Example #1 showing how to use ILU to precondition GMRES. More...
#include "slu_sdefs.h"
Functions | |
| void | spsolve (int n, float x[], float y[]) |
| Performs sgsisx with original matrix A. More... | |
| void | smatvec_mult (float alpha, float x[], float beta, float y[]) |
| Performs matrix-vector multipliation sp_sgemv with original matrix A. More... | |
| int | main (int argc, char *argv[]) |
Variables | |
| superlu_options_t * | GLOBAL_OPTIONS |
| float * | GLOBAL_R |
| float * | GLOBAL_C |
| int * | GLOBAL_PERM_C |
| int * | GLOBAL_PERM_R |
| SuperMatrix * | GLOBAL_A |
| SuperMatrix * | GLOBAL_L |
| SuperMatrix * | GLOBAL_U |
| SuperLUStat_t * | GLOBAL_STAT |
| mem_usage_t * | GLOBAL_MEM_USAGE |
Detailed Description
This example shows that ILU is computed from the equilibrated matrix, and the preconditioned GMRES is applied to the equilibrated system. The driver routine SGSISX is called twice to perform factorization and apply preconditioner separately.
Note that SGSISX performs the following factorization: Pr*Dr*A*Dc*Pc^T ~= LU with Pr being obtained from MC64 statically then partial pivoting dynamically. On return, A is overwritten as A1 = Dr*A*Dc.
We can solve the transformed system, A1*y = Dr*B, using FGMRES. B is first overwritten as Dr*B. Then GMRES step requires requires 2 procedures: 1) Apply preconditioner M^{-1} = Pc^T*U^{-1}*L^{-1}*Pr 2) Matrix-vector multiplication: w = A1*v
Function Documentation
◆ main()
| int main | ( | int | argc, |
| char * | argv[] | ||
| ) |
◆ smatvec_mult()
| void smatvec_mult | ( | float | alpha, |
| float | x[], | ||
| float | beta, | ||
| float | y[] | ||
| ) |
The operations is y := alpha*A*x + beta*y. See documentation of sp_sgemv for further details.
- Parameters
-
[in] alpha Scalar factor for A*x [in] x Vector to multiply with A [in] beta Scalar factor for y [in,out] y Vector to add to to matrix-vector multiplication and storage for result.
◆ spsolve()
| void spsolve | ( | int | n, |
| float | x[], | ||
| float | y[] | ||
| ) |
See documentation of sgsisx for more details.
- Parameters
-
[in] n Dimension of matrices [out] x Solution [in,out] y Right-hand side
Variable Documentation
◆ GLOBAL_A
| SuperMatrix* GLOBAL_A |
◆ GLOBAL_C
| float * GLOBAL_C |
◆ GLOBAL_L
| SuperMatrix * GLOBAL_L |
◆ GLOBAL_MEM_USAGE
| mem_usage_t* GLOBAL_MEM_USAGE |
◆ GLOBAL_OPTIONS
| superlu_options_t* GLOBAL_OPTIONS |
◆ GLOBAL_PERM_C
| int* GLOBAL_PERM_C |
◆ GLOBAL_PERM_R
| int * GLOBAL_PERM_R |
◆ GLOBAL_R
| float* GLOBAL_R |
◆ GLOBAL_STAT
| SuperLUStat_t* GLOBAL_STAT |
◆ GLOBAL_U
| SuperMatrix * GLOBAL_U |
