Actual source code: dt.c
1: /* Discretization tools */
3: #include <petscdt.h>
4: #include <petscblaslapack.h>
5: #include <petsc/private/petscimpl.h>
6: #include <petsc/private/dtimpl.h>
7: #include <petsc/private/petscfeimpl.h>
8: #include <petscviewer.h>
9: #include <petscdmplex.h>
10: #include <petscdmshell.h>
12: #if defined(PETSC_HAVE_MPFR)
13: #include <mpfr.h>
14: #endif
16: const char *const PetscDTNodeTypes_shifted[] = {"default", "gaussjacobi", "equispaced", "tanhsinh", "PETSCDTNODES_", NULL};
17: const char *const *const PetscDTNodeTypes = PetscDTNodeTypes_shifted + 1;
19: const char *const PetscDTSimplexQuadratureTypes_shifted[] = {"default", "conic", "minsym", "PETSCDTSIMPLEXQUAD_", NULL};
20: const char *const *const PetscDTSimplexQuadratureTypes = PetscDTSimplexQuadratureTypes_shifted + 1;
22: static PetscBool GolubWelschCite = PETSC_FALSE;
23: const char GolubWelschCitation[] = "@article{GolubWelsch1969,\n"
24: " author = {Golub and Welsch},\n"
25: " title = {Calculation of Quadrature Rules},\n"
26: " journal = {Math. Comp.},\n"
27: " volume = {23},\n"
28: " number = {106},\n"
29: " pages = {221--230},\n"
30: " year = {1969}\n}\n";
32: /* Numerical tests in src/dm/dt/tests/ex1.c show that when computing the nodes and weights of Gauss-Jacobi
33: quadrature rules:
35: - in double precision, Newton's method and Golub & Welsch both work for moderate degrees (< 100),
36: - in single precision, Newton's method starts producing incorrect roots around n = 15, but
37: the weights from Golub & Welsch become a problem before then: they produces errors
38: in computing the Jacobi-polynomial Gram matrix around n = 6.
40: So we default to Newton's method (required fewer dependencies) */
41: PetscBool PetscDTGaussQuadratureNewton_Internal = PETSC_TRUE;
43: PetscClassId PETSCQUADRATURE_CLASSID = 0;
45: /*@
46: PetscQuadratureCreate - Create a `PetscQuadrature` object
48: Collective
50: Input Parameter:
51: . comm - The communicator for the `PetscQuadrature` object
53: Output Parameter:
54: . q - The `PetscQuadrature` object
56: Level: beginner
58: .seealso: `PetscQuadrature`, `Petscquadraturedestroy()`, `PetscQuadratureGetData()`
59: @*/
60: PetscErrorCode PetscQuadratureCreate(MPI_Comm comm, PetscQuadrature *q)
61: {
62: PetscFunctionBegin;
63: PetscAssertPointer(q, 2);
64: PetscCall(DMInitializePackage());
65: PetscCall(PetscHeaderCreate(*q, PETSCQUADRATURE_CLASSID, "PetscQuadrature", "Quadrature", "DT", comm, PetscQuadratureDestroy, PetscQuadratureView));
66: (*q)->ct = DM_POLYTOPE_UNKNOWN;
67: (*q)->dim = -1;
68: (*q)->Nc = 1;
69: (*q)->order = -1;
70: (*q)->numPoints = 0;
71: (*q)->points = NULL;
72: (*q)->weights = NULL;
73: PetscFunctionReturn(PETSC_SUCCESS);
74: }
76: /*@
77: PetscQuadratureDuplicate - Create a deep copy of the `PetscQuadrature` object
79: Collective
81: Input Parameter:
82: . q - The `PetscQuadrature` object
84: Output Parameter:
85: . r - The new `PetscQuadrature` object
87: Level: beginner
89: .seealso: `PetscQuadrature`, `PetscQuadratureCreate()`, `PetscQuadratureDestroy()`, `PetscQuadratureGetData()`
90: @*/
91: PetscErrorCode PetscQuadratureDuplicate(PetscQuadrature q, PetscQuadrature *r)
92: {
93: DMPolytopeType ct;
94: PetscInt order, dim, Nc, Nq;
95: const PetscReal *points, *weights;
96: PetscReal *p, *w;
98: PetscFunctionBegin;
99: PetscAssertPointer(q, 1);
100: PetscCall(PetscQuadratureCreate(PetscObjectComm((PetscObject)q), r));
101: PetscCall(PetscQuadratureGetCellType(q, &ct));
102: PetscCall(PetscQuadratureSetCellType(*r, ct));
103: PetscCall(PetscQuadratureGetOrder(q, &order));
104: PetscCall(PetscQuadratureSetOrder(*r, order));
105: PetscCall(PetscQuadratureGetData(q, &dim, &Nc, &Nq, &points, &weights));
106: PetscCall(PetscMalloc1(Nq * dim, &p));
107: PetscCall(PetscMalloc1(Nq * Nc, &w));
108: PetscCall(PetscArraycpy(p, points, Nq * dim));
109: PetscCall(PetscArraycpy(w, weights, Nc * Nq));
110: PetscCall(PetscQuadratureSetData(*r, dim, Nc, Nq, p, w));
111: PetscFunctionReturn(PETSC_SUCCESS);
112: }
114: /*@
115: PetscQuadratureDestroy - Destroys a `PetscQuadrature` object
117: Collective
119: Input Parameter:
120: . q - The `PetscQuadrature` object
122: Level: beginner
124: .seealso: `PetscQuadrature`, `PetscQuadratureCreate()`, `PetscQuadratureGetData()`
125: @*/
126: PetscErrorCode PetscQuadratureDestroy(PetscQuadrature *q)
127: {
128: PetscFunctionBegin;
129: if (!*q) PetscFunctionReturn(PETSC_SUCCESS);
131: if (--((PetscObject)(*q))->refct > 0) {
132: *q = NULL;
133: PetscFunctionReturn(PETSC_SUCCESS);
134: }
135: PetscCall(PetscFree((*q)->points));
136: PetscCall(PetscFree((*q)->weights));
137: PetscCall(PetscHeaderDestroy(q));
138: PetscFunctionReturn(PETSC_SUCCESS);
139: }
141: /*@
142: PetscQuadratureGetCellType - Return the cell type of the integration domain
144: Not Collective
146: Input Parameter:
147: . q - The `PetscQuadrature` object
149: Output Parameter:
150: . ct - The cell type of the integration domain
152: Level: intermediate
154: .seealso: `PetscQuadrature`, `PetscQuadratureSetCellType()`, `PetscQuadratureGetData()`, `PetscQuadratureSetData()`
155: @*/
156: PetscErrorCode PetscQuadratureGetCellType(PetscQuadrature q, DMPolytopeType *ct)
157: {
158: PetscFunctionBegin;
160: PetscAssertPointer(ct, 2);
161: *ct = q->ct;
162: PetscFunctionReturn(PETSC_SUCCESS);
163: }
165: /*@
166: PetscQuadratureSetCellType - Set the cell type of the integration domain
168: Not Collective
170: Input Parameters:
171: + q - The `PetscQuadrature` object
172: - ct - The cell type of the integration domain
174: Level: intermediate
176: .seealso: `PetscQuadrature`, `PetscQuadratureGetCellType()`, `PetscQuadratureGetData()`, `PetscQuadratureSetData()`
177: @*/
178: PetscErrorCode PetscQuadratureSetCellType(PetscQuadrature q, DMPolytopeType ct)
179: {
180: PetscFunctionBegin;
182: q->ct = ct;
183: PetscFunctionReturn(PETSC_SUCCESS);
184: }
186: /*@
187: PetscQuadratureGetOrder - Return the order of the method in the `PetscQuadrature`
189: Not Collective
191: Input Parameter:
192: . q - The `PetscQuadrature` object
194: Output Parameter:
195: . order - The order of the quadrature, i.e. the highest degree polynomial that is exactly integrated
197: Level: intermediate
199: .seealso: `PetscQuadrature`, `PetscQuadratureSetOrder()`, `PetscQuadratureGetData()`, `PetscQuadratureSetData()`
200: @*/
201: PetscErrorCode PetscQuadratureGetOrder(PetscQuadrature q, PetscInt *order)
202: {
203: PetscFunctionBegin;
205: PetscAssertPointer(order, 2);
206: *order = q->order;
207: PetscFunctionReturn(PETSC_SUCCESS);
208: }
210: /*@
211: PetscQuadratureSetOrder - Set the order of the method in the `PetscQuadrature`
213: Not Collective
215: Input Parameters:
216: + q - The `PetscQuadrature` object
217: - order - The order of the quadrature, i.e. the highest degree polynomial that is exactly integrated
219: Level: intermediate
221: .seealso: `PetscQuadrature`, `PetscQuadratureGetOrder()`, `PetscQuadratureGetData()`, `PetscQuadratureSetData()`
222: @*/
223: PetscErrorCode PetscQuadratureSetOrder(PetscQuadrature q, PetscInt order)
224: {
225: PetscFunctionBegin;
227: q->order = order;
228: PetscFunctionReturn(PETSC_SUCCESS);
229: }
231: /*@
232: PetscQuadratureGetNumComponents - Return the number of components for functions to be integrated
234: Not Collective
236: Input Parameter:
237: . q - The `PetscQuadrature` object
239: Output Parameter:
240: . Nc - The number of components
242: Level: intermediate
244: Note:
245: We are performing an integral $\int f(x) w(x) dx$, where both $f$ and $w$ (the weight) have `Nc` components.
247: .seealso: `PetscQuadrature`, `PetscQuadratureSetNumComponents()`, `PetscQuadratureGetData()`, `PetscQuadratureSetData()`
248: @*/
249: PetscErrorCode PetscQuadratureGetNumComponents(PetscQuadrature q, PetscInt *Nc)
250: {
251: PetscFunctionBegin;
253: PetscAssertPointer(Nc, 2);
254: *Nc = q->Nc;
255: PetscFunctionReturn(PETSC_SUCCESS);
256: }
258: /*@
259: PetscQuadratureSetNumComponents - Sets the number of components for functions to be integrated
261: Not Collective
263: Input Parameters:
264: + q - The `PetscQuadrature` object
265: - Nc - The number of components
267: Level: intermediate
269: Note:
270: We are performing an integral $\int f(x) w(x) dx$, where both $f$ and $w$ (the weight) have `Nc` components.
272: .seealso: `PetscQuadrature`, `PetscQuadratureGetNumComponents()`, `PetscQuadratureGetData()`, `PetscQuadratureSetData()`
273: @*/
274: PetscErrorCode PetscQuadratureSetNumComponents(PetscQuadrature q, PetscInt Nc)
275: {
276: PetscFunctionBegin;
278: q->Nc = Nc;
279: PetscFunctionReturn(PETSC_SUCCESS);
280: }
282: /*@C
283: PetscQuadratureGetData - Returns the data defining the `PetscQuadrature`
285: Not Collective
287: Input Parameter:
288: . q - The `PetscQuadrature` object
290: Output Parameters:
291: + dim - The spatial dimension
292: . Nc - The number of components
293: . npoints - The number of quadrature points
294: . points - The coordinates of each quadrature point
295: - weights - The weight of each quadrature point
297: Level: intermediate
299: Fortran Note:
300: Call `PetscQuadratureRestoreData()` when you are done with the data
302: .seealso: `PetscQuadrature`, `PetscQuadratureCreate()`, `PetscQuadratureSetData()`
303: @*/
304: PetscErrorCode PetscQuadratureGetData(PetscQuadrature q, PetscInt *dim, PetscInt *Nc, PetscInt *npoints, const PetscReal *points[], const PetscReal *weights[])
305: {
306: PetscFunctionBegin;
308: if (dim) {
309: PetscAssertPointer(dim, 2);
310: *dim = q->dim;
311: }
312: if (Nc) {
313: PetscAssertPointer(Nc, 3);
314: *Nc = q->Nc;
315: }
316: if (npoints) {
317: PetscAssertPointer(npoints, 4);
318: *npoints = q->numPoints;
319: }
320: if (points) {
321: PetscAssertPointer(points, 5);
322: *points = q->points;
323: }
324: if (weights) {
325: PetscAssertPointer(weights, 6);
326: *weights = q->weights;
327: }
328: PetscFunctionReturn(PETSC_SUCCESS);
329: }
331: /*@
332: PetscQuadratureEqual - determine whether two quadratures are equivalent
334: Input Parameters:
335: + A - A `PetscQuadrature` object
336: - B - Another `PetscQuadrature` object
338: Output Parameter:
339: . equal - `PETSC_TRUE` if the quadratures are the same
341: Level: intermediate
343: .seealso: `PetscQuadrature`, `PetscQuadratureCreate()`
344: @*/
345: PetscErrorCode PetscQuadratureEqual(PetscQuadrature A, PetscQuadrature B, PetscBool *equal)
346: {
347: PetscFunctionBegin;
350: PetscAssertPointer(equal, 3);
351: *equal = PETSC_FALSE;
352: if (A->ct != B->ct || A->dim != B->dim || A->Nc != B->Nc || A->order != B->order || A->numPoints != B->numPoints) PetscFunctionReturn(PETSC_SUCCESS);
353: for (PetscInt i = 0; i < A->numPoints * A->dim; i++) {
354: if (PetscAbsReal(A->points[i] - B->points[i]) > PETSC_SMALL) PetscFunctionReturn(PETSC_SUCCESS);
355: }
356: if (!A->weights && !B->weights) {
357: *equal = PETSC_TRUE;
358: PetscFunctionReturn(PETSC_SUCCESS);
359: }
360: if (A->weights && B->weights) {
361: for (PetscInt i = 0; i < A->numPoints; i++) {
362: if (PetscAbsReal(A->weights[i] - B->weights[i]) > PETSC_SMALL) PetscFunctionReturn(PETSC_SUCCESS);
363: }
364: *equal = PETSC_TRUE;
365: }
366: PetscFunctionReturn(PETSC_SUCCESS);
367: }
369: static PetscErrorCode PetscDTJacobianInverse_Internal(PetscInt m, PetscInt n, const PetscReal J[], PetscReal Jinv[])
370: {
371: PetscScalar *Js, *Jinvs;
372: PetscInt i, j, k;
373: PetscBLASInt bm, bn, info;
375: PetscFunctionBegin;
376: if (!m || !n) PetscFunctionReturn(PETSC_SUCCESS);
377: PetscCall(PetscBLASIntCast(m, &bm));
378: PetscCall(PetscBLASIntCast(n, &bn));
379: #if defined(PETSC_USE_COMPLEX)
380: PetscCall(PetscMalloc2(m * n, &Js, m * n, &Jinvs));
381: for (i = 0; i < m * n; i++) Js[i] = J[i];
382: #else
383: Js = (PetscReal *)J;
384: Jinvs = Jinv;
385: #endif
386: if (m == n) {
387: PetscBLASInt *pivots;
388: PetscScalar *W;
390: PetscCall(PetscMalloc2(m, &pivots, m, &W));
392: PetscCall(PetscArraycpy(Jinvs, Js, m * m));
393: PetscCallBLAS("LAPACKgetrf", LAPACKgetrf_(&bm, &bm, Jinvs, &bm, pivots, &info));
394: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_LIB, "Error returned from LAPACKgetrf %" PetscInt_FMT, (PetscInt)info);
395: PetscCallBLAS("LAPACKgetri", LAPACKgetri_(&bm, Jinvs, &bm, pivots, W, &bm, &info));
396: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_LIB, "Error returned from LAPACKgetri %" PetscInt_FMT, (PetscInt)info);
397: PetscCall(PetscFree2(pivots, W));
398: } else if (m < n) {
399: PetscScalar *JJT;
400: PetscBLASInt *pivots;
401: PetscScalar *W;
403: PetscCall(PetscMalloc1(m * m, &JJT));
404: PetscCall(PetscMalloc2(m, &pivots, m, &W));
405: for (i = 0; i < m; i++) {
406: for (j = 0; j < m; j++) {
407: PetscScalar val = 0.;
409: for (k = 0; k < n; k++) val += Js[i * n + k] * Js[j * n + k];
410: JJT[i * m + j] = val;
411: }
412: }
414: PetscCallBLAS("LAPACKgetrf", LAPACKgetrf_(&bm, &bm, JJT, &bm, pivots, &info));
415: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_LIB, "Error returned from LAPACKgetrf %" PetscInt_FMT, (PetscInt)info);
416: PetscCallBLAS("LAPACKgetri", LAPACKgetri_(&bm, JJT, &bm, pivots, W, &bm, &info));
417: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_LIB, "Error returned from LAPACKgetri %" PetscInt_FMT, (PetscInt)info);
418: for (i = 0; i < n; i++) {
419: for (j = 0; j < m; j++) {
420: PetscScalar val = 0.;
422: for (k = 0; k < m; k++) val += Js[k * n + i] * JJT[k * m + j];
423: Jinvs[i * m + j] = val;
424: }
425: }
426: PetscCall(PetscFree2(pivots, W));
427: PetscCall(PetscFree(JJT));
428: } else {
429: PetscScalar *JTJ;
430: PetscBLASInt *pivots;
431: PetscScalar *W;
433: PetscCall(PetscMalloc1(n * n, &JTJ));
434: PetscCall(PetscMalloc2(n, &pivots, n, &W));
435: for (i = 0; i < n; i++) {
436: for (j = 0; j < n; j++) {
437: PetscScalar val = 0.;
439: for (k = 0; k < m; k++) val += Js[k * n + i] * Js[k * n + j];
440: JTJ[i * n + j] = val;
441: }
442: }
444: PetscCallBLAS("LAPACKgetrf", LAPACKgetrf_(&bn, &bn, JTJ, &bn, pivots, &info));
445: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_LIB, "Error returned from LAPACKgetrf %" PetscInt_FMT, (PetscInt)info);
446: PetscCallBLAS("LAPACKgetri", LAPACKgetri_(&bn, JTJ, &bn, pivots, W, &bn, &info));
447: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_LIB, "Error returned from LAPACKgetri %" PetscInt_FMT, (PetscInt)info);
448: for (i = 0; i < n; i++) {
449: for (j = 0; j < m; j++) {
450: PetscScalar val = 0.;
452: for (k = 0; k < n; k++) val += JTJ[i * n + k] * Js[j * n + k];
453: Jinvs[i * m + j] = val;
454: }
455: }
456: PetscCall(PetscFree2(pivots, W));
457: PetscCall(PetscFree(JTJ));
458: }
459: #if defined(PETSC_USE_COMPLEX)
460: for (i = 0; i < m * n; i++) Jinv[i] = PetscRealPart(Jinvs[i]);
461: PetscCall(PetscFree2(Js, Jinvs));
462: #endif
463: PetscFunctionReturn(PETSC_SUCCESS);
464: }
466: /*@
467: PetscQuadraturePushForward - Push forward a quadrature functional under an affine transformation.
469: Collective
471: Input Parameters:
472: + q - the quadrature functional
473: . imageDim - the dimension of the image of the transformation
474: . origin - a point in the original space
475: . originImage - the image of the origin under the transformation
476: . J - the Jacobian of the image: an [imageDim x dim] matrix in row major order
477: - formDegree - transform the quadrature weights as k-forms of this form degree (if the number of components is a multiple of (dim choose `formDegree`),
478: it is assumed that they represent multiple k-forms) [see `PetscDTAltVPullback()` for interpretation of `formDegree`]
480: Output Parameter:
481: . Jinvstarq - a quadrature rule where each point is the image of a point in the original quadrature rule, and where the k-form weights have
482: been pulled-back by the pseudoinverse of `J` to the k-form weights in the image space.
484: Level: intermediate
486: Note:
487: The new quadrature rule will have a different number of components if spaces have different dimensions.
488: For example, pushing a 2-form forward from a two dimensional space to a three dimensional space changes the number of components from 1 to 3.
490: .seealso: `PetscQuadrature`, `PetscDTAltVPullback()`, `PetscDTAltVPullbackMatrix()`
491: @*/
492: PetscErrorCode PetscQuadraturePushForward(PetscQuadrature q, PetscInt imageDim, const PetscReal origin[], const PetscReal originImage[], const PetscReal J[], PetscInt formDegree, PetscQuadrature *Jinvstarq)
493: {
494: PetscInt dim, Nc, imageNc, formSize, Ncopies, imageFormSize, Npoints, pt, i, j, c;
495: const PetscReal *points;
496: const PetscReal *weights;
497: PetscReal *imagePoints, *imageWeights;
498: PetscReal *Jinv;
499: PetscReal *Jinvstar;
501: PetscFunctionBegin;
503: PetscCheck(imageDim >= PetscAbsInt(formDegree), PetscObjectComm((PetscObject)q), PETSC_ERR_ARG_INCOMP, "Cannot represent a %" PetscInt_FMT "-form in %" PetscInt_FMT " dimensions", PetscAbsInt(formDegree), imageDim);
504: PetscCall(PetscQuadratureGetData(q, &dim, &Nc, &Npoints, &points, &weights));
505: PetscCall(PetscDTBinomialInt(dim, PetscAbsInt(formDegree), &formSize));
506: PetscCheck(Nc % formSize == 0, PetscObjectComm((PetscObject)q), PETSC_ERR_ARG_INCOMP, "Number of components %" PetscInt_FMT " is not a multiple of formSize %" PetscInt_FMT, Nc, formSize);
507: Ncopies = Nc / formSize;
508: PetscCall(PetscDTBinomialInt(imageDim, PetscAbsInt(formDegree), &imageFormSize));
509: imageNc = Ncopies * imageFormSize;
510: PetscCall(PetscMalloc1(Npoints * imageDim, &imagePoints));
511: PetscCall(PetscMalloc1(Npoints * imageNc, &imageWeights));
512: PetscCall(PetscMalloc2(imageDim * dim, &Jinv, formSize * imageFormSize, &Jinvstar));
513: PetscCall(PetscDTJacobianInverse_Internal(imageDim, dim, J, Jinv));
514: PetscCall(PetscDTAltVPullbackMatrix(imageDim, dim, Jinv, formDegree, Jinvstar));
515: for (pt = 0; pt < Npoints; pt++) {
516: const PetscReal *point = &points[pt * dim];
517: PetscReal *imagePoint = &imagePoints[pt * imageDim];
519: for (i = 0; i < imageDim; i++) {
520: PetscReal val = originImage[i];
522: for (j = 0; j < dim; j++) val += J[i * dim + j] * (point[j] - origin[j]);
523: imagePoint[i] = val;
524: }
525: for (c = 0; c < Ncopies; c++) {
526: const PetscReal *form = &weights[pt * Nc + c * formSize];
527: PetscReal *imageForm = &imageWeights[pt * imageNc + c * imageFormSize];
529: for (i = 0; i < imageFormSize; i++) {
530: PetscReal val = 0.;
532: for (j = 0; j < formSize; j++) val += Jinvstar[i * formSize + j] * form[j];
533: imageForm[i] = val;
534: }
535: }
536: }
537: PetscCall(PetscQuadratureCreate(PetscObjectComm((PetscObject)q), Jinvstarq));
538: PetscCall(PetscQuadratureSetData(*Jinvstarq, imageDim, imageNc, Npoints, imagePoints, imageWeights));
539: PetscCall(PetscFree2(Jinv, Jinvstar));
540: PetscFunctionReturn(PETSC_SUCCESS);
541: }
543: /*@C
544: PetscQuadratureSetData - Sets the data defining the quadrature
546: Not Collective
548: Input Parameters:
549: + q - The `PetscQuadrature` object
550: . dim - The spatial dimension
551: . Nc - The number of components
552: . npoints - The number of quadrature points
553: . points - The coordinates of each quadrature point
554: - weights - The weight of each quadrature point
556: Level: intermediate
558: Note:
559: This routine owns the references to points and weights, so they must be allocated using `PetscMalloc()` and the user should not free them.
561: .seealso: `PetscQuadrature`, `PetscQuadratureCreate()`, `PetscQuadratureGetData()`
562: @*/
563: PetscErrorCode PetscQuadratureSetData(PetscQuadrature q, PetscInt dim, PetscInt Nc, PetscInt npoints, const PetscReal points[], const PetscReal weights[])
564: {
565: PetscFunctionBegin;
567: if (dim >= 0) q->dim = dim;
568: if (Nc >= 0) q->Nc = Nc;
569: if (npoints >= 0) q->numPoints = npoints;
570: if (points) {
571: PetscAssertPointer(points, 5);
572: q->points = points;
573: }
574: if (weights) {
575: PetscAssertPointer(weights, 6);
576: q->weights = weights;
577: }
578: PetscFunctionReturn(PETSC_SUCCESS);
579: }
581: static PetscErrorCode PetscQuadratureView_Ascii(PetscQuadrature quad, PetscViewer v)
582: {
583: PetscInt q, d, c;
584: PetscViewerFormat format;
586: PetscFunctionBegin;
587: if (quad->Nc > 1)
588: PetscCall(PetscViewerASCIIPrintf(v, "Quadrature on a %s of order %" PetscInt_FMT " on %" PetscInt_FMT " points (dim %" PetscInt_FMT ") with %" PetscInt_FMT " components\n", DMPolytopeTypes[quad->ct], quad->order, quad->numPoints, quad->dim, quad->Nc));
589: else PetscCall(PetscViewerASCIIPrintf(v, "Quadrature on a %s of order %" PetscInt_FMT " on %" PetscInt_FMT " points (dim %" PetscInt_FMT ")\n", DMPolytopeTypes[quad->ct], quad->order, quad->numPoints, quad->dim));
590: PetscCall(PetscViewerGetFormat(v, &format));
591: if (format != PETSC_VIEWER_ASCII_INFO_DETAIL) PetscFunctionReturn(PETSC_SUCCESS);
592: for (q = 0; q < quad->numPoints; ++q) {
593: PetscCall(PetscViewerASCIIPrintf(v, "p%" PetscInt_FMT " (", q));
594: PetscCall(PetscViewerASCIIUseTabs(v, PETSC_FALSE));
595: for (d = 0; d < quad->dim; ++d) {
596: if (d) PetscCall(PetscViewerASCIIPrintf(v, ", "));
597: PetscCall(PetscViewerASCIIPrintf(v, "%+g", (double)quad->points[q * quad->dim + d]));
598: }
599: PetscCall(PetscViewerASCIIPrintf(v, ") "));
600: if (quad->Nc > 1) PetscCall(PetscViewerASCIIPrintf(v, "w%" PetscInt_FMT " (", q));
601: for (c = 0; c < quad->Nc; ++c) {
602: if (c) PetscCall(PetscViewerASCIIPrintf(v, ", "));
603: PetscCall(PetscViewerASCIIPrintf(v, "%+g", (double)quad->weights[q * quad->Nc + c]));
604: }
605: if (quad->Nc > 1) PetscCall(PetscViewerASCIIPrintf(v, ")"));
606: PetscCall(PetscViewerASCIIPrintf(v, "\n"));
607: PetscCall(PetscViewerASCIIUseTabs(v, PETSC_TRUE));
608: }
609: PetscFunctionReturn(PETSC_SUCCESS);
610: }
612: /*@C
613: PetscQuadratureView - View a `PetscQuadrature` object
615: Collective
617: Input Parameters:
618: + quad - The `PetscQuadrature` object
619: - viewer - The `PetscViewer` object
621: Level: beginner
623: .seealso: `PetscQuadrature`, `PetscViewer`, `PetscQuadratureCreate()`, `PetscQuadratureGetData()`
624: @*/
625: PetscErrorCode PetscQuadratureView(PetscQuadrature quad, PetscViewer viewer)
626: {
627: PetscBool iascii;
629: PetscFunctionBegin;
632: if (!viewer) PetscCall(PetscViewerASCIIGetStdout(PetscObjectComm((PetscObject)quad), &viewer));
633: PetscCall(PetscObjectTypeCompare((PetscObject)viewer, PETSCVIEWERASCII, &iascii));
634: PetscCall(PetscViewerASCIIPushTab(viewer));
635: if (iascii) PetscCall(PetscQuadratureView_Ascii(quad, viewer));
636: PetscCall(PetscViewerASCIIPopTab(viewer));
637: PetscFunctionReturn(PETSC_SUCCESS);
638: }
640: /*@C
641: PetscQuadratureExpandComposite - Return a quadrature over the composite element, which has the original quadrature in each subelement
643: Not Collective; No Fortran Support
645: Input Parameters:
646: + q - The original `PetscQuadrature`
647: . numSubelements - The number of subelements the original element is divided into
648: . v0 - An array of the initial points for each subelement
649: - jac - An array of the Jacobian mappings from the reference to each subelement
651: Output Parameter:
652: . qref - The dimension
654: Level: intermediate
656: Note:
657: Together `v0` and `jac` define an affine mapping from the original reference element to each subelement
659: .seealso: `PetscQuadrature`, `PetscFECreate()`, `PetscSpaceGetDimension()`, `PetscDualSpaceGetDimension()`
660: @*/
661: PetscErrorCode PetscQuadratureExpandComposite(PetscQuadrature q, PetscInt numSubelements, const PetscReal v0[], const PetscReal jac[], PetscQuadrature *qref)
662: {
663: DMPolytopeType ct;
664: const PetscReal *points, *weights;
665: PetscReal *pointsRef, *weightsRef;
666: PetscInt dim, Nc, order, npoints, npointsRef, c, p, cp, d, e;
668: PetscFunctionBegin;
670: PetscAssertPointer(v0, 3);
671: PetscAssertPointer(jac, 4);
672: PetscAssertPointer(qref, 5);
673: PetscCall(PetscQuadratureCreate(PETSC_COMM_SELF, qref));
674: PetscCall(PetscQuadratureGetCellType(q, &ct));
675: PetscCall(PetscQuadratureGetOrder(q, &order));
676: PetscCall(PetscQuadratureGetData(q, &dim, &Nc, &npoints, &points, &weights));
677: npointsRef = npoints * numSubelements;
678: PetscCall(PetscMalloc1(npointsRef * dim, &pointsRef));
679: PetscCall(PetscMalloc1(npointsRef * Nc, &weightsRef));
680: for (c = 0; c < numSubelements; ++c) {
681: for (p = 0; p < npoints; ++p) {
682: for (d = 0; d < dim; ++d) {
683: pointsRef[(c * npoints + p) * dim + d] = v0[c * dim + d];
684: for (e = 0; e < dim; ++e) pointsRef[(c * npoints + p) * dim + d] += jac[(c * dim + d) * dim + e] * (points[p * dim + e] + 1.0);
685: }
686: /* Could also use detJ here */
687: for (cp = 0; cp < Nc; ++cp) weightsRef[(c * npoints + p) * Nc + cp] = weights[p * Nc + cp] / numSubelements;
688: }
689: }
690: PetscCall(PetscQuadratureSetCellType(*qref, ct));
691: PetscCall(PetscQuadratureSetOrder(*qref, order));
692: PetscCall(PetscQuadratureSetData(*qref, dim, Nc, npointsRef, pointsRef, weightsRef));
693: PetscFunctionReturn(PETSC_SUCCESS);
694: }
696: /* Compute the coefficients for the Jacobi polynomial recurrence,
698: J^{a,b}_n(x) = (cnm1 + cnm1x * x) * J^{a,b}_{n-1}(x) - cnm2 * J^{a,b}_{n-2}(x).
699: */
700: #define PetscDTJacobiRecurrence_Internal(n, a, b, cnm1, cnm1x, cnm2) \
701: do { \
702: PetscReal _a = (a); \
703: PetscReal _b = (b); \
704: PetscReal _n = (n); \
705: if (n == 1) { \
706: (cnm1) = (_a - _b) * 0.5; \
707: (cnm1x) = (_a + _b + 2.) * 0.5; \
708: (cnm2) = 0.; \
709: } else { \
710: PetscReal _2n = _n + _n; \
711: PetscReal _d = (_2n * (_n + _a + _b) * (_2n + _a + _b - 2)); \
712: PetscReal _n1 = (_2n + _a + _b - 1.) * (_a * _a - _b * _b); \
713: PetscReal _n1x = (_2n + _a + _b - 1.) * (_2n + _a + _b) * (_2n + _a + _b - 2); \
714: PetscReal _n2 = 2. * ((_n + _a - 1.) * (_n + _b - 1.) * (_2n + _a + _b)); \
715: (cnm1) = _n1 / _d; \
716: (cnm1x) = _n1x / _d; \
717: (cnm2) = _n2 / _d; \
718: } \
719: } while (0)
721: /*@
722: PetscDTJacobiNorm - Compute the weighted L2 norm of a Jacobi polynomial.
724: $\| P^{\alpha,\beta}_n \|_{\alpha,\beta}^2 = \int_{-1}^1 (1 + x)^{\alpha} (1 - x)^{\beta} P^{\alpha,\beta}_n (x)^2 dx.$
726: Input Parameters:
727: + alpha - the left exponent > -1
728: . beta - the right exponent > -1
729: - n - the polynomial degree
731: Output Parameter:
732: . norm - the weighted L2 norm
734: Level: beginner
736: .seealso: `PetscQuadrature`, `PetscDTJacobiEval()`
737: @*/
738: PetscErrorCode PetscDTJacobiNorm(PetscReal alpha, PetscReal beta, PetscInt n, PetscReal *norm)
739: {
740: PetscReal twoab1;
741: PetscReal gr;
743: PetscFunctionBegin;
744: PetscCheck(alpha > -1., PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Exponent alpha %g <= -1. invalid", (double)alpha);
745: PetscCheck(beta > -1., PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Exponent beta %g <= -1. invalid", (double)beta);
746: PetscCheck(n >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "n %" PetscInt_FMT " < 0 invalid", n);
747: twoab1 = PetscPowReal(2., alpha + beta + 1.);
748: #if defined(PETSC_HAVE_LGAMMA)
749: if (!n) {
750: gr = PetscExpReal(PetscLGamma(alpha + 1.) + PetscLGamma(beta + 1.) - PetscLGamma(alpha + beta + 2.));
751: } else {
752: gr = PetscExpReal(PetscLGamma(n + alpha + 1.) + PetscLGamma(n + beta + 1.) - (PetscLGamma(n + 1.) + PetscLGamma(n + alpha + beta + 1.))) / (n + n + alpha + beta + 1.);
753: }
754: #else
755: {
756: PetscInt alphai = (PetscInt)alpha;
757: PetscInt betai = (PetscInt)beta;
758: PetscInt i;
760: gr = n ? (1. / (n + n + alpha + beta + 1.)) : 1.;
761: if ((PetscReal)alphai == alpha) {
762: if (!n) {
763: for (i = 0; i < alphai; i++) gr *= (i + 1.) / (beta + i + 1.);
764: gr /= (alpha + beta + 1.);
765: } else {
766: for (i = 0; i < alphai; i++) gr *= (n + i + 1.) / (n + beta + i + 1.);
767: }
768: } else if ((PetscReal)betai == beta) {
769: if (!n) {
770: for (i = 0; i < betai; i++) gr *= (i + 1.) / (alpha + i + 2.);
771: gr /= (alpha + beta + 1.);
772: } else {
773: for (i = 0; i < betai; i++) gr *= (n + i + 1.) / (n + alpha + i + 1.);
774: }
775: } else SETERRQ(PETSC_COMM_SELF, PETSC_ERR_SUP, "lgamma() - math routine is unavailable.");
776: }
777: #endif
778: *norm = PetscSqrtReal(twoab1 * gr);
779: PetscFunctionReturn(PETSC_SUCCESS);
780: }
782: static PetscErrorCode PetscDTJacobiEval_Internal(PetscInt npoints, PetscReal a, PetscReal b, PetscInt k, const PetscReal *points, PetscInt ndegree, const PetscInt *degrees, PetscReal *p)
783: {
784: PetscReal ak, bk;
785: PetscReal abk1;
786: PetscInt i, l, maxdegree;
788: PetscFunctionBegin;
789: maxdegree = degrees[ndegree - 1] - k;
790: ak = a + k;
791: bk = b + k;
792: abk1 = a + b + k + 1.;
793: if (maxdegree < 0) {
794: for (i = 0; i < npoints; i++)
795: for (l = 0; l < ndegree; l++) p[i * ndegree + l] = 0.;
796: PetscFunctionReturn(PETSC_SUCCESS);
797: }
798: for (i = 0; i < npoints; i++) {
799: PetscReal pm1, pm2, x;
800: PetscReal cnm1, cnm1x, cnm2;
801: PetscInt j, m;
803: x = points[i];
804: pm2 = 1.;
805: PetscDTJacobiRecurrence_Internal(1, ak, bk, cnm1, cnm1x, cnm2);
806: pm1 = (cnm1 + cnm1x * x);
807: l = 0;
808: while (l < ndegree && degrees[l] - k < 0) p[l++] = 0.;
809: while (l < ndegree && degrees[l] - k == 0) {
810: p[l] = pm2;
811: for (m = 0; m < k; m++) p[l] *= (abk1 + m) * 0.5;
812: l++;
813: }
814: while (l < ndegree && degrees[l] - k == 1) {
815: p[l] = pm1;
816: for (m = 0; m < k; m++) p[l] *= (abk1 + 1 + m) * 0.5;
817: l++;
818: }
819: for (j = 2; j <= maxdegree; j++) {
820: PetscReal pp;
822: PetscDTJacobiRecurrence_Internal(j, ak, bk, cnm1, cnm1x, cnm2);
823: pp = (cnm1 + cnm1x * x) * pm1 - cnm2 * pm2;
824: pm2 = pm1;
825: pm1 = pp;
826: while (l < ndegree && degrees[l] - k == j) {
827: p[l] = pp;
828: for (m = 0; m < k; m++) p[l] *= (abk1 + j + m) * 0.5;
829: l++;
830: }
831: }
832: p += ndegree;
833: }
834: PetscFunctionReturn(PETSC_SUCCESS);
835: }
837: /*@
838: PetscDTJacobiEvalJet - Evaluate the jet (function and derivatives) of the Jacobi polynomials basis up to a given degree.
840: Input Parameters:
841: + alpha - the left exponent of the weight
842: . beta - the right exponetn of the weight
843: . npoints - the number of points to evaluate the polynomials at
844: . points - [npoints] array of point coordinates
845: . degree - the maximm degree polynomial space to evaluate, (degree + 1) will be evaluated total.
846: - k - the maximum derivative to evaluate in the jet, (k + 1) will be evaluated total.
848: Output Parameter:
849: . p - an array containing the evaluations of the Jacobi polynomials's jets on the points. the size is (degree + 1) x
850: (k + 1) x npoints, which also describes the order of the dimensions of this three-dimensional array: the first
851: (slowest varying) dimension is polynomial degree; the second dimension is derivative order; the third (fastest
852: varying) dimension is the index of the evaluation point.
854: Level: advanced
856: Notes:
857: The Jacobi polynomials with indices $\alpha$ and $\beta$ are orthogonal with respect to the
858: weighted inner product $\langle f, g \rangle = \int_{-1}^1 (1+x)^{\alpha} (1-x)^{\beta} f(x)
859: g(x) dx$.
861: .seealso: `PetscDTJacobiEval()`, `PetscDTPKDEvalJet()`
862: @*/
863: PetscErrorCode PetscDTJacobiEvalJet(PetscReal alpha, PetscReal beta, PetscInt npoints, const PetscReal points[], PetscInt degree, PetscInt k, PetscReal p[])
864: {
865: PetscInt i, j, l;
866: PetscInt *degrees;
867: PetscReal *psingle;
869: PetscFunctionBegin;
870: if (degree == 0) {
871: PetscInt zero = 0;
873: for (i = 0; i <= k; i++) PetscCall(PetscDTJacobiEval_Internal(npoints, alpha, beta, i, points, 1, &zero, &p[i * npoints]));
874: PetscFunctionReturn(PETSC_SUCCESS);
875: }
876: PetscCall(PetscMalloc1(degree + 1, °rees));
877: PetscCall(PetscMalloc1((degree + 1) * npoints, &psingle));
878: for (i = 0; i <= degree; i++) degrees[i] = i;
879: for (i = 0; i <= k; i++) {
880: PetscCall(PetscDTJacobiEval_Internal(npoints, alpha, beta, i, points, degree + 1, degrees, psingle));
881: for (j = 0; j <= degree; j++) {
882: for (l = 0; l < npoints; l++) p[(j * (k + 1) + i) * npoints + l] = psingle[l * (degree + 1) + j];
883: }
884: }
885: PetscCall(PetscFree(psingle));
886: PetscCall(PetscFree(degrees));
887: PetscFunctionReturn(PETSC_SUCCESS);
888: }
890: /*@
891: PetscDTJacobiEval - evaluate Jacobi polynomials for the weight function $(1.+x)^{\alpha} (1.-x)^{\beta}$ at a set of points
892: at points
894: Not Collective
896: Input Parameters:
897: + npoints - number of spatial points to evaluate at
898: . alpha - the left exponent > -1
899: . beta - the right exponent > -1
900: . points - array of locations to evaluate at
901: . ndegree - number of basis degrees to evaluate
902: - degrees - sorted array of degrees to evaluate
904: Output Parameters:
905: + B - row-oriented basis evaluation matrix B[point*ndegree + degree] (dimension npoints*ndegrees, allocated by caller) (or `NULL`)
906: . D - row-oriented derivative evaluation matrix (or `NULL`)
907: - D2 - row-oriented second derivative evaluation matrix (or `NULL`)
909: Level: intermediate
911: .seealso: `PetscDTGaussQuadrature()`, `PetscDTLegendreEval()`
912: @*/
913: PetscErrorCode PetscDTJacobiEval(PetscInt npoints, PetscReal alpha, PetscReal beta, const PetscReal *points, PetscInt ndegree, const PetscInt *degrees, PetscReal *B, PetscReal *D, PetscReal *D2)
914: {
915: PetscFunctionBegin;
916: PetscCheck(alpha > -1., PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "alpha must be > -1.");
917: PetscCheck(beta > -1., PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "beta must be > -1.");
918: if (!npoints || !ndegree) PetscFunctionReturn(PETSC_SUCCESS);
919: if (B) PetscCall(PetscDTJacobiEval_Internal(npoints, alpha, beta, 0, points, ndegree, degrees, B));
920: if (D) PetscCall(PetscDTJacobiEval_Internal(npoints, alpha, beta, 1, points, ndegree, degrees, D));
921: if (D2) PetscCall(PetscDTJacobiEval_Internal(npoints, alpha, beta, 2, points, ndegree, degrees, D2));
922: PetscFunctionReturn(PETSC_SUCCESS);
923: }
925: /*@
926: PetscDTLegendreEval - evaluate Legendre polynomials at points
928: Not Collective
930: Input Parameters:
931: + npoints - number of spatial points to evaluate at
932: . points - array of locations to evaluate at
933: . ndegree - number of basis degrees to evaluate
934: - degrees - sorted array of degrees to evaluate
936: Output Parameters:
937: + B - row-oriented basis evaluation matrix B[point*ndegree + degree] (dimension `npoints`*`ndegrees`, allocated by caller) (or `NULL`)
938: . D - row-oriented derivative evaluation matrix (or `NULL`)
939: - D2 - row-oriented second derivative evaluation matrix (or `NULL`)
941: Level: intermediate
943: .seealso: `PetscDTGaussQuadrature()`
944: @*/
945: PetscErrorCode PetscDTLegendreEval(PetscInt npoints, const PetscReal *points, PetscInt ndegree, const PetscInt *degrees, PetscReal *B, PetscReal *D, PetscReal *D2)
946: {
947: PetscFunctionBegin;
948: PetscCall(PetscDTJacobiEval(npoints, 0., 0., points, ndegree, degrees, B, D, D2));
949: PetscFunctionReturn(PETSC_SUCCESS);
950: }
952: /*@
953: PetscDTIndexToGradedOrder - convert an index into a tuple of monomial degrees in a graded order (that is, if the degree sum of tuple x is less than the degree sum of tuple y,
954: then the index of x is smaller than the index of y)
956: Input Parameters:
957: + len - the desired length of the degree tuple
958: - index - the index to convert: should be >= 0
960: Output Parameter:
961: . degtup - will be filled with a tuple of degrees
963: Level: beginner
965: Note:
966: For two tuples x and y with the same degree sum, partial degree sums over the final elements of the tuples
967: acts as a tiebreaker. For example, (2, 1, 1) and (1, 2, 1) have the same degree sum, but the degree sum over the
968: last two elements is smaller for the former, so (2, 1, 1) < (1, 2, 1).
970: .seealso: `PetscDTGradedOrderToIndex()`
971: @*/
972: PetscErrorCode PetscDTIndexToGradedOrder(PetscInt len, PetscInt index, PetscInt degtup[])
973: {
974: PetscInt i, total;
975: PetscInt sum;
977: PetscFunctionBeginHot;
978: PetscCheck(len >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "length must be non-negative");
979: PetscCheck(index >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "index must be non-negative");
980: total = 1;
981: sum = 0;
982: while (index >= total) {
983: index -= total;
984: total = (total * (len + sum)) / (sum + 1);
985: sum++;
986: }
987: for (i = 0; i < len; i++) {
988: PetscInt c;
990: degtup[i] = sum;
991: for (c = 0, total = 1; c < sum; c++) {
992: /* going into the loop, total is the number of way to have a tuple of sum exactly c with length len - 1 - i */
993: if (index < total) break;
994: index -= total;
995: total = (total * (len - 1 - i + c)) / (c + 1);
996: degtup[i]--;
997: }
998: sum -= degtup[i];
999: }
1000: PetscFunctionReturn(PETSC_SUCCESS);
1001: }
1003: /*@
1004: PetscDTGradedOrderToIndex - convert a tuple into an index in a graded order, the inverse of `PetscDTIndexToGradedOrder()`.
1006: Input Parameters:
1007: + len - the length of the degree tuple
1008: - degtup - tuple with this length
1010: Output Parameter:
1011: . index - index in graded order: >= 0
1013: Level: beginner
1015: Note:
1016: For two tuples x and y with the same degree sum, partial degree sums over the final elements of the tuples
1017: acts as a tiebreaker. For example, (2, 1, 1) and (1, 2, 1) have the same degree sum, but the degree sum over the
1018: last two elements is smaller for the former, so (2, 1, 1) < (1, 2, 1).
1020: .seealso: `PetscDTIndexToGradedOrder()`
1021: @*/
1022: PetscErrorCode PetscDTGradedOrderToIndex(PetscInt len, const PetscInt degtup[], PetscInt *index)
1023: {
1024: PetscInt i, idx, sum, total;
1026: PetscFunctionBeginHot;
1027: PetscCheck(len >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "length must be non-negative");
1028: for (i = 0, sum = 0; i < len; i++) sum += degtup[i];
1029: idx = 0;
1030: total = 1;
1031: for (i = 0; i < sum; i++) {
1032: idx += total;
1033: total = (total * (len + i)) / (i + 1);
1034: }
1035: for (i = 0; i < len - 1; i++) {
1036: PetscInt c;
1038: total = 1;
1039: sum -= degtup[i];
1040: for (c = 0; c < sum; c++) {
1041: idx += total;
1042: total = (total * (len - 1 - i + c)) / (c + 1);
1043: }
1044: }
1045: *index = idx;
1046: PetscFunctionReturn(PETSC_SUCCESS);
1047: }
1049: static PetscBool PKDCite = PETSC_FALSE;
1050: const char PKDCitation[] = "@article{Kirby2010,\n"
1051: " title={Singularity-free evaluation of collapsed-coordinate orthogonal polynomials},\n"
1052: " author={Kirby, Robert C},\n"
1053: " journal={ACM Transactions on Mathematical Software (TOMS)},\n"
1054: " volume={37},\n"
1055: " number={1},\n"
1056: " pages={1--16},\n"
1057: " year={2010},\n"
1058: " publisher={ACM New York, NY, USA}\n}\n";
1060: /*@
1061: PetscDTPKDEvalJet - Evaluate the jet (function and derivatives) of the Proriol-Koornwinder-Dubiner (PKD) basis for
1062: the space of polynomials up to a given degree.
1064: Input Parameters:
1065: + dim - the number of variables in the multivariate polynomials
1066: . npoints - the number of points to evaluate the polynomials at
1067: . points - [npoints x dim] array of point coordinates
1068: . degree - the degree (sum of degrees on the variables in a monomial) of the polynomial space to evaluate. There are ((dim + degree) choose dim) polynomials in this space.
1069: - k - the maximum order partial derivative to evaluate in the jet. There are (dim + k choose dim) partial derivatives
1070: in the jet. Choosing k = 0 means to evaluate just the function and no derivatives
1072: Output Parameter:
1073: . p - an array containing the evaluations of the PKD polynomials' jets on the points. The size is ((dim + degree)
1074: choose dim) x ((dim + k) choose dim) x npoints, which also describes the order of the dimensions of this
1075: three-dimensional array: the first (slowest varying) dimension is basis function index; the second dimension is jet
1076: index; the third (fastest varying) dimension is the index of the evaluation point.
1078: Level: advanced
1080: Notes:
1081: The PKD basis is L2-orthonormal on the biunit simplex (which is used as the reference element
1082: for finite elements in PETSc), which makes it a stable basis to use for evaluating
1083: polynomials in that domain.
1085: The ordering of the basis functions, and the ordering of the derivatives in the jet, both follow the graded
1086: ordering of `PetscDTIndexToGradedOrder()` and `PetscDTGradedOrderToIndex()`. For example, in 3D, the polynomial with
1087: leading monomial x^2,y^0,z^1, which has degree tuple (2,0,1), which by `PetscDTGradedOrderToIndex()` has index 12 (it is the 13th basis function in the space);
1088: the partial derivative $\partial_x \partial_z$ has order tuple (1,0,1), appears at index 6 in the jet (it is the 7th partial derivative in the jet).
1090: The implementation uses Kirby's singularity-free evaluation algorithm, <https://doi.org/10.1145/1644001.1644006>.
1092: .seealso: `PetscDTGradedOrderToIndex()`, `PetscDTIndexToGradedOrder()`, `PetscDTJacobiEvalJet()`
1093: @*/
1094: PetscErrorCode PetscDTPKDEvalJet(PetscInt dim, PetscInt npoints, const PetscReal points[], PetscInt degree, PetscInt k, PetscReal p[])
1095: {
1096: PetscInt degidx, kidx, d, pt;
1097: PetscInt Nk, Ndeg;
1098: PetscInt *ktup, *degtup;
1099: PetscReal *scales, initscale, scaleexp;
1101: PetscFunctionBegin;
1102: PetscCall(PetscCitationsRegister(PKDCitation, &PKDCite));
1103: PetscCall(PetscDTBinomialInt(dim + k, k, &Nk));
1104: PetscCall(PetscDTBinomialInt(degree + dim, degree, &Ndeg));
1105: PetscCall(PetscMalloc2(dim, °tup, dim, &ktup));
1106: PetscCall(PetscMalloc1(Ndeg, &scales));
1107: initscale = 1.;
1108: if (dim > 1) {
1109: PetscCall(PetscDTBinomial(dim, 2, &scaleexp));
1110: initscale = PetscPowReal(2., scaleexp * 0.5);
1111: }
1112: for (degidx = 0; degidx < Ndeg; degidx++) {
1113: PetscInt e, i;
1114: PetscInt m1idx = -1, m2idx = -1;
1115: PetscInt n;
1116: PetscInt degsum;
1117: PetscReal alpha;
1118: PetscReal cnm1, cnm1x, cnm2;
1119: PetscReal norm;
1121: PetscCall(PetscDTIndexToGradedOrder(dim, degidx, degtup));
1122: for (d = dim - 1; d >= 0; d--)
1123: if (degtup[d]) break;
1124: if (d < 0) { /* constant is 1 everywhere, all derivatives are zero */
1125: scales[degidx] = initscale;
1126: for (e = 0; e < dim; e++) {
1127: PetscCall(PetscDTJacobiNorm(e, 0., 0, &norm));
1128: scales[degidx] /= norm;
1129: }
1130: for (i = 0; i < npoints; i++) p[degidx * Nk * npoints + i] = 1.;
1131: for (i = 0; i < (Nk - 1) * npoints; i++) p[(degidx * Nk + 1) * npoints + i] = 0.;
1132: continue;
1133: }
1134: n = degtup[d];
1135: degtup[d]--;
1136: PetscCall(PetscDTGradedOrderToIndex(dim, degtup, &m1idx));
1137: if (degtup[d] > 0) {
1138: degtup[d]--;
1139: PetscCall(PetscDTGradedOrderToIndex(dim, degtup, &m2idx));
1140: degtup[d]++;
1141: }
1142: degtup[d]++;
1143: for (e = 0, degsum = 0; e < d; e++) degsum += degtup[e];
1144: alpha = 2 * degsum + d;
1145: PetscDTJacobiRecurrence_Internal(n, alpha, 0., cnm1, cnm1x, cnm2);
1147: scales[degidx] = initscale;
1148: for (e = 0, degsum = 0; e < dim; e++) {
1149: PetscInt f;
1150: PetscReal ealpha;
1151: PetscReal enorm;
1153: ealpha = 2 * degsum + e;
1154: for (f = 0; f < degsum; f++) scales[degidx] *= 2.;
1155: PetscCall(PetscDTJacobiNorm(ealpha, 0., degtup[e], &enorm));
1156: scales[degidx] /= enorm;
1157: degsum += degtup[e];
1158: }
1160: for (pt = 0; pt < npoints; pt++) {
1161: /* compute the multipliers */
1162: PetscReal thetanm1, thetanm1x, thetanm2;
1164: thetanm1x = dim - (d + 1) + 2. * points[pt * dim + d];
1165: for (e = d + 1; e < dim; e++) thetanm1x += points[pt * dim + e];
1166: thetanm1x *= 0.5;
1167: thetanm1 = (2. - (dim - (d + 1)));
1168: for (e = d + 1; e < dim; e++) thetanm1 -= points[pt * dim + e];
1169: thetanm1 *= 0.5;
1170: thetanm2 = thetanm1 * thetanm1;
1172: for (kidx = 0; kidx < Nk; kidx++) {
1173: PetscInt f;
1175: PetscCall(PetscDTIndexToGradedOrder(dim, kidx, ktup));
1176: /* first sum in the same derivative terms */
1177: p[(degidx * Nk + kidx) * npoints + pt] = (cnm1 * thetanm1 + cnm1x * thetanm1x) * p[(m1idx * Nk + kidx) * npoints + pt];
1178: if (m2idx >= 0) p[(degidx * Nk + kidx) * npoints + pt] -= cnm2 * thetanm2 * p[(m2idx * Nk + kidx) * npoints + pt];
1180: for (f = d; f < dim; f++) {
1181: PetscInt km1idx, mplty = ktup[f];
1183: if (!mplty) continue;
1184: ktup[f]--;
1185: PetscCall(PetscDTGradedOrderToIndex(dim, ktup, &km1idx));
1187: /* the derivative of cnm1x * thetanm1x wrt x variable f is 0.5 * cnm1x if f > d otherwise it is cnm1x */
1188: /* the derivative of cnm1 * thetanm1 wrt x variable f is 0 if f == d, otherwise it is -0.5 * cnm1 */
1189: /* the derivative of -cnm2 * thetanm2 wrt x variable f is 0 if f == d, otherwise it is cnm2 * thetanm1 */
1190: if (f > d) {
1191: PetscInt f2;
1193: p[(degidx * Nk + kidx) * npoints + pt] += mplty * 0.5 * (cnm1x - cnm1) * p[(m1idx * Nk + km1idx) * npoints + pt];
1194: if (m2idx >= 0) {
1195: p[(degidx * Nk + kidx) * npoints + pt] += mplty * cnm2 * thetanm1 * p[(m2idx * Nk + km1idx) * npoints + pt];
1196: /* second derivatives of -cnm2 * thetanm2 wrt x variable f,f2 is like - 0.5 * cnm2 */
1197: for (f2 = f; f2 < dim; f2++) {
1198: PetscInt km2idx, mplty2 = ktup[f2];
1199: PetscInt factor;
1201: if (!mplty2) continue;
1202: ktup[f2]--;
1203: PetscCall(PetscDTGradedOrderToIndex(dim, ktup, &km2idx));
1205: factor = mplty * mplty2;
1206: if (f == f2) factor /= 2;
1207: p[(degidx * Nk + kidx) * npoints + pt] -= 0.5 * factor * cnm2 * p[(m2idx * Nk + km2idx) * npoints + pt];
1208: ktup[f2]++;
1209: }
1210: }
1211: } else {
1212: p[(degidx * Nk + kidx) * npoints + pt] += mplty * cnm1x * p[(m1idx * Nk + km1idx) * npoints + pt];
1213: }
1214: ktup[f]++;
1215: }
1216: }
1217: }
1218: }
1219: for (degidx = 0; degidx < Ndeg; degidx++) {
1220: PetscReal scale = scales[degidx];
1221: PetscInt i;
1223: for (i = 0; i < Nk * npoints; i++) p[degidx * Nk * npoints + i] *= scale;
1224: }
1225: PetscCall(PetscFree(scales));
1226: PetscCall(PetscFree2(degtup, ktup));
1227: PetscFunctionReturn(PETSC_SUCCESS);
1228: }
1230: /*@
1231: PetscDTPTrimmedSize - The size of the trimmed polynomial space of k-forms with a given degree and form degree,
1232: which can be evaluated in `PetscDTPTrimmedEvalJet()`.
1234: Input Parameters:
1235: + dim - the number of variables in the multivariate polynomials
1236: . degree - the degree (sum of degrees on the variables in a monomial) of the trimmed polynomial space.
1237: - formDegree - the degree of the form
1239: Output Parameter:
1240: . size - The number ((`dim` + `degree`) choose (`dim` + `formDegree`)) x ((`degree` + `formDegree` - 1) choose (`formDegree`))
1242: Level: advanced
1244: .seealso: `PetscDTPTrimmedEvalJet()`
1245: @*/
1246: PetscErrorCode PetscDTPTrimmedSize(PetscInt dim, PetscInt degree, PetscInt formDegree, PetscInt *size)
1247: {
1248: PetscInt Nrk, Nbpt; // number of trimmed polynomials
1250: PetscFunctionBegin;
1251: formDegree = PetscAbsInt(formDegree);
1252: PetscCall(PetscDTBinomialInt(degree + dim, degree + formDegree, &Nbpt));
1253: PetscCall(PetscDTBinomialInt(degree + formDegree - 1, formDegree, &Nrk));
1254: Nbpt *= Nrk;
1255: *size = Nbpt;
1256: PetscFunctionReturn(PETSC_SUCCESS);
1257: }
1259: /* there was a reference implementation based on section 4.4 of Arnold, Falk & Winther (acta numerica, 2006), but it
1260: * was inferior to this implementation */
1261: static PetscErrorCode PetscDTPTrimmedEvalJet_Internal(PetscInt dim, PetscInt npoints, const PetscReal points[], PetscInt degree, PetscInt formDegree, PetscInt jetDegree, PetscReal p[])
1262: {
1263: PetscInt formDegreeOrig = formDegree;
1264: PetscBool formNegative = (formDegreeOrig < 0) ? PETSC_TRUE : PETSC_FALSE;
1266: PetscFunctionBegin;
1267: formDegree = PetscAbsInt(formDegreeOrig);
1268: if (formDegree == 0) {
1269: PetscCall(PetscDTPKDEvalJet(dim, npoints, points, degree, jetDegree, p));
1270: PetscFunctionReturn(PETSC_SUCCESS);
1271: }
1272: if (formDegree == dim) {
1273: PetscCall(PetscDTPKDEvalJet(dim, npoints, points, degree - 1, jetDegree, p));
1274: PetscFunctionReturn(PETSC_SUCCESS);
1275: }
1276: PetscInt Nbpt;
1277: PetscCall(PetscDTPTrimmedSize(dim, degree, formDegree, &Nbpt));
1278: PetscInt Nf;
1279: PetscCall(PetscDTBinomialInt(dim, formDegree, &Nf));
1280: PetscInt Nk;
1281: PetscCall(PetscDTBinomialInt(dim + jetDegree, dim, &Nk));
1282: PetscCall(PetscArrayzero(p, Nbpt * Nf * Nk * npoints));
1284: PetscInt Nbpm1; // number of scalar polynomials up to degree - 1;
1285: PetscCall(PetscDTBinomialInt(dim + degree - 1, dim, &Nbpm1));
1286: PetscReal *p_scalar;
1287: PetscCall(PetscMalloc1(Nbpm1 * Nk * npoints, &p_scalar));
1288: PetscCall(PetscDTPKDEvalJet(dim, npoints, points, degree - 1, jetDegree, p_scalar));
1289: PetscInt total = 0;
1290: // First add the full polynomials up to degree - 1 into the basis: take the scalar
1291: // and copy one for each form component
1292: for (PetscInt i = 0; i < Nbpm1; i++) {
1293: const PetscReal *src = &p_scalar[i * Nk * npoints];
1294: for (PetscInt f = 0; f < Nf; f++) {
1295: PetscReal *dest = &p[(total++ * Nf + f) * Nk * npoints];
1296: PetscCall(PetscArraycpy(dest, src, Nk * npoints));
1297: }
1298: }
1299: PetscInt *form_atoms;
1300: PetscCall(PetscMalloc1(formDegree + 1, &form_atoms));
1301: // construct the interior product pattern
1302: PetscInt(*pattern)[3];
1303: PetscInt Nf1; // number of formDegree + 1 forms
1304: PetscCall(PetscDTBinomialInt(dim, formDegree + 1, &Nf1));
1305: PetscInt nnz = Nf1 * (formDegree + 1);
1306: PetscCall(PetscMalloc1(Nf1 * (formDegree + 1), &pattern));
1307: PetscCall(PetscDTAltVInteriorPattern(dim, formDegree + 1, pattern));
1308: PetscReal centroid = (1. - dim) / (dim + 1.);
1309: PetscInt *deriv;
1310: PetscCall(PetscMalloc1(dim, &deriv));
1311: for (PetscInt d = dim; d >= formDegree + 1; d--) {
1312: PetscInt Nfd1; // number of formDegree + 1 forms in dimension d that include dx_0
1313: // (equal to the number of formDegree forms in dimension d-1)
1314: PetscCall(PetscDTBinomialInt(d - 1, formDegree, &Nfd1));
1315: // The number of homogeneous (degree-1) scalar polynomials in d variables
1316: PetscInt Nh;
1317: PetscCall(PetscDTBinomialInt(d - 1 + degree - 1, d - 1, &Nh));
1318: const PetscReal *h_scalar = &p_scalar[(Nbpm1 - Nh) * Nk * npoints];
1319: for (PetscInt b = 0; b < Nh; b++) {
1320: const PetscReal *h_s = &h_scalar[b * Nk * npoints];
1321: for (PetscInt f = 0; f < Nfd1; f++) {
1322: // construct all formDegree+1 forms that start with dx_(dim - d) /\ ...
1323: form_atoms[0] = dim - d;
1324: PetscCall(PetscDTEnumSubset(d - 1, formDegree, f, &form_atoms[1]));
1325: for (PetscInt i = 0; i < formDegree; i++) form_atoms[1 + i] += form_atoms[0] + 1;
1326: PetscInt f_ind; // index of the resulting form
1327: PetscCall(PetscDTSubsetIndex(dim, formDegree + 1, form_atoms, &f_ind));
1328: PetscReal *p_f = &p[total++ * Nf * Nk * npoints];
1329: for (PetscInt nz = 0; nz < nnz; nz++) {
1330: PetscInt i = pattern[nz][0]; // formDegree component
1331: PetscInt j = pattern[nz][1]; // (formDegree + 1) component
1332: PetscInt v = pattern[nz][2]; // coordinate component
1333: PetscReal scale = v < 0 ? -1. : 1.;
1335: i = formNegative ? (Nf - 1 - i) : i;
1336: scale = (formNegative && (i & 1)) ? -scale : scale;
1337: v = v < 0 ? -(v + 1) : v;
1338: if (j != f_ind) continue;
1339: PetscReal *p_i = &p_f[i * Nk * npoints];
1340: for (PetscInt jet = 0; jet < Nk; jet++) {
1341: const PetscReal *h_jet = &h_s[jet * npoints];
1342: PetscReal *p_jet = &p_i[jet * npoints];
1344: for (PetscInt pt = 0; pt < npoints; pt++) p_jet[pt] += scale * h_jet[pt] * (points[pt * dim + v] - centroid);
1345: PetscCall(PetscDTIndexToGradedOrder(dim, jet, deriv));
1346: deriv[v]++;
1347: PetscReal mult = deriv[v];
1348: PetscInt l;
1349: PetscCall(PetscDTGradedOrderToIndex(dim, deriv, &l));
1350: if (l >= Nk) continue;
1351: p_jet = &p_i[l * npoints];
1352: for (PetscInt pt = 0; pt < npoints; pt++) p_jet[pt] += scale * mult * h_jet[pt];
1353: deriv[v]--;
1354: }
1355: }
1356: }
1357: }
1358: }
1359: PetscCheck(total == Nbpt, PETSC_COMM_SELF, PETSC_ERR_PLIB, "Incorrectly counted P trimmed polynomials");
1360: PetscCall(PetscFree(deriv));
1361: PetscCall(PetscFree(pattern));
1362: PetscCall(PetscFree(form_atoms));
1363: PetscCall(PetscFree(p_scalar));
1364: PetscFunctionReturn(PETSC_SUCCESS);
1365: }
1367: /*@
1368: PetscDTPTrimmedEvalJet - Evaluate the jet (function and derivatives) of a basis of the trimmed polynomial k-forms up to
1369: a given degree.
1371: Input Parameters:
1372: + dim - the number of variables in the multivariate polynomials
1373: . npoints - the number of points to evaluate the polynomials at
1374: . points - [npoints x dim] array of point coordinates
1375: . degree - the degree (sum of degrees on the variables in a monomial) of the trimmed polynomial space to evaluate.
1376: There are ((dim + degree) choose (dim + formDegree)) x ((degree + formDegree - 1) choose (formDegree)) polynomials in this space.
1377: (You can use `PetscDTPTrimmedSize()` to compute this size.)
1378: . formDegree - the degree of the form
1379: - jetDegree - the maximum order partial derivative to evaluate in the jet. There are ((dim + jetDegree) choose dim) partial derivatives
1380: in the jet. Choosing jetDegree = 0 means to evaluate just the function and no derivatives
1382: Output Parameter:
1383: . p - an array containing the evaluations of the PKD polynomials' jets on the points.
1385: Level: advanced
1387: Notes:
1388: The size of `p` is `PetscDTPTrimmedSize()` x ((dim + formDegree) choose dim) x ((dim + k)
1389: choose dim) x npoints,which also describes the order of the dimensions of this
1390: four-dimensional array\:
1392: the first (slowest varying) dimension is basis function index;
1393: the second dimension is component of the form;
1394: the third dimension is jet index;
1395: the fourth (fastest varying) dimension is the index of the evaluation point.
1397: The ordering of the basis functions is not graded, so the basis functions are not nested by degree like `PetscDTPKDEvalJet()`.
1398: The basis functions are not an L2-orthonormal basis on any particular domain.
1400: The implementation is based on the description of the trimmed polynomials up to degree r as
1401: the direct sum of polynomials up to degree (r-1) and the Koszul differential applied to
1402: homogeneous polynomials of degree (r-1).
1404: .seealso: `PetscDTPKDEvalJet()`, `PetscDTPTrimmedSize()`
1405: @*/
1406: PetscErrorCode PetscDTPTrimmedEvalJet(PetscInt dim, PetscInt npoints, const PetscReal points[], PetscInt degree, PetscInt formDegree, PetscInt jetDegree, PetscReal p[])
1407: {
1408: PetscFunctionBegin;
1409: PetscCall(PetscDTPTrimmedEvalJet_Internal(dim, npoints, points, degree, formDegree, jetDegree, p));
1410: PetscFunctionReturn(PETSC_SUCCESS);
1411: }
1413: /* solve the symmetric tridiagonal eigenvalue system, writing the eigenvalues into eigs and the eigenvectors into V
1414: * with lds n; diag and subdiag are overwritten */
1415: static PetscErrorCode PetscDTSymmetricTridiagonalEigensolve(PetscInt n, PetscReal diag[], PetscReal subdiag[], PetscReal eigs[], PetscScalar V[])
1416: {
1417: char jobz = 'V'; /* eigenvalues and eigenvectors */
1418: char range = 'A'; /* all eigenvalues will be found */
1419: PetscReal VL = 0.; /* ignored because range is 'A' */
1420: PetscReal VU = 0.; /* ignored because range is 'A' */
1421: PetscBLASInt IL = 0; /* ignored because range is 'A' */
1422: PetscBLASInt IU = 0; /* ignored because range is 'A' */
1423: PetscReal abstol = 0.; /* unused */
1424: PetscBLASInt bn, bm, ldz; /* bm will equal bn on exit */
1425: PetscBLASInt *isuppz;
1426: PetscBLASInt lwork, liwork;
1427: PetscReal workquery;
1428: PetscBLASInt iworkquery;
1429: PetscBLASInt *iwork;
1430: PetscBLASInt info;
1431: PetscReal *work = NULL;
1433: PetscFunctionBegin;
1434: #if !defined(PETSCDTGAUSSIANQUADRATURE_EIG)
1435: SETERRQ(PETSC_COMM_SELF, PETSC_ERR_SUP_SYS, "A LAPACK symmetric tridiagonal eigensolver could not be found");
1436: #endif
1437: PetscCall(PetscBLASIntCast(n, &bn));
1438: PetscCall(PetscBLASIntCast(n, &ldz));
1439: #if !defined(PETSC_MISSING_LAPACK_STEGR)
1440: PetscCall(PetscMalloc1(2 * n, &isuppz));
1441: lwork = -1;
1442: liwork = -1;
1443: PetscCallBLAS("LAPACKstegr", LAPACKstegr_(&jobz, &range, &bn, diag, subdiag, &VL, &VU, &IL, &IU, &abstol, &bm, eigs, V, &ldz, isuppz, &workquery, &lwork, &iworkquery, &liwork, &info));
1444: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_PLIB, "xSTEGR error");
1445: lwork = (PetscBLASInt)workquery;
1446: liwork = (PetscBLASInt)iworkquery;
1447: PetscCall(PetscMalloc2(lwork, &work, liwork, &iwork));
1448: PetscCall(PetscFPTrapPush(PETSC_FP_TRAP_OFF));
1449: PetscCallBLAS("LAPACKstegr", LAPACKstegr_(&jobz, &range, &bn, diag, subdiag, &VL, &VU, &IL, &IU, &abstol, &bm, eigs, V, &ldz, isuppz, work, &lwork, iwork, &liwork, &info));
1450: PetscCall(PetscFPTrapPop());
1451: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_PLIB, "xSTEGR error");
1452: PetscCall(PetscFree2(work, iwork));
1453: PetscCall(PetscFree(isuppz));
1454: #elif !defined(PETSC_MISSING_LAPACK_STEQR)
1455: jobz = 'I'; /* Compute eigenvalues and eigenvectors of the
1456: tridiagonal matrix. Z is initialized to the identity
1457: matrix. */
1458: PetscCall(PetscMalloc1(PetscMax(1, 2 * n - 2), &work));
1459: PetscCallBLAS("LAPACKsteqr", LAPACKsteqr_("I", &bn, diag, subdiag, V, &ldz, work, &info));
1460: PetscCall(PetscFPTrapPop());
1461: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_PLIB, "xSTEQR error");
1462: PetscCall(PetscFree(work));
1463: PetscCall(PetscArraycpy(eigs, diag, n));
1464: #endif
1465: PetscFunctionReturn(PETSC_SUCCESS);
1466: }
1468: /* Formula for the weights at the endpoints (-1 and 1) of Gauss-Lobatto-Jacobi
1469: * quadrature rules on the interval [-1, 1] */
1470: static PetscErrorCode PetscDTGaussLobattoJacobiEndweights_Internal(PetscInt n, PetscReal alpha, PetscReal beta, PetscReal *leftw, PetscReal *rightw)
1471: {
1472: PetscReal twoab1;
1473: PetscInt m = n - 2;
1474: PetscReal a = alpha + 1.;
1475: PetscReal b = beta + 1.;
1476: PetscReal gra, grb;
1478: PetscFunctionBegin;
1479: twoab1 = PetscPowReal(2., a + b - 1.);
1480: #if defined(PETSC_HAVE_LGAMMA)
1481: grb = PetscExpReal(2. * PetscLGamma(b + 1.) + PetscLGamma(m + 1.) + PetscLGamma(m + a + 1.) - (PetscLGamma(m + b + 1) + PetscLGamma(m + a + b + 1.)));
1482: gra = PetscExpReal(2. * PetscLGamma(a + 1.) + PetscLGamma(m + 1.) + PetscLGamma(m + b + 1.) - (PetscLGamma(m + a + 1) + PetscLGamma(m + a + b + 1.)));
1483: #else
1484: {
1485: PetscInt alphai = (PetscInt)alpha;
1486: PetscInt betai = (PetscInt)beta;
1488: if ((PetscReal)alphai == alpha && (PetscReal)betai == beta) {
1489: PetscReal binom1, binom2;
1491: PetscCall(PetscDTBinomial(m + b, b, &binom1));
1492: PetscCall(PetscDTBinomial(m + a + b, b, &binom2));
1493: grb = 1. / (binom1 * binom2);
1494: PetscCall(PetscDTBinomial(m + a, a, &binom1));
1495: PetscCall(PetscDTBinomial(m + a + b, a, &binom2));
1496: gra = 1. / (binom1 * binom2);
1497: } else SETERRQ(PETSC_COMM_SELF, PETSC_ERR_SUP, "lgamma() - math routine is unavailable.");
1498: }
1499: #endif
1500: *leftw = twoab1 * grb / b;
1501: *rightw = twoab1 * gra / a;
1502: PetscFunctionReturn(PETSC_SUCCESS);
1503: }
1505: /* Evaluates the nth jacobi polynomial with weight parameters a,b at a point x.
1506: Recurrence relations implemented from the pseudocode given in Karniadakis and Sherwin, Appendix B */
1507: static inline PetscErrorCode PetscDTComputeJacobi(PetscReal a, PetscReal b, PetscInt n, PetscReal x, PetscReal *P)
1508: {
1509: PetscReal pn1, pn2;
1510: PetscReal cnm1, cnm1x, cnm2;
1511: PetscInt k;
1513: PetscFunctionBegin;
1514: if (!n) {
1515: *P = 1.0;
1516: PetscFunctionReturn(PETSC_SUCCESS);
1517: }
1518: PetscDTJacobiRecurrence_Internal(1, a, b, cnm1, cnm1x, cnm2);
1519: pn2 = 1.;
1520: pn1 = cnm1 + cnm1x * x;
1521: if (n == 1) {
1522: *P = pn1;
1523: PetscFunctionReturn(PETSC_SUCCESS);
1524: }
1525: *P = 0.0;
1526: for (k = 2; k < n + 1; ++k) {
1527: PetscDTJacobiRecurrence_Internal(k, a, b, cnm1, cnm1x, cnm2);
1529: *P = (cnm1 + cnm1x * x) * pn1 - cnm2 * pn2;
1530: pn2 = pn1;
1531: pn1 = *P;
1532: }
1533: PetscFunctionReturn(PETSC_SUCCESS);
1534: }
1536: /* Evaluates the first derivative of P_{n}^{a,b} at a point x. */
1537: static inline PetscErrorCode PetscDTComputeJacobiDerivative(PetscReal a, PetscReal b, PetscInt n, PetscReal x, PetscInt k, PetscReal *P)
1538: {
1539: PetscReal nP;
1540: PetscInt i;
1542: PetscFunctionBegin;
1543: *P = 0.0;
1544: if (k > n) PetscFunctionReturn(PETSC_SUCCESS);
1545: PetscCall(PetscDTComputeJacobi(a + k, b + k, n - k, x, &nP));
1546: for (i = 0; i < k; i++) nP *= (a + b + n + 1. + i) * 0.5;
1547: *P = nP;
1548: PetscFunctionReturn(PETSC_SUCCESS);
1549: }
1551: static PetscErrorCode PetscDTGaussJacobiQuadrature_Newton_Internal(PetscInt npoints, PetscReal a, PetscReal b, PetscReal x[], PetscReal w[])
1552: {
1553: PetscInt maxIter = 100;
1554: PetscReal eps = PetscExpReal(0.75 * PetscLogReal(PETSC_MACHINE_EPSILON));
1555: PetscReal a1, a6, gf;
1556: PetscInt k;
1558: PetscFunctionBegin;
1560: a1 = PetscPowReal(2.0, a + b + 1);
1561: #if defined(PETSC_HAVE_LGAMMA)
1562: {
1563: PetscReal a2, a3, a4, a5;
1564: a2 = PetscLGamma(a + npoints + 1);
1565: a3 = PetscLGamma(b + npoints + 1);
1566: a4 = PetscLGamma(a + b + npoints + 1);
1567: a5 = PetscLGamma(npoints + 1);
1568: gf = PetscExpReal(a2 + a3 - (a4 + a5));
1569: }
1570: #else
1571: {
1572: PetscInt ia, ib;
1574: ia = (PetscInt)a;
1575: ib = (PetscInt)b;
1576: gf = 1.;
1577: if (ia == a && ia >= 0) { /* compute ratio of rising factorals wrt a */
1578: for (k = 0; k < ia; k++) gf *= (npoints + 1. + k) / (npoints + b + 1. + k);
1579: } else if (b == b && ib >= 0) { /* compute ratio of rising factorials wrt b */
1580: for (k = 0; k < ib; k++) gf *= (npoints + 1. + k) / (npoints + a + 1. + k);
1581: } else SETERRQ(PETSC_COMM_SELF, PETSC_ERR_SUP, "lgamma() - math routine is unavailable.");
1582: }
1583: #endif
1585: a6 = a1 * gf;
1586: /* Computes the m roots of P_{m}^{a,b} on [-1,1] by Newton's method with Chebyshev points as initial guesses.
1587: Algorithm implemented from the pseudocode given by Karniadakis and Sherwin and Python in FIAT */
1588: for (k = 0; k < npoints; ++k) {
1589: PetscReal r = PetscCosReal(PETSC_PI * (1. - (4. * k + 3. + 2. * b) / (4. * npoints + 2. * (a + b + 1.)))), dP;
1590: PetscInt j;
1592: if (k > 0) r = 0.5 * (r + x[k - 1]);
1593: for (j = 0; j < maxIter; ++j) {
1594: PetscReal s = 0.0, delta, f, fp;
1595: PetscInt i;
1597: for (i = 0; i < k; ++i) s = s + 1.0 / (r - x[i]);
1598: PetscCall(PetscDTComputeJacobi(a, b, npoints, r, &f));
1599: PetscCall(PetscDTComputeJacobiDerivative(a, b, npoints, r, 1, &fp));
1600: delta = f / (fp - f * s);
1601: r = r - delta;
1602: if (PetscAbsReal(delta) < eps) break;
1603: }
1604: x[k] = r;
1605: PetscCall(PetscDTComputeJacobiDerivative(a, b, npoints, x[k], 1, &dP));
1606: w[k] = a6 / (1.0 - PetscSqr(x[k])) / PetscSqr(dP);
1607: }
1608: PetscFunctionReturn(PETSC_SUCCESS);
1609: }
1611: /* Compute the diagonals of the Jacobi matrix used in Golub & Welsch algorithms for Gauss-Jacobi
1612: * quadrature weight calculations on [-1,1] for exponents (1. + x)^a (1.-x)^b */
1613: static PetscErrorCode PetscDTJacobiMatrix_Internal(PetscInt nPoints, PetscReal a, PetscReal b, PetscReal *d, PetscReal *s)
1614: {
1615: PetscInt i;
1617: PetscFunctionBegin;
1618: for (i = 0; i < nPoints; i++) {
1619: PetscReal A, B, C;
1621: PetscDTJacobiRecurrence_Internal(i + 1, a, b, A, B, C);
1622: d[i] = -A / B;
1623: if (i) s[i - 1] *= C / B;
1624: if (i < nPoints - 1) s[i] = 1. / B;
1625: }
1626: PetscFunctionReturn(PETSC_SUCCESS);
1627: }
1629: static PetscErrorCode PetscDTGaussJacobiQuadrature_GolubWelsch_Internal(PetscInt npoints, PetscReal a, PetscReal b, PetscReal *x, PetscReal *w)
1630: {
1631: PetscReal mu0;
1632: PetscReal ga, gb, gab;
1633: PetscInt i;
1635: PetscFunctionBegin;
1636: PetscCall(PetscCitationsRegister(GolubWelschCitation, &GolubWelschCite));
1638: #if defined(PETSC_HAVE_TGAMMA)
1639: ga = PetscTGamma(a + 1);
1640: gb = PetscTGamma(b + 1);
1641: gab = PetscTGamma(a + b + 2);
1642: #else
1643: {
1644: PetscInt ia, ib;
1646: ia = (PetscInt)a;
1647: ib = (PetscInt)b;
1648: if (ia == a && ib == b && ia + 1 > 0 && ib + 1 > 0 && ia + ib + 2 > 0) { /* All gamma(x) terms are (x-1)! terms */
1649: PetscCall(PetscDTFactorial(ia, &ga));
1650: PetscCall(PetscDTFactorial(ib, &gb));
1651: PetscCall(PetscDTFactorial(ia + ib + 1, &gab));
1652: } else SETERRQ(PETSC_COMM_SELF, PETSC_ERR_SUP, "tgamma() - math routine is unavailable.");
1653: }
1654: #endif
1655: mu0 = PetscPowReal(2., a + b + 1.) * ga * gb / gab;
1657: #if defined(PETSCDTGAUSSIANQUADRATURE_EIG)
1658: {
1659: PetscReal *diag, *subdiag;
1660: PetscScalar *V;
1662: PetscCall(PetscMalloc2(npoints, &diag, npoints, &subdiag));
1663: PetscCall(PetscMalloc1(npoints * npoints, &V));
1664: PetscCall(PetscDTJacobiMatrix_Internal(npoints, a, b, diag, subdiag));
1665: for (i = 0; i < npoints - 1; i++) subdiag[i] = PetscSqrtReal(subdiag[i]);
1666: PetscCall(PetscDTSymmetricTridiagonalEigensolve(npoints, diag, subdiag, x, V));
1667: for (i = 0; i < npoints; i++) w[i] = PetscSqr(PetscRealPart(V[i * npoints])) * mu0;
1668: PetscCall(PetscFree(V));
1669: PetscCall(PetscFree2(diag, subdiag));
1670: }
1671: #else
1672: SETERRQ(PETSC_COMM_SELF, PETSC_ERR_SUP_SYS, "A LAPACK symmetric tridiagonal eigensolver could not be found");
1673: #endif
1674: { /* As of March 2, 2020, The Sun Performance Library breaks the LAPACK contract for xstegr and xsteqr: the
1675: eigenvalues are not guaranteed to be in ascending order. So we heave a passive aggressive sigh and check that
1676: the eigenvalues are sorted */
1677: PetscBool sorted;
1679: PetscCall(PetscSortedReal(npoints, x, &sorted));
1680: if (!sorted) {
1681: PetscInt *order, i;
1682: PetscReal *tmp;
1684: PetscCall(PetscMalloc2(npoints, &order, npoints, &tmp));
1685: for (i = 0; i < npoints; i++) order[i] = i;
1686: PetscCall(PetscSortRealWithPermutation(npoints, x, order));
1687: PetscCall(PetscArraycpy(tmp, x, npoints));
1688: for (i = 0; i < npoints; i++) x[i] = tmp[order[i]];
1689: PetscCall(PetscArraycpy(tmp, w, npoints));
1690: for (i = 0; i < npoints; i++) w[i] = tmp[order[i]];
1691: PetscCall(PetscFree2(order, tmp));
1692: }
1693: }
1694: PetscFunctionReturn(PETSC_SUCCESS);
1695: }
1697: static PetscErrorCode PetscDTGaussJacobiQuadrature_Internal(PetscInt npoints, PetscReal alpha, PetscReal beta, PetscReal x[], PetscReal w[], PetscBool newton)
1698: {
1699: PetscFunctionBegin;
1700: PetscCheck(npoints >= 1, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Number of points must be positive");
1701: /* If asking for a 1D Lobatto point, just return the non-Lobatto 1D point */
1702: PetscCheck(alpha > -1., PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "alpha must be > -1.");
1703: PetscCheck(beta > -1., PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "beta must be > -1.");
1705: if (newton) PetscCall(PetscDTGaussJacobiQuadrature_Newton_Internal(npoints, alpha, beta, x, w));
1706: else PetscCall(PetscDTGaussJacobiQuadrature_GolubWelsch_Internal(npoints, alpha, beta, x, w));
1707: if (alpha == beta) { /* symmetrize */
1708: PetscInt i;
1709: for (i = 0; i < (npoints + 1) / 2; i++) {
1710: PetscInt j = npoints - 1 - i;
1711: PetscReal xi = x[i];
1712: PetscReal xj = x[j];
1713: PetscReal wi = w[i];
1714: PetscReal wj = w[j];
1716: x[i] = (xi - xj) / 2.;
1717: x[j] = (xj - xi) / 2.;
1718: w[i] = w[j] = (wi + wj) / 2.;
1719: }
1720: }
1721: PetscFunctionReturn(PETSC_SUCCESS);
1722: }
1724: /*@
1725: PetscDTGaussJacobiQuadrature - quadrature for the interval $[a, b]$ with the weight function
1726: $(x-a)^\alpha (x-b)^\beta$.
1728: Not Collective
1730: Input Parameters:
1731: + npoints - the number of points in the quadrature rule
1732: . a - the left endpoint of the interval
1733: . b - the right endpoint of the interval
1734: . alpha - the left exponent
1735: - beta - the right exponent
1737: Output Parameters:
1738: + x - array of length `npoints`, the locations of the quadrature points
1739: - w - array of length `npoints`, the weights of the quadrature points
1741: Level: intermediate
1743: Note:
1744: This quadrature rule is exact for polynomials up to degree 2*`npoints` - 1.
1746: .seealso: `PetscDTGaussQuadrature()`
1747: @*/
1748: PetscErrorCode PetscDTGaussJacobiQuadrature(PetscInt npoints, PetscReal a, PetscReal b, PetscReal alpha, PetscReal beta, PetscReal x[], PetscReal w[])
1749: {
1750: PetscInt i;
1752: PetscFunctionBegin;
1753: PetscCall(PetscDTGaussJacobiQuadrature_Internal(npoints, alpha, beta, x, w, PetscDTGaussQuadratureNewton_Internal));
1754: if (a != -1. || b != 1.) { /* shift */
1755: for (i = 0; i < npoints; i++) {
1756: x[i] = (x[i] + 1.) * ((b - a) / 2.) + a;
1757: w[i] *= (b - a) / 2.;
1758: }
1759: }
1760: PetscFunctionReturn(PETSC_SUCCESS);
1761: }
1763: static PetscErrorCode PetscDTGaussLobattoJacobiQuadrature_Internal(PetscInt npoints, PetscReal alpha, PetscReal beta, PetscReal x[], PetscReal w[], PetscBool newton)
1764: {
1765: PetscInt i;
1767: PetscFunctionBegin;
1768: PetscCheck(npoints >= 2, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Number of points must be positive");
1769: /* If asking for a 1D Lobatto point, just return the non-Lobatto 1D point */
1770: PetscCheck(alpha > -1., PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "alpha must be > -1.");
1771: PetscCheck(beta > -1., PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "beta must be > -1.");
1773: x[0] = -1.;
1774: x[npoints - 1] = 1.;
1775: if (npoints > 2) PetscCall(PetscDTGaussJacobiQuadrature_Internal(npoints - 2, alpha + 1., beta + 1., &x[1], &w[1], newton));
1776: for (i = 1; i < npoints - 1; i++) w[i] /= (1. - x[i] * x[i]);
1777: PetscCall(PetscDTGaussLobattoJacobiEndweights_Internal(npoints, alpha, beta, &w[0], &w[npoints - 1]));
1778: PetscFunctionReturn(PETSC_SUCCESS);
1779: }
1781: /*@
1782: PetscDTGaussLobattoJacobiQuadrature - quadrature for the interval $[a, b]$ with the weight function
1783: $(x-a)^\alpha (x-b)^\beta$, with endpoints `a` and `b` included as quadrature points.
1785: Not Collective
1787: Input Parameters:
1788: + npoints - the number of points in the quadrature rule
1789: . a - the left endpoint of the interval
1790: . b - the right endpoint of the interval
1791: . alpha - the left exponent
1792: - beta - the right exponent
1794: Output Parameters:
1795: + x - array of length `npoints`, the locations of the quadrature points
1796: - w - array of length `npoints`, the weights of the quadrature points
1798: Level: intermediate
1800: Note:
1801: This quadrature rule is exact for polynomials up to degree 2*`npoints` - 3.
1803: .seealso: `PetscDTGaussJacobiQuadrature()`
1804: @*/
1805: PetscErrorCode PetscDTGaussLobattoJacobiQuadrature(PetscInt npoints, PetscReal a, PetscReal b, PetscReal alpha, PetscReal beta, PetscReal x[], PetscReal w[])
1806: {
1807: PetscInt i;
1809: PetscFunctionBegin;
1810: PetscCall(PetscDTGaussLobattoJacobiQuadrature_Internal(npoints, alpha, beta, x, w, PetscDTGaussQuadratureNewton_Internal));
1811: if (a != -1. || b != 1.) { /* shift */
1812: for (i = 0; i < npoints; i++) {
1813: x[i] = (x[i] + 1.) * ((b - a) / 2.) + a;
1814: w[i] *= (b - a) / 2.;
1815: }
1816: }
1817: PetscFunctionReturn(PETSC_SUCCESS);
1818: }
1820: /*@
1821: PetscDTGaussQuadrature - create Gauss-Legendre quadrature
1823: Not Collective
1825: Input Parameters:
1826: + npoints - number of points
1827: . a - left end of interval (often-1)
1828: - b - right end of interval (often +1)
1830: Output Parameters:
1831: + x - quadrature points
1832: - w - quadrature weights
1834: Level: intermediate
1836: Note:
1837: See {cite}`golub1969calculation`
1839: .seealso: `PetscDTLegendreEval()`, `PetscDTGaussJacobiQuadrature()`
1840: @*/
1841: PetscErrorCode PetscDTGaussQuadrature(PetscInt npoints, PetscReal a, PetscReal b, PetscReal *x, PetscReal *w)
1842: {
1843: PetscInt i;
1845: PetscFunctionBegin;
1846: PetscCall(PetscDTGaussJacobiQuadrature_Internal(npoints, 0., 0., x, w, PetscDTGaussQuadratureNewton_Internal));
1847: if (a != -1. || b != 1.) { /* shift */
1848: for (i = 0; i < npoints; i++) {
1849: x[i] = (x[i] + 1.) * ((b - a) / 2.) + a;
1850: w[i] *= (b - a) / 2.;
1851: }
1852: }
1853: PetscFunctionReturn(PETSC_SUCCESS);
1854: }
1856: /*@C
1857: PetscDTGaussLobattoLegendreQuadrature - creates a set of the locations and weights of the Gauss-Lobatto-Legendre
1858: nodes of a given size on the domain $[-1,1]$
1860: Not Collective
1862: Input Parameters:
1863: + npoints - number of grid nodes
1864: - type - `PETSCGAUSSLOBATTOLEGENDRE_VIA_LINEAR_ALGEBRA` or `PETSCGAUSSLOBATTOLEGENDRE_VIA_NEWTON`
1866: Output Parameters:
1867: + x - quadrature points
1868: - w - quadrature weights
1870: Level: intermediate
1872: Notes:
1873: For n > 30 the Newton approach computes duplicate (incorrect) values for some nodes because the initial guess is apparently not
1874: close enough to the desired solution
1876: These are useful for implementing spectral methods based on Gauss-Lobatto-Legendre (GLL) nodes
1878: See <https://epubs.siam.org/doi/abs/10.1137/110855442> <https://epubs.siam.org/doi/abs/10.1137/120889873> for better ways to compute GLL nodes
1880: .seealso: `PetscDTGaussQuadrature()`, `PetscGaussLobattoLegendreCreateType`
1882: @*/
1883: PetscErrorCode PetscDTGaussLobattoLegendreQuadrature(PetscInt npoints, PetscGaussLobattoLegendreCreateType type, PetscReal *x, PetscReal *w)
1884: {
1885: PetscBool newton;
1887: PetscFunctionBegin;
1888: PetscCheck(npoints >= 2, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Must provide at least 2 grid points per element");
1889: newton = (PetscBool)(type == PETSCGAUSSLOBATTOLEGENDRE_VIA_NEWTON);
1890: PetscCall(PetscDTGaussLobattoJacobiQuadrature_Internal(npoints, 0., 0., x, w, newton));
1891: PetscFunctionReturn(PETSC_SUCCESS);
1892: }
1894: /*@
1895: PetscDTGaussTensorQuadrature - creates a tensor-product Gauss quadrature
1897: Not Collective
1899: Input Parameters:
1900: + dim - The spatial dimension
1901: . Nc - The number of components
1902: . npoints - number of points in one dimension
1903: . a - left end of interval (often-1)
1904: - b - right end of interval (often +1)
1906: Output Parameter:
1907: . q - A `PetscQuadrature` object
1909: Level: intermediate
1911: .seealso: `PetscDTGaussQuadrature()`, `PetscDTLegendreEval()`
1912: @*/
1913: PetscErrorCode PetscDTGaussTensorQuadrature(PetscInt dim, PetscInt Nc, PetscInt npoints, PetscReal a, PetscReal b, PetscQuadrature *q)
1914: {
1915: DMPolytopeType ct;
1916: PetscInt totpoints = dim > 1 ? dim > 2 ? npoints * PetscSqr(npoints) : PetscSqr(npoints) : npoints;
1917: PetscReal *x, *w, *xw, *ww;
1919: PetscFunctionBegin;
1920: PetscCall(PetscMalloc1(totpoints * dim, &x));
1921: PetscCall(PetscMalloc1(totpoints * Nc, &w));
1922: /* Set up the Golub-Welsch system */
1923: switch (dim) {
1924: case 0:
1925: ct = DM_POLYTOPE_POINT;
1926: PetscCall(PetscFree(x));
1927: PetscCall(PetscFree(w));
1928: PetscCall(PetscMalloc1(1, &x));
1929: PetscCall(PetscMalloc1(Nc, &w));
1930: totpoints = 1;
1931: x[0] = 0.0;
1932: for (PetscInt c = 0; c < Nc; ++c) w[c] = 1.0;
1933: break;
1934: case 1:
1935: ct = DM_POLYTOPE_SEGMENT;
1936: PetscCall(PetscMalloc1(npoints, &ww));
1937: PetscCall(PetscDTGaussQuadrature(npoints, a, b, x, ww));
1938: for (PetscInt i = 0; i < npoints; ++i)
1939: for (PetscInt c = 0; c < Nc; ++c) w[i * Nc + c] = ww[i];
1940: PetscCall(PetscFree(ww));
1941: break;
1942: case 2:
1943: ct = DM_POLYTOPE_QUADRILATERAL;
1944: PetscCall(PetscMalloc2(npoints, &xw, npoints, &ww));
1945: PetscCall(PetscDTGaussQuadrature(npoints, a, b, xw, ww));
1946: for (PetscInt i = 0; i < npoints; ++i) {
1947: for (PetscInt j = 0; j < npoints; ++j) {
1948: x[(i * npoints + j) * dim + 0] = xw[i];
1949: x[(i * npoints + j) * dim + 1] = xw[j];
1950: for (PetscInt c = 0; c < Nc; ++c) w[(i * npoints + j) * Nc + c] = ww[i] * ww[j];
1951: }
1952: }
1953: PetscCall(PetscFree2(xw, ww));
1954: break;
1955: case 3:
1956: ct = DM_POLYTOPE_HEXAHEDRON;
1957: PetscCall(PetscMalloc2(npoints, &xw, npoints, &ww));
1958: PetscCall(PetscDTGaussQuadrature(npoints, a, b, xw, ww));
1959: for (PetscInt i = 0; i < npoints; ++i) {
1960: for (PetscInt j = 0; j < npoints; ++j) {
1961: for (PetscInt k = 0; k < npoints; ++k) {
1962: x[((i * npoints + j) * npoints + k) * dim + 0] = xw[i];
1963: x[((i * npoints + j) * npoints + k) * dim + 1] = xw[j];
1964: x[((i * npoints + j) * npoints + k) * dim + 2] = xw[k];
1965: for (PetscInt c = 0; c < Nc; ++c) w[((i * npoints + j) * npoints + k) * Nc + c] = ww[i] * ww[j] * ww[k];
1966: }
1967: }
1968: }
1969: PetscCall(PetscFree2(xw, ww));
1970: break;
1971: default:
1972: SETERRQ(PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Cannot construct quadrature rule for dimension %" PetscInt_FMT, dim);
1973: }
1974: PetscCall(PetscQuadratureCreate(PETSC_COMM_SELF, q));
1975: PetscCall(PetscQuadratureSetCellType(*q, ct));
1976: PetscCall(PetscQuadratureSetOrder(*q, 2 * npoints - 1));
1977: PetscCall(PetscQuadratureSetData(*q, dim, Nc, totpoints, x, w));
1978: PetscCall(PetscObjectChangeTypeName((PetscObject)*q, "GaussTensor"));
1979: PetscFunctionReturn(PETSC_SUCCESS);
1980: }
1982: /*@
1983: PetscDTStroudConicalQuadrature - create Stroud conical quadrature for a simplex {cite}`karniadakis2005spectral`
1985: Not Collective
1987: Input Parameters:
1988: + dim - The simplex dimension
1989: . Nc - The number of components
1990: . npoints - The number of points in one dimension
1991: . a - left end of interval (often-1)
1992: - b - right end of interval (often +1)
1994: Output Parameter:
1995: . q - A `PetscQuadrature` object
1997: Level: intermediate
1999: Note:
2000: For `dim` == 1, this is Gauss-Legendre quadrature
2002: .seealso: `PetscDTGaussTensorQuadrature()`, `PetscDTGaussQuadrature()`
2003: @*/
2004: PetscErrorCode PetscDTStroudConicalQuadrature(PetscInt dim, PetscInt Nc, PetscInt npoints, PetscReal a, PetscReal b, PetscQuadrature *q)
2005: {
2006: DMPolytopeType ct;
2007: PetscInt totpoints;
2008: PetscReal *p1, *w1;
2009: PetscReal *x, *w;
2011: PetscFunctionBegin;
2012: PetscCheck(!(a != -1.0) && !(b != 1.0), PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Must use default internal right now");
2013: switch (dim) {
2014: case 0:
2015: ct = DM_POLYTOPE_POINT;
2016: break;
2017: case 1:
2018: ct = DM_POLYTOPE_SEGMENT;
2019: break;
2020: case 2:
2021: ct = DM_POLYTOPE_TRIANGLE;
2022: break;
2023: case 3:
2024: ct = DM_POLYTOPE_TETRAHEDRON;
2025: break;
2026: default:
2027: ct = DM_POLYTOPE_UNKNOWN;
2028: }
2029: totpoints = 1;
2030: for (PetscInt i = 0; i < dim; ++i) totpoints *= npoints;
2031: PetscCall(PetscMalloc1(totpoints * dim, &x));
2032: PetscCall(PetscMalloc1(totpoints * Nc, &w));
2033: PetscCall(PetscMalloc2(npoints, &p1, npoints, &w1));
2034: for (PetscInt i = 0; i < totpoints * Nc; ++i) w[i] = 1.;
2035: for (PetscInt i = 0, totprev = 1, totrem = totpoints / npoints; i < dim; ++i) {
2036: PetscReal mul;
2038: mul = PetscPowReal(2., -i);
2039: PetscCall(PetscDTGaussJacobiQuadrature(npoints, -1., 1., i, 0.0, p1, w1));
2040: for (PetscInt pt = 0, l = 0; l < totprev; l++) {
2041: for (PetscInt j = 0; j < npoints; j++) {
2042: for (PetscInt m = 0; m < totrem; m++, pt++) {
2043: for (PetscInt k = 0; k < i; k++) x[pt * dim + k] = (x[pt * dim + k] + 1.) * (1. - p1[j]) * 0.5 - 1.;
2044: x[pt * dim + i] = p1[j];
2045: for (PetscInt c = 0; c < Nc; c++) w[pt * Nc + c] *= mul * w1[j];
2046: }
2047: }
2048: }
2049: totprev *= npoints;
2050: totrem /= npoints;
2051: }
2052: PetscCall(PetscFree2(p1, w1));
2053: PetscCall(PetscQuadratureCreate(PETSC_COMM_SELF, q));
2054: PetscCall(PetscQuadratureSetCellType(*q, ct));
2055: PetscCall(PetscQuadratureSetOrder(*q, 2 * npoints - 1));
2056: PetscCall(PetscQuadratureSetData(*q, dim, Nc, totpoints, x, w));
2057: PetscCall(PetscObjectChangeTypeName((PetscObject)*q, "StroudConical"));
2058: PetscFunctionReturn(PETSC_SUCCESS);
2059: }
2061: static PetscBool MinSymTriQuadCite = PETSC_FALSE;
2062: const char MinSymTriQuadCitation[] = "@article{WitherdenVincent2015,\n"
2063: " title = {On the identification of symmetric quadrature rules for finite element methods},\n"
2064: " journal = {Computers & Mathematics with Applications},\n"
2065: " volume = {69},\n"
2066: " number = {10},\n"
2067: " pages = {1232-1241},\n"
2068: " year = {2015},\n"
2069: " issn = {0898-1221},\n"
2070: " doi = {10.1016/j.camwa.2015.03.017},\n"
2071: " url = {https://www.sciencedirect.com/science/article/pii/S0898122115001224},\n"
2072: " author = {F.D. Witherden and P.E. Vincent},\n"
2073: "}\n";
2075: #include "petscdttriquadrules.h"
2077: static PetscBool MinSymTetQuadCite = PETSC_FALSE;
2078: const char MinSymTetQuadCitation[] = "@article{JaskowiecSukumar2021\n"
2079: " author = {Jaskowiec, Jan and Sukumar, N.},\n"
2080: " title = {High-order symmetric cubature rules for tetrahedra and pyramids},\n"
2081: " journal = {International Journal for Numerical Methods in Engineering},\n"
2082: " volume = {122},\n"
2083: " number = {1},\n"
2084: " pages = {148-171},\n"
2085: " doi = {10.1002/nme.6528},\n"
2086: " url = {https://onlinelibrary.wiley.com/doi/abs/10.1002/nme.6528},\n"
2087: " eprint = {https://onlinelibrary.wiley.com/doi/pdf/10.1002/nme.6528},\n"
2088: " year = {2021}\n"
2089: "}\n";
2091: #include "petscdttetquadrules.h"
2093: // https://en.wikipedia.org/wiki/Partition_(number_theory)
2094: static PetscErrorCode PetscDTPartitionNumber(PetscInt n, PetscInt *p)
2095: {
2096: // sequence A000041 in the OEIS
2097: const PetscInt partition[] = {1, 1, 2, 3, 5, 7, 11, 15, 22, 30, 42, 56, 77, 101, 135, 176, 231, 297, 385, 490, 627, 792, 1002, 1255, 1575, 1958, 2436, 3010, 3718, 4565, 5604};
2098: PetscInt tabulated_max = PETSC_STATIC_ARRAY_LENGTH(partition) - 1;
2100: PetscFunctionBegin;
2101: PetscCheck(n >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Partition number not defined for negative number %" PetscInt_FMT, n);
2102: // not implementing the pentagonal number recurrence, we don't need partition numbers for n that high
2103: PetscCheck(n <= tabulated_max, PETSC_COMM_SELF, PETSC_ERR_SUP, "Partition numbers only tabulated up to %" PetscInt_FMT ", not computed for %" PetscInt_FMT, tabulated_max, n);
2104: *p = partition[n];
2105: PetscFunctionReturn(PETSC_SUCCESS);
2106: }
2108: /*@
2109: PetscDTSimplexQuadrature - Create a quadrature rule for a simplex that exactly integrates polynomials up to a given degree.
2111: Not Collective
2113: Input Parameters:
2114: + dim - The spatial dimension of the simplex (1 = segment, 2 = triangle, 3 = tetrahedron)
2115: . degree - The largest polynomial degree that is required to be integrated exactly
2116: - type - left end of interval (often-1)
2118: Output Parameter:
2119: . quad - A `PetscQuadrature` object for integration over the biunit simplex
2120: (defined by the bounds $x_i >= -1$ and $\sum_i x_i <= 2 - d$) that is exact for
2121: polynomials up to the given degree
2123: Level: intermediate
2125: .seealso: `PetscDTSimplexQuadratureType`, `PetscDTGaussQuadrature()`, `PetscDTStroudCononicalQuadrature()`, `PetscQuadrature`
2126: @*/
2127: PetscErrorCode PetscDTSimplexQuadrature(PetscInt dim, PetscInt degree, PetscDTSimplexQuadratureType type, PetscQuadrature *quad)
2128: {
2129: PetscDTSimplexQuadratureType orig_type = type;
2131: PetscFunctionBegin;
2132: PetscCheck(dim >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Negative dimension %" PetscInt_FMT, dim);
2133: PetscCheck(degree >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Negative degree %" PetscInt_FMT, degree);
2134: if (type == PETSCDTSIMPLEXQUAD_DEFAULT) type = PETSCDTSIMPLEXQUAD_MINSYM;
2135: if (type == PETSCDTSIMPLEXQUAD_CONIC || dim < 2) {
2136: PetscInt points_per_dim = (degree + 2) / 2; // ceil((degree + 1) / 2);
2137: PetscCall(PetscDTStroudConicalQuadrature(dim, 1, points_per_dim, -1, 1, quad));
2138: } else {
2139: DMPolytopeType ct;
2140: PetscInt n = dim + 1;
2141: PetscInt fact = 1;
2142: PetscInt *part, *perm;
2143: PetscInt p = 0;
2144: PetscInt max_degree;
2145: const PetscInt *nodes_per_type = NULL;
2146: const PetscInt *all_num_full_nodes = NULL;
2147: const PetscReal **weights_list = NULL;
2148: const PetscReal **compact_nodes_list = NULL;
2149: const char *citation = NULL;
2150: PetscBool *cited = NULL;
2152: switch (dim) {
2153: case 0:
2154: ct = DM_POLYTOPE_POINT;
2155: break;
2156: case 1:
2157: ct = DM_POLYTOPE_SEGMENT;
2158: break;
2159: case 2:
2160: ct = DM_POLYTOPE_TRIANGLE;
2161: break;
2162: case 3:
2163: ct = DM_POLYTOPE_TETRAHEDRON;
2164: break;
2165: default:
2166: ct = DM_POLYTOPE_UNKNOWN;
2167: }
2168: switch (dim) {
2169: case 2:
2170: cited = &MinSymTriQuadCite;
2171: citation = MinSymTriQuadCitation;
2172: max_degree = PetscDTWVTriQuad_max_degree;
2173: nodes_per_type = PetscDTWVTriQuad_num_orbits;
2174: all_num_full_nodes = PetscDTWVTriQuad_num_nodes;
2175: weights_list = PetscDTWVTriQuad_weights;
2176: compact_nodes_list = PetscDTWVTriQuad_orbits;
2177: break;
2178: case 3:
2179: cited = &MinSymTetQuadCite;
2180: citation = MinSymTetQuadCitation;
2181: max_degree = PetscDTJSTetQuad_max_degree;
2182: nodes_per_type = PetscDTJSTetQuad_num_orbits;
2183: all_num_full_nodes = PetscDTJSTetQuad_num_nodes;
2184: weights_list = PetscDTJSTetQuad_weights;
2185: compact_nodes_list = PetscDTJSTetQuad_orbits;
2186: break;
2187: default:
2188: max_degree = -1;
2189: break;
2190: }
2192: if (degree > max_degree) {
2193: if (orig_type == PETSCDTSIMPLEXQUAD_DEFAULT) {
2194: // fall back to conic
2195: PetscCall(PetscDTSimplexQuadrature(dim, degree, PETSCDTSIMPLEXQUAD_CONIC, quad));
2196: PetscFunctionReturn(PETSC_SUCCESS);
2197: } else SETERRQ(PETSC_COMM_SELF, PETSC_ERR_SUP, "Minimal symmetric quadrature for dim %" PetscInt_FMT ", degree %" PetscInt_FMT " unsupported", dim, degree);
2198: }
2200: PetscCall(PetscCitationsRegister(citation, cited));
2202: PetscCall(PetscDTPartitionNumber(n, &p));
2203: for (PetscInt d = 2; d <= n; d++) fact *= d;
2205: PetscInt num_full_nodes = all_num_full_nodes[degree];
2206: const PetscReal *all_compact_nodes = compact_nodes_list[degree];
2207: const PetscReal *all_compact_weights = weights_list[degree];
2208: nodes_per_type = &nodes_per_type[p * degree];
2210: PetscReal *points;
2211: PetscReal *counts;
2212: PetscReal *weights;
2213: PetscReal *bary_to_biunit; // row-major transformation of barycentric coordinate to biunit
2214: PetscQuadrature q;
2216: // compute the transformation
2217: PetscCall(PetscMalloc1(n * dim, &bary_to_biunit));
2218: for (PetscInt d = 0; d < dim; d++) {
2219: for (PetscInt b = 0; b < n; b++) bary_to_biunit[d * n + b] = (d == b) ? 1.0 : -1.0;
2220: }
2222: PetscCall(PetscMalloc3(n, &part, n, &perm, n, &counts));
2223: PetscCall(PetscCalloc1(num_full_nodes * dim, &points));
2224: PetscCall(PetscMalloc1(num_full_nodes, &weights));
2226: // (0, 0, ...) is the first partition lexicographically
2227: PetscCall(PetscArrayzero(part, n));
2228: PetscCall(PetscArrayzero(counts, n));
2229: counts[0] = n;
2231: // for each partition
2232: for (PetscInt s = 0, node_offset = 0; s < p; s++) {
2233: PetscInt num_compact_coords = part[n - 1] + 1;
2235: const PetscReal *compact_nodes = all_compact_nodes;
2236: const PetscReal *compact_weights = all_compact_weights;
2237: all_compact_nodes += num_compact_coords * nodes_per_type[s];
2238: all_compact_weights += nodes_per_type[s];
2240: // for every permutation of the vertices
2241: for (PetscInt f = 0; f < fact; f++) {
2242: PetscCall(PetscDTEnumPerm(n, f, perm, NULL));
2244: // check if it is a valid permutation
2245: PetscInt digit;
2246: for (digit = 1; digit < n; digit++) {
2247: // skip permutations that would duplicate a node because it has a smaller symmetry group
2248: if (part[digit - 1] == part[digit] && perm[digit - 1] > perm[digit]) break;
2249: }
2250: if (digit < n) continue;
2252: // create full nodes from this permutation of the compact nodes
2253: PetscReal *full_nodes = &points[node_offset * dim];
2254: PetscReal *full_weights = &weights[node_offset];
2256: PetscCall(PetscArraycpy(full_weights, compact_weights, nodes_per_type[s]));
2257: for (PetscInt b = 0; b < n; b++) {
2258: for (PetscInt d = 0; d < dim; d++) {
2259: for (PetscInt node = 0; node < nodes_per_type[s]; node++) full_nodes[node * dim + d] += bary_to_biunit[d * n + perm[b]] * compact_nodes[node * num_compact_coords + part[b]];
2260: }
2261: }
2262: node_offset += nodes_per_type[s];
2263: }
2265: if (s < p - 1) { // Generate the next partition
2266: /* A partition is described by the number of coordinates that are in
2267: * each set of duplicates (counts) and redundantly by mapping each
2268: * index to its set of duplicates (part)
2269: *
2270: * Counts should always be in nonincreasing order
2271: *
2272: * We want to generate the partitions lexically by part, which means
2273: * finding the last index where count > 1 and reducing by 1.
2274: *
2275: * For the new counts beyond that index, we eagerly assign the remaining
2276: * capacity of the partition to smaller indices (ensures lexical ordering),
2277: * while respecting the nonincreasing invariant of the counts
2278: */
2279: PetscInt last_digit = part[n - 1];
2280: PetscInt last_digit_with_extra = last_digit;
2281: while (counts[last_digit_with_extra] == 1) last_digit_with_extra--;
2282: PetscInt limit = --counts[last_digit_with_extra];
2283: PetscInt total_to_distribute = last_digit - last_digit_with_extra + 1;
2284: for (PetscInt digit = last_digit_with_extra + 1; digit < n; digit++) {
2285: counts[digit] = PetscMin(limit, total_to_distribute);
2286: total_to_distribute -= PetscMin(limit, total_to_distribute);
2287: }
2288: for (PetscInt digit = 0, offset = 0; digit < n; digit++) {
2289: PetscInt count = counts[digit];
2290: for (PetscInt c = 0; c < count; c++) part[offset++] = digit;
2291: }
2292: }
2293: }
2294: PetscCall(PetscFree3(part, perm, counts));
2295: PetscCall(PetscFree(bary_to_biunit));
2296: PetscCall(PetscQuadratureCreate(PETSC_COMM_SELF, &q));
2297: PetscCall(PetscQuadratureSetCellType(q, ct));
2298: PetscCall(PetscQuadratureSetOrder(q, degree));
2299: PetscCall(PetscQuadratureSetData(q, dim, 1, num_full_nodes, points, weights));
2300: *quad = q;
2301: }
2302: PetscFunctionReturn(PETSC_SUCCESS);
2303: }
2305: /*@
2306: PetscDTTanhSinhTensorQuadrature - create tanh-sinh quadrature for a tensor product cell
2308: Not Collective
2310: Input Parameters:
2311: + dim - The cell dimension
2312: . level - The number of points in one dimension, $2^l$
2313: . a - left end of interval (often-1)
2314: - b - right end of interval (often +1)
2316: Output Parameter:
2317: . q - A `PetscQuadrature` object
2319: Level: intermediate
2321: .seealso: `PetscDTGaussTensorQuadrature()`, `PetscQuadrature`
2322: @*/
2323: PetscErrorCode PetscDTTanhSinhTensorQuadrature(PetscInt dim, PetscInt level, PetscReal a, PetscReal b, PetscQuadrature *q)
2324: {
2325: DMPolytopeType ct;
2326: const PetscInt p = 16; /* Digits of precision in the evaluation */
2327: const PetscReal alpha = (b - a) / 2.; /* Half-width of the integration interval */
2328: const PetscReal beta = (b + a) / 2.; /* Center of the integration interval */
2329: const PetscReal h = PetscPowReal(2.0, -level); /* Step size, length between x_k */
2330: PetscReal xk; /* Quadrature point x_k on reference domain [-1, 1] */
2331: PetscReal wk = 0.5 * PETSC_PI; /* Quadrature weight at x_k */
2332: PetscReal *x, *w;
2333: PetscInt K, k, npoints;
2335: PetscFunctionBegin;
2336: PetscCheck(dim <= 1, PETSC_COMM_SELF, PETSC_ERR_SUP, "Dimension %" PetscInt_FMT " not yet implemented", dim);
2337: PetscCheck(level, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Must give a number of significant digits");
2338: switch (dim) {
2339: case 0:
2340: ct = DM_POLYTOPE_POINT;
2341: break;
2342: case 1:
2343: ct = DM_POLYTOPE_SEGMENT;
2344: break;
2345: case 2:
2346: ct = DM_POLYTOPE_QUADRILATERAL;
2347: break;
2348: case 3:
2349: ct = DM_POLYTOPE_HEXAHEDRON;
2350: break;
2351: default:
2352: ct = DM_POLYTOPE_UNKNOWN;
2353: }
2354: /* Find K such that the weights are < 32 digits of precision */
2355: for (K = 1; PetscAbsReal(PetscLog10Real(wk)) < 2 * p; ++K) wk = 0.5 * h * PETSC_PI * PetscCoshReal(K * h) / PetscSqr(PetscCoshReal(0.5 * PETSC_PI * PetscSinhReal(K * h)));
2356: PetscCall(PetscQuadratureCreate(PETSC_COMM_SELF, q));
2357: PetscCall(PetscQuadratureSetCellType(*q, ct));
2358: PetscCall(PetscQuadratureSetOrder(*q, 2 * K + 1));
2359: npoints = 2 * K - 1;
2360: PetscCall(PetscMalloc1(npoints * dim, &x));
2361: PetscCall(PetscMalloc1(npoints, &w));
2362: /* Center term */
2363: x[0] = beta;
2364: w[0] = 0.5 * alpha * PETSC_PI;
2365: for (k = 1; k < K; ++k) {
2366: wk = 0.5 * alpha * h * PETSC_PI * PetscCoshReal(k * h) / PetscSqr(PetscCoshReal(0.5 * PETSC_PI * PetscSinhReal(k * h)));
2367: xk = PetscTanhReal(0.5 * PETSC_PI * PetscSinhReal(k * h));
2368: x[2 * k - 1] = -alpha * xk + beta;
2369: w[2 * k - 1] = wk;
2370: x[2 * k + 0] = alpha * xk + beta;
2371: w[2 * k + 0] = wk;
2372: }
2373: PetscCall(PetscQuadratureSetData(*q, dim, 1, npoints, x, w));
2374: PetscFunctionReturn(PETSC_SUCCESS);
2375: }
2377: PetscErrorCode PetscDTTanhSinhIntegrate(void (*func)(const PetscReal[], void *, PetscReal *), PetscReal a, PetscReal b, PetscInt digits, void *ctx, PetscReal *sol)
2378: {
2379: const PetscInt p = 16; /* Digits of precision in the evaluation */
2380: const PetscReal alpha = (b - a) / 2.; /* Half-width of the integration interval */
2381: const PetscReal beta = (b + a) / 2.; /* Center of the integration interval */
2382: PetscReal h = 1.0; /* Step size, length between x_k */
2383: PetscInt l = 0; /* Level of refinement, h = 2^{-l} */
2384: PetscReal osum = 0.0; /* Integral on last level */
2385: PetscReal psum = 0.0; /* Integral on the level before the last level */
2386: PetscReal sum; /* Integral on current level */
2387: PetscReal yk; /* Quadrature point 1 - x_k on reference domain [-1, 1] */
2388: PetscReal lx, rx; /* Quadrature points to the left and right of 0 on the real domain [a, b] */
2389: PetscReal wk; /* Quadrature weight at x_k */
2390: PetscReal lval, rval; /* Terms in the quadature sum to the left and right of 0 */
2391: PetscInt d; /* Digits of precision in the integral */
2393: PetscFunctionBegin;
2394: PetscCheck(digits > 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Must give a positive number of significant digits");
2395: PetscCall(PetscFPTrapPush(PETSC_FP_TRAP_OFF));
2396: /* Center term */
2397: func(&beta, ctx, &lval);
2398: sum = 0.5 * alpha * PETSC_PI * lval;
2399: /* */
2400: do {
2401: PetscReal lterm, rterm, maxTerm = 0.0, d1, d2, d3, d4;
2402: PetscInt k = 1;
2404: ++l;
2405: /* PetscPrintf(PETSC_COMM_SELF, "LEVEL %" PetscInt_FMT " sum: %15.15f\n", l, sum); */
2406: /* At each level of refinement, h --> h/2 and sum --> sum/2 */
2407: psum = osum;
2408: osum = sum;
2409: h *= 0.5;
2410: sum *= 0.5;
2411: do {
2412: wk = 0.5 * h * PETSC_PI * PetscCoshReal(k * h) / PetscSqr(PetscCoshReal(0.5 * PETSC_PI * PetscSinhReal(k * h)));
2413: yk = 1.0 / (PetscExpReal(0.5 * PETSC_PI * PetscSinhReal(k * h)) * PetscCoshReal(0.5 * PETSC_PI * PetscSinhReal(k * h)));
2414: lx = -alpha * (1.0 - yk) + beta;
2415: rx = alpha * (1.0 - yk) + beta;
2416: func(&lx, ctx, &lval);
2417: func(&rx, ctx, &rval);
2418: lterm = alpha * wk * lval;
2419: maxTerm = PetscMax(PetscAbsReal(lterm), maxTerm);
2420: sum += lterm;
2421: rterm = alpha * wk * rval;
2422: maxTerm = PetscMax(PetscAbsReal(rterm), maxTerm);
2423: sum += rterm;
2424: ++k;
2425: /* Only need to evaluate every other point on refined levels */
2426: if (l != 1) ++k;
2427: } while (PetscAbsReal(PetscLog10Real(wk)) < p); /* Only need to evaluate sum until weights are < 32 digits of precision */
2429: d1 = PetscLog10Real(PetscAbsReal(sum - osum));
2430: d2 = PetscLog10Real(PetscAbsReal(sum - psum));
2431: d3 = PetscLog10Real(maxTerm) - p;
2432: if (PetscMax(PetscAbsReal(lterm), PetscAbsReal(rterm)) == 0.0) d4 = 0.0;
2433: else d4 = PetscLog10Real(PetscMax(PetscAbsReal(lterm), PetscAbsReal(rterm)));
2434: d = PetscAbsInt(PetscMin(0, PetscMax(PetscMax(PetscMax(PetscSqr(d1) / d2, 2 * d1), d3), d4)));
2435: } while (d < digits && l < 12);
2436: *sol = sum;
2437: PetscCall(PetscFPTrapPop());
2438: PetscFunctionReturn(PETSC_SUCCESS);
2439: }
2441: #if defined(PETSC_HAVE_MPFR)
2442: PetscErrorCode PetscDTTanhSinhIntegrateMPFR(void (*func)(const PetscReal[], void *, PetscReal *), PetscReal a, PetscReal b, PetscInt digits, void *ctx, PetscReal *sol)
2443: {
2444: const PetscInt safetyFactor = 2; /* Calculate abcissa until 2*p digits */
2445: PetscInt l = 0; /* Level of refinement, h = 2^{-l} */
2446: mpfr_t alpha; /* Half-width of the integration interval */
2447: mpfr_t beta; /* Center of the integration interval */
2448: mpfr_t h; /* Step size, length between x_k */
2449: mpfr_t osum; /* Integral on last level */
2450: mpfr_t psum; /* Integral on the level before the last level */
2451: mpfr_t sum; /* Integral on current level */
2452: mpfr_t yk; /* Quadrature point 1 - x_k on reference domain [-1, 1] */
2453: mpfr_t lx, rx; /* Quadrature points to the left and right of 0 on the real domain [a, b] */
2454: mpfr_t wk; /* Quadrature weight at x_k */
2455: PetscReal lval, rval, rtmp; /* Terms in the quadature sum to the left and right of 0 */
2456: PetscInt d; /* Digits of precision in the integral */
2457: mpfr_t pi2, kh, msinh, mcosh, maxTerm, curTerm, tmp;
2459: PetscFunctionBegin;
2460: PetscCheck(digits > 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Must give a positive number of significant digits");
2461: /* Create high precision storage */
2462: mpfr_inits2(PetscCeilReal(safetyFactor * digits * PetscLogReal(10.) / PetscLogReal(2.)), alpha, beta, h, sum, osum, psum, yk, wk, lx, rx, tmp, maxTerm, curTerm, pi2, kh, msinh, mcosh, NULL);
2463: /* Initialization */
2464: mpfr_set_d(alpha, 0.5 * (b - a), MPFR_RNDN);
2465: mpfr_set_d(beta, 0.5 * (b + a), MPFR_RNDN);
2466: mpfr_set_d(osum, 0.0, MPFR_RNDN);
2467: mpfr_set_d(psum, 0.0, MPFR_RNDN);
2468: mpfr_set_d(h, 1.0, MPFR_RNDN);
2469: mpfr_const_pi(pi2, MPFR_RNDN);
2470: mpfr_mul_d(pi2, pi2, 0.5, MPFR_RNDN);
2471: /* Center term */
2472: rtmp = 0.5 * (b + a);
2473: func(&rtmp, ctx, &lval);
2474: mpfr_set(sum, pi2, MPFR_RNDN);
2475: mpfr_mul(sum, sum, alpha, MPFR_RNDN);
2476: mpfr_mul_d(sum, sum, lval, MPFR_RNDN);
2477: /* */
2478: do {
2479: PetscReal d1, d2, d3, d4;
2480: PetscInt k = 1;
2482: ++l;
2483: mpfr_set_d(maxTerm, 0.0, MPFR_RNDN);
2484: /* PetscPrintf(PETSC_COMM_SELF, "LEVEL %" PetscInt_FMT " sum: %15.15f\n", l, sum); */
2485: /* At each level of refinement, h --> h/2 and sum --> sum/2 */
2486: mpfr_set(psum, osum, MPFR_RNDN);
2487: mpfr_set(osum, sum, MPFR_RNDN);
2488: mpfr_mul_d(h, h, 0.5, MPFR_RNDN);
2489: mpfr_mul_d(sum, sum, 0.5, MPFR_RNDN);
2490: do {
2491: mpfr_set_si(kh, k, MPFR_RNDN);
2492: mpfr_mul(kh, kh, h, MPFR_RNDN);
2493: /* Weight */
2494: mpfr_set(wk, h, MPFR_RNDN);
2495: mpfr_sinh_cosh(msinh, mcosh, kh, MPFR_RNDN);
2496: mpfr_mul(msinh, msinh, pi2, MPFR_RNDN);
2497: mpfr_mul(mcosh, mcosh, pi2, MPFR_RNDN);
2498: mpfr_cosh(tmp, msinh, MPFR_RNDN);
2499: mpfr_sqr(tmp, tmp, MPFR_RNDN);
2500: mpfr_mul(wk, wk, mcosh, MPFR_RNDN);
2501: mpfr_div(wk, wk, tmp, MPFR_RNDN);
2502: /* Abscissa */
2503: mpfr_set_d(yk, 1.0, MPFR_RNDZ);
2504: mpfr_cosh(tmp, msinh, MPFR_RNDN);
2505: mpfr_div(yk, yk, tmp, MPFR_RNDZ);
2506: mpfr_exp(tmp, msinh, MPFR_RNDN);
2507: mpfr_div(yk, yk, tmp, MPFR_RNDZ);
2508: /* Quadrature points */
2509: mpfr_sub_d(lx, yk, 1.0, MPFR_RNDZ);
2510: mpfr_mul(lx, lx, alpha, MPFR_RNDU);
2511: mpfr_add(lx, lx, beta, MPFR_RNDU);
2512: mpfr_d_sub(rx, 1.0, yk, MPFR_RNDZ);
2513: mpfr_mul(rx, rx, alpha, MPFR_RNDD);
2514: mpfr_add(rx, rx, beta, MPFR_RNDD);
2515: /* Evaluation */
2516: rtmp = mpfr_get_d(lx, MPFR_RNDU);
2517: func(&rtmp, ctx, &lval);
2518: rtmp = mpfr_get_d(rx, MPFR_RNDD);
2519: func(&rtmp, ctx, &rval);
2520: /* Update */
2521: mpfr_mul(tmp, wk, alpha, MPFR_RNDN);
2522: mpfr_mul_d(tmp, tmp, lval, MPFR_RNDN);
2523: mpfr_add(sum, sum, tmp, MPFR_RNDN);
2524: mpfr_abs(tmp, tmp, MPFR_RNDN);
2525: mpfr_max(maxTerm, maxTerm, tmp, MPFR_RNDN);
2526: mpfr_set(curTerm, tmp, MPFR_RNDN);
2527: mpfr_mul(tmp, wk, alpha, MPFR_RNDN);
2528: mpfr_mul_d(tmp, tmp, rval, MPFR_RNDN);
2529: mpfr_add(sum, sum, tmp, MPFR_RNDN);
2530: mpfr_abs(tmp, tmp, MPFR_RNDN);
2531: mpfr_max(maxTerm, maxTerm, tmp, MPFR_RNDN);
2532: mpfr_max(curTerm, curTerm, tmp, MPFR_RNDN);
2533: ++k;
2534: /* Only need to evaluate every other point on refined levels */
2535: if (l != 1) ++k;
2536: mpfr_log10(tmp, wk, MPFR_RNDN);
2537: mpfr_abs(tmp, tmp, MPFR_RNDN);
2538: } while (mpfr_get_d(tmp, MPFR_RNDN) < safetyFactor * digits); /* Only need to evaluate sum until weights are < 32 digits of precision */
2539: mpfr_sub(tmp, sum, osum, MPFR_RNDN);
2540: mpfr_abs(tmp, tmp, MPFR_RNDN);
2541: mpfr_log10(tmp, tmp, MPFR_RNDN);
2542: d1 = mpfr_get_d(tmp, MPFR_RNDN);
2543: mpfr_sub(tmp, sum, psum, MPFR_RNDN);
2544: mpfr_abs(tmp, tmp, MPFR_RNDN);
2545: mpfr_log10(tmp, tmp, MPFR_RNDN);
2546: d2 = mpfr_get_d(tmp, MPFR_RNDN);
2547: mpfr_log10(tmp, maxTerm, MPFR_RNDN);
2548: d3 = mpfr_get_d(tmp, MPFR_RNDN) - digits;
2549: mpfr_log10(tmp, curTerm, MPFR_RNDN);
2550: d4 = mpfr_get_d(tmp, MPFR_RNDN);
2551: d = PetscAbsInt(PetscMin(0, PetscMax(PetscMax(PetscMax(PetscSqr(d1) / d2, 2 * d1), d3), d4)));
2552: } while (d < digits && l < 8);
2553: *sol = mpfr_get_d(sum, MPFR_RNDN);
2554: /* Cleanup */
2555: mpfr_clears(alpha, beta, h, sum, osum, psum, yk, wk, lx, rx, tmp, maxTerm, curTerm, pi2, kh, msinh, mcosh, NULL);
2556: PetscFunctionReturn(PETSC_SUCCESS);
2557: }
2558: #else
2560: PetscErrorCode PetscDTTanhSinhIntegrateMPFR(void (*func)(const PetscReal[], void *, PetscReal *), PetscReal a, PetscReal b, PetscInt digits, void *ctx, PetscReal *sol)
2561: {
2562: SETERRQ(PETSC_COMM_SELF, PETSC_ERR_SUP, "This method will not work without MPFR. Reconfigure using --download-mpfr --download-gmp");
2563: }
2564: #endif
2566: /*@
2567: PetscDTTensorQuadratureCreate - create the tensor product quadrature from two lower-dimensional quadratures
2569: Not Collective
2571: Input Parameters:
2572: + q1 - The first quadrature
2573: - q2 - The second quadrature
2575: Output Parameter:
2576: . q - A `PetscQuadrature` object
2578: Level: intermediate
2580: .seealso: `PetscQuadrature`, `PetscDTGaussTensorQuadrature()`
2581: @*/
2582: PetscErrorCode PetscDTTensorQuadratureCreate(PetscQuadrature q1, PetscQuadrature q2, PetscQuadrature *q)
2583: {
2584: DMPolytopeType ct1, ct2, ct;
2585: const PetscReal *x1, *w1, *x2, *w2;
2586: PetscReal *x, *w;
2587: PetscInt dim1, Nc1, Np1, order1, qa, d1;
2588: PetscInt dim2, Nc2, Np2, order2, qb, d2;
2589: PetscInt dim, Nc, Np, order, qc, d;
2591: PetscFunctionBegin;
2594: PetscAssertPointer(q, 3);
2595: PetscCall(PetscQuadratureGetOrder(q1, &order1));
2596: PetscCall(PetscQuadratureGetOrder(q2, &order2));
2597: PetscCheck(order1 == order2, PETSC_COMM_SELF, PETSC_ERR_ARG_INCOMP, "Order1 %" PetscInt_FMT " != %" PetscInt_FMT " Order2", order1, order2);
2598: PetscCall(PetscQuadratureGetData(q1, &dim1, &Nc1, &Np1, &x1, &w1));
2599: PetscCall(PetscQuadratureGetCellType(q1, &ct1));
2600: PetscCall(PetscQuadratureGetData(q2, &dim2, &Nc2, &Np2, &x2, &w2));
2601: PetscCall(PetscQuadratureGetCellType(q2, &ct2));
2602: PetscCheck(Nc1 == Nc2, PETSC_COMM_SELF, PETSC_ERR_ARG_INCOMP, "NumComp1 %" PetscInt_FMT " != %" PetscInt_FMT " NumComp2", Nc1, Nc2);
2604: switch (ct1) {
2605: case DM_POLYTOPE_POINT:
2606: ct = ct2;
2607: break;
2608: case DM_POLYTOPE_SEGMENT:
2609: switch (ct2) {
2610: case DM_POLYTOPE_POINT:
2611: ct = ct1;
2612: break;
2613: case DM_POLYTOPE_SEGMENT:
2614: ct = DM_POLYTOPE_QUADRILATERAL;
2615: break;
2616: case DM_POLYTOPE_TRIANGLE:
2617: ct = DM_POLYTOPE_TRI_PRISM;
2618: break;
2619: case DM_POLYTOPE_QUADRILATERAL:
2620: ct = DM_POLYTOPE_HEXAHEDRON;
2621: break;
2622: case DM_POLYTOPE_TETRAHEDRON:
2623: ct = DM_POLYTOPE_UNKNOWN;
2624: break;
2625: case DM_POLYTOPE_HEXAHEDRON:
2626: ct = DM_POLYTOPE_UNKNOWN;
2627: break;
2628: default:
2629: ct = DM_POLYTOPE_UNKNOWN;
2630: }
2631: break;
2632: case DM_POLYTOPE_TRIANGLE:
2633: switch (ct2) {
2634: case DM_POLYTOPE_POINT:
2635: ct = ct1;
2636: break;
2637: case DM_POLYTOPE_SEGMENT:
2638: ct = DM_POLYTOPE_TRI_PRISM;
2639: break;
2640: case DM_POLYTOPE_TRIANGLE:
2641: ct = DM_POLYTOPE_UNKNOWN;
2642: break;
2643: case DM_POLYTOPE_QUADRILATERAL:
2644: ct = DM_POLYTOPE_UNKNOWN;
2645: break;
2646: case DM_POLYTOPE_TETRAHEDRON:
2647: ct = DM_POLYTOPE_UNKNOWN;
2648: break;
2649: case DM_POLYTOPE_HEXAHEDRON:
2650: ct = DM_POLYTOPE_UNKNOWN;
2651: break;
2652: default:
2653: ct = DM_POLYTOPE_UNKNOWN;
2654: }
2655: break;
2656: case DM_POLYTOPE_QUADRILATERAL:
2657: switch (ct2) {
2658: case DM_POLYTOPE_POINT:
2659: ct = ct1;
2660: break;
2661: case DM_POLYTOPE_SEGMENT:
2662: ct = DM_POLYTOPE_HEXAHEDRON;
2663: break;
2664: case DM_POLYTOPE_TRIANGLE:
2665: ct = DM_POLYTOPE_UNKNOWN;
2666: break;
2667: case DM_POLYTOPE_QUADRILATERAL:
2668: ct = DM_POLYTOPE_UNKNOWN;
2669: break;
2670: case DM_POLYTOPE_TETRAHEDRON:
2671: ct = DM_POLYTOPE_UNKNOWN;
2672: break;
2673: case DM_POLYTOPE_HEXAHEDRON:
2674: ct = DM_POLYTOPE_UNKNOWN;
2675: break;
2676: default:
2677: ct = DM_POLYTOPE_UNKNOWN;
2678: }
2679: break;
2680: case DM_POLYTOPE_TETRAHEDRON:
2681: switch (ct2) {
2682: case DM_POLYTOPE_POINT:
2683: ct = ct1;
2684: break;
2685: case DM_POLYTOPE_SEGMENT:
2686: ct = DM_POLYTOPE_UNKNOWN;
2687: break;
2688: case DM_POLYTOPE_TRIANGLE:
2689: ct = DM_POLYTOPE_UNKNOWN;
2690: break;
2691: case DM_POLYTOPE_QUADRILATERAL:
2692: ct = DM_POLYTOPE_UNKNOWN;
2693: break;
2694: case DM_POLYTOPE_TETRAHEDRON:
2695: ct = DM_POLYTOPE_UNKNOWN;
2696: break;
2697: case DM_POLYTOPE_HEXAHEDRON:
2698: ct = DM_POLYTOPE_UNKNOWN;
2699: break;
2700: default:
2701: ct = DM_POLYTOPE_UNKNOWN;
2702: }
2703: break;
2704: case DM_POLYTOPE_HEXAHEDRON:
2705: switch (ct2) {
2706: case DM_POLYTOPE_POINT:
2707: ct = ct1;
2708: break;
2709: case DM_POLYTOPE_SEGMENT:
2710: ct = DM_POLYTOPE_UNKNOWN;
2711: break;
2712: case DM_POLYTOPE_TRIANGLE:
2713: ct = DM_POLYTOPE_UNKNOWN;
2714: break;
2715: case DM_POLYTOPE_QUADRILATERAL:
2716: ct = DM_POLYTOPE_UNKNOWN;
2717: break;
2718: case DM_POLYTOPE_TETRAHEDRON:
2719: ct = DM_POLYTOPE_UNKNOWN;
2720: break;
2721: case DM_POLYTOPE_HEXAHEDRON:
2722: ct = DM_POLYTOPE_UNKNOWN;
2723: break;
2724: default:
2725: ct = DM_POLYTOPE_UNKNOWN;
2726: }
2727: break;
2728: default:
2729: ct = DM_POLYTOPE_UNKNOWN;
2730: }
2731: dim = dim1 + dim2;
2732: Nc = Nc1;
2733: Np = Np1 * Np2;
2734: order = order1;
2735: PetscCall(PetscQuadratureCreate(PETSC_COMM_SELF, q));
2736: PetscCall(PetscQuadratureSetCellType(*q, ct));
2737: PetscCall(PetscQuadratureSetOrder(*q, order));
2738: PetscCall(PetscMalloc1(Np * dim, &x));
2739: PetscCall(PetscMalloc1(Np, &w));
2740: for (qa = 0, qc = 0; qa < Np1; ++qa) {
2741: for (qb = 0; qb < Np2; ++qb, ++qc) {
2742: for (d1 = 0, d = 0; d1 < dim1; ++d1, ++d) x[qc * dim + d] = x1[qa * dim1 + d1];
2743: for (d2 = 0; d2 < dim2; ++d2, ++d) x[qc * dim + d] = x2[qb * dim2 + d2];
2744: w[qc] = w1[qa] * w2[qb];
2745: }
2746: }
2747: PetscCall(PetscQuadratureSetData(*q, dim, Nc, Np, x, w));
2748: PetscFunctionReturn(PETSC_SUCCESS);
2749: }
2751: /* Overwrites A. Can only handle full-rank problems with m>=n
2752: A in column-major format
2753: Ainv in row-major format
2754: tau has length m
2755: worksize must be >= max(1,n)
2756: */
2757: static PetscErrorCode PetscDTPseudoInverseQR(PetscInt m, PetscInt mstride, PetscInt n, PetscReal *A_in, PetscReal *Ainv_out, PetscScalar *tau, PetscInt worksize, PetscScalar *work)
2758: {
2759: PetscBLASInt M, N, K, lda, ldb, ldwork, info;
2760: PetscScalar *A, *Ainv, *R, *Q, Alpha;
2762: PetscFunctionBegin;
2763: #if defined(PETSC_USE_COMPLEX)
2764: {
2765: PetscInt i, j;
2766: PetscCall(PetscMalloc2(m * n, &A, m * n, &Ainv));
2767: for (j = 0; j < n; j++) {
2768: for (i = 0; i < m; i++) A[i + m * j] = A_in[i + mstride * j];
2769: }
2770: mstride = m;
2771: }
2772: #else
2773: A = A_in;
2774: Ainv = Ainv_out;
2775: #endif
2777: PetscCall(PetscBLASIntCast(m, &M));
2778: PetscCall(PetscBLASIntCast(n, &N));
2779: PetscCall(PetscBLASIntCast(mstride, &lda));
2780: PetscCall(PetscBLASIntCast(worksize, &ldwork));
2781: PetscCall(PetscFPTrapPush(PETSC_FP_TRAP_OFF));
2782: PetscCallBLAS("LAPACKgeqrf", LAPACKgeqrf_(&M, &N, A, &lda, tau, work, &ldwork, &info));
2783: PetscCall(PetscFPTrapPop());
2784: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_LIB, "xGEQRF error");
2785: R = A; /* Upper triangular part of A now contains R, the rest contains the elementary reflectors */
2787: /* Extract an explicit representation of Q */
2788: Q = Ainv;
2789: PetscCall(PetscArraycpy(Q, A, mstride * n));
2790: K = N; /* full rank */
2791: PetscCallBLAS("LAPACKorgqr", LAPACKorgqr_(&M, &N, &K, Q, &lda, tau, work, &ldwork, &info));
2792: PetscCheck(!info, PETSC_COMM_SELF, PETSC_ERR_LIB, "xORGQR/xUNGQR error");
2794: /* Compute A^{-T} = (R^{-1} Q^T)^T = Q R^{-T} */
2795: Alpha = 1.0;
2796: ldb = lda;
2797: PetscCallBLAS("BLAStrsm", BLAStrsm_("Right", "Upper", "ConjugateTranspose", "NotUnitTriangular", &M, &N, &Alpha, R, &lda, Q, &ldb));
2798: /* Ainv is Q, overwritten with inverse */
2800: #if defined(PETSC_USE_COMPLEX)
2801: {
2802: PetscInt i;
2803: for (i = 0; i < m * n; i++) Ainv_out[i] = PetscRealPart(Ainv[i]);
2804: PetscCall(PetscFree2(A, Ainv));
2805: }
2806: #endif
2807: PetscFunctionReturn(PETSC_SUCCESS);
2808: }
2810: /* Computes integral of L_p' over intervals {(x0,x1),(x1,x2),...} */
2811: static PetscErrorCode PetscDTLegendreIntegrate(PetscInt ninterval, const PetscReal *x, PetscInt ndegree, const PetscInt *degrees, PetscBool Transpose, PetscReal *B)
2812: {
2813: PetscReal *Bv;
2814: PetscInt i, j;
2816: PetscFunctionBegin;
2817: PetscCall(PetscMalloc1((ninterval + 1) * ndegree, &Bv));
2818: /* Point evaluation of L_p on all the source vertices */
2819: PetscCall(PetscDTLegendreEval(ninterval + 1, x, ndegree, degrees, Bv, NULL, NULL));
2820: /* Integral over each interval: \int_a^b L_p' = L_p(b)-L_p(a) */
2821: for (i = 0; i < ninterval; i++) {
2822: for (j = 0; j < ndegree; j++) {
2823: if (Transpose) B[i + ninterval * j] = Bv[(i + 1) * ndegree + j] - Bv[i * ndegree + j];
2824: else B[i * ndegree + j] = Bv[(i + 1) * ndegree + j] - Bv[i * ndegree + j];
2825: }
2826: }
2827: PetscCall(PetscFree(Bv));
2828: PetscFunctionReturn(PETSC_SUCCESS);
2829: }
2831: /*@
2832: PetscDTReconstructPoly - create matrix representing polynomial reconstruction using cell intervals and evaluation at target intervals
2834: Not Collective
2836: Input Parameters:
2837: + degree - degree of reconstruction polynomial
2838: . nsource - number of source intervals
2839: . sourcex - sorted coordinates of source cell boundaries (length `nsource`+1)
2840: . ntarget - number of target intervals
2841: - targetx - sorted coordinates of target cell boundaries (length `ntarget`+1)
2843: Output Parameter:
2844: . R - reconstruction matrix, utarget = sum_s R[t*nsource+s] * usource[s]
2846: Level: advanced
2848: .seealso: `PetscDTLegendreEval()`
2849: @*/
2850: PetscErrorCode PetscDTReconstructPoly(PetscInt degree, PetscInt nsource, const PetscReal *sourcex, PetscInt ntarget, const PetscReal *targetx, PetscReal *R)
2851: {
2852: PetscInt i, j, k, *bdegrees, worksize;
2853: PetscReal xmin, xmax, center, hscale, *sourcey, *targety, *Bsource, *Bsinv, *Btarget;
2854: PetscScalar *tau, *work;
2856: PetscFunctionBegin;
2857: PetscAssertPointer(sourcex, 3);
2858: PetscAssertPointer(targetx, 5);
2859: PetscAssertPointer(R, 6);
2860: PetscCheck(degree < nsource, PETSC_COMM_SELF, PETSC_ERR_ARG_INCOMP, "Reconstruction degree %" PetscInt_FMT " must be less than number of source intervals %" PetscInt_FMT, degree, nsource);
2861: if (PetscDefined(USE_DEBUG)) {
2862: for (i = 0; i < nsource; i++) PetscCheck(sourcex[i] < sourcex[i + 1], PETSC_COMM_SELF, PETSC_ERR_ARG_CORRUPT, "Source interval %" PetscInt_FMT " has negative orientation (%g,%g)", i, (double)sourcex[i], (double)sourcex[i + 1]);
2863: for (i = 0; i < ntarget; i++) PetscCheck(targetx[i] < targetx[i + 1], PETSC_COMM_SELF, PETSC_ERR_ARG_CORRUPT, "Target interval %" PetscInt_FMT " has negative orientation (%g,%g)", i, (double)targetx[i], (double)targetx[i + 1]);
2864: }
2865: xmin = PetscMin(sourcex[0], targetx[0]);
2866: xmax = PetscMax(sourcex[nsource], targetx[ntarget]);
2867: center = (xmin + xmax) / 2;
2868: hscale = (xmax - xmin) / 2;
2869: worksize = nsource;
2870: PetscCall(PetscMalloc4(degree + 1, &bdegrees, nsource + 1, &sourcey, nsource * (degree + 1), &Bsource, worksize, &work));
2871: PetscCall(PetscMalloc4(nsource, &tau, nsource * (degree + 1), &Bsinv, ntarget + 1, &targety, ntarget * (degree + 1), &Btarget));
2872: for (i = 0; i <= nsource; i++) sourcey[i] = (sourcex[i] - center) / hscale;
2873: for (i = 0; i <= degree; i++) bdegrees[i] = i + 1;
2874: PetscCall(PetscDTLegendreIntegrate(nsource, sourcey, degree + 1, bdegrees, PETSC_TRUE, Bsource));
2875: PetscCall(PetscDTPseudoInverseQR(nsource, nsource, degree + 1, Bsource, Bsinv, tau, nsource, work));
2876: for (i = 0; i <= ntarget; i++) targety[i] = (targetx[i] - center) / hscale;
2877: PetscCall(PetscDTLegendreIntegrate(ntarget, targety, degree + 1, bdegrees, PETSC_FALSE, Btarget));
2878: for (i = 0; i < ntarget; i++) {
2879: PetscReal rowsum = 0;
2880: for (j = 0; j < nsource; j++) {
2881: PetscReal sum = 0;
2882: for (k = 0; k < degree + 1; k++) sum += Btarget[i * (degree + 1) + k] * Bsinv[k * nsource + j];
2883: R[i * nsource + j] = sum;
2884: rowsum += sum;
2885: }
2886: for (j = 0; j < nsource; j++) R[i * nsource + j] /= rowsum; /* normalize each row */
2887: }
2888: PetscCall(PetscFree4(bdegrees, sourcey, Bsource, work));
2889: PetscCall(PetscFree4(tau, Bsinv, targety, Btarget));
2890: PetscFunctionReturn(PETSC_SUCCESS);
2891: }
2893: /*@C
2894: PetscGaussLobattoLegendreIntegrate - Compute the L2 integral of a function on the GLL points
2896: Not Collective
2898: Input Parameters:
2899: + n - the number of GLL nodes
2900: . nodes - the GLL nodes
2901: . weights - the GLL weights
2902: - f - the function values at the nodes
2904: Output Parameter:
2905: . in - the value of the integral
2907: Level: beginner
2909: .seealso: `PetscDTGaussLobattoLegendreQuadrature()`
2910: @*/
2911: PetscErrorCode PetscGaussLobattoLegendreIntegrate(PetscInt n, PetscReal *nodes, PetscReal *weights, const PetscReal *f, PetscReal *in)
2912: {
2913: PetscInt i;
2915: PetscFunctionBegin;
2916: *in = 0.;
2917: for (i = 0; i < n; i++) *in += f[i] * f[i] * weights[i];
2918: PetscFunctionReturn(PETSC_SUCCESS);
2919: }
2921: /*@C
2922: PetscGaussLobattoLegendreElementLaplacianCreate - computes the Laplacian for a single 1d GLL element
2924: Not Collective
2926: Input Parameters:
2927: + n - the number of GLL nodes
2928: . nodes - the GLL nodes
2929: - weights - the GLL weights
2931: Output Parameter:
2932: . AA - the stiffness element
2934: Level: beginner
2936: Notes:
2937: Destroy this with `PetscGaussLobattoLegendreElementLaplacianDestroy()`
2939: You can access entries in this array with AA[i][j] but in memory it is stored in contiguous memory, row oriented (the array is symmetric)
2941: .seealso: `PetscDTGaussLobattoLegendreQuadrature()`, `PetscGaussLobattoLegendreElementLaplacianDestroy()`
2942: @*/
2943: PetscErrorCode PetscGaussLobattoLegendreElementLaplacianCreate(PetscInt n, PetscReal *nodes, PetscReal *weights, PetscReal ***AA)
2944: {
2945: PetscReal **A;
2946: const PetscReal *gllnodes = nodes;
2947: const PetscInt p = n - 1;
2948: PetscReal z0, z1, z2 = -1, x, Lpj, Lpr;
2949: PetscInt i, j, nn, r;
2951: PetscFunctionBegin;
2952: PetscCall(PetscMalloc1(n, &A));
2953: PetscCall(PetscMalloc1(n * n, &A[0]));
2954: for (i = 1; i < n; i++) A[i] = A[i - 1] + n;
2956: for (j = 1; j < p; j++) {
2957: x = gllnodes[j];
2958: z0 = 1.;
2959: z1 = x;
2960: for (nn = 1; nn < p; nn++) {
2961: z2 = x * z1 * (2. * ((PetscReal)nn) + 1.) / (((PetscReal)nn) + 1.) - z0 * (((PetscReal)nn) / (((PetscReal)nn) + 1.));
2962: z0 = z1;
2963: z1 = z2;
2964: }
2965: Lpj = z2;
2966: for (r = 1; r < p; r++) {
2967: if (r == j) {
2968: A[j][j] = 2. / (3. * (1. - gllnodes[j] * gllnodes[j]) * Lpj * Lpj);
2969: } else {
2970: x = gllnodes[r];
2971: z0 = 1.;
2972: z1 = x;
2973: for (nn = 1; nn < p; nn++) {
2974: z2 = x * z1 * (2. * ((PetscReal)nn) + 1.) / (((PetscReal)nn) + 1.) - z0 * (((PetscReal)nn) / (((PetscReal)nn) + 1.));
2975: z0 = z1;
2976: z1 = z2;
2977: }
2978: Lpr = z2;
2979: A[r][j] = 4. / (((PetscReal)p) * (((PetscReal)p) + 1.) * Lpj * Lpr * (gllnodes[j] - gllnodes[r]) * (gllnodes[j] - gllnodes[r]));
2980: }
2981: }
2982: }
2983: for (j = 1; j < p + 1; j++) {
2984: x = gllnodes[j];
2985: z0 = 1.;
2986: z1 = x;
2987: for (nn = 1; nn < p; nn++) {
2988: z2 = x * z1 * (2. * ((PetscReal)nn) + 1.) / (((PetscReal)nn) + 1.) - z0 * (((PetscReal)nn) / (((PetscReal)nn) + 1.));
2989: z0 = z1;
2990: z1 = z2;
2991: }
2992: Lpj = z2;
2993: A[j][0] = 4. * PetscPowRealInt(-1., p) / (((PetscReal)p) * (((PetscReal)p) + 1.) * Lpj * (1. + gllnodes[j]) * (1. + gllnodes[j]));
2994: A[0][j] = A[j][0];
2995: }
2996: for (j = 0; j < p; j++) {
2997: x = gllnodes[j];
2998: z0 = 1.;
2999: z1 = x;
3000: for (nn = 1; nn < p; nn++) {
3001: z2 = x * z1 * (2. * ((PetscReal)nn) + 1.) / (((PetscReal)nn) + 1.) - z0 * (((PetscReal)nn) / (((PetscReal)nn) + 1.));
3002: z0 = z1;
3003: z1 = z2;
3004: }
3005: Lpj = z2;
3007: A[p][j] = 4. / (((PetscReal)p) * (((PetscReal)p) + 1.) * Lpj * (1. - gllnodes[j]) * (1. - gllnodes[j]));
3008: A[j][p] = A[p][j];
3009: }
3010: A[0][0] = 0.5 + (((PetscReal)p) * (((PetscReal)p) + 1.) - 2.) / 6.;
3011: A[p][p] = A[0][0];
3012: *AA = A;
3013: PetscFunctionReturn(PETSC_SUCCESS);
3014: }
3016: /*@C
3017: PetscGaussLobattoLegendreElementLaplacianDestroy - frees the Laplacian for a single 1d GLL element created with `PetscGaussLobattoLegendreElementLaplacianCreate()`
3019: Not Collective
3021: Input Parameters:
3022: + n - the number of GLL nodes
3023: . nodes - the GLL nodes
3024: . weights - the GLL weightss
3025: - AA - the stiffness element
3027: Level: beginner
3029: .seealso: `PetscDTGaussLobattoLegendreQuadrature()`, `PetscGaussLobattoLegendreElementLaplacianCreate()`
3030: @*/
3031: PetscErrorCode PetscGaussLobattoLegendreElementLaplacianDestroy(PetscInt n, PetscReal *nodes, PetscReal *weights, PetscReal ***AA)
3032: {
3033: PetscFunctionBegin;
3034: PetscCall(PetscFree((*AA)[0]));
3035: PetscCall(PetscFree(*AA));
3036: *AA = NULL;
3037: PetscFunctionReturn(PETSC_SUCCESS);
3038: }
3040: /*@C
3041: PetscGaussLobattoLegendreElementGradientCreate - computes the gradient for a single 1d GLL element
3043: Not Collective
3045: Input Parameters:
3046: + n - the number of GLL nodes
3047: . nodes - the GLL nodes
3048: - weights - the GLL weights
3050: Output Parameters:
3051: + AA - the stiffness element
3052: - AAT - the transpose of AA (pass in `NULL` if you do not need this array)
3054: Level: beginner
3056: Notes:
3057: Destroy this with `PetscGaussLobattoLegendreElementGradientDestroy()`
3059: You can access entries in these arrays with AA[i][j] but in memory it is stored in contiguous memory, row oriented
3061: .seealso: `PetscDTGaussLobattoLegendreQuadrature()`, `PetscGaussLobattoLegendreElementLaplacianDestroy()`, `PetscGaussLobattoLegendreElementGradientDestroy()`
3062: @*/
3063: PetscErrorCode PetscGaussLobattoLegendreElementGradientCreate(PetscInt n, PetscReal *nodes, PetscReal *weights, PetscReal ***AA, PetscReal ***AAT)
3064: {
3065: PetscReal **A, **AT = NULL;
3066: const PetscReal *gllnodes = nodes;
3067: const PetscInt p = n - 1;
3068: PetscReal Li, Lj, d0;
3069: PetscInt i, j;
3071: PetscFunctionBegin;
3072: PetscCall(PetscMalloc1(n, &A));
3073: PetscCall(PetscMalloc1(n * n, &A[0]));
3074: for (i = 1; i < n; i++) A[i] = A[i - 1] + n;
3076: if (AAT) {
3077: PetscCall(PetscMalloc1(n, &AT));
3078: PetscCall(PetscMalloc1(n * n, &AT[0]));
3079: for (i = 1; i < n; i++) AT[i] = AT[i - 1] + n;
3080: }
3082: if (n == 1) A[0][0] = 0.;
3083: d0 = (PetscReal)p * ((PetscReal)p + 1.) / 4.;
3084: for (i = 0; i < n; i++) {
3085: for (j = 0; j < n; j++) {
3086: A[i][j] = 0.;
3087: PetscCall(PetscDTComputeJacobi(0., 0., p, gllnodes[i], &Li));
3088: PetscCall(PetscDTComputeJacobi(0., 0., p, gllnodes[j], &Lj));
3089: if (i != j) A[i][j] = Li / (Lj * (gllnodes[i] - gllnodes[j]));
3090: if ((j == i) && (i == 0)) A[i][j] = -d0;
3091: if (j == i && i == p) A[i][j] = d0;
3092: if (AT) AT[j][i] = A[i][j];
3093: }
3094: }
3095: if (AAT) *AAT = AT;
3096: *AA = A;
3097: PetscFunctionReturn(PETSC_SUCCESS);
3098: }
3100: /*@C
3101: PetscGaussLobattoLegendreElementGradientDestroy - frees the gradient for a single 1d GLL element obtained with `PetscGaussLobattoLegendreElementGradientCreate()`
3103: Not Collective
3105: Input Parameters:
3106: + n - the number of GLL nodes
3107: . nodes - the GLL nodes
3108: . weights - the GLL weights
3109: . AA - the stiffness element
3110: - AAT - the transpose of the element
3112: Level: beginner
3114: .seealso: `PetscDTGaussLobattoLegendreQuadrature()`, `PetscGaussLobattoLegendreElementLaplacianCreate()`, `PetscGaussLobattoLegendreElementAdvectionCreate()`
3115: @*/
3116: PetscErrorCode PetscGaussLobattoLegendreElementGradientDestroy(PetscInt n, PetscReal *nodes, PetscReal *weights, PetscReal ***AA, PetscReal ***AAT)
3117: {
3118: PetscFunctionBegin;
3119: PetscCall(PetscFree((*AA)[0]));
3120: PetscCall(PetscFree(*AA));
3121: *AA = NULL;
3122: if (AAT) {
3123: PetscCall(PetscFree((*AAT)[0]));
3124: PetscCall(PetscFree(*AAT));
3125: *AAT = NULL;
3126: }
3127: PetscFunctionReturn(PETSC_SUCCESS);
3128: }
3130: /*@C
3131: PetscGaussLobattoLegendreElementAdvectionCreate - computes the advection operator for a single 1d GLL element
3133: Not Collective
3135: Input Parameters:
3136: + n - the number of GLL nodes
3137: . nodes - the GLL nodes
3138: - weights - the GLL weightss
3140: Output Parameter:
3141: . AA - the stiffness element
3143: Level: beginner
3145: Notes:
3146: Destroy this with `PetscGaussLobattoLegendreElementAdvectionDestroy()`
3148: This is the same as the Gradient operator multiplied by the diagonal mass matrix
3150: You can access entries in this array with AA[i][j] but in memory it is stored in contiguous memory, row oriented
3152: .seealso: `PetscDTGaussLobattoLegendreQuadrature()`, `PetscGaussLobattoLegendreElementLaplacianCreate()`, `PetscGaussLobattoLegendreElementAdvectionDestroy()`
3153: @*/
3154: PetscErrorCode PetscGaussLobattoLegendreElementAdvectionCreate(PetscInt n, PetscReal *nodes, PetscReal *weights, PetscReal ***AA)
3155: {
3156: PetscReal **D;
3157: const PetscReal *gllweights = weights;
3158: const PetscInt glln = n;
3159: PetscInt i, j;
3161: PetscFunctionBegin;
3162: PetscCall(PetscGaussLobattoLegendreElementGradientCreate(n, nodes, weights, &D, NULL));
3163: for (i = 0; i < glln; i++) {
3164: for (j = 0; j < glln; j++) D[i][j] = gllweights[i] * D[i][j];
3165: }
3166: *AA = D;
3167: PetscFunctionReturn(PETSC_SUCCESS);
3168: }
3170: /*@C
3171: PetscGaussLobattoLegendreElementAdvectionDestroy - frees the advection stiffness for a single 1d GLL element created with `PetscGaussLobattoLegendreElementAdvectionCreate()`
3173: Not Collective
3175: Input Parameters:
3176: + n - the number of GLL nodes
3177: . nodes - the GLL nodes
3178: . weights - the GLL weights
3179: - AA - advection
3181: Level: beginner
3183: .seealso: `PetscDTGaussLobattoLegendreQuadrature()`, `PetscGaussLobattoLegendreElementAdvectionCreate()`
3184: @*/
3185: PetscErrorCode PetscGaussLobattoLegendreElementAdvectionDestroy(PetscInt n, PetscReal *nodes, PetscReal *weights, PetscReal ***AA)
3186: {
3187: PetscFunctionBegin;
3188: PetscCall(PetscFree((*AA)[0]));
3189: PetscCall(PetscFree(*AA));
3190: *AA = NULL;
3191: PetscFunctionReturn(PETSC_SUCCESS);
3192: }
3194: PetscErrorCode PetscGaussLobattoLegendreElementMassCreate(PetscInt n, PetscReal *nodes, PetscReal *weights, PetscReal ***AA)
3195: {
3196: PetscReal **A;
3197: const PetscReal *gllweights = weights;
3198: const PetscInt glln = n;
3199: PetscInt i, j;
3201: PetscFunctionBegin;
3202: PetscCall(PetscMalloc1(glln, &A));
3203: PetscCall(PetscMalloc1(glln * glln, &A[0]));
3204: for (i = 1; i < glln; i++) A[i] = A[i - 1] + glln;
3205: if (glln == 1) A[0][0] = 0.;
3206: for (i = 0; i < glln; i++) {
3207: for (j = 0; j < glln; j++) {
3208: A[i][j] = 0.;
3209: if (j == i) A[i][j] = gllweights[i];
3210: }
3211: }
3212: *AA = A;
3213: PetscFunctionReturn(PETSC_SUCCESS);
3214: }
3216: PetscErrorCode PetscGaussLobattoLegendreElementMassDestroy(PetscInt n, PetscReal *nodes, PetscReal *weights, PetscReal ***AA)
3217: {
3218: PetscFunctionBegin;
3219: PetscCall(PetscFree((*AA)[0]));
3220: PetscCall(PetscFree(*AA));
3221: *AA = NULL;
3222: PetscFunctionReturn(PETSC_SUCCESS);
3223: }
3225: /*@
3226: PetscDTIndexToBary - convert an index into a barycentric coordinate.
3228: Input Parameters:
3229: + len - the desired length of the barycentric tuple (usually 1 more than the dimension it represents, so a barycentric coordinate in a triangle has length 3)
3230: . sum - the value that the sum of the barycentric coordinates (which will be non-negative integers) should sum to
3231: - index - the index to convert: should be >= 0 and < Binomial(len - 1 + sum, sum)
3233: Output Parameter:
3234: . coord - will be filled with the barycentric coordinate
3236: Level: beginner
3238: Note:
3239: The indices map to barycentric coordinates in lexicographic order, where the first index is the
3240: least significant and the last index is the most significant.
3242: .seealso: `PetscDTBaryToIndex()`
3243: @*/
3244: PetscErrorCode PetscDTIndexToBary(PetscInt len, PetscInt sum, PetscInt index, PetscInt coord[])
3245: {
3246: PetscInt c, d, s, total, subtotal, nexttotal;
3248: PetscFunctionBeginHot;
3249: PetscCheck(len >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "length must be non-negative");
3250: PetscCheck(index >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "index must be non-negative");
3251: if (!len) {
3252: if (!sum && !index) PetscFunctionReturn(PETSC_SUCCESS);
3253: SETERRQ(PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Invalid index or sum for length 0 barycentric coordinate");
3254: }
3255: for (c = 1, total = 1; c <= len; c++) {
3256: /* total is the number of ways to have a tuple of length c with sum */
3257: if (index < total) break;
3258: total = (total * (sum + c)) / c;
3259: }
3260: PetscCheck(c <= len, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "index out of range");
3261: for (d = c; d < len; d++) coord[d] = 0;
3262: for (s = 0, subtotal = 1, nexttotal = 1; c > 0;) {
3263: /* subtotal is the number of ways to have a tuple of length c with sum s */
3264: /* nexttotal is the number of ways to have a tuple of length c-1 with sum s */
3265: if ((index + subtotal) >= total) {
3266: coord[--c] = sum - s;
3267: index -= (total - subtotal);
3268: sum = s;
3269: total = nexttotal;
3270: subtotal = 1;
3271: nexttotal = 1;
3272: s = 0;
3273: } else {
3274: subtotal = (subtotal * (c + s)) / (s + 1);
3275: nexttotal = (nexttotal * (c - 1 + s)) / (s + 1);
3276: s++;
3277: }
3278: }
3279: PetscFunctionReturn(PETSC_SUCCESS);
3280: }
3282: /*@
3283: PetscDTBaryToIndex - convert a barycentric coordinate to an index
3285: Input Parameters:
3286: + len - the desired length of the barycentric tuple (usually 1 more than the dimension it represents, so a barycentric coordinate in a triangle has length 3)
3287: . sum - the value that the sum of the barycentric coordinates (which will be non-negative integers) should sum to
3288: - coord - a barycentric coordinate with the given length and sum
3290: Output Parameter:
3291: . index - the unique index for the coordinate, >= 0 and < Binomial(len - 1 + sum, sum)
3293: Level: beginner
3295: Note:
3296: The indices map to barycentric coordinates in lexicographic order, where the first index is the
3297: least significant and the last index is the most significant.
3299: .seealso: `PetscDTIndexToBary`
3300: @*/
3301: PetscErrorCode PetscDTBaryToIndex(PetscInt len, PetscInt sum, const PetscInt coord[], PetscInt *index)
3302: {
3303: PetscInt c;
3304: PetscInt i;
3305: PetscInt total;
3307: PetscFunctionBeginHot;
3308: PetscCheck(len >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "length must be non-negative");
3309: if (!len) {
3310: if (!sum) {
3311: *index = 0;
3312: PetscFunctionReturn(PETSC_SUCCESS);
3313: }
3314: SETERRQ(PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Invalid index or sum for length 0 barycentric coordinate");
3315: }
3316: for (c = 1, total = 1; c < len; c++) total = (total * (sum + c)) / c;
3317: i = total - 1;
3318: c = len - 1;
3319: sum -= coord[c];
3320: while (sum > 0) {
3321: PetscInt subtotal;
3322: PetscInt s;
3324: for (s = 1, subtotal = 1; s < sum; s++) subtotal = (subtotal * (c + s)) / s;
3325: i -= subtotal;
3326: sum -= coord[--c];
3327: }
3328: *index = i;
3329: PetscFunctionReturn(PETSC_SUCCESS);
3330: }
3332: /*@
3333: PetscQuadratureComputePermutations - Compute permutations of quadrature points corresponding to domain orientations
3335: Input Parameter:
3336: . quad - The `PetscQuadrature`
3338: Output Parameters:
3339: + Np - The number of domain orientations
3340: - perm - An array of `IS` permutations, one for ech orientation,
3342: Level: developer
3344: .seealso: `PetscQuadratureSetCellType()`, `PetscQuadrature`
3345: @*/
3346: PetscErrorCode PetscQuadratureComputePermutations(PetscQuadrature quad, PetscInt *Np, IS *perm[])
3347: {
3348: DMPolytopeType ct;
3349: const PetscReal *xq, *wq;
3350: PetscInt dim, qdim, d, Na, o, Nq, q, qp;
3352: PetscFunctionBegin;
3353: PetscCall(PetscQuadratureGetData(quad, &qdim, NULL, &Nq, &xq, &wq));
3354: PetscCall(PetscQuadratureGetCellType(quad, &ct));
3355: dim = DMPolytopeTypeGetDim(ct);
3356: Na = DMPolytopeTypeGetNumArrangments(ct);
3357: PetscCall(PetscMalloc1(Na, perm));
3358: if (Np) *Np = Na;
3359: Na /= 2;
3360: for (o = -Na; o < Na; ++o) {
3361: DM refdm;
3362: PetscInt *idx;
3363: PetscReal xi0[3] = {-1., -1., -1.}, v0[3], J[9], detJ, txq[3];
3364: PetscBool flg;
3366: PetscCall(DMPlexCreateReferenceCell(PETSC_COMM_SELF, ct, &refdm));
3367: PetscCall(DMPlexOrientPoint(refdm, 0, o));
3368: PetscCall(DMPlexComputeCellGeometryFEM(refdm, 0, NULL, v0, J, NULL, &detJ));
3369: PetscCall(PetscMalloc1(Nq, &idx));
3370: for (q = 0; q < Nq; ++q) {
3371: CoordinatesRefToReal(dim, dim, xi0, v0, J, &xq[q * dim], txq);
3372: for (qp = 0; qp < Nq; ++qp) {
3373: PetscReal diff = 0.;
3375: for (d = 0; d < dim; ++d) diff += PetscAbsReal(txq[d] - xq[qp * dim + d]);
3376: if (diff < PETSC_SMALL) break;
3377: }
3378: PetscCheck(qp < Nq, PETSC_COMM_SELF, PETSC_ERR_PLIB, "Transformed quad point %" PetscInt_FMT " does not match another quad point", q);
3379: idx[q] = qp;
3380: }
3381: PetscCall(DMDestroy(&refdm));
3382: PetscCall(ISCreateGeneral(PETSC_COMM_SELF, Nq, idx, PETSC_OWN_POINTER, &(*perm)[o + Na]));
3383: PetscCall(ISGetInfo((*perm)[o + Na], IS_PERMUTATION, IS_LOCAL, PETSC_TRUE, &flg));
3384: PetscCheck(flg, PETSC_COMM_SELF, PETSC_ERR_ARG_WRONG, "Ordering for orientation %" PetscInt_FMT " was not a permutation", o);
3385: PetscCall(ISSetPermutation((*perm)[o + Na]));
3386: }
3387: if (!Na) (*perm)[0] = NULL;
3388: PetscFunctionReturn(PETSC_SUCCESS);
3389: }
3391: /*@
3392: PetscDTCreateDefaultQuadrature - Create default quadrature for a given cell
3394: Not collective
3396: Input Parameters:
3397: + ct - The integration domain
3398: - qorder - The desired quadrature order
3400: Output Parameters:
3401: + q - The cell quadrature
3402: - fq - The face quadrature
3404: Level: developer
3406: .seealso: `PetscFECreateDefault()`, `PetscDTGaussTensorQuadrature()`, `PetscDTSimplexQuadrature()`, `PetscDTTensorQuadratureCreate()`
3407: @*/
3408: PetscErrorCode PetscDTCreateDefaultQuadrature(DMPolytopeType ct, PetscInt qorder, PetscQuadrature *q, PetscQuadrature *fq)
3409: {
3410: const PetscInt quadPointsPerEdge = PetscMax(qorder + 1, 1);
3411: const PetscInt dim = DMPolytopeTypeGetDim(ct);
3413: PetscFunctionBegin;
3414: switch (ct) {
3415: case DM_POLYTOPE_SEGMENT:
3416: case DM_POLYTOPE_POINT_PRISM_TENSOR:
3417: case DM_POLYTOPE_QUADRILATERAL:
3418: case DM_POLYTOPE_SEG_PRISM_TENSOR:
3419: case DM_POLYTOPE_HEXAHEDRON:
3420: case DM_POLYTOPE_QUAD_PRISM_TENSOR:
3421: PetscCall(PetscDTGaussTensorQuadrature(dim, 1, quadPointsPerEdge, -1.0, 1.0, q));
3422: PetscCall(PetscDTGaussTensorQuadrature(dim - 1, 1, quadPointsPerEdge, -1.0, 1.0, fq));
3423: break;
3424: case DM_POLYTOPE_TRIANGLE:
3425: case DM_POLYTOPE_TETRAHEDRON:
3426: PetscCall(PetscDTSimplexQuadrature(dim, 2 * qorder, PETSCDTSIMPLEXQUAD_DEFAULT, q));
3427: PetscCall(PetscDTSimplexQuadrature(dim - 1, 2 * qorder, PETSCDTSIMPLEXQUAD_DEFAULT, fq));
3428: break;
3429: case DM_POLYTOPE_TRI_PRISM:
3430: case DM_POLYTOPE_TRI_PRISM_TENSOR: {
3431: PetscQuadrature q1, q2;
3433: // TODO: this should be able to use symmetric rules, but doing so causes tests to fail
3434: PetscCall(PetscDTSimplexQuadrature(2, 2 * qorder, PETSCDTSIMPLEXQUAD_CONIC, &q1));
3435: PetscCall(PetscDTGaussTensorQuadrature(1, 1, quadPointsPerEdge, -1.0, 1.0, &q2));
3436: PetscCall(PetscDTTensorQuadratureCreate(q1, q2, q));
3437: PetscCall(PetscQuadratureDestroy(&q2));
3438: *fq = q1;
3439: /* TODO Need separate quadratures for each face */
3440: } break;
3441: default:
3442: SETERRQ(PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "No quadrature for celltype %s", DMPolytopeTypes[PetscMin(ct, DM_POLYTOPE_UNKNOWN)]);
3443: }
3444: PetscFunctionReturn(PETSC_SUCCESS);
3445: }