Actual source code: dualspace.c
1: #include <petsc/private/petscfeimpl.h>
2: #include <petscdmplex.h>
4: PetscClassId PETSCDUALSPACE_CLASSID = 0;
6: PetscLogEvent PETSCDUALSPACE_SetUp;
8: PetscFunctionList PetscDualSpaceList = NULL;
9: PetscBool PetscDualSpaceRegisterAllCalled = PETSC_FALSE;
11: /*
12: PetscDualSpaceLatticePointLexicographic_Internal - Returns all tuples of size 'len' with nonnegative integers that sum up to at most 'max'.
13: Ordering is lexicographic with lowest index as least significant in ordering.
14: e.g. for len == 2 and max == 2, this will return, in order, {0,0}, {1,0}, {2,0}, {0,1}, {1,1}, {0,2}.
16: Input Parameters:
17: + len - The length of the tuple
18: . max - The maximum sum
19: - tup - A tuple of length len+1: tup[len] > 0 indicates a stopping condition
21: Output Parameter:
22: . tup - A tuple of `len` integers whose sum is at most `max`
24: Level: developer
26: .seealso: `PetscDualSpaceType`, `PetscDualSpaceTensorPointLexicographic_Internal()`
27: */
28: PetscErrorCode PetscDualSpaceLatticePointLexicographic_Internal(PetscInt len, PetscInt max, PetscInt tup[])
29: {
30: PetscFunctionBegin;
31: while (len--) {
32: max -= tup[len];
33: if (!max) {
34: tup[len] = 0;
35: break;
36: }
37: }
38: tup[++len]++;
39: PetscFunctionReturn(PETSC_SUCCESS);
40: }
42: /*
43: PetscDualSpaceTensorPointLexicographic_Internal - Returns all tuples of size 'len' with nonnegative integers that are all less than or equal to 'max'.
44: Ordering is lexicographic with lowest index as least significant in ordering.
45: e.g. for len == 2 and max == 2, this will return, in order, {0,0}, {1,0}, {2,0}, {0,1}, {1,1}, {2,1}, {0,2}, {1,2}, {2,2}.
47: Input Parameters:
48: + len - The length of the tuple
49: . max - The maximum value
50: - tup - A tuple of length len+1: tup[len] > 0 indicates a stopping condition
52: Output Parameter:
53: . tup - A tuple of `len` integers whose entries are at most `max`
55: Level: developer
57: .seealso: `PetscDualSpaceType`, `PetscDualSpaceLatticePointLexicographic_Internal()`
58: */
59: PetscErrorCode PetscDualSpaceTensorPointLexicographic_Internal(PetscInt len, PetscInt max, PetscInt tup[])
60: {
61: PetscInt i;
63: PetscFunctionBegin;
64: for (i = 0; i < len; i++) {
65: if (tup[i] < max) {
66: break;
67: } else {
68: tup[i] = 0;
69: }
70: }
71: tup[i]++;
72: PetscFunctionReturn(PETSC_SUCCESS);
73: }
75: /*@C
76: PetscDualSpaceRegister - Adds a new `PetscDualSpaceType`
78: Not Collective
80: Input Parameters:
81: + sname - The name of a new user-defined creation routine
82: - function - The creation routine
84: Sample usage:
85: .vb
86: PetscDualSpaceRegister("my_space", MyPetscDualSpaceCreate);
87: .ve
89: Then, your PetscDualSpace type can be chosen with the procedural interface via
90: .vb
91: PetscDualSpaceCreate(MPI_Comm, PetscDualSpace *);
92: PetscDualSpaceSetType(PetscDualSpace, "my_dual_space");
93: .ve
94: or at runtime via the option
95: .vb
96: -petscdualspace_type my_dual_space
97: .ve
99: Level: advanced
101: Note:
102: `PetscDualSpaceRegister()` may be called multiple times to add several user-defined `PetscDualSpace`
104: .seealso: `PetscDualSpace`, `PetscDualSpaceType`, `PetscDualSpaceRegisterAll()`, `PetscDualSpaceRegisterDestroy()`
105: @*/
106: PetscErrorCode PetscDualSpaceRegister(const char sname[], PetscErrorCode (*function)(PetscDualSpace))
107: {
108: PetscFunctionBegin;
109: PetscCall(PetscFunctionListAdd(&PetscDualSpaceList, sname, function));
110: PetscFunctionReturn(PETSC_SUCCESS);
111: }
113: /*@C
114: PetscDualSpaceSetType - Builds a particular `PetscDualSpace` based on its `PetscDualSpaceType`
116: Collective
118: Input Parameters:
119: + sp - The `PetscDualSpace` object
120: - name - The kind of space
122: Options Database Key:
123: . -petscdualspace_type <type> - Sets the PetscDualSpace type; use -help for a list of available types
125: Level: intermediate
127: .seealso: `PetscDualSpace`, `PetscDualSpaceType`, `PetscDualSpaceGetType()`, `PetscDualSpaceCreate()`
128: @*/
129: PetscErrorCode PetscDualSpaceSetType(PetscDualSpace sp, PetscDualSpaceType name)
130: {
131: PetscErrorCode (*r)(PetscDualSpace);
132: PetscBool match;
134: PetscFunctionBegin;
136: PetscCall(PetscObjectTypeCompare((PetscObject)sp, name, &match));
137: if (match) PetscFunctionReturn(PETSC_SUCCESS);
139: if (!PetscDualSpaceRegisterAllCalled) PetscCall(PetscDualSpaceRegisterAll());
140: PetscCall(PetscFunctionListFind(PetscDualSpaceList, name, &r));
141: PetscCheck(r, PetscObjectComm((PetscObject)sp), PETSC_ERR_ARG_UNKNOWN_TYPE, "Unknown PetscDualSpace type: %s", name);
143: PetscTryTypeMethod(sp, destroy);
144: sp->ops->destroy = NULL;
146: PetscCall((*r)(sp));
147: PetscCall(PetscObjectChangeTypeName((PetscObject)sp, name));
148: PetscFunctionReturn(PETSC_SUCCESS);
149: }
151: /*@C
152: PetscDualSpaceGetType - Gets the `PetscDualSpaceType` name (as a string) from the object.
154: Not Collective
156: Input Parameter:
157: . sp - The `PetscDualSpace`
159: Output Parameter:
160: . name - The `PetscDualSpaceType` name
162: Level: intermediate
164: .seealso: `PetscDualSpace`, `PetscDualSpaceType`, `PetscDualSpaceSetType()`, `PetscDualSpaceCreate()`
165: @*/
166: PetscErrorCode PetscDualSpaceGetType(PetscDualSpace sp, PetscDualSpaceType *name)
167: {
168: PetscFunctionBegin;
171: if (!PetscDualSpaceRegisterAllCalled) PetscCall(PetscDualSpaceRegisterAll());
172: *name = ((PetscObject)sp)->type_name;
173: PetscFunctionReturn(PETSC_SUCCESS);
174: }
176: static PetscErrorCode PetscDualSpaceView_ASCII(PetscDualSpace sp, PetscViewer v)
177: {
178: PetscViewerFormat format;
179: PetscInt pdim, f;
181: PetscFunctionBegin;
182: PetscCall(PetscDualSpaceGetDimension(sp, &pdim));
183: PetscCall(PetscObjectPrintClassNamePrefixType((PetscObject)sp, v));
184: PetscCall(PetscViewerASCIIPushTab(v));
185: if (sp->k) {
186: PetscCall(PetscViewerASCIIPrintf(v, "Dual space for %" PetscInt_FMT "-forms %swith %" PetscInt_FMT " components, size %" PetscInt_FMT "\n", PetscAbsInt(sp->k), sp->k < 0 ? "(stored in dual form) " : "", sp->Nc, pdim));
187: } else {
188: PetscCall(PetscViewerASCIIPrintf(v, "Dual space with %" PetscInt_FMT " components, size %" PetscInt_FMT "\n", sp->Nc, pdim));
189: }
190: PetscTryTypeMethod(sp, view, v);
191: PetscCall(PetscViewerGetFormat(v, &format));
192: if (format == PETSC_VIEWER_ASCII_INFO_DETAIL) {
193: PetscCall(PetscViewerASCIIPushTab(v));
194: for (f = 0; f < pdim; ++f) {
195: PetscCall(PetscViewerASCIIPrintf(v, "Dual basis vector %" PetscInt_FMT "\n", f));
196: PetscCall(PetscViewerASCIIPushTab(v));
197: PetscCall(PetscQuadratureView(sp->functional[f], v));
198: PetscCall(PetscViewerASCIIPopTab(v));
199: }
200: PetscCall(PetscViewerASCIIPopTab(v));
201: }
202: PetscCall(PetscViewerASCIIPopTab(v));
203: PetscFunctionReturn(PETSC_SUCCESS);
204: }
206: /*@C
207: PetscDualSpaceViewFromOptions - View a `PetscDualSpace` based on values in the options database
209: Collective
211: Input Parameters:
212: + A - the `PetscDualSpace` object
213: . obj - Optional object, provides the options prefix
214: - name - command line option name
216: Level: intermediate
218: Note:
219: See `PetscObjectViewFromOptions()` for possible command line values
221: .seealso: `PetscDualSpace`, `PetscDualSpaceView()`, `PetscObjectViewFromOptions()`, `PetscDualSpaceCreate()`
222: @*/
223: PetscErrorCode PetscDualSpaceViewFromOptions(PetscDualSpace A, PetscObject obj, const char name[])
224: {
225: PetscFunctionBegin;
227: PetscCall(PetscObjectViewFromOptions((PetscObject)A, obj, name));
228: PetscFunctionReturn(PETSC_SUCCESS);
229: }
231: /*@
232: PetscDualSpaceView - Views a `PetscDualSpace`
234: Collective
236: Input Parameters:
237: + sp - the `PetscDualSpace` object to view
238: - v - the viewer
240: Level: beginner
242: .seealso: `PetscViewer`, `PetscDualSpaceDestroy()`, `PetscDualSpace`
243: @*/
244: PetscErrorCode PetscDualSpaceView(PetscDualSpace sp, PetscViewer v)
245: {
246: PetscBool iascii;
248: PetscFunctionBegin;
251: if (!v) PetscCall(PetscViewerASCIIGetStdout(PetscObjectComm((PetscObject)sp), &v));
252: PetscCall(PetscObjectTypeCompare((PetscObject)v, PETSCVIEWERASCII, &iascii));
253: if (iascii) PetscCall(PetscDualSpaceView_ASCII(sp, v));
254: PetscFunctionReturn(PETSC_SUCCESS);
255: }
257: /*@
258: PetscDualSpaceSetFromOptions - sets parameters in a `PetscDualSpace` from the options database
260: Collective
262: Input Parameter:
263: . sp - the `PetscDualSpace` object to set options for
265: Options Database Keys:
266: + -petscdualspace_order <order> - the approximation order of the space
267: . -petscdualspace_form_degree <deg> - the form degree, say 0 for point evaluations, or 2 for area integrals
268: . -petscdualspace_components <c> - the number of components, say d for a vector field
269: . -petscdualspace_refcell <celltype> - Reference cell type name
270: . -petscdualspace_lagrange_continuity - Flag for continuous element
271: . -petscdualspace_lagrange_tensor - Flag for tensor dual space
272: . -petscdualspace_lagrange_trimmed - Flag for trimmed dual space
273: . -petscdualspace_lagrange_node_type <nodetype> - Lagrange node location type
274: . -petscdualspace_lagrange_node_endpoints - Flag for nodes that include endpoints
275: . -petscdualspace_lagrange_node_exponent - Gauss-Jacobi weight function exponent
276: . -petscdualspace_lagrange_use_moments - Use moments (where appropriate) for functionals
277: - -petscdualspace_lagrange_moment_order <order> - Quadrature order for moment functionals
279: Level: intermediate
281: .seealso: `PetscDualSpaceView()`, `PetscDualSpace`, `PetscObjectSetFromOptions()`
282: @*/
283: PetscErrorCode PetscDualSpaceSetFromOptions(PetscDualSpace sp)
284: {
285: DMPolytopeType refCell = DM_POLYTOPE_TRIANGLE;
286: const char *defaultType;
287: char name[256];
288: PetscBool flg;
290: PetscFunctionBegin;
292: if (!((PetscObject)sp)->type_name) {
293: defaultType = PETSCDUALSPACELAGRANGE;
294: } else {
295: defaultType = ((PetscObject)sp)->type_name;
296: }
297: if (!PetscSpaceRegisterAllCalled) PetscCall(PetscSpaceRegisterAll());
299: PetscObjectOptionsBegin((PetscObject)sp);
300: PetscCall(PetscOptionsFList("-petscdualspace_type", "Dual space", "PetscDualSpaceSetType", PetscDualSpaceList, defaultType, name, 256, &flg));
301: if (flg) {
302: PetscCall(PetscDualSpaceSetType(sp, name));
303: } else if (!((PetscObject)sp)->type_name) {
304: PetscCall(PetscDualSpaceSetType(sp, defaultType));
305: }
306: PetscCall(PetscOptionsBoundedInt("-petscdualspace_order", "The approximation order", "PetscDualSpaceSetOrder", sp->order, &sp->order, NULL, 0));
307: PetscCall(PetscOptionsInt("-petscdualspace_form_degree", "The form degree of the dofs", "PetscDualSpaceSetFormDegree", sp->k, &sp->k, NULL));
308: PetscCall(PetscOptionsBoundedInt("-petscdualspace_components", "The number of components", "PetscDualSpaceSetNumComponents", sp->Nc, &sp->Nc, NULL, 1));
309: PetscTryTypeMethod(sp, setfromoptions, PetscOptionsObject);
310: PetscCall(PetscOptionsEnum("-petscdualspace_refcell", "Reference cell shape", "PetscDualSpaceSetReferenceCell", DMPolytopeTypes, (PetscEnum)refCell, (PetscEnum *)&refCell, &flg));
311: if (flg) {
312: DM K;
314: PetscCall(DMPlexCreateReferenceCell(PETSC_COMM_SELF, refCell, &K));
315: PetscCall(PetscDualSpaceSetDM(sp, K));
316: PetscCall(DMDestroy(&K));
317: }
319: /* process any options handlers added with PetscObjectAddOptionsHandler() */
320: PetscCall(PetscObjectProcessOptionsHandlers((PetscObject)sp, PetscOptionsObject));
321: PetscOptionsEnd();
322: sp->setfromoptionscalled = PETSC_TRUE;
323: PetscFunctionReturn(PETSC_SUCCESS);
324: }
326: /*@
327: PetscDualSpaceSetUp - Construct a basis for a `PetscDualSpace`
329: Collective
331: Input Parameter:
332: . sp - the `PetscDualSpace` object to setup
334: Level: intermediate
336: .seealso: `PetscDualSpaceView()`, `PetscDualSpaceDestroy()`, `PetscDualSpace`
337: @*/
338: PetscErrorCode PetscDualSpaceSetUp(PetscDualSpace sp)
339: {
340: PetscFunctionBegin;
342: if (sp->setupcalled) PetscFunctionReturn(PETSC_SUCCESS);
343: PetscCall(PetscLogEventBegin(PETSCDUALSPACE_SetUp, sp, 0, 0, 0));
344: sp->setupcalled = PETSC_TRUE;
345: PetscTryTypeMethod(sp, setup);
346: PetscCall(PetscLogEventEnd(PETSCDUALSPACE_SetUp, sp, 0, 0, 0));
347: if (sp->setfromoptionscalled) PetscCall(PetscDualSpaceViewFromOptions(sp, NULL, "-petscdualspace_view"));
348: PetscFunctionReturn(PETSC_SUCCESS);
349: }
351: static PetscErrorCode PetscDualSpaceClearDMData_Internal(PetscDualSpace sp, DM dm)
352: {
353: PetscInt pStart = -1, pEnd = -1, depth = -1;
355: PetscFunctionBegin;
356: if (!dm) PetscFunctionReturn(PETSC_SUCCESS);
357: PetscCall(DMPlexGetChart(dm, &pStart, &pEnd));
358: PetscCall(DMPlexGetDepth(dm, &depth));
360: if (sp->pointSpaces) {
361: PetscInt i;
363: for (i = 0; i < pEnd - pStart; i++) PetscCall(PetscDualSpaceDestroy(&(sp->pointSpaces[i])));
364: }
365: PetscCall(PetscFree(sp->pointSpaces));
367: if (sp->heightSpaces) {
368: PetscInt i;
370: for (i = 0; i <= depth; i++) PetscCall(PetscDualSpaceDestroy(&(sp->heightSpaces[i])));
371: }
372: PetscCall(PetscFree(sp->heightSpaces));
374: PetscCall(PetscSectionDestroy(&(sp->pointSection)));
375: PetscCall(PetscQuadratureDestroy(&(sp->intNodes)));
376: PetscCall(VecDestroy(&(sp->intDofValues)));
377: PetscCall(VecDestroy(&(sp->intNodeValues)));
378: PetscCall(MatDestroy(&(sp->intMat)));
379: PetscCall(PetscQuadratureDestroy(&(sp->allNodes)));
380: PetscCall(VecDestroy(&(sp->allDofValues)));
381: PetscCall(VecDestroy(&(sp->allNodeValues)));
382: PetscCall(MatDestroy(&(sp->allMat)));
383: PetscCall(PetscFree(sp->numDof));
384: PetscFunctionReturn(PETSC_SUCCESS);
385: }
387: /*@
388: PetscDualSpaceDestroy - Destroys a `PetscDualSpace` object
390: Collective
392: Input Parameter:
393: . sp - the `PetscDualSpace` object to destroy
395: Level: beginner
397: .seealso: `PetscDualSpace`, `PetscDualSpaceView()`, `PetscDualSpace()`, `PetscDualSpaceCreate()`
398: @*/
399: PetscErrorCode PetscDualSpaceDestroy(PetscDualSpace *sp)
400: {
401: PetscInt dim, f;
402: DM dm;
404: PetscFunctionBegin;
405: if (!*sp) PetscFunctionReturn(PETSC_SUCCESS);
408: if (--((PetscObject)(*sp))->refct > 0) {
409: *sp = NULL;
410: PetscFunctionReturn(PETSC_SUCCESS);
411: }
412: ((PetscObject)(*sp))->refct = 0;
414: PetscCall(PetscDualSpaceGetDimension(*sp, &dim));
415: dm = (*sp)->dm;
417: PetscTryTypeMethod((*sp), destroy);
418: PetscCall(PetscDualSpaceClearDMData_Internal(*sp, dm));
420: for (f = 0; f < dim; ++f) PetscCall(PetscQuadratureDestroy(&(*sp)->functional[f]));
421: PetscCall(PetscFree((*sp)->functional));
422: PetscCall(DMDestroy(&(*sp)->dm));
423: PetscCall(PetscHeaderDestroy(sp));
424: PetscFunctionReturn(PETSC_SUCCESS);
425: }
427: /*@
428: PetscDualSpaceCreate - Creates an empty `PetscDualSpace` object. The type can then be set with `PetscDualSpaceSetType()`.
430: Collective
432: Input Parameter:
433: . comm - The communicator for the `PetscDualSpace` object
435: Output Parameter:
436: . sp - The `PetscDualSpace` object
438: Level: beginner
440: .seealso: `PetscDualSpace`, `PetscDualSpaceSetType()`, `PETSCDUALSPACELAGRANGE`
441: @*/
442: PetscErrorCode PetscDualSpaceCreate(MPI_Comm comm, PetscDualSpace *sp)
443: {
444: PetscDualSpace s;
446: PetscFunctionBegin;
448: PetscCall(PetscCitationsRegister(FECitation, &FEcite));
449: *sp = NULL;
450: PetscCall(PetscFEInitializePackage());
452: PetscCall(PetscHeaderCreate(s, PETSCDUALSPACE_CLASSID, "PetscDualSpace", "Dual Space", "PetscDualSpace", comm, PetscDualSpaceDestroy, PetscDualSpaceView));
454: s->order = 0;
455: s->Nc = 1;
456: s->k = 0;
457: s->spdim = -1;
458: s->spintdim = -1;
459: s->uniform = PETSC_TRUE;
460: s->setupcalled = PETSC_FALSE;
462: *sp = s;
463: PetscFunctionReturn(PETSC_SUCCESS);
464: }
466: /*@
467: PetscDualSpaceDuplicate - Creates a duplicate `PetscDualSpace` object that is not setup.
469: Collective
471: Input Parameter:
472: . sp - The original `PetscDualSpace`
474: Output Parameter:
475: . spNew - The duplicate `PetscDualSpace`
477: Level: beginner
479: .seealso: `PetscDualSpace`, `PetscDualSpaceCreate()`, `PetscDualSpaceSetType()`
480: @*/
481: PetscErrorCode PetscDualSpaceDuplicate(PetscDualSpace sp, PetscDualSpace *spNew)
482: {
483: DM dm;
484: PetscDualSpaceType type;
485: const char *name;
487: PetscFunctionBegin;
490: PetscCall(PetscDualSpaceCreate(PetscObjectComm((PetscObject)sp), spNew));
491: PetscCall(PetscObjectGetName((PetscObject)sp, &name));
492: PetscCall(PetscObjectSetName((PetscObject)*spNew, name));
493: PetscCall(PetscDualSpaceGetType(sp, &type));
494: PetscCall(PetscDualSpaceSetType(*spNew, type));
495: PetscCall(PetscDualSpaceGetDM(sp, &dm));
496: PetscCall(PetscDualSpaceSetDM(*spNew, dm));
498: (*spNew)->order = sp->order;
499: (*spNew)->k = sp->k;
500: (*spNew)->Nc = sp->Nc;
501: (*spNew)->uniform = sp->uniform;
502: PetscTryTypeMethod(sp, duplicate, *spNew);
503: PetscFunctionReturn(PETSC_SUCCESS);
504: }
506: /*@
507: PetscDualSpaceGetDM - Get the `DM` representing the reference cell of a `PetscDualSpace`
509: Not Collective
511: Input Parameter:
512: . sp - The `PetscDualSpace`
514: Output Parameter:
515: . dm - The reference cell, that is a `DM` that consists of a single cell
517: Level: intermediate
519: .seealso: `PetscDualSpace`, `PetscDualSpaceSetDM()`, `PetscDualSpaceCreate()`
520: @*/
521: PetscErrorCode PetscDualSpaceGetDM(PetscDualSpace sp, DM *dm)
522: {
523: PetscFunctionBegin;
526: *dm = sp->dm;
527: PetscFunctionReturn(PETSC_SUCCESS);
528: }
530: /*@
531: PetscDualSpaceSetDM - Get the `DM` representing the reference cell
533: Not Collective
535: Input Parameters:
536: + sp - The `PetscDual`Space
537: - dm - The reference cell
539: Level: intermediate
541: .seealso: `PetscDualSpace`, `DM`, `PetscDualSpaceGetDM()`, `PetscDualSpaceCreate()`
542: @*/
543: PetscErrorCode PetscDualSpaceSetDM(PetscDualSpace sp, DM dm)
544: {
545: PetscFunctionBegin;
548: PetscCheck(!sp->setupcalled, PetscObjectComm((PetscObject)sp), PETSC_ERR_ARG_WRONGSTATE, "Cannot change DM after dualspace is set up");
549: PetscCall(PetscObjectReference((PetscObject)dm));
550: if (sp->dm && sp->dm != dm) PetscCall(PetscDualSpaceClearDMData_Internal(sp, sp->dm));
551: PetscCall(DMDestroy(&sp->dm));
552: sp->dm = dm;
553: PetscFunctionReturn(PETSC_SUCCESS);
554: }
556: /*@
557: PetscDualSpaceGetOrder - Get the order of the dual space
559: Not Collective
561: Input Parameter:
562: . sp - The `PetscDualSpace`
564: Output Parameter:
565: . order - The order
567: Level: intermediate
569: .seealso: `PetscDualSpace`, `PetscDualSpaceSetOrder()`, `PetscDualSpaceCreate()`
570: @*/
571: PetscErrorCode PetscDualSpaceGetOrder(PetscDualSpace sp, PetscInt *order)
572: {
573: PetscFunctionBegin;
576: *order = sp->order;
577: PetscFunctionReturn(PETSC_SUCCESS);
578: }
580: /*@
581: PetscDualSpaceSetOrder - Set the order of the dual space
583: Not Collective
585: Input Parameters:
586: + sp - The `PetscDualSpace`
587: - order - The order
589: Level: intermediate
591: .seealso: `PetscDualSpace`, `PetscDualSpaceGetOrder()`, `PetscDualSpaceCreate()`
592: @*/
593: PetscErrorCode PetscDualSpaceSetOrder(PetscDualSpace sp, PetscInt order)
594: {
595: PetscFunctionBegin;
597: PetscCheck(!sp->setupcalled, PetscObjectComm((PetscObject)sp), PETSC_ERR_ARG_WRONGSTATE, "Cannot change order after dualspace is set up");
598: sp->order = order;
599: PetscFunctionReturn(PETSC_SUCCESS);
600: }
602: /*@
603: PetscDualSpaceGetNumComponents - Return the number of components for this space
605: Input Parameter:
606: . sp - The `PetscDualSpace`
608: Output Parameter:
609: . Nc - The number of components
611: Level: intermediate
613: Note:
614: A vector space, for example, will have d components, where d is the spatial dimension
616: .seealso: `PetscDualSpaceSetNumComponents()`, `PetscDualSpaceGetDimension()`, `PetscDualSpaceCreate()`, `PetscDualSpace`
617: @*/
618: PetscErrorCode PetscDualSpaceGetNumComponents(PetscDualSpace sp, PetscInt *Nc)
619: {
620: PetscFunctionBegin;
623: *Nc = sp->Nc;
624: PetscFunctionReturn(PETSC_SUCCESS);
625: }
627: /*@
628: PetscDualSpaceSetNumComponents - Set the number of components for this space
630: Input Parameters:
631: + sp - The `PetscDualSpace`
632: - order - The number of components
634: Level: intermediate
636: .seealso: `PetscDualSpaceGetNumComponents()`, `PetscDualSpaceCreate()`, `PetscDualSpace`
637: @*/
638: PetscErrorCode PetscDualSpaceSetNumComponents(PetscDualSpace sp, PetscInt Nc)
639: {
640: PetscFunctionBegin;
642: PetscCheck(!sp->setupcalled, PetscObjectComm((PetscObject)sp), PETSC_ERR_ARG_WRONGSTATE, "Cannot change number of components after dualspace is set up");
643: sp->Nc = Nc;
644: PetscFunctionReturn(PETSC_SUCCESS);
645: }
647: /*@
648: PetscDualSpaceGetFunctional - Get the i-th basis functional in the dual space
650: Not Collective
652: Input Parameters:
653: + sp - The `PetscDualSpace`
654: - i - The basis number
656: Output Parameter:
657: . functional - The basis functional
659: Level: intermediate
661: .seealso: `PetscDualSpace`, `PetscQuadrature`, `PetscDualSpaceGetDimension()`, `PetscDualSpaceCreate()`
662: @*/
663: PetscErrorCode PetscDualSpaceGetFunctional(PetscDualSpace sp, PetscInt i, PetscQuadrature *functional)
664: {
665: PetscInt dim;
667: PetscFunctionBegin;
670: PetscCall(PetscDualSpaceGetDimension(sp, &dim));
671: PetscCheck(!(i < 0) && !(i >= dim), PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Functional index %" PetscInt_FMT " must be in [0, %" PetscInt_FMT ")", i, dim);
672: *functional = sp->functional[i];
673: PetscFunctionReturn(PETSC_SUCCESS);
674: }
676: /*@
677: PetscDualSpaceGetDimension - Get the dimension of the dual space, i.e. the number of basis functionals
679: Not Collective
681: Input Parameter:
682: . sp - The `PetscDualSpace`
684: Output Parameter:
685: . dim - The dimension
687: Level: intermediate
689: .seealso: `PetscDualSpace`, `PetscDualSpaceGetFunctional()`, `PetscDualSpaceCreate()`
690: @*/
691: PetscErrorCode PetscDualSpaceGetDimension(PetscDualSpace sp, PetscInt *dim)
692: {
693: PetscFunctionBegin;
696: if (sp->spdim < 0) {
697: PetscSection section;
699: PetscCall(PetscDualSpaceGetSection(sp, §ion));
700: if (section) {
701: PetscCall(PetscSectionGetStorageSize(section, &(sp->spdim)));
702: } else sp->spdim = 0;
703: }
704: *dim = sp->spdim;
705: PetscFunctionReturn(PETSC_SUCCESS);
706: }
708: /*@
709: PetscDualSpaceGetInteriorDimension - Get the interior dimension of the dual space, i.e. the number of basis functionals assigned to the interior of the reference domain
711: Not Collective
713: Input Parameter:
714: . sp - The `PetscDualSpace`
716: Output Parameter:
717: . dim - The dimension
719: Level: intermediate
721: .seealso: `PetscDualSpace`, `PetscDualSpaceGetFunctional()`, `PetscDualSpaceCreate()`
722: @*/
723: PetscErrorCode PetscDualSpaceGetInteriorDimension(PetscDualSpace sp, PetscInt *intdim)
724: {
725: PetscFunctionBegin;
728: if (sp->spintdim < 0) {
729: PetscSection section;
731: PetscCall(PetscDualSpaceGetSection(sp, §ion));
732: if (section) {
733: PetscCall(PetscSectionGetConstrainedStorageSize(section, &(sp->spintdim)));
734: } else sp->spintdim = 0;
735: }
736: *intdim = sp->spintdim;
737: PetscFunctionReturn(PETSC_SUCCESS);
738: }
740: /*@
741: PetscDualSpaceGetUniform - Whether this dual space is uniform
743: Not Collective
745: Input Parameter:
746: . sp - A dual space
748: Output Parameter:
749: . uniform - `PETSC_TRUE` if (a) the dual space is the same for each point in a stratum of the reference `DMPLEX`, and
750: (b) every symmetry of each point in the reference `DMPLEX` is also a symmetry of the point's dual space.
752: Level: advanced
754: Note:
755: All of the usual spaces on simplex or tensor-product elements will be uniform, only reference cells
756: with non-uniform strata (like trianguar-prisms) or anisotropic hp dual spaces will not be uniform.
758: .seealso: `PetscDualSpace`, `PetscDualSpaceGetPointSubspace()`, `PetscDualSpaceGetSymmetries()`
759: @*/
760: PetscErrorCode PetscDualSpaceGetUniform(PetscDualSpace sp, PetscBool *uniform)
761: {
762: PetscFunctionBegin;
765: *uniform = sp->uniform;
766: PetscFunctionReturn(PETSC_SUCCESS);
767: }
769: /*@C
770: PetscDualSpaceGetNumDof - Get the number of degrees of freedom for each spatial (topological) dimension
772: Not Collective
774: Input Parameter:
775: . sp - The `PetscDualSpace`
777: Output Parameter:
778: . numDof - An array of length dim+1 which holds the number of dofs for each dimension
780: Level: intermediate
782: .seealso: `PetscDualSpace`, `PetscDualSpaceGetFunctional()`, `PetscDualSpaceCreate()`
783: @*/
784: PetscErrorCode PetscDualSpaceGetNumDof(PetscDualSpace sp, const PetscInt **numDof)
785: {
786: PetscFunctionBegin;
789: PetscCheck(sp->uniform, PETSC_COMM_SELF, PETSC_ERR_ARG_WRONG, "A non-uniform space does not have a fixed number of dofs for each height");
790: if (!sp->numDof) {
791: DM dm;
792: PetscInt depth, d;
793: PetscSection section;
795: PetscCall(PetscDualSpaceGetDM(sp, &dm));
796: PetscCall(DMPlexGetDepth(dm, &depth));
797: PetscCall(PetscCalloc1(depth + 1, &(sp->numDof)));
798: PetscCall(PetscDualSpaceGetSection(sp, §ion));
799: for (d = 0; d <= depth; d++) {
800: PetscInt dStart, dEnd;
802: PetscCall(DMPlexGetDepthStratum(dm, d, &dStart, &dEnd));
803: if (dEnd <= dStart) continue;
804: PetscCall(PetscSectionGetDof(section, dStart, &(sp->numDof[d])));
805: }
806: }
807: *numDof = sp->numDof;
808: PetscCheck(*numDof, PetscObjectComm((PetscObject)sp), PETSC_ERR_LIB, "Empty numDof[] returned from dual space implementation");
809: PetscFunctionReturn(PETSC_SUCCESS);
810: }
812: /* create the section of the right size and set a permutation for topological ordering */
813: PetscErrorCode PetscDualSpaceSectionCreate_Internal(PetscDualSpace sp, PetscSection *topSection)
814: {
815: DM dm;
816: PetscInt pStart, pEnd, cStart, cEnd, c, depth, count, i;
817: PetscInt *seen, *perm;
818: PetscSection section;
820: PetscFunctionBegin;
821: dm = sp->dm;
822: PetscCall(PetscSectionCreate(PETSC_COMM_SELF, §ion));
823: PetscCall(DMPlexGetChart(dm, &pStart, &pEnd));
824: PetscCall(PetscSectionSetChart(section, pStart, pEnd));
825: PetscCall(PetscCalloc1(pEnd - pStart, &seen));
826: PetscCall(PetscMalloc1(pEnd - pStart, &perm));
827: PetscCall(DMPlexGetDepth(dm, &depth));
828: PetscCall(DMPlexGetHeightStratum(dm, 0, &cStart, &cEnd));
829: for (c = cStart, count = 0; c < cEnd; c++) {
830: PetscInt closureSize = -1, e;
831: PetscInt *closure = NULL;
833: perm[count++] = c;
834: seen[c - pStart] = 1;
835: PetscCall(DMPlexGetTransitiveClosure(dm, c, PETSC_TRUE, &closureSize, &closure));
836: for (e = 0; e < closureSize; e++) {
837: PetscInt point = closure[2 * e];
839: if (seen[point - pStart]) continue;
840: perm[count++] = point;
841: seen[point - pStart] = 1;
842: }
843: PetscCall(DMPlexRestoreTransitiveClosure(dm, c, PETSC_TRUE, &closureSize, &closure));
844: }
845: PetscCheck(count == pEnd - pStart, PETSC_COMM_SELF, PETSC_ERR_PLIB, "Bad topological ordering");
846: for (i = 0; i < pEnd - pStart; i++)
847: if (perm[i] != i) break;
848: if (i < pEnd - pStart) {
849: IS permIS;
851: PetscCall(ISCreateGeneral(PETSC_COMM_SELF, pEnd - pStart, perm, PETSC_OWN_POINTER, &permIS));
852: PetscCall(ISSetPermutation(permIS));
853: PetscCall(PetscSectionSetPermutation(section, permIS));
854: PetscCall(ISDestroy(&permIS));
855: } else {
856: PetscCall(PetscFree(perm));
857: }
858: PetscCall(PetscFree(seen));
859: *topSection = section;
860: PetscFunctionReturn(PETSC_SUCCESS);
861: }
863: /* mark boundary points and set up */
864: PetscErrorCode PetscDualSpaceSectionSetUp_Internal(PetscDualSpace sp, PetscSection section)
865: {
866: DM dm;
867: DMLabel boundary;
868: PetscInt pStart, pEnd, p;
870: PetscFunctionBegin;
871: dm = sp->dm;
872: PetscCall(DMLabelCreate(PETSC_COMM_SELF, "boundary", &boundary));
873: PetscCall(PetscDualSpaceGetDM(sp, &dm));
874: PetscCall(DMPlexMarkBoundaryFaces(dm, 1, boundary));
875: PetscCall(DMPlexLabelComplete(dm, boundary));
876: PetscCall(DMPlexGetChart(dm, &pStart, &pEnd));
877: for (p = pStart; p < pEnd; p++) {
878: PetscInt bval;
880: PetscCall(DMLabelGetValue(boundary, p, &bval));
881: if (bval == 1) {
882: PetscInt dof;
884: PetscCall(PetscSectionGetDof(section, p, &dof));
885: PetscCall(PetscSectionSetConstraintDof(section, p, dof));
886: }
887: }
888: PetscCall(DMLabelDestroy(&boundary));
889: PetscCall(PetscSectionSetUp(section));
890: PetscFunctionReturn(PETSC_SUCCESS);
891: }
893: /*@
894: PetscDualSpaceGetSection - Create a `PetscSection` over the reference cell with the layout from this space
896: Collective
898: Input Parameter:
899: . sp - The `PetscDualSpace`
901: Output Parameter:
902: . section - The section
904: Level: advanced
906: .seealso: `PetscDualSpace`, `PetscSection`, `PetscDualSpaceCreate()`, `DMPLEX`
907: @*/
908: PetscErrorCode PetscDualSpaceGetSection(PetscDualSpace sp, PetscSection *section)
909: {
910: PetscInt pStart, pEnd, p;
912: PetscFunctionBegin;
913: if (!sp->dm) {
914: *section = NULL;
915: PetscFunctionReturn(PETSC_SUCCESS);
916: }
917: if (!sp->pointSection) {
918: /* mark the boundary */
919: PetscCall(PetscDualSpaceSectionCreate_Internal(sp, &(sp->pointSection)));
920: PetscCall(DMPlexGetChart(sp->dm, &pStart, &pEnd));
921: for (p = pStart; p < pEnd; p++) {
922: PetscDualSpace psp;
924: PetscCall(PetscDualSpaceGetPointSubspace(sp, p, &psp));
925: if (psp) {
926: PetscInt dof;
928: PetscCall(PetscDualSpaceGetInteriorDimension(psp, &dof));
929: PetscCall(PetscSectionSetDof(sp->pointSection, p, dof));
930: }
931: }
932: PetscCall(PetscDualSpaceSectionSetUp_Internal(sp, sp->pointSection));
933: }
934: *section = sp->pointSection;
935: PetscFunctionReturn(PETSC_SUCCESS);
936: }
938: /* this assumes that all of the point dual spaces store their interior dofs first, which is true when the point DMs
939: * have one cell */
940: PetscErrorCode PetscDualSpacePushForwardSubspaces_Internal(PetscDualSpace sp, PetscInt sStart, PetscInt sEnd)
941: {
942: PetscReal *sv0, *v0, *J;
943: PetscSection section;
944: PetscInt dim, s, k;
945: DM dm;
947: PetscFunctionBegin;
948: PetscCall(PetscDualSpaceGetDM(sp, &dm));
949: PetscCall(DMGetDimension(dm, &dim));
950: PetscCall(PetscDualSpaceGetSection(sp, §ion));
951: PetscCall(PetscMalloc3(dim, &v0, dim, &sv0, dim * dim, &J));
952: PetscCall(PetscDualSpaceGetFormDegree(sp, &k));
953: for (s = sStart; s < sEnd; s++) {
954: PetscReal detJ, hdetJ;
955: PetscDualSpace ssp;
956: PetscInt dof, off, f, sdim;
957: PetscInt i, j;
958: DM sdm;
960: PetscCall(PetscDualSpaceGetPointSubspace(sp, s, &ssp));
961: if (!ssp) continue;
962: PetscCall(PetscSectionGetDof(section, s, &dof));
963: PetscCall(PetscSectionGetOffset(section, s, &off));
964: /* get the first vertex of the reference cell */
965: PetscCall(PetscDualSpaceGetDM(ssp, &sdm));
966: PetscCall(DMGetDimension(sdm, &sdim));
967: PetscCall(DMPlexComputeCellGeometryAffineFEM(sdm, 0, sv0, NULL, NULL, &hdetJ));
968: PetscCall(DMPlexComputeCellGeometryAffineFEM(dm, s, v0, J, NULL, &detJ));
969: /* compactify Jacobian */
970: for (i = 0; i < dim; i++)
971: for (j = 0; j < sdim; j++) J[i * sdim + j] = J[i * dim + j];
972: for (f = 0; f < dof; f++) {
973: PetscQuadrature fn;
975: PetscCall(PetscDualSpaceGetFunctional(ssp, f, &fn));
976: PetscCall(PetscQuadraturePushForward(fn, dim, sv0, v0, J, k, &(sp->functional[off + f])));
977: }
978: }
979: PetscCall(PetscFree3(v0, sv0, J));
980: PetscFunctionReturn(PETSC_SUCCESS);
981: }
983: /*@C
984: PetscDualSpaceApply - Apply a functional from the dual space basis to an input function
986: Input Parameters:
987: + sp - The `PetscDualSpace` object
988: . f - The basis functional index
989: . time - The time
990: . cgeom - A context with geometric information for this cell, we use v0 (the initial vertex) and J (the Jacobian) (or evaluated at the coordinates of the functional)
991: . numComp - The number of components for the function
992: . func - The input function
993: - ctx - A context for the function
995: Output Parameter:
996: . value - numComp output values
998: Calling Sequence of `func`:
999: .vb
1000: PetscErrorCode func(PetscInt dim, PetscReal time, const PetscReal x[], PetscInt numComponents, PetscScalar values[], void *ctx)
1001: .ve
1003: Level: beginner
1005: .seealso: `PetscDualSpace`, `PetscDualSpaceCreate()`
1006: @*/
1007: PetscErrorCode PetscDualSpaceApply(PetscDualSpace sp, PetscInt f, PetscReal time, PetscFEGeom *cgeom, PetscInt numComp, PetscErrorCode (*func)(PetscInt, PetscReal, const PetscReal[], PetscInt, PetscScalar *, void *), void *ctx, PetscScalar *value)
1008: {
1009: PetscFunctionBegin;
1013: PetscUseTypeMethod(sp, apply, f, time, cgeom, numComp, func, ctx, value);
1014: PetscFunctionReturn(PETSC_SUCCESS);
1015: }
1017: /*@C
1018: PetscDualSpaceApplyAll - Apply all functionals from the dual space basis to the result of an evaluation at the points returned by `PetscDualSpaceGetAllData()`
1020: Input Parameters:
1021: + sp - The `PetscDualSpace` object
1022: - pointEval - Evaluation at the points returned by `PetscDualSpaceGetAllData()`
1024: Output Parameter:
1025: . spValue - The values of all dual space functionals
1027: Level: advanced
1029: .seealso: `PetscDualSpace`, `PetscDualSpaceCreate()`
1030: @*/
1031: PetscErrorCode PetscDualSpaceApplyAll(PetscDualSpace sp, const PetscScalar *pointEval, PetscScalar *spValue)
1032: {
1033: PetscFunctionBegin;
1035: PetscUseTypeMethod(sp, applyall, pointEval, spValue);
1036: PetscFunctionReturn(PETSC_SUCCESS);
1037: }
1039: /*@C
1040: PetscDualSpaceApplyInterior - Apply interior functionals from the dual space basis to the result of an evaluation at the points returned by `PetscDualSpaceGetInteriorData()`
1042: Input Parameters:
1043: + sp - The `PetscDualSpace` object
1044: - pointEval - Evaluation at the points returned by `PetscDualSpaceGetInteriorData()`
1046: Output Parameter:
1047: . spValue - The values of interior dual space functionals
1049: Level: advanced
1051: .seealso: `PetscDualSpace`, `PetscDualSpaceCreate()`
1052: @*/
1053: PetscErrorCode PetscDualSpaceApplyInterior(PetscDualSpace sp, const PetscScalar *pointEval, PetscScalar *spValue)
1054: {
1055: PetscFunctionBegin;
1057: PetscUseTypeMethod(sp, applyint, pointEval, spValue);
1058: PetscFunctionReturn(PETSC_SUCCESS);
1059: }
1061: /*@C
1062: PetscDualSpaceApplyDefault - Apply a functional from the dual space basis to an input function by assuming a point evaluation functional.
1064: Input Parameters:
1065: + sp - The `PetscDualSpace` object
1066: . f - The basis functional index
1067: . time - The time
1068: . cgeom - A context with geometric information for this cell, we use v0 (the initial vertex) and J (the Jacobian)
1069: . Nc - The number of components for the function
1070: . func - The input function
1071: - ctx - A context for the function
1073: Output Parameter:
1074: . value - The output value
1076: Calling Sequence of `func`:
1077: .vb
1078: PetscErrorCode func(PetscInt dim, PetscReal time, const PetscReal x[],PetscInt numComponents, PetscScalar values[], void *ctx)
1079: .ve
1081: Level: advanced
1083: Note:
1084: The idea is to evaluate the functional as an integral $ n(f) = \int dx n(x) . f(x) $ where both n and f have Nc components.
1086: .seealso: `PetscDualSpace`, `PetscDualSpaceCreate()`
1087: @*/
1088: PetscErrorCode PetscDualSpaceApplyDefault(PetscDualSpace sp, PetscInt f, PetscReal time, PetscFEGeom *cgeom, PetscInt Nc, PetscErrorCode (*func)(PetscInt, PetscReal, const PetscReal[], PetscInt, PetscScalar *, void *), void *ctx, PetscScalar *value)
1089: {
1090: DM dm;
1091: PetscQuadrature n;
1092: const PetscReal *points, *weights;
1093: PetscReal x[3];
1094: PetscScalar *val;
1095: PetscInt dim, dE, qNc, c, Nq, q;
1096: PetscBool isAffine;
1098: PetscFunctionBegin;
1101: PetscCall(PetscDualSpaceGetDM(sp, &dm));
1102: PetscCall(PetscDualSpaceGetFunctional(sp, f, &n));
1103: PetscCall(PetscQuadratureGetData(n, &dim, &qNc, &Nq, &points, &weights));
1104: PetscCheck(dim == cgeom->dim, PetscObjectComm((PetscObject)sp), PETSC_ERR_ARG_SIZ, "The quadrature spatial dimension %" PetscInt_FMT " != cell geometry dimension %" PetscInt_FMT, dim, cgeom->dim);
1105: PetscCheck(qNc == Nc, PetscObjectComm((PetscObject)sp), PETSC_ERR_ARG_SIZ, "The quadrature components %" PetscInt_FMT " != function components %" PetscInt_FMT, qNc, Nc);
1106: PetscCall(DMGetWorkArray(dm, Nc, MPIU_SCALAR, &val));
1107: *value = 0.0;
1108: isAffine = cgeom->isAffine;
1109: dE = cgeom->dimEmbed;
1110: for (q = 0; q < Nq; ++q) {
1111: if (isAffine) {
1112: CoordinatesRefToReal(dE, cgeom->dim, cgeom->xi, cgeom->v, cgeom->J, &points[q * dim], x);
1113: PetscCall((*func)(dE, time, x, Nc, val, ctx));
1114: } else {
1115: PetscCall((*func)(dE, time, &cgeom->v[dE * q], Nc, val, ctx));
1116: }
1117: for (c = 0; c < Nc; ++c) *value += val[c] * weights[q * Nc + c];
1118: }
1119: PetscCall(DMRestoreWorkArray(dm, Nc, MPIU_SCALAR, &val));
1120: PetscFunctionReturn(PETSC_SUCCESS);
1121: }
1123: /*@C
1124: PetscDualSpaceApplyAllDefault - Apply all functionals from the dual space basis to the result of an evaluation at the points returned by `PetscDualSpaceGetAllData()`
1126: Input Parameters:
1127: + sp - The `PetscDualSpace` object
1128: - pointEval - Evaluation at the points returned by `PetscDualSpaceGetAllData()`
1130: Output Parameter:
1131: . spValue - The values of all dual space functionals
1133: Level: advanced
1135: .seealso: `PetscDualSpace`, `PetscDualSpaceCreate()`
1136: @*/
1137: PetscErrorCode PetscDualSpaceApplyAllDefault(PetscDualSpace sp, const PetscScalar *pointEval, PetscScalar *spValue)
1138: {
1139: Vec pointValues, dofValues;
1140: Mat allMat;
1142: PetscFunctionBegin;
1146: PetscCall(PetscDualSpaceGetAllData(sp, NULL, &allMat));
1147: if (!(sp->allNodeValues)) PetscCall(MatCreateVecs(allMat, &(sp->allNodeValues), NULL));
1148: pointValues = sp->allNodeValues;
1149: if (!(sp->allDofValues)) PetscCall(MatCreateVecs(allMat, NULL, &(sp->allDofValues)));
1150: dofValues = sp->allDofValues;
1151: PetscCall(VecPlaceArray(pointValues, pointEval));
1152: PetscCall(VecPlaceArray(dofValues, spValue));
1153: PetscCall(MatMult(allMat, pointValues, dofValues));
1154: PetscCall(VecResetArray(dofValues));
1155: PetscCall(VecResetArray(pointValues));
1156: PetscFunctionReturn(PETSC_SUCCESS);
1157: }
1159: /*@C
1160: PetscDualSpaceApplyInteriorDefault - Apply interior functionals from the dual space basis to the result of an evaluation at the points returned by `PetscDualSpaceGetInteriorData()`
1162: Input Parameters:
1163: + sp - The `PetscDualSpace` object
1164: - pointEval - Evaluation at the points returned by `PetscDualSpaceGetInteriorData()`
1166: Output Parameter:
1167: . spValue - The values of interior dual space functionals
1169: Level: advanced
1171: .seealso: `PetscDualSpace`, `PetscDualSpaceCreate()`
1172: @*/
1173: PetscErrorCode PetscDualSpaceApplyInteriorDefault(PetscDualSpace sp, const PetscScalar *pointEval, PetscScalar *spValue)
1174: {
1175: Vec pointValues, dofValues;
1176: Mat intMat;
1178: PetscFunctionBegin;
1182: PetscCall(PetscDualSpaceGetInteriorData(sp, NULL, &intMat));
1183: if (!(sp->intNodeValues)) PetscCall(MatCreateVecs(intMat, &(sp->intNodeValues), NULL));
1184: pointValues = sp->intNodeValues;
1185: if (!(sp->intDofValues)) PetscCall(MatCreateVecs(intMat, NULL, &(sp->intDofValues)));
1186: dofValues = sp->intDofValues;
1187: PetscCall(VecPlaceArray(pointValues, pointEval));
1188: PetscCall(VecPlaceArray(dofValues, spValue));
1189: PetscCall(MatMult(intMat, pointValues, dofValues));
1190: PetscCall(VecResetArray(dofValues));
1191: PetscCall(VecResetArray(pointValues));
1192: PetscFunctionReturn(PETSC_SUCCESS);
1193: }
1195: /*@
1196: PetscDualSpaceGetAllData - Get all quadrature nodes from this space, and the matrix that sends quadrature node values to degree-of-freedom values
1198: Input Parameter:
1199: . sp - The dualspace
1201: Output Parameters:
1202: + allNodes - A `PetscQuadrature` object containing all evaluation nodes
1203: - allMat - A `Mat` for the node-to-dof transformation
1205: Level: advanced
1207: .seealso: `PetscQuadrature`, `PetscDualSpace`, `PetscDualSpaceCreate()`, `Mat`
1208: @*/
1209: PetscErrorCode PetscDualSpaceGetAllData(PetscDualSpace sp, PetscQuadrature *allNodes, Mat *allMat)
1210: {
1211: PetscFunctionBegin;
1215: if ((!sp->allNodes || !sp->allMat) && sp->ops->createalldata) {
1216: PetscQuadrature qpoints;
1217: Mat amat;
1219: PetscUseTypeMethod(sp, createalldata, &qpoints, &amat);
1220: PetscCall(PetscQuadratureDestroy(&(sp->allNodes)));
1221: PetscCall(MatDestroy(&(sp->allMat)));
1222: sp->allNodes = qpoints;
1223: sp->allMat = amat;
1224: }
1225: if (allNodes) *allNodes = sp->allNodes;
1226: if (allMat) *allMat = sp->allMat;
1227: PetscFunctionReturn(PETSC_SUCCESS);
1228: }
1230: /*@
1231: PetscDualSpaceCreateAllDataDefault - Create all evaluation nodes and the node-to-dof matrix by examining functionals
1233: Input Parameter:
1234: . sp - The dualspace
1236: Output Parameters:
1237: + allNodes - A `PetscQuadrature` object containing all evaluation nodes
1238: - allMat - A `Mat` for the node-to-dof transformation
1240: Level: advanced
1242: .seealso: `PetscDualSpace`, `PetscDualSpaceCreate()`, `Mat`, `PetscQuadrature`
1243: @*/
1244: PetscErrorCode PetscDualSpaceCreateAllDataDefault(PetscDualSpace sp, PetscQuadrature *allNodes, Mat *allMat)
1245: {
1246: PetscInt spdim;
1247: PetscInt numPoints, offset;
1248: PetscReal *points;
1249: PetscInt f, dim;
1250: PetscInt Nc, nrows, ncols;
1251: PetscInt maxNumPoints;
1252: PetscQuadrature q;
1253: Mat A;
1255: PetscFunctionBegin;
1256: PetscCall(PetscDualSpaceGetNumComponents(sp, &Nc));
1257: PetscCall(PetscDualSpaceGetDimension(sp, &spdim));
1258: if (!spdim) {
1259: PetscCall(PetscQuadratureCreate(PETSC_COMM_SELF, allNodes));
1260: PetscCall(PetscQuadratureSetData(*allNodes, 0, 0, 0, NULL, NULL));
1261: }
1262: nrows = spdim;
1263: PetscCall(PetscDualSpaceGetFunctional(sp, 0, &q));
1264: PetscCall(PetscQuadratureGetData(q, &dim, NULL, &numPoints, NULL, NULL));
1265: maxNumPoints = numPoints;
1266: for (f = 1; f < spdim; f++) {
1267: PetscInt Np;
1269: PetscCall(PetscDualSpaceGetFunctional(sp, f, &q));
1270: PetscCall(PetscQuadratureGetData(q, NULL, NULL, &Np, NULL, NULL));
1271: numPoints += Np;
1272: maxNumPoints = PetscMax(maxNumPoints, Np);
1273: }
1274: ncols = numPoints * Nc;
1275: PetscCall(PetscMalloc1(dim * numPoints, &points));
1276: PetscCall(MatCreateSeqAIJ(PETSC_COMM_SELF, nrows, ncols, maxNumPoints * Nc, NULL, &A));
1277: for (f = 0, offset = 0; f < spdim; f++) {
1278: const PetscReal *p, *w;
1279: PetscInt Np, i;
1280: PetscInt fnc;
1282: PetscCall(PetscDualSpaceGetFunctional(sp, f, &q));
1283: PetscCall(PetscQuadratureGetData(q, NULL, &fnc, &Np, &p, &w));
1284: PetscCheck(fnc == Nc, PETSC_COMM_SELF, PETSC_ERR_PLIB, "functional component mismatch");
1285: for (i = 0; i < Np * dim; i++) points[offset * dim + i] = p[i];
1286: for (i = 0; i < Np * Nc; i++) PetscCall(MatSetValue(A, f, offset * Nc, w[i], INSERT_VALUES));
1287: offset += Np;
1288: }
1289: PetscCall(MatAssemblyBegin(A, MAT_FINAL_ASSEMBLY));
1290: PetscCall(MatAssemblyEnd(A, MAT_FINAL_ASSEMBLY));
1291: PetscCall(PetscQuadratureCreate(PETSC_COMM_SELF, allNodes));
1292: PetscCall(PetscQuadratureSetData(*allNodes, dim, 0, numPoints, points, NULL));
1293: *allMat = A;
1294: PetscFunctionReturn(PETSC_SUCCESS);
1295: }
1297: /*@
1298: PetscDualSpaceGetInteriorData - Get all quadrature points necessary to compute the interior degrees of freedom from
1299: this space, as well as the matrix that computes the degrees of freedom from the quadrature values. Degrees of
1300: freedom are interior degrees of freedom if they belong (by `PetscDualSpaceGetSection()`) to interior points in the
1301: reference `DMPLEX`: complementary boundary degrees of freedom are marked as constrained in the section returned by
1302: `PetscDualSpaceGetSection()`).
1304: Input Parameter:
1305: . sp - The dualspace
1307: Output Parameters:
1308: + intNodes - A `PetscQuadrature` object containing all evaluation points needed to evaluate interior degrees of freedom
1309: - intMat - A matrix that computes dual space values from point values: size [spdim0 x (npoints * nc)], where spdim0 is
1310: the size of the constrained layout (`PetscSectionGetConstrainStorageSize()`) of the dual space section,
1311: npoints is the number of points in intNodes and nc is `PetscDualSpaceGetNumComponents()`.
1313: Level: advanced
1315: .seealso: `PetscDualSpace`, `PetscQuadrature`, `Mat`, `PetscDualSpaceCreate()`, `PetscDualSpaceGetDimension()`, `PetscDualSpaceGetNumComponents()`, `PetscQuadratureGetData()`
1316: @*/
1317: PetscErrorCode PetscDualSpaceGetInteriorData(PetscDualSpace sp, PetscQuadrature *intNodes, Mat *intMat)
1318: {
1319: PetscFunctionBegin;
1323: if ((!sp->intNodes || !sp->intMat) && sp->ops->createintdata) {
1324: PetscQuadrature qpoints;
1325: Mat imat;
1327: PetscUseTypeMethod(sp, createintdata, &qpoints, &imat);
1328: PetscCall(PetscQuadratureDestroy(&(sp->intNodes)));
1329: PetscCall(MatDestroy(&(sp->intMat)));
1330: sp->intNodes = qpoints;
1331: sp->intMat = imat;
1332: }
1333: if (intNodes) *intNodes = sp->intNodes;
1334: if (intMat) *intMat = sp->intMat;
1335: PetscFunctionReturn(PETSC_SUCCESS);
1336: }
1338: /*@
1339: PetscDualSpaceCreateInteriorDataDefault - Create quadrature points by examining interior functionals and create the matrix mapping quadrature point values to interior dual space values
1341: Input Parameter:
1342: . sp - The dualspace
1344: Output Parameters:
1345: + intNodes - A `PetscQuadrature` object containing all evaluation points needed to evaluate interior degrees of freedom
1346: - intMat - A matrix that computes dual space values from point values: size [spdim0 x (npoints * nc)], where spdim0 is
1347: the size of the constrained layout (`PetscSectionGetConstrainStorageSize()`) of the dual space section,
1348: npoints is the number of points in allNodes and nc is `PetscDualSpaceGetNumComponents()`.
1350: Level: advanced
1352: .seealso: `PetscDualSpace`, `PetscQuadrature`, `Mat`, `PetscDualSpaceCreate()`, `PetscDualSpaceGetInteriorData()`
1353: @*/
1354: PetscErrorCode PetscDualSpaceCreateInteriorDataDefault(PetscDualSpace sp, PetscQuadrature *intNodes, Mat *intMat)
1355: {
1356: DM dm;
1357: PetscInt spdim0;
1358: PetscInt Nc;
1359: PetscInt pStart, pEnd, p, f;
1360: PetscSection section;
1361: PetscInt numPoints, offset, matoffset;
1362: PetscReal *points;
1363: PetscInt dim;
1364: PetscInt *nnz;
1365: PetscQuadrature q;
1366: Mat imat;
1368: PetscFunctionBegin;
1370: PetscCall(PetscDualSpaceGetSection(sp, §ion));
1371: PetscCall(PetscSectionGetConstrainedStorageSize(section, &spdim0));
1372: if (!spdim0) {
1373: *intNodes = NULL;
1374: *intMat = NULL;
1375: PetscFunctionReturn(PETSC_SUCCESS);
1376: }
1377: PetscCall(PetscDualSpaceGetNumComponents(sp, &Nc));
1378: PetscCall(PetscSectionGetChart(section, &pStart, &pEnd));
1379: PetscCall(PetscDualSpaceGetDM(sp, &dm));
1380: PetscCall(DMGetDimension(dm, &dim));
1381: PetscCall(PetscMalloc1(spdim0, &nnz));
1382: for (p = pStart, f = 0, numPoints = 0; p < pEnd; p++) {
1383: PetscInt dof, cdof, off, d;
1385: PetscCall(PetscSectionGetDof(section, p, &dof));
1386: PetscCall(PetscSectionGetConstraintDof(section, p, &cdof));
1387: if (!(dof - cdof)) continue;
1388: PetscCall(PetscSectionGetOffset(section, p, &off));
1389: for (d = 0; d < dof; d++, off++, f++) {
1390: PetscInt Np;
1392: PetscCall(PetscDualSpaceGetFunctional(sp, off, &q));
1393: PetscCall(PetscQuadratureGetData(q, NULL, NULL, &Np, NULL, NULL));
1394: nnz[f] = Np * Nc;
1395: numPoints += Np;
1396: }
1397: }
1398: PetscCall(MatCreateSeqAIJ(PETSC_COMM_SELF, spdim0, numPoints * Nc, 0, nnz, &imat));
1399: PetscCall(PetscFree(nnz));
1400: PetscCall(PetscMalloc1(dim * numPoints, &points));
1401: for (p = pStart, f = 0, offset = 0, matoffset = 0; p < pEnd; p++) {
1402: PetscInt dof, cdof, off, d;
1404: PetscCall(PetscSectionGetDof(section, p, &dof));
1405: PetscCall(PetscSectionGetConstraintDof(section, p, &cdof));
1406: if (!(dof - cdof)) continue;
1407: PetscCall(PetscSectionGetOffset(section, p, &off));
1408: for (d = 0; d < dof; d++, off++, f++) {
1409: const PetscReal *p;
1410: const PetscReal *w;
1411: PetscInt Np, i;
1413: PetscCall(PetscDualSpaceGetFunctional(sp, off, &q));
1414: PetscCall(PetscQuadratureGetData(q, NULL, NULL, &Np, &p, &w));
1415: for (i = 0; i < Np * dim; i++) points[offset + i] = p[i];
1416: for (i = 0; i < Np * Nc; i++) PetscCall(MatSetValue(imat, f, matoffset + i, w[i], INSERT_VALUES));
1417: offset += Np * dim;
1418: matoffset += Np * Nc;
1419: }
1420: }
1421: PetscCall(PetscQuadratureCreate(PETSC_COMM_SELF, intNodes));
1422: PetscCall(PetscQuadratureSetData(*intNodes, dim, 0, numPoints, points, NULL));
1423: PetscCall(MatAssemblyBegin(imat, MAT_FINAL_ASSEMBLY));
1424: PetscCall(MatAssemblyEnd(imat, MAT_FINAL_ASSEMBLY));
1425: *intMat = imat;
1426: PetscFunctionReturn(PETSC_SUCCESS);
1427: }
1429: /*@
1430: PetscDualSpaceEqual - Determine if two dual spaces are equivalent
1432: Input Parameters:
1433: + A - A `PetscDualSpace` object
1434: - B - Another `PetscDualSpace` object
1436: Output Parameter:
1437: . equal - `PETSC_TRUE` if the dual spaces are equivalent
1439: Level: advanced
1441: .seealso: `PetscDualSpace`, `PetscDualSpaceCreate()`
1442: @*/
1443: PetscErrorCode PetscDualSpaceEqual(PetscDualSpace A, PetscDualSpace B, PetscBool *equal)
1444: {
1445: PetscInt sizeA, sizeB, dimA, dimB;
1446: const PetscInt *dofA, *dofB;
1447: PetscQuadrature quadA, quadB;
1448: Mat matA, matB;
1450: PetscFunctionBegin;
1454: *equal = PETSC_FALSE;
1455: PetscCall(PetscDualSpaceGetDimension(A, &sizeA));
1456: PetscCall(PetscDualSpaceGetDimension(B, &sizeB));
1457: if (sizeB != sizeA) PetscFunctionReturn(PETSC_SUCCESS);
1458: PetscCall(DMGetDimension(A->dm, &dimA));
1459: PetscCall(DMGetDimension(B->dm, &dimB));
1460: if (dimA != dimB) PetscFunctionReturn(PETSC_SUCCESS);
1462: PetscCall(PetscDualSpaceGetNumDof(A, &dofA));
1463: PetscCall(PetscDualSpaceGetNumDof(B, &dofB));
1464: for (PetscInt d = 0; d < dimA; d++) {
1465: if (dofA[d] != dofB[d]) PetscFunctionReturn(PETSC_SUCCESS);
1466: }
1468: PetscCall(PetscDualSpaceGetInteriorData(A, &quadA, &matA));
1469: PetscCall(PetscDualSpaceGetInteriorData(B, &quadB, &matB));
1470: if (!quadA && !quadB) {
1471: *equal = PETSC_TRUE;
1472: } else if (quadA && quadB) {
1473: PetscCall(PetscQuadratureEqual(quadA, quadB, equal));
1474: if (*equal == PETSC_FALSE) PetscFunctionReturn(PETSC_SUCCESS);
1475: if (!matA && !matB) PetscFunctionReturn(PETSC_SUCCESS);
1476: if (matA && matB) PetscCall(MatEqual(matA, matB, equal));
1477: else *equal = PETSC_FALSE;
1478: }
1479: PetscFunctionReturn(PETSC_SUCCESS);
1480: }
1482: /*@C
1483: PetscDualSpaceApplyFVM - Apply a functional from the dual space basis to an input function by assuming a point evaluation functional at the cell centroid.
1485: Input Parameters:
1486: + sp - The `PetscDualSpace` object
1487: . f - The basis functional index
1488: . time - The time
1489: . cgeom - A context with geometric information for this cell, we currently just use the centroid
1490: . Nc - The number of components for the function
1491: . func - The input function
1492: - ctx - A context for the function
1494: Output Parameter:
1495: . value - The output value (scalar)
1497: Calling Sequence of `func`:
1498: .vb
1499: PetscErrorCode func(PetscInt dim, PetscReal time, const PetscReal x[], PetscInt numComponents, PetscScalar values[], void *ctx)
1500: .ve
1502: Level: advanced
1504: Note:
1505: The idea is to evaluate the functional as an integral $ n(f) = \int dx n(x) . f(x)$ where both n and f have Nc components.
1507: .seealso: `PetscDualSpace`, `PetscDualSpaceCreate()`
1508: @*/
1509: PetscErrorCode PetscDualSpaceApplyFVM(PetscDualSpace sp, PetscInt f, PetscReal time, PetscFVCellGeom *cgeom, PetscInt Nc, PetscErrorCode (*func)(PetscInt, PetscReal, const PetscReal[], PetscInt, PetscScalar *, void *), void *ctx, PetscScalar *value)
1510: {
1511: DM dm;
1512: PetscQuadrature n;
1513: const PetscReal *points, *weights;
1514: PetscScalar *val;
1515: PetscInt dimEmbed, qNc, c, Nq, q;
1517: PetscFunctionBegin;
1520: PetscCall(PetscDualSpaceGetDM(sp, &dm));
1521: PetscCall(DMGetCoordinateDim(dm, &dimEmbed));
1522: PetscCall(PetscDualSpaceGetFunctional(sp, f, &n));
1523: PetscCall(PetscQuadratureGetData(n, NULL, &qNc, &Nq, &points, &weights));
1524: PetscCheck(qNc == Nc, PetscObjectComm((PetscObject)sp), PETSC_ERR_ARG_SIZ, "The quadrature components %" PetscInt_FMT " != function components %" PetscInt_FMT, qNc, Nc);
1525: PetscCall(DMGetWorkArray(dm, Nc, MPIU_SCALAR, &val));
1526: *value = 0.;
1527: for (q = 0; q < Nq; ++q) {
1528: PetscCall((*func)(dimEmbed, time, cgeom->centroid, Nc, val, ctx));
1529: for (c = 0; c < Nc; ++c) *value += val[c] * weights[q * Nc + c];
1530: }
1531: PetscCall(DMRestoreWorkArray(dm, Nc, MPIU_SCALAR, &val));
1532: PetscFunctionReturn(PETSC_SUCCESS);
1533: }
1535: /*@
1536: PetscDualSpaceGetHeightSubspace - Get the subset of the dual space basis that is supported on a mesh point of a
1537: given height. This assumes that the reference cell is symmetric over points of this height.
1539: Not Collective
1541: Input Parameters:
1542: + sp - the `PetscDualSpace` object
1543: - height - the height of the mesh point for which the subspace is desired
1545: Output Parameter:
1546: . subsp - the subspace. Note that the functionals in the subspace are with respect to the intrinsic geometry of the
1547: point, which will be of lesser dimension if height > 0.
1549: Level: advanced
1551: Notes:
1552: If the dual space is not defined on mesh points of the given height (e.g. if the space is discontinuous and
1553: pointwise values are not defined on the element boundaries), or if the implementation of `PetscDualSpace` does not
1554: support extracting subspaces, then NULL is returned.
1556: This does not increment the reference count on the returned dual space, and the user should not destroy it.
1558: .seealso: `PetscDualSpace`, `PetscSpaceGetHeightSubspace()`, `PetscDualSpace`, `PetscDualSpaceGetPointSubspace()`
1559: @*/
1560: PetscErrorCode PetscDualSpaceGetHeightSubspace(PetscDualSpace sp, PetscInt height, PetscDualSpace *subsp)
1561: {
1562: PetscInt depth = -1, cStart, cEnd;
1563: DM dm;
1565: PetscFunctionBegin;
1568: PetscCheck((sp->uniform), PETSC_COMM_SELF, PETSC_ERR_ARG_WRONG, "A non-uniform dual space does not have a single dual space at each height");
1569: *subsp = NULL;
1570: dm = sp->dm;
1571: PetscCall(DMPlexGetDepth(dm, &depth));
1572: PetscCheck(height >= 0 && height <= depth, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Invalid height");
1573: PetscCall(DMPlexGetHeightStratum(dm, 0, &cStart, &cEnd));
1574: if (height == 0 && cEnd == cStart + 1) {
1575: *subsp = sp;
1576: PetscFunctionReturn(PETSC_SUCCESS);
1577: }
1578: if (!sp->heightSpaces) {
1579: PetscInt h;
1580: PetscCall(PetscCalloc1(depth + 1, &(sp->heightSpaces)));
1582: for (h = 0; h <= depth; h++) {
1583: if (h == 0 && cEnd == cStart + 1) continue;
1584: if (sp->ops->createheightsubspace) PetscCall((*sp->ops->createheightsubspace)(sp, height, &(sp->heightSpaces[h])));
1585: else if (sp->pointSpaces) {
1586: PetscInt hStart, hEnd;
1588: PetscCall(DMPlexGetHeightStratum(dm, h, &hStart, &hEnd));
1589: if (hEnd > hStart) {
1590: const char *name;
1592: PetscCall(PetscObjectReference((PetscObject)(sp->pointSpaces[hStart])));
1593: if (sp->pointSpaces[hStart]) {
1594: PetscCall(PetscObjectGetName((PetscObject)sp, &name));
1595: PetscCall(PetscObjectSetName((PetscObject)sp->pointSpaces[hStart], name));
1596: }
1597: sp->heightSpaces[h] = sp->pointSpaces[hStart];
1598: }
1599: }
1600: }
1601: }
1602: *subsp = sp->heightSpaces[height];
1603: PetscFunctionReturn(PETSC_SUCCESS);
1604: }
1606: /*@
1607: PetscDualSpaceGetPointSubspace - Get the subset of the dual space basis that is supported on a particular mesh point.
1609: Not Collective
1611: Input Parameters:
1612: + sp - the `PetscDualSpace` object
1613: - point - the point (in the dual space's DM) for which the subspace is desired
1615: Output Parameters:
1616: bdsp - the subspace. The functionals in the subspace are with respect to the intrinsic geometry of the
1617: point, which will be of lesser dimension if height > 0.
1619: Level: advanced
1621: Notes:
1622: If the dual space is not defined on the mesh point (e.g. if the space is discontinuous and pointwise values are not
1623: defined on the element boundaries), or if the implementation of `PetscDualSpace` does not support extracting
1624: subspaces, then NULL is returned.
1626: This does not increment the reference count on the returned dual space, and the user should not destroy it.
1628: .seealso: `PetscDualSpace`, `PetscDualSpaceGetHeightSubspace()`
1629: @*/
1630: PetscErrorCode PetscDualSpaceGetPointSubspace(PetscDualSpace sp, PetscInt point, PetscDualSpace *bdsp)
1631: {
1632: PetscInt pStart = 0, pEnd = 0, cStart, cEnd;
1633: DM dm;
1635: PetscFunctionBegin;
1638: *bdsp = NULL;
1639: dm = sp->dm;
1640: PetscCall(DMPlexGetChart(dm, &pStart, &pEnd));
1641: PetscCheck(point >= pStart && point <= pEnd, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Invalid point");
1642: PetscCall(DMPlexGetHeightStratum(dm, 0, &cStart, &cEnd));
1643: if (point == cStart && cEnd == cStart + 1) { /* the dual space is only equivalent to the dual space on a cell if the reference mesh has just one cell */
1644: *bdsp = sp;
1645: PetscFunctionReturn(PETSC_SUCCESS);
1646: }
1647: if (!sp->pointSpaces) {
1648: PetscInt p;
1649: PetscCall(PetscCalloc1(pEnd - pStart, &(sp->pointSpaces)));
1651: for (p = 0; p < pEnd - pStart; p++) {
1652: if (p + pStart == cStart && cEnd == cStart + 1) continue;
1653: if (sp->ops->createpointsubspace) PetscCall((*sp->ops->createpointsubspace)(sp, p + pStart, &(sp->pointSpaces[p])));
1654: else if (sp->heightSpaces || sp->ops->createheightsubspace) {
1655: PetscInt dim, depth, height;
1656: DMLabel label;
1658: PetscCall(DMPlexGetDepth(dm, &dim));
1659: PetscCall(DMPlexGetDepthLabel(dm, &label));
1660: PetscCall(DMLabelGetValue(label, p + pStart, &depth));
1661: height = dim - depth;
1662: PetscCall(PetscDualSpaceGetHeightSubspace(sp, height, &(sp->pointSpaces[p])));
1663: PetscCall(PetscObjectReference((PetscObject)sp->pointSpaces[p]));
1664: }
1665: }
1666: }
1667: *bdsp = sp->pointSpaces[point - pStart];
1668: PetscFunctionReturn(PETSC_SUCCESS);
1669: }
1671: /*@C
1672: PetscDualSpaceGetSymmetries - Returns a description of the symmetries of this basis
1674: Not Collective
1676: Input Parameter:
1677: . sp - the `PetscDualSpace` object
1679: Output Parameters:
1680: + perms - Permutations of the interior degrees of freedom, parameterized by the point orientation
1681: - flips - Sign reversal of the interior degrees of freedom, parameterized by the point orientation
1683: Level: developer
1685: Note:
1686: The permutation and flip arrays are organized in the following way
1687: .vb
1688: perms[p][ornt][dof # on point] = new local dof #
1689: flips[p][ornt][dof # on point] = reversal or not
1690: .ve
1692: .seealso: `PetscDualSpace`
1693: @*/
1694: PetscErrorCode PetscDualSpaceGetSymmetries(PetscDualSpace sp, const PetscInt ****perms, const PetscScalar ****flips)
1695: {
1696: PetscFunctionBegin;
1698: if (perms) {
1700: *perms = NULL;
1701: }
1702: if (flips) {
1704: *flips = NULL;
1705: }
1706: if (sp->ops->getsymmetries) PetscCall((sp->ops->getsymmetries)(sp, perms, flips));
1707: PetscFunctionReturn(PETSC_SUCCESS);
1708: }
1710: /*@
1711: PetscDualSpaceGetFormDegree - Get the form degree k for the k-form the describes the pushforwards/pullbacks of this
1712: dual space's functionals.
1714: Input Parameter:
1715: . dsp - The `PetscDualSpace`
1717: Output Parameter:
1718: . k - The *signed* degree k of the k. If k >= 0, this means that the degrees of freedom are k-forms, and are stored
1719: in lexicographic order according to the basis of k-forms constructed from the wedge product of 1-forms. So for example,
1720: the 1-form basis in 3-D is (dx, dy, dz), and the 2-form basis in 3-D is (dx wedge dy, dx wedge dz, dy wedge dz).
1721: If k < 0, this means that the degrees transform as k-forms, but are stored as (N-k) forms according to the
1722: Hodge star map. So for example if k = -2 and N = 3, this means that the degrees of freedom transform as 2-forms
1723: but are stored as 1-forms.
1725: Level: developer
1727: .seealso: `PetscDualSpace`, `PetscDTAltV`, `PetscDualSpacePullback()`, `PetscDualSpacePushforward()`, `PetscDualSpaceTransform()`, `PetscDualSpaceTransformType`
1728: @*/
1729: PetscErrorCode PetscDualSpaceGetFormDegree(PetscDualSpace dsp, PetscInt *k)
1730: {
1731: PetscFunctionBeginHot;
1734: *k = dsp->k;
1735: PetscFunctionReturn(PETSC_SUCCESS);
1736: }
1738: /*@
1739: PetscDualSpaceSetFormDegree - Set the form degree k for the k-form the describes the pushforwards/pullbacks of this
1740: dual space's functionals.
1742: Input Parameters:
1743: + dsp - The `PetscDualSpace`
1744: - k - The *signed* degree k of the k. If k >= 0, this means that the degrees of freedom are k-forms, and are stored
1745: in lexicographic order according to the basis of k-forms constructed from the wedge product of 1-forms. So for example,
1746: the 1-form basis in 3-D is (dx, dy, dz), and the 2-form basis in 3-D is (dx wedge dy, dx wedge dz, dy wedge dz).
1747: If k < 0, this means that the degrees transform as k-forms, but are stored as (N-k) forms according to the
1748: Hodge star map. So for example if k = -2 and N = 3, this means that the degrees of freedom transform as 2-forms
1749: but are stored as 1-forms.
1751: Level: developer
1753: .seealso: `PetscDualSpace`, `PetscDTAltV`, `PetscDualSpacePullback()`, `PetscDualSpacePushforward()`, `PetscDualSpaceTransform()`, `PetscDualSpaceTransformType`
1754: @*/
1755: PetscErrorCode PetscDualSpaceSetFormDegree(PetscDualSpace dsp, PetscInt k)
1756: {
1757: PetscInt dim;
1759: PetscFunctionBeginHot;
1761: PetscCheck(!dsp->setupcalled, PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_WRONGSTATE, "Cannot change number of components after dualspace is set up");
1762: dim = dsp->dm->dim;
1763: PetscCheck(k >= -dim && k <= dim, PETSC_COMM_SELF, PETSC_ERR_PLIB, "Unsupported %" PetscInt_FMT "-form on %" PetscInt_FMT "-dimensional reference cell", PetscAbsInt(k), dim);
1764: dsp->k = k;
1765: PetscFunctionReturn(PETSC_SUCCESS);
1766: }
1768: /*@
1769: PetscDualSpaceGetDeRahm - Get the k-simplex associated with the functionals in this dual space
1771: Input Parameter:
1772: . dsp - The `PetscDualSpace`
1774: Output Parameter:
1775: . k - The simplex dimension
1777: Level: developer
1779: Note:
1780: Currently supported values are
1781: .vb
1782: 0: These are H_1 methods that only transform coordinates
1783: 1: These are Hcurl methods that transform functions using the covariant Piola transform (COVARIANT_PIOLA_TRANSFORM)
1784: 2: These are the same as 1
1785: 3: These are Hdiv methods that transform functions using the contravariant Piola transform (CONTRAVARIANT_PIOLA_TRANSFORM)
1786: .ve
1788: .seealso: `PetscDualSpace`, `PetscDualSpacePullback()`, `PetscDualSpacePushforward()`, `PetscDualSpaceTransform()`, `PetscDualSpaceTransformType`
1789: @*/
1790: PetscErrorCode PetscDualSpaceGetDeRahm(PetscDualSpace dsp, PetscInt *k)
1791: {
1792: PetscInt dim;
1794: PetscFunctionBeginHot;
1797: dim = dsp->dm->dim;
1798: if (!dsp->k) *k = IDENTITY_TRANSFORM;
1799: else if (dsp->k == 1) *k = COVARIANT_PIOLA_TRANSFORM;
1800: else if (dsp->k == -(dim - 1)) *k = CONTRAVARIANT_PIOLA_TRANSFORM;
1801: else SETERRQ(PETSC_COMM_SELF, PETSC_ERR_PLIB, "Unsupported transformation");
1802: PetscFunctionReturn(PETSC_SUCCESS);
1803: }
1805: /*@C
1806: PetscDualSpaceTransform - Transform the function values
1808: Input Parameters:
1809: + dsp - The `PetscDualSpace`
1810: . trans - The type of transform
1811: . isInverse - Flag to invert the transform
1812: . fegeom - The cell geometry
1813: . Nv - The number of function samples
1814: . Nc - The number of function components
1815: - vals - The function values
1817: Output Parameter:
1818: . vals - The transformed function values
1820: Level: intermediate
1822: Note:
1823: This only handles transformations when the embedding dimension of the geometry in fegeom is the same as the reference dimension.
1825: .seealso: `PetscDualSpace`, `PetscDualSpaceTransformGradient()`, `PetscDualSpaceTransformHessian()`, `PetscDualSpacePullback()`, `PetscDualSpacePushforward()`, `PetscDualSpaceTransformType`
1826: @*/
1827: PetscErrorCode PetscDualSpaceTransform(PetscDualSpace dsp, PetscDualSpaceTransformType trans, PetscBool isInverse, PetscFEGeom *fegeom, PetscInt Nv, PetscInt Nc, PetscScalar vals[])
1828: {
1829: PetscReal Jstar[9] = {0};
1830: PetscInt dim, v, c, Nk;
1832: PetscFunctionBeginHot;
1836: /* TODO: not handling dimEmbed != dim right now */
1837: dim = dsp->dm->dim;
1838: /* No change needed for 0-forms */
1839: if (!dsp->k) PetscFunctionReturn(PETSC_SUCCESS);
1840: PetscCall(PetscDTBinomialInt(dim, PetscAbsInt(dsp->k), &Nk));
1841: /* TODO: use fegeom->isAffine */
1842: PetscCall(PetscDTAltVPullbackMatrix(dim, dim, isInverse ? fegeom->J : fegeom->invJ, dsp->k, Jstar));
1843: for (v = 0; v < Nv; ++v) {
1844: switch (Nk) {
1845: case 1:
1846: for (c = 0; c < Nc; c++) vals[v * Nc + c] *= Jstar[0];
1847: break;
1848: case 2:
1849: for (c = 0; c < Nc; c += 2) DMPlex_Mult2DReal_Internal(Jstar, 1, &vals[v * Nc + c], &vals[v * Nc + c]);
1850: break;
1851: case 3:
1852: for (c = 0; c < Nc; c += 3) DMPlex_Mult3DReal_Internal(Jstar, 1, &vals[v * Nc + c], &vals[v * Nc + c]);
1853: break;
1854: default:
1855: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported form size %" PetscInt_FMT " for transformation", Nk);
1856: }
1857: }
1858: PetscFunctionReturn(PETSC_SUCCESS);
1859: }
1861: /*@C
1862: PetscDualSpaceTransformGradient - Transform the function gradient values
1864: Input Parameters:
1865: + dsp - The `PetscDualSpace`
1866: . trans - The type of transform
1867: . isInverse - Flag to invert the transform
1868: . fegeom - The cell geometry
1869: . Nv - The number of function gradient samples
1870: . Nc - The number of function components
1871: - vals - The function gradient values
1873: Output Parameter:
1874: . vals - The transformed function gradient values
1876: Level: intermediate
1878: Note:
1879: This only handles transformations when the embedding dimension of the geometry in fegeom is the same as the reference dimension.
1881: .seealso: `PetscDualSpace`, `PetscDualSpaceTransform()`, `PetscDualSpacePullback()`, `PetscDualSpacePushforward()`, `PetscDualSpaceTransformType`
1882: @*/
1883: PetscErrorCode PetscDualSpaceTransformGradient(PetscDualSpace dsp, PetscDualSpaceTransformType trans, PetscBool isInverse, PetscFEGeom *fegeom, PetscInt Nv, PetscInt Nc, PetscScalar vals[])
1884: {
1885: const PetscInt dim = dsp->dm->dim, dE = fegeom->dimEmbed;
1886: PetscInt v, c, d;
1888: PetscFunctionBeginHot;
1892: #ifdef PETSC_USE_DEBUG
1893: PetscCheck(dE > 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Invalid embedding dimension %" PetscInt_FMT, dE);
1894: #endif
1895: /* Transform gradient */
1896: if (dim == dE) {
1897: for (v = 0; v < Nv; ++v) {
1898: for (c = 0; c < Nc; ++c) {
1899: switch (dim) {
1900: case 1:
1901: vals[(v * Nc + c) * dim] *= fegeom->invJ[0];
1902: break;
1903: case 2:
1904: DMPlex_MultTranspose2DReal_Internal(fegeom->invJ, 1, &vals[(v * Nc + c) * dim], &vals[(v * Nc + c) * dim]);
1905: break;
1906: case 3:
1907: DMPlex_MultTranspose3DReal_Internal(fegeom->invJ, 1, &vals[(v * Nc + c) * dim], &vals[(v * Nc + c) * dim]);
1908: break;
1909: default:
1910: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported dim %" PetscInt_FMT " for transformation", dim);
1911: }
1912: }
1913: }
1914: } else {
1915: for (v = 0; v < Nv; ++v) {
1916: for (c = 0; c < Nc; ++c) DMPlex_MultTransposeReal_Internal(fegeom->invJ, dim, dE, 1, &vals[(v * Nc + c) * dE], &vals[(v * Nc + c) * dE]);
1917: }
1918: }
1919: /* Assume its a vector, otherwise assume its a bunch of scalars */
1920: if (Nc == 1 || Nc != dim) PetscFunctionReturn(PETSC_SUCCESS);
1921: switch (trans) {
1922: case IDENTITY_TRANSFORM:
1923: break;
1924: case COVARIANT_PIOLA_TRANSFORM: /* Covariant Piola mapping $\sigma^*(F) = J^{-T} F \circ \phi^{-1)$ */
1925: if (isInverse) {
1926: for (v = 0; v < Nv; ++v) {
1927: for (d = 0; d < dim; ++d) {
1928: switch (dim) {
1929: case 2:
1930: DMPlex_MultTranspose2DReal_Internal(fegeom->J, dim, &vals[v * Nc * dim + d], &vals[v * Nc * dim + d]);
1931: break;
1932: case 3:
1933: DMPlex_MultTranspose3DReal_Internal(fegeom->J, dim, &vals[v * Nc * dim + d], &vals[v * Nc * dim + d]);
1934: break;
1935: default:
1936: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported dim %" PetscInt_FMT " for transformation", dim);
1937: }
1938: }
1939: }
1940: } else {
1941: for (v = 0; v < Nv; ++v) {
1942: for (d = 0; d < dim; ++d) {
1943: switch (dim) {
1944: case 2:
1945: DMPlex_MultTranspose2DReal_Internal(fegeom->invJ, dim, &vals[v * Nc * dim + d], &vals[v * Nc * dim + d]);
1946: break;
1947: case 3:
1948: DMPlex_MultTranspose3DReal_Internal(fegeom->invJ, dim, &vals[v * Nc * dim + d], &vals[v * Nc * dim + d]);
1949: break;
1950: default:
1951: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported dim %" PetscInt_FMT " for transformation", dim);
1952: }
1953: }
1954: }
1955: }
1956: break;
1957: case CONTRAVARIANT_PIOLA_TRANSFORM: /* Contravariant Piola mapping $\sigma^*(F) = \frac{1}{|\det J|} J F \circ \phi^{-1}$ */
1958: if (isInverse) {
1959: for (v = 0; v < Nv; ++v) {
1960: for (d = 0; d < dim; ++d) {
1961: switch (dim) {
1962: case 2:
1963: DMPlex_Mult2DReal_Internal(fegeom->invJ, dim, &vals[v * Nc * dim + d], &vals[v * Nc * dim + d]);
1964: break;
1965: case 3:
1966: DMPlex_Mult3DReal_Internal(fegeom->invJ, dim, &vals[v * Nc * dim + d], &vals[v * Nc * dim + d]);
1967: break;
1968: default:
1969: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported dim %" PetscInt_FMT " for transformation", dim);
1970: }
1971: for (c = 0; c < Nc; ++c) vals[(v * Nc + c) * dim + d] *= fegeom->detJ[0];
1972: }
1973: }
1974: } else {
1975: for (v = 0; v < Nv; ++v) {
1976: for (d = 0; d < dim; ++d) {
1977: switch (dim) {
1978: case 2:
1979: DMPlex_Mult2DReal_Internal(fegeom->J, dim, &vals[v * Nc * dim + d], &vals[v * Nc * dim + d]);
1980: break;
1981: case 3:
1982: DMPlex_Mult3DReal_Internal(fegeom->J, dim, &vals[v * Nc * dim + d], &vals[v * Nc * dim + d]);
1983: break;
1984: default:
1985: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported dim %" PetscInt_FMT " for transformation", dim);
1986: }
1987: for (c = 0; c < Nc; ++c) vals[(v * Nc + c) * dim + d] /= fegeom->detJ[0];
1988: }
1989: }
1990: }
1991: break;
1992: }
1993: PetscFunctionReturn(PETSC_SUCCESS);
1994: }
1996: /*@C
1997: PetscDualSpaceTransformHessian - Transform the function Hessian values
1999: Input Parameters:
2000: + dsp - The `PetscDualSpace`
2001: . trans - The type of transform
2002: . isInverse - Flag to invert the transform
2003: . fegeom - The cell geometry
2004: . Nv - The number of function Hessian samples
2005: . Nc - The number of function components
2006: - vals - The function gradient values
2008: Output Parameter:
2009: . vals - The transformed function Hessian values
2011: Level: intermediate
2013: Note:
2014: This only handles transformations when the embedding dimension of the geometry in fegeom is the same as the reference dimension.
2016: .seealso: `PetscDualSpace`, `PetscDualSpaceTransform()`, `PetscDualSpacePullback()`, `PetscDualSpacePushforward()`, `PetscDualSpaceTransformType`
2017: @*/
2018: PetscErrorCode PetscDualSpaceTransformHessian(PetscDualSpace dsp, PetscDualSpaceTransformType trans, PetscBool isInverse, PetscFEGeom *fegeom, PetscInt Nv, PetscInt Nc, PetscScalar vals[])
2019: {
2020: const PetscInt dim = dsp->dm->dim, dE = fegeom->dimEmbed;
2021: PetscInt v, c;
2023: PetscFunctionBeginHot;
2027: #ifdef PETSC_USE_DEBUG
2028: PetscCheck(dE > 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Invalid embedding dimension %" PetscInt_FMT, dE);
2029: #endif
2030: /* Transform Hessian: J^{-T}_{ik} J^{-T}_{jl} H(f)_{kl} = J^{-T}_{ik} H(f)_{kl} J^{-1}_{lj} */
2031: if (dim == dE) {
2032: for (v = 0; v < Nv; ++v) {
2033: for (c = 0; c < Nc; ++c) {
2034: switch (dim) {
2035: case 1:
2036: vals[(v * Nc + c) * dim * dim] *= PetscSqr(fegeom->invJ[0]);
2037: break;
2038: case 2:
2039: DMPlex_PTAP2DReal_Internal(fegeom->invJ, &vals[(v * Nc + c) * dim * dim], &vals[(v * Nc + c) * dim * dim]);
2040: break;
2041: case 3:
2042: DMPlex_PTAP3DReal_Internal(fegeom->invJ, &vals[(v * Nc + c) * dim * dim], &vals[(v * Nc + c) * dim * dim]);
2043: break;
2044: default:
2045: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported dim %" PetscInt_FMT " for transformation", dim);
2046: }
2047: }
2048: }
2049: } else {
2050: for (v = 0; v < Nv; ++v) {
2051: for (c = 0; c < Nc; ++c) DMPlex_PTAPReal_Internal(fegeom->invJ, dim, dE, &vals[(v * Nc + c) * dE * dE], &vals[(v * Nc + c) * dE * dE]);
2052: }
2053: }
2054: /* Assume its a vector, otherwise assume its a bunch of scalars */
2055: if (Nc == 1 || Nc != dim) PetscFunctionReturn(PETSC_SUCCESS);
2056: switch (trans) {
2057: case IDENTITY_TRANSFORM:
2058: break;
2059: case COVARIANT_PIOLA_TRANSFORM: /* Covariant Piola mapping $\sigma^*(F) = J^{-T} F \circ \phi^{-1)$ */
2060: SETERRQ(PETSC_COMM_SELF, PETSC_ERR_SUP, "Piola mapping for Hessians not yet supported");
2061: case CONTRAVARIANT_PIOLA_TRANSFORM: /* Contravariant Piola mapping $\sigma^*(F) = \frac{1}{|\det J|} J F \circ \phi^{-1}$ */
2062: SETERRQ(PETSC_COMM_SELF, PETSC_ERR_SUP, "Piola mapping for Hessians not yet supported");
2063: }
2064: PetscFunctionReturn(PETSC_SUCCESS);
2065: }
2067: /*@C
2068: PetscDualSpacePullback - Transform the given functional so that it operates on real space, rather than the reference element. Operationally, this means that we map the function evaluations depending on continuity requirements of our finite element method.
2070: Input Parameters:
2071: + dsp - The `PetscDualSpace`
2072: . fegeom - The geometry for this cell
2073: . Nq - The number of function samples
2074: . Nc - The number of function components
2075: - pointEval - The function values
2077: Output Parameter:
2078: . pointEval - The transformed function values
2080: Level: advanced
2082: Notes:
2083: Functions transform in a complementary way (pushforward) to functionals, so that the scalar product is invariant. The type of transform is dependent on the associated k-simplex from the DeRahm complex.
2085: This only handles transformations when the embedding dimension of the geometry in fegeom is the same as the reference dimension.
2087: .seealso: `PetscDualSpace`, `PetscDualSpacePushforward()`, `PetscDualSpaceTransform()`, `PetscDualSpaceGetDeRahm()`
2088: @*/
2089: PetscErrorCode PetscDualSpacePullback(PetscDualSpace dsp, PetscFEGeom *fegeom, PetscInt Nq, PetscInt Nc, PetscScalar pointEval[])
2090: {
2091: PetscDualSpaceTransformType trans;
2092: PetscInt k;
2094: PetscFunctionBeginHot;
2098: /* The dualspace dofs correspond to some simplex in the DeRahm complex, which we label by k.
2099: This determines their transformation properties. */
2100: PetscCall(PetscDualSpaceGetDeRahm(dsp, &k));
2101: switch (k) {
2102: case 0: /* H^1 point evaluations */
2103: trans = IDENTITY_TRANSFORM;
2104: break;
2105: case 1: /* Hcurl preserves tangential edge traces */
2106: trans = COVARIANT_PIOLA_TRANSFORM;
2107: break;
2108: case 2:
2109: case 3: /* Hdiv preserve normal traces */
2110: trans = CONTRAVARIANT_PIOLA_TRANSFORM;
2111: break;
2112: default:
2113: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported simplex dim %" PetscInt_FMT " for transformation", k);
2114: }
2115: PetscCall(PetscDualSpaceTransform(dsp, trans, PETSC_TRUE, fegeom, Nq, Nc, pointEval));
2116: PetscFunctionReturn(PETSC_SUCCESS);
2117: }
2119: /*@C
2120: PetscDualSpacePushforward - Transform the given function so that it operates on real space, rather than the reference element. Operationally, this means that we map the function evaluations depending on continuity requirements of our finite element method.
2122: Input Parameters:
2123: + dsp - The `PetscDualSpace`
2124: . fegeom - The geometry for this cell
2125: . Nq - The number of function samples
2126: . Nc - The number of function components
2127: - pointEval - The function values
2129: Output Parameter:
2130: . pointEval - The transformed function values
2132: Level: advanced
2134: Notes:
2135: Functionals transform in a complementary way (pullback) to functions, so that the scalar product is invariant. The type of transform is dependent on the associated k-simplex from the DeRahm complex.
2137: This only handles transformations when the embedding dimension of the geometry in fegeom is the same as the reference dimension.
2139: .seealso: `PetscDualSpace`, `PetscDualSpacePullback()`, `PetscDualSpaceTransform()`, `PetscDualSpaceGetDeRahm()`
2140: @*/
2141: PetscErrorCode PetscDualSpacePushforward(PetscDualSpace dsp, PetscFEGeom *fegeom, PetscInt Nq, PetscInt Nc, PetscScalar pointEval[])
2142: {
2143: PetscDualSpaceTransformType trans;
2144: PetscInt k;
2146: PetscFunctionBeginHot;
2150: /* The dualspace dofs correspond to some simplex in the DeRahm complex, which we label by k.
2151: This determines their transformation properties. */
2152: PetscCall(PetscDualSpaceGetDeRahm(dsp, &k));
2153: switch (k) {
2154: case 0: /* H^1 point evaluations */
2155: trans = IDENTITY_TRANSFORM;
2156: break;
2157: case 1: /* Hcurl preserves tangential edge traces */
2158: trans = COVARIANT_PIOLA_TRANSFORM;
2159: break;
2160: case 2:
2161: case 3: /* Hdiv preserve normal traces */
2162: trans = CONTRAVARIANT_PIOLA_TRANSFORM;
2163: break;
2164: default:
2165: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported simplex dim %" PetscInt_FMT " for transformation", k);
2166: }
2167: PetscCall(PetscDualSpaceTransform(dsp, trans, PETSC_FALSE, fegeom, Nq, Nc, pointEval));
2168: PetscFunctionReturn(PETSC_SUCCESS);
2169: }
2171: /*@C
2172: PetscDualSpacePushforwardGradient - Transform the given function gradient so that it operates on real space, rather than the reference element. Operationally, this means that we map the function evaluations depending on continuity requirements of our finite element method.
2174: Input Parameters:
2175: + dsp - The `PetscDualSpace`
2176: . fegeom - The geometry for this cell
2177: . Nq - The number of function gradient samples
2178: . Nc - The number of function components
2179: - pointEval - The function gradient values
2181: Output Parameter:
2182: . pointEval - The transformed function gradient values
2184: Level: advanced
2186: Notes:
2187: Functionals transform in a complementary way (pullback) to functions, so that the scalar product is invariant. The type of transform is dependent on the associated k-simplex from the DeRahm complex.
2189: This only handles transformations when the embedding dimension of the geometry in fegeom is the same as the reference dimension.
2191: .seealso: `PetscDualSpace`, `PetscDualSpacePushforward()`, `PPetscDualSpacePullback()`, `PetscDualSpaceTransform()`, `PetscDualSpaceGetDeRahm()`
2192: @*/
2193: PetscErrorCode PetscDualSpacePushforwardGradient(PetscDualSpace dsp, PetscFEGeom *fegeom, PetscInt Nq, PetscInt Nc, PetscScalar pointEval[])
2194: {
2195: PetscDualSpaceTransformType trans;
2196: PetscInt k;
2198: PetscFunctionBeginHot;
2202: /* The dualspace dofs correspond to some simplex in the DeRahm complex, which we label by k.
2203: This determines their transformation properties. */
2204: PetscCall(PetscDualSpaceGetDeRahm(dsp, &k));
2205: switch (k) {
2206: case 0: /* H^1 point evaluations */
2207: trans = IDENTITY_TRANSFORM;
2208: break;
2209: case 1: /* Hcurl preserves tangential edge traces */
2210: trans = COVARIANT_PIOLA_TRANSFORM;
2211: break;
2212: case 2:
2213: case 3: /* Hdiv preserve normal traces */
2214: trans = CONTRAVARIANT_PIOLA_TRANSFORM;
2215: break;
2216: default:
2217: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported simplex dim %" PetscInt_FMT " for transformation", k);
2218: }
2219: PetscCall(PetscDualSpaceTransformGradient(dsp, trans, PETSC_FALSE, fegeom, Nq, Nc, pointEval));
2220: PetscFunctionReturn(PETSC_SUCCESS);
2221: }
2223: /*@C
2224: PetscDualSpacePushforwardHessian - Transform the given function Hessian so that it operates on real space, rather than the reference element. Operationally, this means that we map the function evaluations depending on continuity requirements of our finite element method.
2226: Input Parameters:
2227: + dsp - The `PetscDualSpace`
2228: . fegeom - The geometry for this cell
2229: . Nq - The number of function Hessian samples
2230: . Nc - The number of function components
2231: - pointEval - The function gradient values
2233: Output Parameter:
2234: . pointEval - The transformed function Hessian values
2236: Level: advanced
2238: Notes:
2239: Functionals transform in a complementary way (pullback) to functions, so that the scalar product is invariant. The type of transform is dependent on the associated k-simplex from the DeRahm complex.
2241: This only handles transformations when the embedding dimension of the geometry in fegeom is the same as the reference dimension.
2243: .seealso: `PetscDualSpace`, `PetscDualSpacePushforward()`, `PPetscDualSpacePullback()`, `PetscDualSpaceTransform()`, `PetscDualSpaceGetDeRahm()`
2244: @*/
2245: PetscErrorCode PetscDualSpacePushforwardHessian(PetscDualSpace dsp, PetscFEGeom *fegeom, PetscInt Nq, PetscInt Nc, PetscScalar pointEval[])
2246: {
2247: PetscDualSpaceTransformType trans;
2248: PetscInt k;
2250: PetscFunctionBeginHot;
2254: /* The dualspace dofs correspond to some simplex in the DeRahm complex, which we label by k.
2255: This determines their transformation properties. */
2256: PetscCall(PetscDualSpaceGetDeRahm(dsp, &k));
2257: switch (k) {
2258: case 0: /* H^1 point evaluations */
2259: trans = IDENTITY_TRANSFORM;
2260: break;
2261: case 1: /* Hcurl preserves tangential edge traces */
2262: trans = COVARIANT_PIOLA_TRANSFORM;
2263: break;
2264: case 2:
2265: case 3: /* Hdiv preserve normal traces */
2266: trans = CONTRAVARIANT_PIOLA_TRANSFORM;
2267: break;
2268: default:
2269: SETERRQ(PetscObjectComm((PetscObject)dsp), PETSC_ERR_ARG_OUTOFRANGE, "Unsupported simplex dim %" PetscInt_FMT " for transformation", k);
2270: }
2271: PetscCall(PetscDualSpaceTransformHessian(dsp, trans, PETSC_FALSE, fegeom, Nq, Nc, pointEval));
2272: PetscFunctionReturn(PETSC_SUCCESS);
2273: }