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blender/intern/opennl/superlu/spivotL.c
Brecht Van Lommel 4f1c674ee0 Added SuperLU 3.0: 
http://crd.lbl.gov/~xiaoye/SuperLU/

This is a library to solve sparse matrix systems (type A*x=B). It is able
to solve large systems very FAST. Only the necessary parts of the library
are included to limit file size and compilation time. This means the example
files, fortran interface, test files, matlab interface, cblas library,
complex number part and build system have been left out. All (gcc) warnings
have been fixed too.

This library will be used for LSCM UV unwrapping. With this library, LSCM
unwrapping can be calculated in a split second, making the unwrapping proces
much more interactive.

Added OpenNL (Open Numerical Libary):
http://www.loria.fr/~levy/OpenNL/

OpenNL is a library to easily construct and solve sparse linear systems. We
use a stripped down version, as an interface to SuperLU.

This library was kindly given to use by Bruno Levy.
2004-07-13 11:42:13 +00:00

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/*
* -- SuperLU routine (version 3.0) --
* Univ. of California Berkeley, Xerox Palo Alto Research Center,
* and Lawrence Berkeley National Lab.
* October 15, 2003
*
*/
/*
Copyright (c) 1994 by Xerox Corporation. All rights reserved.
THIS MATERIAL IS PROVIDED AS IS, WITH ABSOLUTELY NO WARRANTY
EXPRESSED OR IMPLIED. ANY USE IS AT YOUR OWN RISK.
Permission is hereby granted to use or copy this program for any
purpose, provided the above notices are retained on all copies.
Permission to modify the code and to distribute modified code is
granted, provided the above notices are retained, and a notice that
the code was modified is included with the above copyright notice.
*/
#include <math.h>
#include <stdlib.h>
#include "ssp_defs.h"
#undef DEBUG
int
spivotL(
const int jcol, /* in */
const float u, /* in - diagonal pivoting threshold */
int *usepr, /* re-use the pivot sequence given by perm_r/iperm_r */
int *perm_r, /* may be modified */
int *iperm_r, /* in - inverse of perm_r */
int *iperm_c, /* in - used to find diagonal of Pc*A*Pc' */
int *pivrow, /* out */
GlobalLU_t *Glu, /* modified - global LU data structures */
SuperLUStat_t *stat /* output */
)
{
/*
* Purpose
* =======
* Performs the numerical pivoting on the current column of L,
* and the CDIV operation.
*
* Pivot policy:
* (1) Compute thresh = u * max_(i>=j) abs(A_ij);
* (2) IF user specifies pivot row k and abs(A_kj) >= thresh THEN
* pivot row = k;
* ELSE IF abs(A_jj) >= thresh THEN
* pivot row = j;
* ELSE
* pivot row = m;
*
* Note: If you absolutely want to use a given pivot order, then set u=0.0.
*
* Return value: 0 success;
* i > 0 U(i,i) is exactly zero.
*
*/
int fsupc; /* first column in the supernode */
int nsupc; /* no of columns in the supernode */
int nsupr; /* no of rows in the supernode */
int lptr; /* points to the starting subscript of the supernode */
int pivptr, old_pivptr, diag, diagind;
float pivmax, rtemp, thresh;
float temp;
float *lu_sup_ptr;
float *lu_col_ptr;
int *lsub_ptr;
int isub, icol, k, itemp;
int *lsub, *xlsub;
float *lusup;
int *xlusup;
flops_t *ops = stat->ops;
/* Initialize pointers */
lsub = Glu->lsub;
xlsub = Glu->xlsub;
lusup = Glu->lusup;
xlusup = Glu->xlusup;
fsupc = (Glu->xsup)[(Glu->supno)[jcol]];
nsupc = jcol - fsupc; /* excluding jcol; nsupc >= 0 */
lptr = xlsub[fsupc];
nsupr = xlsub[fsupc+1] - lptr;
lu_sup_ptr = &lusup[xlusup[fsupc]]; /* start of the current supernode */
lu_col_ptr = &lusup[xlusup[jcol]]; /* start of jcol in the supernode */
lsub_ptr = &lsub[lptr]; /* start of row indices of the supernode */
#ifdef DEBUG
if ( jcol == MIN_COL ) {
printf("Before cdiv: col %d\n", jcol);
for (k = nsupc; k < nsupr; k++)
printf(" lu[%d] %f\n", lsub_ptr[k], lu_col_ptr[k]);
}
#endif
/* Determine the largest abs numerical value for partial pivoting;
Also search for user-specified pivot, and diagonal element. */
if ( *usepr ) *pivrow = iperm_r[jcol];
diagind = iperm_c[jcol];
pivmax = 0.0;
pivptr = nsupc;
diag = EMPTY;
old_pivptr = nsupc;
for (isub = nsupc; isub < nsupr; ++isub) {
rtemp = fabs (lu_col_ptr[isub]);
if ( rtemp > pivmax ) {
pivmax = rtemp;
pivptr = isub;
}
if ( *usepr && lsub_ptr[isub] == *pivrow ) old_pivptr = isub;
if ( lsub_ptr[isub] == diagind ) diag = isub;
}
/* Test for singularity */
if ( pivmax == 0.0 ) {
*pivrow = lsub_ptr[pivptr];
perm_r[*pivrow] = jcol;
*usepr = 0;
return (jcol+1);
}
thresh = u * pivmax;
/* Choose appropriate pivotal element by our policy. */
if ( *usepr ) {
rtemp = fabs (lu_col_ptr[old_pivptr]);
if ( rtemp != 0.0 && rtemp >= thresh )
pivptr = old_pivptr;
else
*usepr = 0;
}
if ( *usepr == 0 ) {
/* Use diagonal pivot? */
if ( diag >= 0 ) { /* diagonal exists */
rtemp = fabs (lu_col_ptr[diag]);
if ( rtemp != 0.0 && rtemp >= thresh ) pivptr = diag;
}
*pivrow = lsub_ptr[pivptr];
}
/* Record pivot row */
perm_r[*pivrow] = jcol;
/* Interchange row subscripts */
if ( pivptr != nsupc ) {
itemp = lsub_ptr[pivptr];
lsub_ptr[pivptr] = lsub_ptr[nsupc];
lsub_ptr[nsupc] = itemp;
/* Interchange numerical values as well, for the whole snode, such
* that L is indexed the same way as A.
*/
for (icol = 0; icol <= nsupc; icol++) {
itemp = pivptr + icol * nsupr;
temp = lu_sup_ptr[itemp];
lu_sup_ptr[itemp] = lu_sup_ptr[nsupc + icol*nsupr];
lu_sup_ptr[nsupc + icol*nsupr] = temp;
}
} /* if */
/* cdiv operation */
ops[FACT] += nsupr - nsupc;
temp = 1.0 / lu_col_ptr[nsupc];
for (k = nsupc+1; k < nsupr; k++)
lu_col_ptr[k] *= temp;
return 0;
}
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