Actual source code: umfpack.c
petsc-3.9.4 2018-09-11
2: /*
3: Provides an interface to the UMFPACK sparse solver available through SuiteSparse version 4.2.1
5: When build with PETSC_USE_64BIT_INDICES this will use Suitesparse_long as the
6: integer type in UMFPACK, otherwise it will use int. This means
7: all integers in this file as simply declared as PetscInt. Also it means
8: that one cannot use 64BIT_INDICES on 32bit machines [as Suitesparse_long is 32bit only]
10: */
11: #include <../src/mat/impls/aij/seq/aij.h>
13: #if defined(PETSC_USE_64BIT_INDICES)
14: #if defined(PETSC_USE_COMPLEX)
15: #define umfpack_UMF_free_symbolic umfpack_zl_free_symbolic
16: #define umfpack_UMF_free_numeric umfpack_zl_free_numeric
17: /* the type casts are needed because PetscInt is long long while SuiteSparse_long is long and compilers warn even when they are identical */
18: #define umfpack_UMF_wsolve(a,b,c,d,e,f,g,h,i,j,k,l,m,n) umfpack_zl_wsolve(a,(SuiteSparse_long*)b,(SuiteSparse_long*)c,d,e,f,g,h,i,(SuiteSparse_long*)j,k,l,(SuiteSparse_long*)m,n)
19: #define umfpack_UMF_numeric(a,b,c,d,e,f,g,h) umfpack_zl_numeric((SuiteSparse_long*)a,(SuiteSparse_long*)b,c,d,e,f,g,h)
20: #define umfpack_UMF_report_numeric umfpack_zl_report_numeric
21: #define umfpack_UMF_report_control umfpack_zl_report_control
22: #define umfpack_UMF_report_status umfpack_zl_report_status
23: #define umfpack_UMF_report_info umfpack_zl_report_info
24: #define umfpack_UMF_report_symbolic umfpack_zl_report_symbolic
25: #define umfpack_UMF_qsymbolic(a,b,c,d,e,f,g,h,i,j) umfpack_zl_qsymbolic(a,b,(SuiteSparse_long*)c,(SuiteSparse_long*)d,e,f,(SuiteSparse_long*)g,h,i,j)
26: #define umfpack_UMF_symbolic(a,b,c,d,e,f,g,h,i) umfpack_zl_symbolic(a,b,(SuiteSparse_long*)c,(SuiteSparse_long*)d,e,f,g,h,i)
27: #define umfpack_UMF_defaults umfpack_zl_defaults
29: #else
30: #define umfpack_UMF_free_symbolic umfpack_dl_free_symbolic
31: #define umfpack_UMF_free_numeric umfpack_dl_free_numeric
32: #define umfpack_UMF_wsolve(a,b,c,d,e,f,g,h,i,j,k) umfpack_dl_wsolve(a,(SuiteSparse_long*)b,(SuiteSparse_long*)c,d,e,f,g,h,i,(SuiteSparse_long*)j,k)
33: #define umfpack_UMF_numeric(a,b,c,d,e,f,g) umfpack_dl_numeric((SuiteSparse_long*)a,(SuiteSparse_long*)b,c,d,e,f,g)
34: #define umfpack_UMF_report_numeric umfpack_dl_report_numeric
35: #define umfpack_UMF_report_control umfpack_dl_report_control
36: #define umfpack_UMF_report_status umfpack_dl_report_status
37: #define umfpack_UMF_report_info umfpack_dl_report_info
38: #define umfpack_UMF_report_symbolic umfpack_dl_report_symbolic
39: #define umfpack_UMF_qsymbolic(a,b,c,d,e,f,g,h,i) umfpack_dl_qsymbolic(a,b,(SuiteSparse_long*)c,(SuiteSparse_long*)d,e,(SuiteSparse_long*)f,g,h,i)
40: #define umfpack_UMF_symbolic(a,b,c,d,e,f,g,h) umfpack_dl_symbolic(a,b,(SuiteSparse_long*)c,(SuiteSparse_long*)d,e,f,g,h)
41: #define umfpack_UMF_defaults umfpack_dl_defaults
42: #endif
44: #else
45: #if defined(PETSC_USE_COMPLEX)
46: #define umfpack_UMF_free_symbolic umfpack_zi_free_symbolic
47: #define umfpack_UMF_free_numeric umfpack_zi_free_numeric
48: #define umfpack_UMF_wsolve umfpack_zi_wsolve
49: #define umfpack_UMF_numeric umfpack_zi_numeric
50: #define umfpack_UMF_report_numeric umfpack_zi_report_numeric
51: #define umfpack_UMF_report_control umfpack_zi_report_control
52: #define umfpack_UMF_report_status umfpack_zi_report_status
53: #define umfpack_UMF_report_info umfpack_zi_report_info
54: #define umfpack_UMF_report_symbolic umfpack_zi_report_symbolic
55: #define umfpack_UMF_qsymbolic umfpack_zi_qsymbolic
56: #define umfpack_UMF_symbolic umfpack_zi_symbolic
57: #define umfpack_UMF_defaults umfpack_zi_defaults
59: #else
60: #define umfpack_UMF_free_symbolic umfpack_di_free_symbolic
61: #define umfpack_UMF_free_numeric umfpack_di_free_numeric
62: #define umfpack_UMF_wsolve umfpack_di_wsolve
63: #define umfpack_UMF_numeric umfpack_di_numeric
64: #define umfpack_UMF_report_numeric umfpack_di_report_numeric
65: #define umfpack_UMF_report_control umfpack_di_report_control
66: #define umfpack_UMF_report_status umfpack_di_report_status
67: #define umfpack_UMF_report_info umfpack_di_report_info
68: #define umfpack_UMF_report_symbolic umfpack_di_report_symbolic
69: #define umfpack_UMF_qsymbolic umfpack_di_qsymbolic
70: #define umfpack_UMF_symbolic umfpack_di_symbolic
71: #define umfpack_UMF_defaults umfpack_di_defaults
72: #endif
73: #endif
75: EXTERN_C_BEGIN
76: #include <umfpack.h>
77: EXTERN_C_END
79: static const char *const UmfpackOrderingTypes[] = {"CHOLMOD","AMD","GIVEN","METIS","BEST","NONE","USER","UmfpackOrderingTypes","UMFPACK_ORDERING_",0};
81: typedef struct {
82: void *Symbolic, *Numeric;
83: double Info[UMFPACK_INFO], Control[UMFPACK_CONTROL],*W;
84: PetscInt *Wi,*perm_c;
85: Mat A; /* Matrix used for factorization */
86: MatStructure flg;
87: PetscBool PetscMatOrdering;
89: /* Flag to clean up UMFPACK objects during Destroy */
90: PetscBool CleanUpUMFPACK;
91: } Mat_UMFPACK;
93: static PetscErrorCode MatDestroy_UMFPACK(Mat A)
94: {
96: Mat_UMFPACK *lu=(Mat_UMFPACK*)A->data;
99: if (lu->CleanUpUMFPACK) {
100: umfpack_UMF_free_symbolic(&lu->Symbolic);
101: umfpack_UMF_free_numeric(&lu->Numeric);
102: PetscFree(lu->Wi);
103: PetscFree(lu->W);
104: PetscFree(lu->perm_c);
105: }
106: MatDestroy(&lu->A);
107: PetscFree(A->data);
108: return(0);
109: }
111: static PetscErrorCode MatSolve_UMFPACK_Private(Mat A,Vec b,Vec x,int uflag)
112: {
113: Mat_UMFPACK *lu = (Mat_UMFPACK*)A->data;
114: Mat_SeqAIJ *a = (Mat_SeqAIJ*)lu->A->data;
115: PetscScalar *av = a->a,*xa;
116: const PetscScalar *ba;
117: PetscErrorCode ierr;
118: PetscInt *ai = a->i,*aj = a->j,status;
119: static PetscBool cite = PETSC_FALSE;
122: if (!A->rmap->n) return(0);
123: PetscCitationsRegister("@article{davis2004algorithm,\n title={Algorithm 832: {UMFPACK} V4.3---An Unsymmetric-Pattern Multifrontal Method},\n author={Davis, Timothy A},\n journal={ACM Transactions on Mathematical Software (TOMS)},\n volume={30},\n number={2},\n pages={196--199},\n year={2004},\n publisher={ACM}\n}\n",&cite);
124: /* solve Ax = b by umfpack_*_wsolve */
125: /* ----------------------------------*/
127: if (!lu->Wi) { /* first time, allocate working space for wsolve */
128: PetscMalloc1(A->rmap->n,&lu->Wi);
129: PetscMalloc1(5*A->rmap->n,&lu->W);
130: }
132: VecGetArrayRead(b,&ba);
133: VecGetArray(x,&xa);
134: #if defined(PETSC_USE_COMPLEX)
135: status = umfpack_UMF_wsolve(uflag,ai,aj,(PetscReal*)av,NULL,(PetscReal*)xa,NULL,(PetscReal*)ba,NULL,lu->Numeric,lu->Control,lu->Info,lu->Wi,lu->W);
136: #else
137: status = umfpack_UMF_wsolve(uflag,ai,aj,av,xa,ba,lu->Numeric,lu->Control,lu->Info,lu->Wi,lu->W);
138: #endif
139: umfpack_UMF_report_info(lu->Control, lu->Info);
140: if (status < 0) {
141: umfpack_UMF_report_status(lu->Control, status);
142: SETERRQ(PETSC_COMM_SELF,PETSC_ERR_LIB,"umfpack_UMF_wsolve failed");
143: }
145: VecRestoreArrayRead(b,&ba);
146: VecRestoreArray(x,&xa);
147: return(0);
148: }
150: static PetscErrorCode MatSolve_UMFPACK(Mat A,Vec b,Vec x)
151: {
155: /* We gave UMFPACK the algebraic transpose (because it assumes column alignment) */
156: MatSolve_UMFPACK_Private(A,b,x,UMFPACK_Aat);
157: return(0);
158: }
160: static PetscErrorCode MatSolveTranspose_UMFPACK(Mat A,Vec b,Vec x)
161: {
165: /* We gave UMFPACK the algebraic transpose (because it assumes column alignment) */
166: MatSolve_UMFPACK_Private(A,b,x,UMFPACK_A);
167: return(0);
168: }
170: static PetscErrorCode MatLUFactorNumeric_UMFPACK(Mat F,Mat A,const MatFactorInfo *info)
171: {
172: Mat_UMFPACK *lu = (Mat_UMFPACK*)(F)->data;
173: Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data;
174: PetscInt *ai = a->i,*aj=a->j,status;
175: PetscScalar *av = a->a;
179: if (!A->rmap->n) return(0);
180: /* numeric factorization of A' */
181: /* ----------------------------*/
183: if (lu->flg == SAME_NONZERO_PATTERN && lu->Numeric) {
184: umfpack_UMF_free_numeric(&lu->Numeric);
185: }
186: #if defined(PETSC_USE_COMPLEX)
187: status = umfpack_UMF_numeric(ai,aj,(double*)av,NULL,lu->Symbolic,&lu->Numeric,lu->Control,lu->Info);
188: #else
189: status = umfpack_UMF_numeric(ai,aj,av,lu->Symbolic,&lu->Numeric,lu->Control,lu->Info);
190: #endif
191: if (status < 0) {
192: umfpack_UMF_report_status(lu->Control, status);
193: SETERRQ(PETSC_COMM_SELF,PETSC_ERR_LIB,"umfpack_UMF_numeric failed");
194: }
195: /* report numeric factorization of A' when Control[PRL] > 3 */
196: (void) umfpack_UMF_report_numeric(lu->Numeric, lu->Control);
198: PetscObjectReference((PetscObject)A);
199: MatDestroy(&lu->A);
201: lu->A = A;
202: lu->flg = SAME_NONZERO_PATTERN;
203: lu->CleanUpUMFPACK = PETSC_TRUE;
204: F->ops->solve = MatSolve_UMFPACK;
205: F->ops->solvetranspose = MatSolveTranspose_UMFPACK;
206: return(0);
207: }
209: /*
210: Note the r permutation is ignored
211: */
212: static PetscErrorCode MatLUFactorSymbolic_UMFPACK(Mat F,Mat A,IS r,IS c,const MatFactorInfo *info)
213: {
214: Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data;
215: Mat_UMFPACK *lu = (Mat_UMFPACK*)(F->data);
217: PetscInt i,*ai = a->i,*aj = a->j,m=A->rmap->n,n=A->cmap->n;
218: #if !defined(PETSC_USE_COMPLEX)
219: PetscScalar *av = a->a;
220: #endif
221: const PetscInt *ra;
222: PetscInt status;
225: (F)->ops->lufactornumeric = MatLUFactorNumeric_UMFPACK;
226: if (!n) return(0);
227: if (lu->PetscMatOrdering) {
228: ISGetIndices(r,&ra);
229: PetscMalloc1(m,&lu->perm_c);
230: /* we cannot simply memcpy on 64 bit archs */
231: for (i = 0; i < m; i++) lu->perm_c[i] = ra[i];
232: ISRestoreIndices(r,&ra);
233: }
235: /* print the control parameters */
236: if (lu->Control[UMFPACK_PRL] > 1) umfpack_UMF_report_control(lu->Control);
238: /* symbolic factorization of A' */
239: /* ---------------------------------------------------------------------- */
240: if (lu->PetscMatOrdering) { /* use Petsc row ordering */
241: #if !defined(PETSC_USE_COMPLEX)
242: status = umfpack_UMF_qsymbolic(n,m,ai,aj,av,lu->perm_c,&lu->Symbolic,lu->Control,lu->Info);
243: #else
244: status = umfpack_UMF_qsymbolic(n,m,ai,aj,NULL,NULL,lu->perm_c,&lu->Symbolic,lu->Control,lu->Info);
245: #endif
246: } else { /* use Umfpack col ordering */
247: #if !defined(PETSC_USE_COMPLEX)
248: status = umfpack_UMF_symbolic(n,m,ai,aj,av,&lu->Symbolic,lu->Control,lu->Info);
249: #else
250: status = umfpack_UMF_symbolic(n,m,ai,aj,NULL,NULL,&lu->Symbolic,lu->Control,lu->Info);
251: #endif
252: }
253: if (status < 0) {
254: umfpack_UMF_report_info(lu->Control, lu->Info);
255: umfpack_UMF_report_status(lu->Control, status);
256: SETERRQ(PETSC_COMM_SELF,PETSC_ERR_LIB,"umfpack_UMF_symbolic failed");
257: }
258: /* report sumbolic factorization of A' when Control[PRL] > 3 */
259: (void) umfpack_UMF_report_symbolic(lu->Symbolic, lu->Control);
261: lu->flg = DIFFERENT_NONZERO_PATTERN;
262: lu->CleanUpUMFPACK = PETSC_TRUE;
263: return(0);
264: }
266: static PetscErrorCode MatView_Info_UMFPACK(Mat A,PetscViewer viewer)
267: {
268: Mat_UMFPACK *lu= (Mat_UMFPACK*)A->data;
272: /* check if matrix is UMFPACK type */
273: if (A->ops->solve != MatSolve_UMFPACK) return(0);
275: PetscViewerASCIIPrintf(viewer,"UMFPACK run parameters:\n");
276: /* Control parameters used by reporting routiones */
277: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_PRL]: %g\n",lu->Control[UMFPACK_PRL]);
279: /* Control parameters used by symbolic factorization */
280: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_STRATEGY]: %g\n",lu->Control[UMFPACK_STRATEGY]);
281: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_DENSE_COL]: %g\n",lu->Control[UMFPACK_DENSE_COL]);
282: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_DENSE_ROW]: %g\n",lu->Control[UMFPACK_DENSE_ROW]);
283: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_AMD_DENSE]: %g\n",lu->Control[UMFPACK_AMD_DENSE]);
284: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_BLOCK_SIZE]: %g\n",lu->Control[UMFPACK_BLOCK_SIZE]);
285: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_FIXQ]: %g\n",lu->Control[UMFPACK_FIXQ]);
286: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_AGGRESSIVE]: %g\n",lu->Control[UMFPACK_AGGRESSIVE]);
288: /* Control parameters used by numeric factorization */
289: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_PIVOT_TOLERANCE]: %g\n",lu->Control[UMFPACK_PIVOT_TOLERANCE]);
290: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_SYM_PIVOT_TOLERANCE]: %g\n",lu->Control[UMFPACK_SYM_PIVOT_TOLERANCE]);
291: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_SCALE]: %g\n",lu->Control[UMFPACK_SCALE]);
292: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_ALLOC_INIT]: %g\n",lu->Control[UMFPACK_ALLOC_INIT]);
293: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_DROPTOL]: %g\n",lu->Control[UMFPACK_DROPTOL]);
295: /* Control parameters used by solve */
296: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_IRSTEP]: %g\n",lu->Control[UMFPACK_IRSTEP]);
298: /* mat ordering */
299: if (!lu->PetscMatOrdering) {
300: PetscViewerASCIIPrintf(viewer," Control[UMFPACK_ORDERING]: %s (not using the PETSc ordering)\n",UmfpackOrderingTypes[(int)lu->Control[UMFPACK_ORDERING]]);
301: }
302: return(0);
303: }
305: static PetscErrorCode MatView_UMFPACK(Mat A,PetscViewer viewer)
306: {
307: PetscErrorCode ierr;
308: PetscBool iascii;
309: PetscViewerFormat format;
312: PetscObjectTypeCompare((PetscObject)viewer,PETSCVIEWERASCII,&iascii);
313: if (iascii) {
314: PetscViewerGetFormat(viewer,&format);
315: if (format == PETSC_VIEWER_ASCII_INFO) {
316: MatView_Info_UMFPACK(A,viewer);
317: }
318: }
319: return(0);
320: }
322: PetscErrorCode MatFactorGetSolverType_seqaij_umfpack(Mat A,MatSolverType *type)
323: {
325: *type = MATSOLVERUMFPACK;
326: return(0);
327: }
330: /*MC
331: MATSOLVERUMFPACK = "umfpack" - A matrix type providing direct solvers (LU) for sequential matrices
332: via the external package UMFPACK.
334: Use ./configure --download-suitesparse to install PETSc to use UMFPACK
336: Use -pc_type lu -pc_factor_mat_solver_type umfpack to use this direct solver
338: Consult UMFPACK documentation for more information about the Control parameters
339: which correspond to the options database keys below.
341: Options Database Keys:
342: + -mat_umfpack_ordering - CHOLMOD, AMD, GIVEN, METIS, BEST, NONE
343: . -mat_umfpack_prl - UMFPACK print level: Control[UMFPACK_PRL]
344: . -mat_umfpack_strategy <AUTO> - (choose one of) AUTO UNSYMMETRIC SYMMETRIC 2BY2
345: . -mat_umfpack_dense_col <alpha_c> - UMFPACK dense column threshold: Control[UMFPACK_DENSE_COL]
346: . -mat_umfpack_dense_row <0.2> - Control[UMFPACK_DENSE_ROW]
347: . -mat_umfpack_amd_dense <10> - Control[UMFPACK_AMD_DENSE]
348: . -mat_umfpack_block_size <bs> - UMFPACK block size for BLAS-Level 3 calls: Control[UMFPACK_BLOCK_SIZE]
349: . -mat_umfpack_2by2_tolerance <0.01> - Control[UMFPACK_2BY2_TOLERANCE]
350: . -mat_umfpack_fixq <0> - Control[UMFPACK_FIXQ]
351: . -mat_umfpack_aggressive <1> - Control[UMFPACK_AGGRESSIVE]
352: . -mat_umfpack_pivot_tolerance <delta> - UMFPACK partial pivot tolerance: Control[UMFPACK_PIVOT_TOLERANCE]
353: . -mat_umfpack_sym_pivot_tolerance <0.001> - Control[UMFPACK_SYM_PIVOT_TOLERANCE]
354: . -mat_umfpack_scale <NONE> - (choose one of) NONE SUM MAX
355: . -mat_umfpack_alloc_init <delta> - UMFPACK factorized matrix allocation modifier: Control[UMFPACK_ALLOC_INIT]
356: . -mat_umfpack_droptol <0> - Control[UMFPACK_DROPTOL]
357: - -mat_umfpack_irstep <maxit> - UMFPACK maximum number of iterative refinement steps: Control[UMFPACK_IRSTEP]
359: Level: beginner
361: Note: UMFPACK is part of SuiteSparse http://faculty.cse.tamu.edu/davis/suitesparse.html
363: .seealso: PCLU, MATSOLVERSUPERLU, MATSOLVERMUMPS, PCFactorSetMatSolverType(), MatSolverType
364: M*/
366: PETSC_EXTERN PetscErrorCode MatGetFactor_seqaij_umfpack(Mat A,MatFactorType ftype,Mat *F)
367: {
368: Mat B;
369: Mat_UMFPACK *lu;
371: PetscInt m=A->rmap->n,n=A->cmap->n,idx;
373: const char *strategy[]={"AUTO","UNSYMMETRIC","SYMMETRIC"};
374: const char *scale[] ={"NONE","SUM","MAX"};
375: PetscBool flg;
378: /* Create the factorization matrix F */
379: MatCreate(PetscObjectComm((PetscObject)A),&B);
380: MatSetSizes(B,PETSC_DECIDE,PETSC_DECIDE,m,n);
381: PetscStrallocpy("umfpack",&((PetscObject)B)->type_name);
382: MatSetUp(B);
384: PetscNewLog(B,&lu);
386: B->data = lu;
387: B->ops->getinfo = MatGetInfo_External;
388: B->ops->lufactorsymbolic = MatLUFactorSymbolic_UMFPACK;
389: B->ops->destroy = MatDestroy_UMFPACK;
390: B->ops->view = MatView_UMFPACK;
391: B->ops->matsolve = NULL;
393: PetscObjectComposeFunction((PetscObject)B,"MatFactorGetSolverType_C",MatFactorGetSolverType_seqaij_umfpack);
395: B->factortype = MAT_FACTOR_LU;
396: B->assembled = PETSC_TRUE; /* required by -ksp_view */
397: B->preallocated = PETSC_TRUE;
399: PetscFree(B->solvertype);
400: PetscStrallocpy(MATSOLVERUMFPACK,&B->solvertype);
402: /* initializations */
403: /* ------------------------------------------------*/
404: /* get the default control parameters */
405: umfpack_UMF_defaults(lu->Control);
406: lu->perm_c = NULL; /* use defaul UMFPACK col permutation */
407: lu->Control[UMFPACK_IRSTEP] = 0; /* max num of iterative refinement steps to attempt */
409: PetscOptionsBegin(PetscObjectComm((PetscObject)A),((PetscObject)A)->prefix,"UMFPACK Options","Mat");
410: /* Control parameters used by reporting routiones */
411: PetscOptionsReal("-mat_umfpack_prl","Control[UMFPACK_PRL]","None",lu->Control[UMFPACK_PRL],&lu->Control[UMFPACK_PRL],NULL);
413: /* Control parameters for symbolic factorization */
414: PetscOptionsEList("-mat_umfpack_strategy","ordering and pivoting strategy","None",strategy,3,strategy[0],&idx,&flg);
415: if (flg) {
416: switch (idx) {
417: case 0: lu->Control[UMFPACK_STRATEGY] = UMFPACK_STRATEGY_AUTO; break;
418: case 1: lu->Control[UMFPACK_STRATEGY] = UMFPACK_STRATEGY_UNSYMMETRIC; break;
419: case 2: lu->Control[UMFPACK_STRATEGY] = UMFPACK_STRATEGY_SYMMETRIC; break;
420: }
421: }
422: PetscOptionsEList("-mat_umfpack_ordering","Internal ordering method","None",UmfpackOrderingTypes,sizeof(UmfpackOrderingTypes)/sizeof(UmfpackOrderingTypes[0]),UmfpackOrderingTypes[(int)lu->Control[UMFPACK_ORDERING]],&idx,&flg);
423: if (flg) lu->Control[UMFPACK_ORDERING] = (int)idx;
424: PetscOptionsReal("-mat_umfpack_dense_col","Control[UMFPACK_DENSE_COL]","None",lu->Control[UMFPACK_DENSE_COL],&lu->Control[UMFPACK_DENSE_COL],NULL);
425: PetscOptionsReal("-mat_umfpack_dense_row","Control[UMFPACK_DENSE_ROW]","None",lu->Control[UMFPACK_DENSE_ROW],&lu->Control[UMFPACK_DENSE_ROW],NULL);
426: PetscOptionsReal("-mat_umfpack_amd_dense","Control[UMFPACK_AMD_DENSE]","None",lu->Control[UMFPACK_AMD_DENSE],&lu->Control[UMFPACK_AMD_DENSE],NULL);
427: PetscOptionsReal("-mat_umfpack_block_size","Control[UMFPACK_BLOCK_SIZE]","None",lu->Control[UMFPACK_BLOCK_SIZE],&lu->Control[UMFPACK_BLOCK_SIZE],NULL);
428: PetscOptionsReal("-mat_umfpack_fixq","Control[UMFPACK_FIXQ]","None",lu->Control[UMFPACK_FIXQ],&lu->Control[UMFPACK_FIXQ],NULL);
429: PetscOptionsReal("-mat_umfpack_aggressive","Control[UMFPACK_AGGRESSIVE]","None",lu->Control[UMFPACK_AGGRESSIVE],&lu->Control[UMFPACK_AGGRESSIVE],NULL);
431: /* Control parameters used by numeric factorization */
432: PetscOptionsReal("-mat_umfpack_pivot_tolerance","Control[UMFPACK_PIVOT_TOLERANCE]","None",lu->Control[UMFPACK_PIVOT_TOLERANCE],&lu->Control[UMFPACK_PIVOT_TOLERANCE],NULL);
433: PetscOptionsReal("-mat_umfpack_sym_pivot_tolerance","Control[UMFPACK_SYM_PIVOT_TOLERANCE]","None",lu->Control[UMFPACK_SYM_PIVOT_TOLERANCE],&lu->Control[UMFPACK_SYM_PIVOT_TOLERANCE],NULL);
434: PetscOptionsEList("-mat_umfpack_scale","Control[UMFPACK_SCALE]","None",scale,3,scale[0],&idx,&flg);
435: if (flg) {
436: switch (idx) {
437: case 0: lu->Control[UMFPACK_SCALE] = UMFPACK_SCALE_NONE; break;
438: case 1: lu->Control[UMFPACK_SCALE] = UMFPACK_SCALE_SUM; break;
439: case 2: lu->Control[UMFPACK_SCALE] = UMFPACK_SCALE_MAX; break;
440: }
441: }
442: PetscOptionsReal("-mat_umfpack_alloc_init","Control[UMFPACK_ALLOC_INIT]","None",lu->Control[UMFPACK_ALLOC_INIT],&lu->Control[UMFPACK_ALLOC_INIT],NULL);
443: PetscOptionsReal("-mat_umfpack_front_alloc_init","Control[UMFPACK_FRONT_ALLOC_INIT]","None",lu->Control[UMFPACK_FRONT_ALLOC_INIT],&lu->Control[UMFPACK_ALLOC_INIT],NULL);
444: PetscOptionsReal("-mat_umfpack_droptol","Control[UMFPACK_DROPTOL]","None",lu->Control[UMFPACK_DROPTOL],&lu->Control[UMFPACK_DROPTOL],NULL);
446: /* Control parameters used by solve */
447: PetscOptionsReal("-mat_umfpack_irstep","Control[UMFPACK_IRSTEP]","None",lu->Control[UMFPACK_IRSTEP],&lu->Control[UMFPACK_IRSTEP],NULL);
449: /* use Petsc mat ordering (note: size is for the transpose, and PETSc r = Umfpack perm_c) */
450: PetscOptionsName("-pc_factor_mat_ordering_type","Ordering to do factorization in","MatGetOrdering",&lu->PetscMatOrdering);
451: PetscOptionsEnd();
452: *F = B;
453: return(0);
454: }
456: PETSC_INTERN PetscErrorCode MatGetFactor_seqaij_cholmod(Mat,MatFactorType,Mat*);
457: PETSC_INTERN PetscErrorCode MatGetFactor_seqsbaij_cholmod(Mat,MatFactorType,Mat*);
458: PETSC_INTERN PetscErrorCode MatGetFactor_seqaij_klu(Mat,MatFactorType,Mat*);
460: PETSC_EXTERN PetscErrorCode MatSolverTypeRegister_SuiteSparse(void)
461: {
465: MatSolverTypeRegister(MATSOLVERUMFPACK,MATSEQAIJ, MAT_FACTOR_LU,MatGetFactor_seqaij_umfpack);
466: MatSolverTypeRegister(MATSOLVERCHOLMOD,MATSEQAIJ, MAT_FACTOR_CHOLESKY,MatGetFactor_seqaij_cholmod);
467: MatSolverTypeRegister(MATSOLVERCHOLMOD,MATSEQSBAIJ, MAT_FACTOR_CHOLESKY,MatGetFactor_seqsbaij_cholmod);
468: MatSolverTypeRegister(MATSOLVERKLU,MATSEQAIJ, MAT_FACTOR_LU,MatGetFactor_seqaij_klu);
469: return(0);
470: }