abs. values in each row)")) ; } else if (scale == UMFPACK_SCALE_MAX) { PRINTF ((" (divide each row by max. abs. value in each row)")) ; } PRINTF (("\n")) ; /* ---------------------------------------------------------------------- */ /* frontal matrix allocation parameter */ /* ---------------------------------------------------------------------- */ front_alloc_init = GET_CONTROL (UMFPACK_FRONT_ALLOC_INIT, UMFPACK_DEFAULT_FRONT_ALLOC_INIT) ; front_alloc_init = MIN (1.0, front_alloc_init) ; if (front_alloc_init >= 0) { PRINTF ((" "ID": frontal matrix allocation ratio: %g\n", (Int) INDEX (UMFPACK_FRONT_ALLOC_INIT), front_alloc_init)) ; } else { s = -front_alloc_init ; s = MAX (1, s) ; PRINTF ((" "ID": initial frontal matrix size (# of Entry's): "ID"\n", (Int) INDEX (UMFPACK_FRONT_ALLOC_INIT), s)) ; } /* ---------------------------------------------------------------------- */ /* drop tolerance */ /* ---------------------------------------------------------------------- */ droptol = GET_CONTROL (UMFPACK_DROPTOL, UMFPACK_DEFAULT_DROPTOL) ; PRINTF ((" "ID": drop tolerance: %g\n", (Int) INDEX (UMFPACK_DROPTOL), droptol)) ; /* ---------------------------------------------------------------------- */ /* aggressive absorption */ /* ---------------------------------------------------------------------- */ aggr = GET_CONTROL (UMFPACK_AGGRESSIVE, UMFPACK_DEFAULT_AGGRESSIVE) ; PRINTF ((" "ID": AMD and COLAMD aggressive absorption: %g", (Int) INDEX (UMFPACK_AGGRESSIVE), aggr)) ; if (aggr != 0.0) { PRINTF ((" (yes)\n")) ; } else { PRINTF ((" (no)\n")) ; } /* ---------------------------------------------------------------------- */ /* compile-time options */ /* ---------------------------------------------------------------------- */ PRINTF (( "\n The following options can only be changed at compile-time:\n")) ; PRINTF ((" "ID": BLAS library used: ", (Int) INDEX (UMFPACK_COMPILED_WITH_BLAS))) ; #ifdef NBLAS PRINTF (("none. UMFPACK will be slow.\n")) ; #else PRINTF (("Fortran BLAS. size of BLAS integer: "ID"\n", (Int) (sizeof (BLAS_INT)))) ; #endif #ifdef MATLAB_MEX_FILE PRINTF ((" compiled for MATLAB\n")) ; #else PRINTF ((" compiled for ANSI C\n")) ; #endif #ifdef SUITESPARSE_TIMER_ENABLED PRINTF ((" POSIX C clock_getttime.\n")) ; #else PRINTF ((" no timer used.\n")) ; #endif PRINTF ((" computer/operating system: %s\n", UMFPACK_ARCHITECTURE)) ; PRINTF ((" size of int: %g SuiteSparse_long: %g Int: %g pointer: %g" " double: %g Entry: %g (in bytes)\n\n", (double) sizeof (int), (double) sizeof (SuiteSparse_long), (double) sizeof (Int), (double) sizeof (void *), (double) sizeof (double), (double) sizeof (Entry))) ; }