umf_kernel.c
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/* ========================================================================== */
/* === UMF_kernel =========================================================== */
/* ========================================================================== */
/* -------------------------------------------------------------------------- */
/* UMFPACK Copyright (c) Timothy A. Davis, CISE, */
/* Univ. of Florida. All Rights Reserved. See ../Doc/License for License. */
/* web: http://www.cise.ufl.edu/research/sparse/umfpack */
/* -------------------------------------------------------------------------- */
/*
Primary factorization routine. Called by UMFPACK_numeric.
Returns:
UMFPACK_OK if successful,
UMFPACK_ERROR_out_of_memory if out of memory, or
UMFPACK_ERROR_different_pattern if pattern of matrix (Ap and/or Ai)
has changed since the call to UMFPACK_*symbolic.
*/
#include "umf_internal.h"
#include "umf_kernel_init.h"
#include "umf_init_front.h"
#include "umf_start_front.h"
#include "umf_assemble.h"
#include "umf_scale_column.h"
#include "umf_local_search.h"
#include "umf_create_element.h"
#include "umf_extend_front.h"
#include "umf_blas3_update.h"
#include "umf_store_lu.h"
#include "umf_kernel_wrapup.h"
/* perform an action, and return if out of memory */
#define DO(action) { if (! (action)) { return (UMFPACK_ERROR_out_of_memory) ; }}
GLOBAL Int UMF_kernel
(
const Int Ap [ ],
const Int Ai [ ],
const double Ax [ ],
#ifdef COMPLEX
const double Az [ ],
#endif
NumericType *Numeric,
WorkType *Work,
SymbolicType *Symbolic
)
{
/* ---------------------------------------------------------------------- */
/* local variables */
/* ---------------------------------------------------------------------- */
Int j, f1, f2, chain, nchains, *Chain_start, status, fixQ, evaporate,
*Front_npivcol, jmax, nb, drop ;
/* ---------------------------------------------------------------------- */
/* initialize memory space and load the matrix. Optionally scale. */
/* ---------------------------------------------------------------------- */
if (!UMF_kernel_init (Ap, Ai, Ax,
#ifdef COMPLEX
Az,
#endif
Numeric, Work, Symbolic))
{
/* UMF_kernel_init is guaranteed to succeed, since UMFPACK_numeric */
/* either allocates enough space or if not, UMF_kernel does not get */
/* called. So running out of memory here is a fatal error, and means */
/* that the user changed Ap and/or Ai since the call to */
/* UMFPACK_*symbolic. */
DEBUGm4 (("kernel init failed\n")) ;
return (UMFPACK_ERROR_different_pattern) ;
}
/* ---------------------------------------------------------------------- */
/* get the symbolic factorization */
/* ---------------------------------------------------------------------- */
nchains = Symbolic->nchains ;
Chain_start = Symbolic->Chain_start ;
Front_npivcol = Symbolic->Front_npivcol ;
nb = Symbolic->nb ;
fixQ = Symbolic->fixQ ;
drop = Numeric->droptol > 0.0 ;
#ifndef NDEBUG
for (chain = 0 ; chain < nchains ; chain++)
{
Int i ;
f1 = Chain_start [chain] ;
f2 = Chain_start [chain+1] - 1 ;
DEBUG1 (("\nCHain: "ID" start "ID" end "ID"\n", chain, f1, f2)) ;
for (i = f1 ; i <= f2 ; i++)
{
DEBUG1 (("Front "ID", npivcol "ID"\n", i, Front_npivcol [i])) ;
}
}
#endif
/* ---------------------------------------------------------------------- */
/* factorize each chain of frontal matrices */
/* ---------------------------------------------------------------------- */
for (chain = 0 ; chain < nchains ; chain++)
{
f1 = Chain_start [chain] ;
f2 = Chain_start [chain+1] - 1 ;
/* ------------------------------------------------------------------ */
/* get the initial frontal matrix size for this chain */
/* ------------------------------------------------------------------ */
DO (UMF_start_front (chain, Numeric, Work, Symbolic)) ;
/* ------------------------------------------------------------------ */
/* factorize each front in the chain */
/* ------------------------------------------------------------------ */
for (Work->frontid = f1 ; Work->frontid <= f2 ; Work->frontid++)
{
/* -------------------------------------------------------------- */
/* Initialize the pivot column candidate set */
/* -------------------------------------------------------------- */
Work->ncand = Front_npivcol [Work->frontid] ;
Work->lo = Work->nextcand ;
Work->hi = Work->nextcand + Work->ncand - 1 ;
jmax = MIN (MAX_CANDIDATES, Work->ncand) ;
DEBUGm1 ((">>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> Starting front "
ID", npivcol: "ID"\n", Work->frontid, Work->ncand)) ;
if (fixQ)
{
/* do not modify the column order */
jmax = 1 ;
}
DEBUGm1 (("Initial candidates: ")) ;
for (j = 0 ; j < jmax ; j++)
{
DEBUGm1 ((" "ID, Work->nextcand)) ;
ASSERT (Work->nextcand <= Work->hi) ;
Work->Candidates [j] = Work->nextcand++ ;
}
Work->nCandidates = jmax ;
DEBUGm1 (("\n")) ;
/* -------------------------------------------------------------- */
/* Assemble and factorize the current frontal matrix */
/* -------------------------------------------------------------- */
while (Work->ncand > 0)
{
/* ---------------------------------------------------------- */
/* get the pivot row and column */
/* ---------------------------------------------------------- */
status = UMF_local_search (Numeric, Work, Symbolic) ;
if (status == UMFPACK_ERROR_different_pattern)
{
/* :: pattern change detected in umf_local_search :: */
/* input matrix has changed since umfpack_*symbolic */
DEBUGm4 (("local search failed\n")) ;
return (UMFPACK_ERROR_different_pattern) ;
}
if (status == UMFPACK_WARNING_singular_matrix)
{
/* no pivot found, discard and try again */
continue ;
}
/* ---------------------------------------------------------- */
/* update if front not extended or too many zeros in L,U */
/* ---------------------------------------------------------- */
if (Work->do_update)
{
UMF_blas3_update (Work) ;
if (drop)
{
DO (UMF_store_lu_drop (Numeric, Work)) ;
}
else
{
DO (UMF_store_lu (Numeric, Work)) ;
}
}
/* ---------------------------------------------------------- */
/* extend the frontal matrix, or start a new one */
/* ---------------------------------------------------------- */
if (Work->do_extend)
{
/* extend the current front */
DO (UMF_extend_front (Numeric, Work)) ;
}
else
{
/* finish the current front (if any) and start a new one */
DO (UMF_create_element (Numeric, Work, Symbolic)) ;
DO (UMF_init_front (Numeric, Work)) ;
}
/* ---------------------------------------------------------- */
/* Numerical & symbolic assembly into current frontal matrix */
/* ---------------------------------------------------------- */
if (fixQ)
{
UMF_assemble_fixq (Numeric, Work) ;
}
else
{
UMF_assemble (Numeric, Work) ;
}
/* ---------------------------------------------------------- */
/* scale the pivot column */
/* ---------------------------------------------------------- */
UMF_scale_column (Numeric, Work) ;
/* ---------------------------------------------------------- */
/* Numerical update if enough pivots accumulated */
/* ---------------------------------------------------------- */
evaporate = Work->fnrows == 0 || Work->fncols == 0 ;
if (Work->fnpiv >= nb || evaporate)
{
UMF_blas3_update (Work) ;
if (drop)
{
DO (UMF_store_lu_drop (Numeric, Work)) ;
}
else
{
DO (UMF_store_lu (Numeric, Work)) ;
}
}
Work->pivrow_in_front = FALSE ;
Work->pivcol_in_front = FALSE ;
/* ---------------------------------------------------------- */
/* If front is empty, evaporate it */
/* ---------------------------------------------------------- */
if (evaporate)
{
/* This does not create an element, just evaporates it.
* It ensures that a front is not 0-by-c or r-by-0. No
* memory is allocated, so it is guaranteed to succeed. */
(void) UMF_create_element (Numeric, Work, Symbolic) ;
Work->fnrows = 0 ;
Work->fncols = 0 ;
}
}
}
/* ------------------------------------------------------------------
* Wrapup the current frontal matrix. This is the last in a chain
* in the column elimination tree. The next frontal matrix
* cannot overlap with the current one, which will be its sibling
* in the column etree.
* ------------------------------------------------------------------ */
UMF_blas3_update (Work) ;
if (drop)
{
DO (UMF_store_lu_drop (Numeric, Work)) ;
}
else
{
DO (UMF_store_lu (Numeric, Work)) ;
}
Work->fnrows_new = Work->fnrows ;
Work->fncols_new = Work->fncols ;
DO (UMF_create_element (Numeric, Work, Symbolic)) ;
/* ------------------------------------------------------------------ */
/* current front is now empty */
/* ------------------------------------------------------------------ */
Work->fnrows = 0 ;
Work->fncols = 0 ;
}
/* ---------------------------------------------------------------------- */
/* end the last Lchain and Uchain and finalize the LU factors */
/* ---------------------------------------------------------------------- */
UMF_kernel_wrapup (Numeric, Symbolic, Work) ;
/* note that the matrix may be singular (this is OK) */
return (UMFPACK_OK) ;
}