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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
*
*/
#ifndef __SUPERLU_sSP_DEFS /* allow multiple inclusions */
#define __SUPERLU_sSP_DEFS
/*
* File name: ssp_defs.h
* Purpose: Sparse matrix types and function prototypes
* History:
*/
#ifdef _CRAY
#include <fortran.h>
#include <string.h>
#endif
/* Define my integer type int_t */
typedef int int_t; /* default */
#include "Cnames.h"
#include "supermatrix.h"
#include "util.h"
/*
* Global data structures used in LU factorization -
*
* nsuper: #supernodes = nsuper + 1, numbered [0, nsuper].
* (xsup,supno): supno[i] is the supernode no to which i belongs;
* xsup(s) points to the beginning of the s-th supernode.
* e.g. supno 0 1 2 2 3 3 3 4 4 4 4 4 (n=12)
* xsup 0 1 2 4 7 12
* Note: dfs will be performed on supernode rep. relative to the new
* row pivoting ordering
*
* (xlsub,lsub): lsub[*] contains the compressed subscript of
* rectangular supernodes; xlsub[j] points to the starting
* location of the j-th column in lsub[*]. Note that xlsub
* is indexed by column.
* Storage: original row subscripts
*
* During the course of sparse LU factorization, we also use
* (xlsub,lsub) for the purpose of symmetric pruning. For each
* supernode {s,s+1,...,t=s+r} with first column s and last
* column t, the subscript set
* lsub[j], j=xlsub[s], .., xlsub[s+1]-1
* is the structure of column s (i.e. structure of this supernode).
* It is used for the storage of numerical values.
* Furthermore,
* lsub[j], j=xlsub[t], .., xlsub[t+1]-1
* is the structure of the last column t of this supernode.
* It is for the purpose of symmetric pruning. Therefore, the
* structural subscripts can be rearranged without making physical
* interchanges among the numerical values.
*
* However, if the supernode has only one column, then we
* only keep one set of subscripts. For any subscript interchange
* performed, similar interchange must be done on the numerical
* values.
*
* The last column structures (for pruning) will be removed
* after the numercial LU factorization phase.
*
* (xlusup,lusup): lusup[*] contains the numerical values of the
* rectangular supernodes; xlusup[j] points to the starting
* location of the j-th column in storage vector lusup[*]
* Note: xlusup is indexed by column.
* Each rectangular supernode is stored by column-major
* scheme, consistent with Fortran 2-dim array storage.
*
* (xusub,ucol,usub): ucol[*] stores the numerical values of
* U-columns outside the rectangular supernodes. The row
* subscript of nonzero ucol[k] is stored in usub[k].
* xusub[i] points to the starting location of column i in ucol.
* Storage: new row subscripts; that is subscripts of PA.
*/
typedef struct {
int *xsup; /* supernode and column mapping */
int *supno;
int *lsub; /* compressed L subscripts */
int *xlsub;
float *lusup; /* L supernodes */
int *xlusup;
float *ucol; /* U columns */
int *usub;
int *xusub;
int nzlmax; /* current max size of lsub */
int nzumax; /* " " " ucol */
int nzlumax; /* " " " lusup */
int n; /* number of columns in the matrix */
LU_space_t MemModel; /* 0 - system malloc'd; 1 - user provided */
} GlobalLU_t;
typedef struct {
float for_lu;
float total_needed;
int expansions;
} mem_usage_t;
#ifdef __cplusplus
extern "C" {
#endif
/* Driver routines */
extern void
sgssv(superlu_options_t *, SuperMatrix *, int *, int *, SuperMatrix *,
SuperMatrix *, SuperMatrix *, SuperLUStat_t *, int *);
extern void
sgssvx(superlu_options_t *, SuperMatrix *, int *, int *, int *,
char *, float *, float *, SuperMatrix *, SuperMatrix *,
void *, int, SuperMatrix *, SuperMatrix *,
float *, float *, float *, float *,
mem_usage_t *, SuperLUStat_t *, int *);
/* Supernodal LU factor related */
extern void
sCreate_CompCol_Matrix(SuperMatrix *, int, int, int, float *,
int *, int *, Stype_t, Dtype_t, Mtype_t);
extern void
sCreate_CompRow_Matrix(SuperMatrix *, int, int, int, float *,
int *, int *, Stype_t, Dtype_t, Mtype_t);
extern void
sCopy_CompCol_Matrix(SuperMatrix *, SuperMatrix *);
extern void
sCreate_Dense_Matrix(SuperMatrix *, int, int, float *, int,
Stype_t, Dtype_t, Mtype_t);
extern void
sCreate_SuperNode_Matrix(SuperMatrix *, int, int, int, float *,
int *, int *, int *, int *, int *,
Stype_t, Dtype_t, Mtype_t);
extern void
sCopy_Dense_Matrix(int, int, float *, int, float *, int);
extern void countnz (const int, int *, int *, int *, GlobalLU_t *);
extern void fixupL (const int, const int *, GlobalLU_t *);
extern void sallocateA (int, int, float **, int **, int **);
extern void sgstrf (superlu_options_t*, SuperMatrix*,
int, int, int*, void *, int, int *, int *,
SuperMatrix *, SuperMatrix *, SuperLUStat_t*, int *);
extern int ssnode_dfs (const int, const int, const int *, const int *,
const int *, int *, int *, GlobalLU_t *);
extern int ssnode_bmod (const int, const int, float *,
float *, GlobalLU_t *, SuperLUStat_t*);
extern void spanel_dfs (const int, const int, const int, SuperMatrix *,
int *, int *, float *, int *, int *, int *,
int *, int *, int *, int *, GlobalLU_t *);
extern void spanel_bmod (const int, const int, const int, const int,
float *, float *, int *, int *,
GlobalLU_t *, SuperLUStat_t*);
extern int scolumn_dfs (const int, const int, int *, int *, int *, int *,
int *, int *, int *, int *, int *, GlobalLU_t *);
extern int scolumn_bmod (const int, const int, float *,
float *, int *, int *, int,
GlobalLU_t *, SuperLUStat_t*);
extern int scopy_to_ucol (int, int, int *, int *, int *,
float *, GlobalLU_t *);
extern int spivotL (const int, const float, int *, int *,
int *, int *, int *, GlobalLU_t *, SuperLUStat_t*);
extern void spruneL (const int, const int *, const int, const int,
const int *, const int *, int *, GlobalLU_t *);
extern void sreadmt (int *, int *, int *, float **, int **, int **);
extern void sGenXtrue (int, int, float *, int);
extern void sFillRHS (trans_t, int, float *, int, SuperMatrix *,
SuperMatrix *);
extern void sgstrs (trans_t, SuperMatrix *, SuperMatrix *, int *, int *,
SuperMatrix *, SuperLUStat_t*, int *);
/* Driver related */
extern void sgsequ (SuperMatrix *, float *, float *, float *,
float *, float *, int *);
extern void slaqgs (SuperMatrix *, float *, float *, float,
float, float, char *);
extern void sgscon (char *, SuperMatrix *, SuperMatrix *,
float, float *, SuperLUStat_t*, int *);
extern float sPivotGrowth(int, SuperMatrix *, int *,
SuperMatrix *, SuperMatrix *);
extern void sgsrfs (trans_t, SuperMatrix *, SuperMatrix *,
SuperMatrix *, int *, int *, char *, float *,
float *, SuperMatrix *, SuperMatrix *,
float *, float *, SuperLUStat_t*, int *);
extern int sp_strsv (char *, char *, char *, SuperMatrix *,
SuperMatrix *, float *, SuperLUStat_t*, int *);
extern int sp_sgemv (char *, float, SuperMatrix *, float *,
int, float, float *, int);
extern int sp_sgemm (char *, int, float,
SuperMatrix *, float *, int, float,
float *, int);
/* Memory-related */
extern int sLUMemInit (fact_t, void *, int, int, int, int, int,
SuperMatrix *, SuperMatrix *,
GlobalLU_t *, int **, float **);
extern void sSetRWork (int, int, float *, float **, float **);
extern void sLUWorkFree (int *, float *, GlobalLU_t *);
extern int sLUMemXpand (int, int, MemType, int *, GlobalLU_t *);
extern float *floatMalloc(int);
extern float *floatCalloc(int);
extern int smemory_usage(const int, const int, const int, const int);
extern int sQuerySpace (SuperMatrix *, SuperMatrix *, mem_usage_t *);
/* Auxiliary routines */
extern void sreadhb(int *, int *, int *, float **, int **, int **);
extern void sCompRow_to_CompCol(int, int, int, float*, int*, int*,
float **, int **, int **);
extern void sfill (float *, int, float);
extern void sinf_norm_error (int, SuperMatrix *, float *);
extern void PrintPerf (SuperMatrix *, SuperMatrix *, mem_usage_t *,
float, float, float *, float *, char *);
/* Routines for debugging */
extern void sPrint_CompCol_Matrix(char *, SuperMatrix *);
extern void sPrint_SuperNode_Matrix(char *, SuperMatrix *);
extern void sPrint_Dense_Matrix(char *, SuperMatrix *);
extern void print_lu_col(char *, int, int, int *, GlobalLU_t *);
extern void check_tempv(int, float *);
extern int print_int_vec(char *what, int n, int *vec);
extern int sp_symetree(int *acolst, int *acolend, int *arow, int n, int *parent);
extern void sprint_lu_col(char *msg, int jcol, int pivrow, int *xprune, GlobalLU_t *Glu); // added to build with debug for blender - campbell
#ifdef __cplusplus
}
#endif
#endif /* __SUPERLU_sSP_DEFS */
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