Actual source code: vector.c
petsc-3.10.5 2019-03-28
2: /*
3: Provides the interface functions for vector operations that do NOT have PetscScalar/PetscReal in the signature
4: These are the vector functions the user calls.
5: */
6: #include <petsc/private/vecimpl.h>
8: /* Logging support */
9: PetscClassId VEC_CLASSID;
10: PetscLogEvent VEC_View, VEC_Max, VEC_Min, VEC_Dot, VEC_MDot, VEC_TDot;
11: PetscLogEvent VEC_Norm, VEC_Normalize, VEC_Scale, VEC_Copy, VEC_Set, VEC_AXPY, VEC_AYPX, VEC_WAXPY;
12: PetscLogEvent VEC_MTDot, VEC_MAXPY, VEC_Swap, VEC_AssemblyBegin, VEC_ScatterBegin, VEC_ScatterEnd;
13: PetscLogEvent VEC_AssemblyEnd, VEC_PointwiseMult, VEC_SetValues, VEC_Load;
14: PetscLogEvent VEC_SetRandom, VEC_ReduceArithmetic, VEC_ReduceCommunication,VEC_ReduceBegin,VEC_ReduceEnd,VEC_Ops;
15: PetscLogEvent VEC_DotNorm2, VEC_AXPBYPCZ;
16: PetscLogEvent VEC_ViennaCLCopyFromGPU, VEC_ViennaCLCopyToGPU;
17: PetscLogEvent VEC_CUDACopyFromGPU, VEC_CUDACopyToGPU;
18: PetscLogEvent VEC_CUDACopyFromGPUSome, VEC_CUDACopyToGPUSome;
20: /*@
21: VecStashGetInfo - Gets how many values are currently in the vector stash, i.e. need
22: to be communicated to other processors during the VecAssemblyBegin/End() process
24: Not collective
26: Input Parameter:
27: . vec - the vector
29: Output Parameters:
30: + nstash - the size of the stash
31: . reallocs - the number of additional mallocs incurred.
32: . bnstash - the size of the block stash
33: - breallocs - the number of additional mallocs incurred.in the block stash
35: Level: advanced
37: .seealso: VecAssemblyBegin(), VecAssemblyEnd(), Vec, VecStashSetInitialSize(), VecStashView()
39: @*/
40: PetscErrorCode VecStashGetInfo(Vec vec,PetscInt *nstash,PetscInt *reallocs,PetscInt *bnstash,PetscInt *breallocs)
41: {
45: VecStashGetInfo_Private(&vec->stash,nstash,reallocs);
46: VecStashGetInfo_Private(&vec->bstash,bnstash,breallocs);
47: return(0);
48: }
50: /*@
51: VecSetLocalToGlobalMapping - Sets a local numbering to global numbering used
52: by the routine VecSetValuesLocal() to allow users to insert vector entries
53: using a local (per-processor) numbering.
55: Logically Collective on Vec
57: Input Parameters:
58: + x - vector
59: - mapping - mapping created with ISLocalToGlobalMappingCreate() or ISLocalToGlobalMappingCreateIS()
61: Notes:
62: All vectors obtained with VecDuplicate() from this vector inherit the same mapping.
64: Level: intermediate
66: Concepts: vector^setting values with local numbering
68: seealso: VecAssemblyBegin(), VecAssemblyEnd(), VecSetValues(), VecSetValuesLocal(),
69: VecSetLocalToGlobalMapping(), VecSetValuesBlockedLocal()
70: @*/
71: PetscErrorCode VecSetLocalToGlobalMapping(Vec x,ISLocalToGlobalMapping mapping)
72: {
79: if (x->ops->setlocaltoglobalmapping) {
80: (*x->ops->setlocaltoglobalmapping)(x,mapping);
81: } else {
82: PetscLayoutSetISLocalToGlobalMapping(x->map,mapping);
83: }
84: return(0);
85: }
87: /*@
88: VecGetLocalToGlobalMapping - Gets the local-to-global numbering set by VecSetLocalToGlobalMapping()
90: Not Collective
92: Input Parameter:
93: . X - the vector
95: Output Parameter:
96: . mapping - the mapping
98: Level: advanced
100: Concepts: vectors^local to global mapping
101: Concepts: local to global mapping^for vectors
103: .seealso: VecSetValuesLocal()
104: @*/
105: PetscErrorCode VecGetLocalToGlobalMapping(Vec X,ISLocalToGlobalMapping *mapping)
106: {
111: *mapping = X->map->mapping;
112: return(0);
113: }
115: /*@
116: VecAssemblyBegin - Begins assembling the vector. This routine should
117: be called after completing all calls to VecSetValues().
119: Collective on Vec
121: Input Parameter:
122: . vec - the vector
124: Level: beginner
126: Concepts: assembly^vectors
128: .seealso: VecAssemblyEnd(), VecSetValues()
129: @*/
130: PetscErrorCode VecAssemblyBegin(Vec vec)
131: {
137: VecStashViewFromOptions(vec,NULL,"-vec_view_stash");
138: PetscLogEventBegin(VEC_AssemblyBegin,vec,0,0,0);
139: if (vec->ops->assemblybegin) {
140: (*vec->ops->assemblybegin)(vec);
141: }
142: PetscLogEventEnd(VEC_AssemblyBegin,vec,0,0,0);
143: PetscObjectStateIncrease((PetscObject)vec);
144: return(0);
145: }
147: /*@
148: VecAssemblyEnd - Completes assembling the vector. This routine should
149: be called after VecAssemblyBegin().
151: Collective on Vec
153: Input Parameter:
154: . vec - the vector
156: Options Database Keys:
157: + -vec_view - Prints vector in ASCII format
158: . -vec_view ::ascii_matlab - Prints vector in ASCII MATLAB format to stdout
159: . -vec_view matlab:filename - Prints vector in MATLAB format to matlaboutput.mat
160: . -vec_view draw - Activates vector viewing using drawing tools
161: . -display <name> - Sets display name (default is host)
162: . -draw_pause <sec> - Sets number of seconds to pause after display
163: - -vec_view socket - Activates vector viewing using a socket
165: Level: beginner
167: .seealso: VecAssemblyBegin(), VecSetValues()
168: @*/
169: PetscErrorCode VecAssemblyEnd(Vec vec)
170: {
175: PetscLogEventBegin(VEC_AssemblyEnd,vec,0,0,0);
177: if (vec->ops->assemblyend) {
178: (*vec->ops->assemblyend)(vec);
179: }
180: PetscLogEventEnd(VEC_AssemblyEnd,vec,0,0,0);
181: VecViewFromOptions(vec,NULL,"-vec_view");
182: return(0);
183: }
185: /*@
186: VecPointwiseMax - Computes the componentwise maximum w_i = max(x_i, y_i).
188: Logically Collective on Vec
190: Input Parameters:
191: . x, y - the vectors
193: Output Parameter:
194: . w - the result
196: Level: advanced
198: Notes:
199: any subset of the x, y, and w may be the same vector.
200: For complex numbers compares only the real part
202: Concepts: vector^pointwise multiply
204: .seealso: VecPointwiseDivide(), VecPointwiseMult(), VecPointwiseMin(), VecPointwiseMaxAbs(), VecMaxPointwiseDivide()
205: @*/
206: PetscErrorCode VecPointwiseMax(Vec w,Vec x,Vec y)
207: {
219: VecCheckSameSize(w,1,x,2);
220: VecCheckSameSize(w,1,y,3);
221: (*w->ops->pointwisemax)(w,x,y);
222: PetscObjectStateIncrease((PetscObject)w);
223: return(0);
224: }
227: /*@
228: VecPointwiseMin - Computes the componentwise minimum w_i = min(x_i, y_i).
230: Logically Collective on Vec
232: Input Parameters:
233: . x, y - the vectors
235: Output Parameter:
236: . w - the result
238: Level: advanced
240: Notes:
241: any subset of the x, y, and w may be the same vector.
242: For complex numbers compares only the real part
244: Concepts: vector^pointwise multiply
246: .seealso: VecPointwiseDivide(), VecPointwiseMult(), VecPointwiseMin(), VecPointwiseMaxAbs(), VecMaxPointwiseDivide()
247: @*/
248: PetscErrorCode VecPointwiseMin(Vec w,Vec x,Vec y)
249: {
261: VecCheckSameSize(w,1,x,2);
262: VecCheckSameSize(w,1,y,3);
263: (*w->ops->pointwisemin)(w,x,y);
264: PetscObjectStateIncrease((PetscObject)w);
265: return(0);
266: }
268: /*@
269: VecPointwiseMaxAbs - Computes the componentwise maximum of the absolute values w_i = max(abs(x_i), abs(y_i)).
271: Logically Collective on Vec
273: Input Parameters:
274: . x, y - the vectors
276: Output Parameter:
277: . w - the result
279: Level: advanced
281: Notes:
282: any subset of the x, y, and w may be the same vector.
284: Concepts: vector^pointwise multiply
286: .seealso: VecPointwiseDivide(), VecPointwiseMult(), VecPointwiseMin(), VecPointwiseMax(), VecMaxPointwiseDivide()
287: @*/
288: PetscErrorCode VecPointwiseMaxAbs(Vec w,Vec x,Vec y)
289: {
301: VecCheckSameSize(w,1,x,2);
302: VecCheckSameSize(w,1,y,3);
303: (*w->ops->pointwisemaxabs)(w,x,y);
304: PetscObjectStateIncrease((PetscObject)w);
305: return(0);
306: }
308: /*@
309: VecPointwiseDivide - Computes the componentwise division w = x/y.
311: Logically Collective on Vec
313: Input Parameters:
314: . x, y - the vectors
316: Output Parameter:
317: . w - the result
319: Level: advanced
321: Notes:
322: any subset of the x, y, and w may be the same vector.
324: Concepts: vector^pointwise divide
326: .seealso: VecPointwiseMult(), VecPointwiseMax(), VecPointwiseMin(), VecPointwiseMaxAbs(), VecMaxPointwiseDivide()
327: @*/
328: PetscErrorCode VecPointwiseDivide(Vec w,Vec x,Vec y)
329: {
341: VecCheckSameSize(w,1,x,2);
342: VecCheckSameSize(w,1,y,3);
343: (*w->ops->pointwisedivide)(w,x,y);
344: PetscObjectStateIncrease((PetscObject)w);
345: return(0);
346: }
349: /*@
350: VecDuplicate - Creates a new vector of the same type as an existing vector.
352: Collective on Vec
354: Input Parameters:
355: . v - a vector to mimic
357: Output Parameter:
358: . newv - location to put new vector
360: Notes:
361: VecDuplicate() DOES NOT COPY the vector entries, but rather allocates storage
362: for the new vector. Use VecCopy() to copy a vector.
364: Use VecDestroy() to free the space. Use VecDuplicateVecs() to get several
365: vectors.
367: Level: beginner
369: .seealso: VecDestroy(), VecDuplicateVecs(), VecCreate(), VecCopy()
370: @*/
371: PetscErrorCode VecDuplicate(Vec v,Vec *newv)
372: {
379: (*v->ops->duplicate)(v,newv);
380: PetscObjectStateIncrease((PetscObject)*newv);
381: return(0);
382: }
384: /*@
385: VecDestroy - Destroys a vector.
387: Collective on Vec
389: Input Parameters:
390: . v - the vector
392: Level: beginner
394: .seealso: VecDuplicate(), VecDestroyVecs()
395: @*/
396: PetscErrorCode VecDestroy(Vec *v)
397: {
401: if (!*v) return(0);
403: if (--((PetscObject)(*v))->refct > 0) {*v = 0; return(0);}
405: PetscObjectSAWsViewOff((PetscObject)*v);
406: /* destroy the internal part */
407: if ((*v)->ops->destroy) {
408: (*(*v)->ops->destroy)(*v);
409: }
410: /* destroy the external/common part */
411: PetscLayoutDestroy(&(*v)->map);
412: PetscHeaderDestroy(v);
413: return(0);
414: }
416: /*@C
417: VecDuplicateVecs - Creates several vectors of the same type as an existing vector.
419: Collective on Vec
421: Input Parameters:
422: + m - the number of vectors to obtain
423: - v - a vector to mimic
425: Output Parameter:
426: . V - location to put pointer to array of vectors
428: Notes:
429: Use VecDestroyVecs() to free the space. Use VecDuplicate() to form a single
430: vector.
432: Fortran Note:
433: The Fortran interface is slightly different from that given below, it
434: requires one to pass in V a Vec (integer) array of size at least m.
435: See the Fortran chapter of the users manual and petsc/src/vec/vec/examples for details.
437: Level: intermediate
439: .seealso: VecDestroyVecs(), VecDuplicate(), VecCreate(), VecDuplicateVecsF90()
440: @*/
441: PetscErrorCode VecDuplicateVecs(Vec v,PetscInt m,Vec *V[])
442: {
449: (*v->ops->duplicatevecs)(v,m,V);
450: return(0);
451: }
453: /*@C
454: VecDestroyVecs - Frees a block of vectors obtained with VecDuplicateVecs().
456: Collective on Vec
458: Input Parameters:
459: + vv - pointer to pointer to array of vector pointers, if NULL no vectors are destroyed
460: - m - the number of vectors previously obtained, if zero no vectors are destroyed
462: Fortran Note:
463: The Fortran interface is slightly different from that given below.
464: See the Fortran chapter of the users manual
466: Level: intermediate
468: .seealso: VecDuplicateVecs(), VecDestroyVecsf90()
469: @*/
470: PetscErrorCode VecDestroyVecs(PetscInt m,Vec *vv[])
471: {
476: if (m < 0) SETERRQ1(PETSC_COMM_SELF,PETSC_ERR_ARG_OUTOFRANGE,"Trying to destroy negative number of vectors %D",m);
477: if (!m || !*vv) {*vv = NULL; return(0);}
480: (*(**vv)->ops->destroyvecs)(m,*vv);
481: *vv = NULL;
482: return(0);
483: }
485: /*@C
486: VecView - Views a vector object.
488: Collective on Vec
490: Input Parameters:
491: + vec - the vector
492: - viewer - an optional visualization context
494: Notes:
495: The available visualization contexts include
496: + PETSC_VIEWER_STDOUT_SELF - for sequential vectors
497: . PETSC_VIEWER_STDOUT_WORLD - for parallel vectors created on PETSC_COMM_WORLD
498: - PETSC_VIEWER_STDOUT_(comm) - for parallel vectors created on MPI communicator comm
500: You can change the format the vector is printed using the
501: option PetscViewerPushFormat().
503: The user can open alternative visualization contexts with
504: + PetscViewerASCIIOpen() - Outputs vector to a specified file
505: . PetscViewerBinaryOpen() - Outputs vector in binary to a
506: specified file; corresponding input uses VecLoad()
507: . PetscViewerDrawOpen() - Outputs vector to an X window display
508: - PetscViewerSocketOpen() - Outputs vector to Socket viewer
510: The user can call PetscViewerPushFormat() to specify the output
511: format of ASCII printed objects (when using PETSC_VIEWER_STDOUT_SELF,
512: PETSC_VIEWER_STDOUT_WORLD and PetscViewerASCIIOpen). Available formats include
513: + PETSC_VIEWER_DEFAULT - default, prints vector contents
514: . PETSC_VIEWER_ASCII_MATLAB - prints vector contents in MATLAB format
515: . PETSC_VIEWER_ASCII_INDEX - prints vector contents, including indices of vector elements
516: - PETSC_VIEWER_ASCII_COMMON - prints vector contents, using a
517: format common among all vector types
519: Notes:
520: You can pass any number of vector objects, or other PETSc objects to the same viewer.
522: Notes for binary viewer: If you pass multiply vectors to a binary viewer you can read them back in in the same order
523: $ with VecLoad().
524: $
525: $ If the blocksize of the vector is greater than one then you must provide a unique prefix to
526: $ the vector with PetscObjectSetOptionsPrefix((PetscObject)vec,"uniqueprefix"); BEFORE calling VecView() on the
527: $ vector to be stored and then set that same unique prefix on the vector that you pass to VecLoad(). The blocksize
528: $ information is stored in an ASCII file with the same name as the binary file plus a ".info" appended to the
529: $ filename. If you copy the binary file, make sure you copy the associated .info file with it.
531: Notes for HDF5 Viewer: the name of the Vec (given with PetscObjectSetName() is the name that is used
532: $ for the object in the HDF5 file. If you wish to store the same vector to the HDF5 viewer (with different values,
533: $ obviously) several times, you must change its name each time before calling the VecView(). The name you use
534: $ here should equal the name that you use in the Vec object that you use with VecLoad().
536: See the manual page for VecLoad() on the exact format the binary viewer stores
537: the values in the file.
539: Level: beginner
541: Concepts: vector^printing
542: Concepts: vector^saving to disk
544: .seealso: PetscViewerASCIIOpen(), PetscViewerDrawOpen(), PetscDrawLGCreate(),
545: PetscViewerSocketOpen(), PetscViewerBinaryOpen(), VecLoad(), PetscViewerCreate(),
546: PetscRealView(), PetscScalarView(), PetscIntView()
547: @*/
548: PetscErrorCode VecView(Vec vec,PetscViewer viewer)
549: {
550: PetscErrorCode ierr;
551: PetscBool iascii;
552: PetscViewerFormat format;
553: PetscMPIInt size;
558: if (!viewer) {
559: PetscViewerASCIIGetStdout(PetscObjectComm((PetscObject)vec),&viewer);
560: }
562: PetscViewerGetFormat(viewer,&format);
563: MPI_Comm_size(PetscObjectComm((PetscObject)vec),&size);
564: if (size == 1 && format == PETSC_VIEWER_LOAD_BALANCE) return(0);
566: if (vec->stash.n || vec->bstash.n) SETERRQ(PETSC_COMM_SELF,PETSC_ERR_ARG_WRONGSTATE,"Must call VecAssemblyBegin/End() before viewing this vector");
568: PetscLogEventBegin(VEC_View,vec,viewer,0,0);
569: PetscObjectTypeCompare((PetscObject)viewer,PETSCVIEWERASCII,&iascii);
570: if (iascii) {
571: PetscInt rows,bs;
573: PetscObjectPrintClassNamePrefixType((PetscObject)vec,viewer);
574: if (format == PETSC_VIEWER_ASCII_INFO || format == PETSC_VIEWER_ASCII_INFO_DETAIL) {
575: PetscViewerASCIIPushTab(viewer);
576: VecGetSize(vec,&rows);
577: VecGetBlockSize(vec,&bs);
578: if (bs != 1) {
579: PetscViewerASCIIPrintf(viewer,"length=%D, bs=%D\n",rows,bs);
580: } else {
581: PetscViewerASCIIPrintf(viewer,"length=%D\n",rows);
582: }
583: PetscViewerASCIIPopTab(viewer);
584: }
585: }
586: VecLockPush(vec);
587: if ((format == PETSC_VIEWER_NATIVE || format == PETSC_VIEWER_LOAD_BALANCE) && vec->ops->viewnative) {
588: (*vec->ops->viewnative)(vec,viewer);
589: } else {
590: (*vec->ops->view)(vec,viewer);
591: }
592: VecLockPop(vec);
593: PetscLogEventEnd(VEC_View,vec,viewer,0,0);
594: return(0);
595: }
597: #if defined(PETSC_USE_DEBUG)
598: #include <../src/sys/totalview/tv_data_display.h>
599: PETSC_UNUSED static int TV_display_type(const struct _p_Vec *v)
600: {
601: const PetscScalar *values;
602: char type[32];
603: PetscErrorCode ierr;
606: TV_add_row("Local rows", "int", &v->map->n);
607: TV_add_row("Global rows", "int", &v->map->N);
608: TV_add_row("Typename", TV_ascii_string_type, ((PetscObject)v)->type_name);
609: VecGetArrayRead((Vec)v,&values);
610: PetscSNPrintf(type,32,"double[%d]",v->map->n);
611: TV_add_row("values",type, values);
612: VecRestoreArrayRead((Vec)v,&values);
613: return TV_format_OK;
614: }
615: #endif
617: /*@
618: VecGetSize - Returns the global number of elements of the vector.
620: Not Collective
622: Input Parameter:
623: . x - the vector
625: Output Parameters:
626: . size - the global length of the vector
628: Level: beginner
630: Concepts: vector^local size
632: .seealso: VecGetLocalSize()
633: @*/
634: PetscErrorCode VecGetSize(Vec x,PetscInt *size)
635: {
642: (*x->ops->getsize)(x,size);
643: return(0);
644: }
646: /*@
647: VecGetLocalSize - Returns the number of elements of the vector stored
648: in local memory. This routine may be implementation dependent, so use
649: with care.
651: Not Collective
653: Input Parameter:
654: . x - the vector
656: Output Parameter:
657: . size - the length of the local piece of the vector
659: Level: beginner
661: Concepts: vector^size
663: .seealso: VecGetSize()
664: @*/
665: PetscErrorCode VecGetLocalSize(Vec x,PetscInt *size)
666: {
673: (*x->ops->getlocalsize)(x,size);
674: return(0);
675: }
677: /*@C
678: VecGetOwnershipRange - Returns the range of indices owned by
679: this processor, assuming that the vectors are laid out with the
680: first n1 elements on the first processor, next n2 elements on the
681: second, etc. For certain parallel layouts this range may not be
682: well defined.
684: Not Collective
686: Input Parameter:
687: . x - the vector
689: Output Parameters:
690: + low - the first local element, pass in NULL if not interested
691: - high - one more than the last local element, pass in NULL if not interested
693: Note:
694: The high argument is one more than the last element stored locally.
696: Fortran: NULL_INTEGER should be used instead of NULL
698: Level: beginner
700: Concepts: ownership^of vectors
701: Concepts: vector^ownership of elements
703: .seealso: MatGetOwnershipRange(), MatGetOwnershipRanges(), VecGetOwnershipRanges()
704: @*/
705: PetscErrorCode VecGetOwnershipRange(Vec x,PetscInt *low,PetscInt *high)
706: {
712: if (low) *low = x->map->rstart;
713: if (high) *high = x->map->rend;
714: return(0);
715: }
717: /*@C
718: VecGetOwnershipRanges - Returns the range of indices owned by EACH processor,
719: assuming that the vectors are laid out with the
720: first n1 elements on the first processor, next n2 elements on the
721: second, etc. For certain parallel layouts this range may not be
722: well defined.
724: Not Collective
726: Input Parameter:
727: . x - the vector
729: Output Parameters:
730: . range - array of length size+1 with the start and end+1 for each process
732: Note:
733: The high argument is one more than the last element stored locally.
735: Fortran: You must PASS in an array of length size+1
737: Level: beginner
739: Concepts: ownership^of vectors
740: Concepts: vector^ownership of elements
742: .seealso: MatGetOwnershipRange(), MatGetOwnershipRanges(), VecGetOwnershipRange()
743: @*/
744: PetscErrorCode VecGetOwnershipRanges(Vec x,const PetscInt *ranges[])
745: {
751: PetscLayoutGetRanges(x->map,ranges);
752: return(0);
753: }
755: /*@
756: VecSetOption - Sets an option for controling a vector's behavior.
758: Collective on Vec
760: Input Parameter:
761: + x - the vector
762: . op - the option
763: - flag - turn the option on or off
765: Supported Options:
766: + VEC_IGNORE_OFF_PROC_ENTRIES, which causes VecSetValues() to ignore
767: entries destined to be stored on a separate processor. This can be used
768: to eliminate the global reduction in the VecAssemblyXXXX() if you know
769: that you have only used VecSetValues() to set local elements
770: . VEC_IGNORE_NEGATIVE_INDICES, which means you can pass negative indices
771: in ix in calls to VecSetValues() or VecGetValues(). These rows are simply
772: ignored.
773: - VEC_SUBSET_OFF_PROC_ENTRIES, which causes VecAssemblyBegin() to assume that the off-process
774: entries will always be a subset (possibly equal) of the off-process entries set on the
775: first assembly. This reuses the communication pattern, thus avoiding a global reduction.
776: Subsequent assemblies setting off-process values should use the same InsertMode as the
777: first assembly.
779: Developer Note:
780: The InsertMode restriction could be removed by packing the stash messages out of place.
782: Level: intermediate
784: @*/
785: PetscErrorCode VecSetOption(Vec x,VecOption op,PetscBool flag)
786: {
792: if (x->ops->setoption) {
793: (*x->ops->setoption)(x,op,flag);
794: }
795: return(0);
796: }
798: /* Default routines for obtaining and releasing; */
799: /* may be used by any implementation */
800: PetscErrorCode VecDuplicateVecs_Default(Vec w,PetscInt m,Vec *V[])
801: {
803: PetscInt i;
808: if (m <= 0) SETERRQ1(PETSC_COMM_SELF,PETSC_ERR_ARG_OUTOFRANGE,"m must be > 0: m = %D",m);
809: PetscMalloc1(m,V);
810: for (i=0; i<m; i++) {VecDuplicate(w,*V+i);}
811: return(0);
812: }
814: PetscErrorCode VecDestroyVecs_Default(PetscInt m,Vec v[])
815: {
817: PetscInt i;
821: for (i=0; i<m; i++) {VecDestroy(&v[i]);}
822: PetscFree(v);
823: return(0);
824: }
826: /*@
827: VecResetArray - Resets a vector to use its default memory. Call this
828: after the use of VecPlaceArray().
830: Not Collective
832: Input Parameters:
833: . vec - the vector
835: Level: developer
837: .seealso: VecGetArray(), VecRestoreArray(), VecReplaceArray(), VecPlaceArray()
839: @*/
840: PetscErrorCode VecResetArray(Vec vec)
841: {
847: if (vec->ops->resetarray) {
848: (*vec->ops->resetarray)(vec);
849: } else SETERRQ(PETSC_COMM_SELF,PETSC_ERR_SUP,"Cannot reset array in this type of vector");
850: PetscObjectStateIncrease((PetscObject)vec);
851: return(0);
852: }
854: /*@C
855: VecLoad - Loads a vector that has been stored in binary or HDF5 format
856: with VecView().
858: Collective on PetscViewer
860: Input Parameters:
861: + newvec - the newly loaded vector, this needs to have been created with VecCreate() or
862: some related function before a call to VecLoad().
863: - viewer - binary file viewer, obtained from PetscViewerBinaryOpen() or
864: HDF5 file viewer, obtained from PetscViewerHDF5Open()
866: Level: intermediate
868: Notes:
869: Defaults to the standard Seq or MPI Vec, if you want some other type of Vec call VecSetFromOptions()
870: before calling this.
872: The input file must contain the full global vector, as
873: written by the routine VecView().
875: If the type or size of newvec is not set before a call to VecLoad, PETSc
876: sets the type and the local and global sizes. If type and/or
877: sizes are already set, then the same are used.
879: If using binary and the blocksize of the vector is greater than one then you must provide a unique prefix to
880: the vector with PetscObjectSetOptionsPrefix((PetscObject)vec,"uniqueprefix"); BEFORE calling VecView() on the
881: vector to be stored and then set that same unique prefix on the vector that you pass to VecLoad(). The blocksize
882: information is stored in an ASCII file with the same name as the binary file plus a ".info" appended to the
883: filename. If you copy the binary file, make sure you copy the associated .info file with it.
885: If using HDF5, you must assign the Vec the same name as was used in the Vec
886: that was stored in the file using PetscObjectSetName(). Otherwise you will
887: get the error message: "Cannot H5DOpen2() with Vec name NAMEOFOBJECT"
889: Notes for advanced users:
890: Most users should not need to know the details of the binary storage
891: format, since VecLoad() and VecView() completely hide these details.
892: But for anyone who's interested, the standard binary vector storage
893: format is
894: .vb
895: int VEC_FILE_CLASSID
896: int number of rows
897: PetscScalar *values of all entries
898: .ve
900: In addition, PETSc automatically does the byte swapping for
901: machines that store the bytes reversed, e.g. DEC alpha, freebsd,
902: linux, Windows and the paragon; thus if you write your own binary
903: read/write routines you have to swap the bytes; see PetscBinaryRead()
904: and PetscBinaryWrite() to see how this may be done.
906: Concepts: vector^loading from file
908: .seealso: PetscViewerBinaryOpen(), VecView(), MatLoad(), VecLoad()
909: @*/
910: PetscErrorCode VecLoad(Vec newvec, PetscViewer viewer)
911: {
912: PetscErrorCode ierr;
913: PetscBool isbinary,ishdf5,isadios,isadios2;
914: PetscViewerFormat format;
919: PetscObjectTypeCompare((PetscObject)viewer,PETSCVIEWERBINARY,&isbinary);
920: PetscObjectTypeCompare((PetscObject)viewer,PETSCVIEWERHDF5,&ishdf5);
921: PetscObjectTypeCompare((PetscObject)viewer,PETSCVIEWERADIOS,&isadios);
922: PetscObjectTypeCompare((PetscObject)viewer,PETSCVIEWERADIOS,&isadios2);
923: if (!isbinary && !ishdf5 && !isadios && !isadios2) SETERRQ(PETSC_COMM_SELF,PETSC_ERR_ARG_WRONG,"Invalid viewer; open viewer with PetscViewerBinaryOpen()");
925: PetscLogEventBegin(VEC_Load,viewer,0,0,0);
926: if (!((PetscObject)newvec)->type_name && !newvec->ops->create) {
927: VecSetType(newvec, VECSTANDARD);
928: }
929: PetscViewerGetFormat(viewer,&format);
930: if (format == PETSC_VIEWER_NATIVE && newvec->ops->loadnative) {
931: (*newvec->ops->loadnative)(newvec,viewer);
932: } else {
933: (*newvec->ops->load)(newvec,viewer);
934: }
935: PetscLogEventEnd(VEC_Load,viewer,0,0,0);
936: return(0);
937: }
940: /*@
941: VecReciprocal - Replaces each component of a vector by its reciprocal.
943: Logically Collective on Vec
945: Input Parameter:
946: . vec - the vector
948: Output Parameter:
949: . vec - the vector reciprocal
951: Level: intermediate
953: Concepts: vector^reciprocal
955: .seealso: VecLog(), VecExp(), VecSqrtAbs()
957: @*/
958: PetscErrorCode VecReciprocal(Vec vec)
959: {
965: if (vec->stash.insertmode != NOT_SET_VALUES) SETERRQ(PETSC_COMM_SELF,PETSC_ERR_ARG_WRONGSTATE,"Not for unassembled vector");
966: if (!vec->ops->reciprocal) SETERRQ(PETSC_COMM_SELF,PETSC_ERR_SUP,"Vector does not support reciprocal operation");
967: (*vec->ops->reciprocal)(vec);
968: PetscObjectStateIncrease((PetscObject)vec);
969: return(0);
970: }
972: /*@C
973: VecSetOperation - Allows user to set a vector operation.
975: Logically Collective on Vec
977: Input Parameters:
978: + vec - the vector
979: . op - the name of the operation
980: - f - the function that provides the operation.
982: Level: advanced
984: Usage:
985: $ PetscErrorCode userview(Vec,PetscViewer);
986: $ VecCreateMPI(comm,m,M,&x);
987: $ VecSetOperation(x,VECOP_VIEW,(void(*)(void))userview);
989: Notes:
990: See the file include/petscvec.h for a complete list of matrix
991: operations, which all have the form VECOP_<OPERATION>, where
992: <OPERATION> is the name (in all capital letters) of the
993: user interface routine (e.g., VecView() -> VECOP_VIEW).
995: This function is not currently available from Fortran.
997: .keywords: vector, set, operation
999: .seealso: VecCreate(), MatShellSetOperation()
1000: @*/
1001: PetscErrorCode VecSetOperation(Vec vec,VecOperation op, void (*f)(void))
1002: {
1005: if (op == VECOP_VIEW && !vec->ops->viewnative) {
1006: vec->ops->viewnative = vec->ops->view;
1007: } else if (op == VECOP_LOAD && !vec->ops->loadnative) {
1008: vec->ops->loadnative = vec->ops->load;
1009: }
1010: (((void(**)(void))vec->ops)[(int)op]) = f;
1011: return(0);
1012: }
1015: /*@
1016: VecStashSetInitialSize - sets the sizes of the vec-stash, that is
1017: used during the assembly process to store values that belong to
1018: other processors.
1020: Not Collective, different processes can have different size stashes
1022: Input Parameters:
1023: + vec - the vector
1024: . size - the initial size of the stash.
1025: - bsize - the initial size of the block-stash(if used).
1027: Options Database Keys:
1028: + -vecstash_initial_size <size> or <size0,size1,...sizep-1>
1029: - -vecstash_block_initial_size <bsize> or <bsize0,bsize1,...bsizep-1>
1031: Level: intermediate
1033: Notes:
1034: The block-stash is used for values set with VecSetValuesBlocked() while
1035: the stash is used for values set with VecSetValues()
1037: Run with the option -info and look for output of the form
1038: VecAssemblyBegin_MPIXXX:Stash has MM entries, uses nn mallocs.
1039: to determine the appropriate value, MM, to use for size and
1040: VecAssemblyBegin_MPIXXX:Block-Stash has BMM entries, uses nn mallocs.
1041: to determine the value, BMM to use for bsize
1043: Concepts: vector^stash
1044: Concepts: stash^vector
1046: .seealso: VecSetBlockSize(), VecSetValues(), VecSetValuesBlocked(), VecStashView()
1048: @*/
1049: PetscErrorCode VecStashSetInitialSize(Vec vec,PetscInt size,PetscInt bsize)
1050: {
1055: VecStashSetInitialSize_Private(&vec->stash,size);
1056: VecStashSetInitialSize_Private(&vec->bstash,bsize);
1057: return(0);
1058: }
1060: /*@
1061: VecConjugate - Conjugates a vector.
1063: Logically Collective on Vec
1065: Input Parameters:
1066: . x - the vector
1068: Level: intermediate
1070: Concepts: vector^conjugate
1072: @*/
1073: PetscErrorCode VecConjugate(Vec x)
1074: {
1075: #if defined(PETSC_USE_COMPLEX)
1081: if (x->stash.insertmode != NOT_SET_VALUES) SETERRQ(PETSC_COMM_SELF,PETSC_ERR_ARG_WRONGSTATE,"Not for unassembled vector");
1082: (*x->ops->conjugate)(x);
1083: /* we need to copy norms here */
1084: PetscObjectStateIncrease((PetscObject)x);
1085: return(0);
1086: #else
1087: return(0);
1088: #endif
1089: }
1091: /*@
1092: VecPointwiseMult - Computes the componentwise multiplication w = x*y.
1094: Logically Collective on Vec
1096: Input Parameters:
1097: . x, y - the vectors
1099: Output Parameter:
1100: . w - the result
1102: Level: advanced
1104: Notes:
1105: any subset of the x, y, and w may be the same vector.
1107: Concepts: vector^pointwise multiply
1109: .seealso: VecPointwiseDivide(), VecPointwiseMax(), VecPointwiseMin(), VecPointwiseMaxAbs(), VecMaxPointwiseDivide()
1110: @*/
1111: PetscErrorCode VecPointwiseMult(Vec w, Vec x,Vec y)
1112: {
1124: VecCheckSameSize(w,1,x,2);
1125: VecCheckSameSize(w,2,y,3);
1126: PetscLogEventBegin(VEC_PointwiseMult,x,y,w,0);
1127: (*w->ops->pointwisemult)(w,x,y);
1128: PetscLogEventEnd(VEC_PointwiseMult,x,y,w,0);
1129: PetscObjectStateIncrease((PetscObject)w);
1130: return(0);
1131: }
1133: /*@
1134: VecSetRandom - Sets all components of a vector to random numbers.
1136: Logically Collective on Vec
1138: Input Parameters:
1139: + x - the vector
1140: - rctx - the random number context, formed by PetscRandomCreate(), or NULL and
1141: it will create one internally.
1143: Output Parameter:
1144: . x - the vector
1146: Example of Usage:
1147: .vb
1148: PetscRandomCreate(PETSC_COMM_WORLD,&rctx);
1149: VecSetRandom(x,rctx);
1150: PetscRandomDestroy(rctx);
1151: .ve
1153: Level: intermediate
1155: Concepts: vector^setting to random
1156: Concepts: random^vector
1158: .seealso: VecSet(), VecSetValues(), PetscRandomCreate(), PetscRandomDestroy()
1159: @*/
1160: PetscErrorCode VecSetRandom(Vec x,PetscRandom rctx)
1161: {
1163: PetscRandom randObj = NULL;
1169: if (x->stash.insertmode != NOT_SET_VALUES) SETERRQ(PETSC_COMM_SELF,PETSC_ERR_ARG_WRONGSTATE,"Not for unassembled vector");
1171: if (!rctx) {
1172: MPI_Comm comm;
1173: PetscObjectGetComm((PetscObject)x,&comm);
1174: PetscRandomCreate(comm,&randObj);
1175: PetscRandomSetFromOptions(randObj);
1176: rctx = randObj;
1177: }
1179: PetscLogEventBegin(VEC_SetRandom,x,rctx,0,0);
1180: (*x->ops->setrandom)(x,rctx);
1181: PetscLogEventEnd(VEC_SetRandom,x,rctx,0,0);
1183: PetscRandomDestroy(&randObj);
1184: PetscObjectStateIncrease((PetscObject)x);
1185: return(0);
1186: }
1188: /*@
1189: VecZeroEntries - puts a 0.0 in each element of a vector
1191: Logically Collective on Vec
1193: Input Parameter:
1194: . vec - The vector
1196: Level: beginner
1198: Developer Note: This routine does not need to exist since the exact functionality is obtained with
1199: VecSet(vec,0); I guess someone added it to mirror the functionality of MatZeroEntries() but Mat is nothing
1200: like a Vec (one is an operator and one is an element of a vector space, yeah yeah dual blah blah blah) so
1201: this routine should not exist.
1203: .keywords: Vec, set, options, database
1204: .seealso: VecCreate(), VecSetOptionsPrefix(), VecSet(), VecSetValues()
1205: @*/
1206: PetscErrorCode VecZeroEntries(Vec vec)
1207: {
1211: VecSet(vec,0);
1212: return(0);
1213: }
1215: /*
1216: VecSetTypeFromOptions_Private - Sets the type of vector from user options. Defaults to a PETSc sequential vector on one
1217: processor and a PETSc MPI vector on more than one processor.
1219: Collective on Vec
1221: Input Parameter:
1222: . vec - The vector
1224: Level: intermediate
1226: .keywords: Vec, set, options, database, type
1227: .seealso: VecSetFromOptions(), VecSetType()
1228: */
1229: static PetscErrorCode VecSetTypeFromOptions_Private(PetscOptionItems *PetscOptionsObject,Vec vec)
1230: {
1231: PetscBool opt;
1232: VecType defaultType;
1233: char typeName[256];
1234: PetscMPIInt size;
1238: if (((PetscObject)vec)->type_name) defaultType = ((PetscObject)vec)->type_name;
1239: else {
1240: MPI_Comm_size(PetscObjectComm((PetscObject)vec), &size);
1241: if (size > 1) defaultType = VECMPI;
1242: else defaultType = VECSEQ;
1243: }
1245: VecRegisterAll();
1246: PetscOptionsFList("-vec_type","Vector type","VecSetType",VecList,defaultType,typeName,256,&opt);
1247: if (opt) {
1248: VecSetType(vec, typeName);
1249: } else {
1250: VecSetType(vec, defaultType);
1251: }
1252: return(0);
1253: }
1255: /*@
1256: VecSetFromOptions - Configures the vector from the options database.
1258: Collective on Vec
1260: Input Parameter:
1261: . vec - The vector
1263: Notes:
1264: To see all options, run your program with the -help option, or consult the users manual.
1265: Must be called after VecCreate() but before the vector is used.
1267: Level: beginner
1269: Concepts: vectors^setting options
1270: Concepts: vectors^setting type
1272: .keywords: Vec, set, options, database
1273: .seealso: VecCreate(), VecSetOptionsPrefix()
1274: @*/
1275: PetscErrorCode VecSetFromOptions(Vec vec)
1276: {
1282: PetscObjectOptionsBegin((PetscObject)vec);
1283: /* Handle vector type options */
1284: VecSetTypeFromOptions_Private(PetscOptionsObject,vec);
1286: /* Handle specific vector options */
1287: if (vec->ops->setfromoptions) {
1288: (*vec->ops->setfromoptions)(PetscOptionsObject,vec);
1289: }
1291: /* process any options handlers added with PetscObjectAddOptionsHandler() */
1292: PetscObjectProcessOptionsHandlers(PetscOptionsObject,(PetscObject)vec);
1293: PetscOptionsEnd();
1294: return(0);
1295: }
1297: /*@
1298: VecSetSizes - Sets the local and global sizes, and checks to determine compatibility
1300: Collective on Vec
1302: Input Parameters:
1303: + v - the vector
1304: . n - the local size (or PETSC_DECIDE to have it set)
1305: - N - the global size (or PETSC_DECIDE)
1307: Notes:
1308: n and N cannot be both PETSC_DECIDE
1309: If one processor calls this with N of PETSC_DECIDE then all processors must, otherwise the program will hang.
1311: Level: intermediate
1313: .seealso: VecGetSize(), PetscSplitOwnership()
1314: @*/
1315: PetscErrorCode VecSetSizes(Vec v, PetscInt n, PetscInt N)
1316: {
1322: if (N >= 0 && n > N) SETERRQ2(PETSC_COMM_SELF,PETSC_ERR_ARG_INCOMP,"Local size %D cannot be larger than global size %D",n,N);
1323: if ((v->map->n >= 0 || v->map->N >= 0) && (v->map->n != n || v->map->N != N)) SETERRQ4(PETSC_COMM_SELF,PETSC_ERR_SUP,"Cannot change/reset vector sizes to %D local %D global after previously setting them to %D local %D global",n,N,v->map->n,v->map->N);
1324: v->map->n = n;
1325: v->map->N = N;
1326: if (v->ops->create) {
1327: (*v->ops->create)(v);
1328: v->ops->create = 0;
1329: }
1330: return(0);
1331: }
1333: /*@
1334: VecSetBlockSize - Sets the blocksize for future calls to VecSetValuesBlocked()
1335: and VecSetValuesBlockedLocal().
1337: Logically Collective on Vec
1339: Input Parameter:
1340: + v - the vector
1341: - bs - the blocksize
1343: Notes:
1344: All vectors obtained by VecDuplicate() inherit the same blocksize.
1346: Level: advanced
1348: .seealso: VecSetValuesBlocked(), VecSetLocalToGlobalMapping(), VecGetBlockSize()
1350: Concepts: block size^vectors
1351: @*/
1352: PetscErrorCode VecSetBlockSize(Vec v,PetscInt bs)
1353: {
1358: if (bs < 0 || bs == v->map->bs) return(0);
1360: PetscLayoutSetBlockSize(v->map,bs);
1361: v->bstash.bs = bs; /* use the same blocksize for the vec's block-stash */
1362: return(0);
1363: }
1365: /*@
1366: VecGetBlockSize - Gets the blocksize for the vector, i.e. what is used for VecSetValuesBlocked()
1367: and VecSetValuesBlockedLocal().
1369: Not Collective
1371: Input Parameter:
1372: . v - the vector
1374: Output Parameter:
1375: . bs - the blocksize
1377: Notes:
1378: All vectors obtained by VecDuplicate() inherit the same blocksize.
1380: Level: advanced
1382: .seealso: VecSetValuesBlocked(), VecSetLocalToGlobalMapping(), VecSetBlockSize()
1384: Concepts: vector^block size
1385: Concepts: block^vector
1387: @*/
1388: PetscErrorCode VecGetBlockSize(Vec v,PetscInt *bs)
1389: {
1395: PetscLayoutGetBlockSize(v->map,bs);
1396: return(0);
1397: }
1399: /*@C
1400: VecSetOptionsPrefix - Sets the prefix used for searching for all
1401: Vec options in the database.
1403: Logically Collective on Vec
1405: Input Parameter:
1406: + v - the Vec context
1407: - prefix - the prefix to prepend to all option names
1409: Notes:
1410: A hyphen (-) must NOT be given at the beginning of the prefix name.
1411: The first character of all runtime options is AUTOMATICALLY the hyphen.
1413: Level: advanced
1415: .keywords: Vec, set, options, prefix, database
1417: .seealso: VecSetFromOptions()
1418: @*/
1419: PetscErrorCode VecSetOptionsPrefix(Vec v,const char prefix[])
1420: {
1425: PetscObjectSetOptionsPrefix((PetscObject)v,prefix);
1426: return(0);
1427: }
1429: /*@C
1430: VecAppendOptionsPrefix - Appends to the prefix used for searching for all
1431: Vec options in the database.
1433: Logically Collective on Vec
1435: Input Parameters:
1436: + v - the Vec context
1437: - prefix - the prefix to prepend to all option names
1439: Notes:
1440: A hyphen (-) must NOT be given at the beginning of the prefix name.
1441: The first character of all runtime options is AUTOMATICALLY the hyphen.
1443: Level: advanced
1445: .keywords: Vec, append, options, prefix, database
1447: .seealso: VecGetOptionsPrefix()
1448: @*/
1449: PetscErrorCode VecAppendOptionsPrefix(Vec v,const char prefix[])
1450: {
1455: PetscObjectAppendOptionsPrefix((PetscObject)v,prefix);
1456: return(0);
1457: }
1459: /*@C
1460: VecGetOptionsPrefix - Sets the prefix used for searching for all
1461: Vec options in the database.
1463: Not Collective
1465: Input Parameter:
1466: . v - the Vec context
1468: Output Parameter:
1469: . prefix - pointer to the prefix string used
1471: Notes:
1472: On the fortran side, the user should pass in a string 'prefix' of
1473: sufficient length to hold the prefix.
1475: Level: advanced
1477: .keywords: Vec, get, options, prefix, database
1479: .seealso: VecAppendOptionsPrefix()
1480: @*/
1481: PetscErrorCode VecGetOptionsPrefix(Vec v,const char *prefix[])
1482: {
1487: PetscObjectGetOptionsPrefix((PetscObject)v,prefix);
1488: return(0);
1489: }
1491: /*@
1492: VecSetUp - Sets up the internal vector data structures for the later use.
1494: Collective on Vec
1496: Input Parameters:
1497: . v - the Vec context
1499: Notes:
1500: For basic use of the Vec classes the user need not explicitly call
1501: VecSetUp(), since these actions will happen automatically.
1503: Level: advanced
1505: .keywords: Vec, setup
1507: .seealso: VecCreate(), VecDestroy()
1508: @*/
1509: PetscErrorCode VecSetUp(Vec v)
1510: {
1511: PetscMPIInt size;
1516: if (!((PetscObject)v)->type_name) {
1517: MPI_Comm_size(PetscObjectComm((PetscObject)v), &size);
1518: if (size == 1) {
1519: VecSetType(v, VECSEQ);
1520: } else {
1521: VecSetType(v, VECMPI);
1522: }
1523: }
1524: return(0);
1525: }
1527: /*
1528: These currently expose the PetscScalar/PetscReal in updating the
1529: cached norm. If we push those down into the implementation these
1530: will become independent of PetscScalar/PetscReal
1531: */
1533: /*@
1534: VecCopy - Copies a vector. y <- x
1536: Logically Collective on Vec
1538: Input Parameter:
1539: . x - the vector
1541: Output Parameter:
1542: . y - the copy
1544: Notes:
1545: For default parallel PETSc vectors, both x and y must be distributed in
1546: the same manner; local copies are done.
1548: Developer Notes:
1550: of the vectors to be sequential and one to be parallel so long as both have the same
1551: local sizes. This is used in some internal functions in PETSc.
1553: Level: beginner
1555: .seealso: VecDuplicate()
1556: @*/
1557: PetscErrorCode VecCopy(Vec x,Vec y)
1558: {
1559: PetscBool flgs[4];
1560: PetscReal norms[4] = {0.0,0.0,0.0,0.0};
1562: PetscInt i;
1569: if (x == y) return(0);
1570: VecCheckSameLocalSize(x,1,y,2);
1571: if (x->stash.insertmode != NOT_SET_VALUES) SETERRQ(PETSC_COMM_SELF,PETSC_ERR_ARG_WRONGSTATE,"Not for unassembled vector");
1572: VecLocked(y,2);
1574: #if !defined(PETSC_USE_MIXED_PRECISION)
1575: for (i=0; i<4; i++) {
1576: PetscObjectComposedDataGetReal((PetscObject)x,NormIds[i],norms[i],flgs[i]);
1577: }
1578: #endif
1580: PetscLogEventBegin(VEC_Copy,x,y,0,0);
1581: #if defined(PETSC_USE_MIXED_PRECISION)
1582: extern PetscErrorCode VecGetArray(Vec,double**);
1583: extern PetscErrorCode VecRestoreArray(Vec,double**);
1584: extern PetscErrorCode VecGetArray(Vec,float**);
1585: extern PetscErrorCode VecRestoreArray(Vec,float**);
1586: extern PetscErrorCode VecGetArrayRead(Vec,const double**);
1587: extern PetscErrorCode VecRestoreArrayRead(Vec,const double**);
1588: extern PetscErrorCode VecGetArrayRead(Vec,const float**);
1589: extern PetscErrorCode VecRestoreArrayRead(Vec,const float**);
1590: if ((((PetscObject)x)->precision == PETSC_PRECISION_SINGLE) && (((PetscObject)y)->precision == PETSC_PRECISION_DOUBLE)) {
1591: PetscInt i,n;
1592: const float *xx;
1593: double *yy;
1594: VecGetArrayRead(x,&xx);
1595: VecGetArray(y,&yy);
1596: VecGetLocalSize(x,&n);
1597: for (i=0; i<n; i++) yy[i] = xx[i];
1598: VecRestoreArrayRead(x,&xx);
1599: VecRestoreArray(y,&yy);
1600: } else if ((((PetscObject)x)->precision == PETSC_PRECISION_DOUBLE) && (((PetscObject)y)->precision == PETSC_PRECISION_SINGLE)) {
1601: PetscInt i,n;
1602: float *yy;
1603: const double *xx;
1604: VecGetArrayRead(x,&xx);
1605: VecGetArray(y,&yy);
1606: VecGetLocalSize(x,&n);
1607: for (i=0; i<n; i++) yy[i] = (float) xx[i];
1608: VecRestoreArrayRead(x,&xx);
1609: VecRestoreArray(y,&yy);
1610: } else {
1611: (*x->ops->copy)(x,y);
1612: }
1613: #else
1614: (*x->ops->copy)(x,y);
1615: #endif
1617: PetscObjectStateIncrease((PetscObject)y);
1618: #if !defined(PETSC_USE_MIXED_PRECISION)
1619: for (i=0; i<4; i++) {
1620: if (flgs[i]) {
1621: PetscObjectComposedDataSetReal((PetscObject)y,NormIds[i],norms[i]);
1622: }
1623: }
1624: #endif
1626: PetscLogEventEnd(VEC_Copy,x,y,0,0);
1627: return(0);
1628: }
1630: /*@
1631: VecSwap - Swaps the vectors x and y.
1633: Logically Collective on Vec
1635: Input Parameters:
1636: . x, y - the vectors
1638: Level: advanced
1640: Concepts: vector^swapping values
1642: @*/
1643: PetscErrorCode VecSwap(Vec x,Vec y)
1644: {
1645: PetscReal normxs[4]={0.0,0.0,0.0,0.0},normys[4]={0.0,0.0,0.0,0.0};
1646: PetscBool flgxs[4],flgys[4];
1648: PetscInt i;
1656: VecCheckSameSize(x,1,y,2);
1657: if (x->stash.insertmode != NOT_SET_VALUES) SETERRQ(PETSC_COMM_SELF,PETSC_ERR_ARG_WRONGSTATE,"Not for unassembled vector");
1658: if (y->stash.insertmode != NOT_SET_VALUES) SETERRQ(PETSC_COMM_SELF,PETSC_ERR_ARG_WRONGSTATE,"Not for unassembled vector");
1660: PetscLogEventBegin(VEC_Swap,x,y,0,0);
1661: for (i=0; i<4; i++) {
1662: PetscObjectComposedDataGetReal((PetscObject)x,NormIds[i],normxs[i],flgxs[i]);
1663: PetscObjectComposedDataGetReal((PetscObject)y,NormIds[i],normys[i],flgys[i]);
1664: }
1665: (*x->ops->swap)(x,y);
1666: PetscObjectStateIncrease((PetscObject)x);
1667: PetscObjectStateIncrease((PetscObject)y);
1668: for (i=0; i<4; i++) {
1669: if (flgxs[i]) {
1670: PetscObjectComposedDataSetReal((PetscObject)y,NormIds[i],normxs[i]);
1671: }
1672: if (flgys[i]) {
1673: PetscObjectComposedDataSetReal((PetscObject)x,NormIds[i],normys[i]);
1674: }
1675: }
1676: PetscLogEventEnd(VEC_Swap,x,y,0,0);
1677: return(0);
1678: }
1680: /*
1681: VecStashViewFromOptions - Processes command line options to determine if/how an VecStash object is to be viewed.
1683: Collective on VecStash
1685: Input Parameters:
1686: + obj - the VecStash object
1687: . bobj - optional other object that provides the prefix
1688: - optionname - option to activate viewing
1690: Level: intermediate
1692: Developer Note: This cannot use PetscObjectViewFromOptions() because it takes a Vec as an argument but does not use VecView
1694: */
1695: PetscErrorCode VecStashViewFromOptions(Vec obj,PetscObject bobj,const char optionname[])
1696: {
1697: PetscErrorCode ierr;
1698: PetscViewer viewer;
1699: PetscBool flg;
1700: PetscViewerFormat format;
1701: char *prefix;
1704: prefix = bobj ? bobj->prefix : ((PetscObject)obj)->prefix;
1705: PetscOptionsGetViewer(PetscObjectComm((PetscObject)obj),prefix,optionname,&viewer,&format,&flg);
1706: if (flg) {
1707: PetscViewerPushFormat(viewer,format);
1708: VecStashView(obj,viewer);
1709: PetscViewerPopFormat(viewer);
1710: PetscViewerDestroy(&viewer);
1711: }
1712: return(0);
1713: }
1715: /*@
1716: VecStashView - Prints the entries in the vector stash and block stash.
1718: Collective on Vec
1720: Input Parameters:
1721: + v - the vector
1722: - viewer - the viewer
1724: Level: advanced
1726: Concepts: vector^stash
1727: Concepts: stash^vector
1729: .seealso: VecSetBlockSize(), VecSetValues(), VecSetValuesBlocked()
1731: @*/
1732: PetscErrorCode VecStashView(Vec v,PetscViewer viewer)
1733: {
1735: PetscMPIInt rank;
1736: PetscInt i,j;
1737: PetscBool match;
1738: VecStash *s;
1739: PetscScalar val;
1746: PetscObjectTypeCompare((PetscObject)viewer,PETSCVIEWERASCII,&match);
1747: if (!match) SETERRQ1(PETSC_COMM_SELF,PETSC_ERR_SUP,"Stash viewer only works with ASCII viewer not %s\n",((PetscObject)v)->type_name);
1748: PetscViewerASCIIUseTabs(viewer,PETSC_FALSE);
1749: MPI_Comm_rank(PetscObjectComm((PetscObject)v),&rank);
1750: s = &v->bstash;
1752: /* print block stash */
1753: PetscViewerASCIIPushSynchronized(viewer);
1754: PetscViewerASCIISynchronizedPrintf(viewer,"[%d]Vector Block stash size %D block size %D\n",rank,s->n,s->bs);
1755: for (i=0; i<s->n; i++) {
1756: PetscViewerASCIISynchronizedPrintf(viewer,"[%d] Element %D ",rank,s->idx[i]);
1757: for (j=0; j<s->bs; j++) {
1758: val = s->array[i*s->bs+j];
1759: #if defined(PETSC_USE_COMPLEX)
1760: PetscViewerASCIISynchronizedPrintf(viewer,"(%18.16e %18.16e) ",PetscRealPart(val),PetscImaginaryPart(val));
1761: #else
1762: PetscViewerASCIISynchronizedPrintf(viewer,"%18.16e ",val);
1763: #endif
1764: }
1765: PetscViewerASCIISynchronizedPrintf(viewer,"\n");
1766: }
1767: PetscViewerFlush(viewer);
1769: s = &v->stash;
1771: /* print basic stash */
1772: PetscViewerASCIISynchronizedPrintf(viewer,"[%d]Vector stash size %D\n",rank,s->n);
1773: for (i=0; i<s->n; i++) {
1774: val = s->array[i];
1775: #if defined(PETSC_USE_COMPLEX)
1776: PetscViewerASCIISynchronizedPrintf(viewer,"[%d] Element %D (%18.16e %18.16e) ",rank,s->idx[i],PetscRealPart(val),PetscImaginaryPart(val));
1777: #else
1778: PetscViewerASCIISynchronizedPrintf(viewer,"[%d] Element %D %18.16e\n",rank,s->idx[i],val);
1779: #endif
1780: }
1781: PetscViewerFlush(viewer);
1782: PetscViewerASCIIPopSynchronized(viewer);
1783: PetscViewerASCIIUseTabs(viewer,PETSC_TRUE);
1784: return(0);
1785: }
1787: PetscErrorCode PetscOptionsGetVec(PetscOptions options,const char prefix[],const char key[],Vec v,PetscBool *set)
1788: {
1789: PetscInt i,N,rstart,rend;
1791: PetscScalar *xx;
1792: PetscReal *xreal;
1793: PetscBool iset;
1796: VecGetOwnershipRange(v,&rstart,&rend);
1797: VecGetSize(v,&N);
1798: PetscCalloc1(N,&xreal);
1799: PetscOptionsGetRealArray(options,prefix,key,xreal,&N,&iset);
1800: if (iset) {
1801: VecGetArray(v,&xx);
1802: for (i=rstart; i<rend; i++) xx[i-rstart] = xreal[i];
1803: VecRestoreArray(v,&xx);
1804: }
1805: PetscFree(xreal);
1806: if (set) *set = iset;
1807: return(0);
1808: }
1810: /*@
1811: VecGetLayout - get PetscLayout describing vector layout
1813: Not Collective
1815: Input Arguments:
1816: . x - the vector
1818: Output Arguments:
1819: . map - the layout
1821: Level: developer
1823: .seealso: VecGetSizes(), VecGetOwnershipRange(), VecGetOwnershipRanges()
1824: @*/
1825: PetscErrorCode VecGetLayout(Vec x,PetscLayout *map)
1826: {
1830: *map = x->map;
1831: return(0);
1832: }
1834: /*@
1835: VecSetLayout - set PetscLayout describing vector layout
1837: Not Collective
1839: Input Arguments:
1840: + x - the vector
1841: - map - the layout
1843: Notes:
1844: It is normally only valid to replace the layout with a layout known to be equivalent.
1846: Level: developer
1848: .seealso: VecGetLayout(), VecGetSizes(), VecGetOwnershipRange(), VecGetOwnershipRanges()
1849: @*/
1850: PetscErrorCode VecSetLayout(Vec x,PetscLayout map)
1851: {
1856: PetscLayoutReference(map,&x->map);
1857: return(0);
1858: }
1860: PetscErrorCode VecSetInf(Vec xin)
1861: {
1862: PetscInt i,n = xin->map->n;
1863: PetscScalar *xx;
1864: PetscScalar zero=0.0,one=1.0,inf=one/zero;
1868: VecGetArray(xin,&xx);
1869: for (i=0; i<n; i++) xx[i] = inf;
1870: VecRestoreArray(xin,&xx);
1871: return(0);
1872: }