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FaceElementForcesAndSourcesCore.cpp
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1/** \file FaceElementForcesAndSourcesCore.cpp
2
3\brief Implementation of face element
4
5*/
6
7namespace MoFEM {
8
9FaceElementForcesAndSourcesCore::FaceElementForcesAndSourcesCore(
10 Interface &m_field)
11 : ForcesAndSourcesCore(m_field),
12 meshPositionsFieldName("MESH_NODE_POSITIONS"), aRea(elementMeasure) {}
13
14MoFEMErrorCode
15FaceElementForcesAndSourcesCore::calculateAreaAndNormalAtIntegrationPts() {
16 MoFEMFunctionBegin;
17
18 auto type = numeredEntFiniteElementPtr->getEntType();
19
20 FTensor::Index<'i', 3> i;
21 FTensor::Index<'j', 3> j;
22 FTensor::Index<'k', 3> k;
23
24 auto get_ftensor_from_vec_3d = [](VectorDouble &v) {
25 return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(&v[0], &v[1],
26 &v[2]);
27 };
28
29 auto get_ftensor_n_diff = [&]() {
30 const auto &m = dataH1.dataOnEntities[MBVERTEX][0].getDiffN(NOBASE);
31 return FTensor::Tensor1<FTensor::PackPtr<const double *, 2>, 2>(&m(0, 0),
32 &m(0, 1));
33 };
34
35 auto get_ftensor_from_mat_3d = [](MatrixDouble &m) {
36 return FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3>(
37 &m(0, 0), &m(0, 1), &m(0, 2));
38 };
39
40 if (type == MBTRI) {
41
42 const size_t nb_gauss_pts = gaussPts.size2();
43 normalsAtGaussPts.resize(nb_gauss_pts, 3);
44 tangentOneAtGaussPts.resize(nb_gauss_pts, 3);
45 tangentTwoAtGaussPts.resize(nb_gauss_pts, 3);
46
47 auto t_tan1 = get_ftensor_from_mat_3d(tangentOneAtGaussPts);
48 auto t_tan2 = get_ftensor_from_mat_3d(tangentTwoAtGaussPts);
49 auto t_normal = get_ftensor_from_mat_3d(normalsAtGaussPts);
50
51 auto t_n =
52 FTensor::Tensor1<double *, 3>(&nOrmal[0], &nOrmal[1], &nOrmal[2]);
53 auto t_t1 = FTensor::Tensor1<double *, 3>(&tangentOne[0], &tangentOne[1],
54 &tangentOne[2]);
55 auto t_t2 = FTensor::Tensor1<double *, 3>(&tangentTwo[0], &tangentTwo[1],
56 &tangentTwo[2]);
57
58 for (int gg = 0; gg != nb_gauss_pts; ++gg) {
59 t_normal(i) = t_n(i);
60 t_tan1(i) = t_t1(i);
61 t_tan2(i) = t_t2(i);
62 ++t_tan1;
63 ++t_tan2;
64 ++t_normal;
65 }
66
67 } else if (type == MBQUAD) {
68
69 EntityHandle ent = numeredEntFiniteElementPtr->getEnt();
70 CHKERR mField.get_moab().get_connectivity(ent, conn, num_nodes, true);
71 coords.resize(num_nodes * 3, false);
72 CHKERR mField.get_moab().get_coords(conn, num_nodes,
73 &*coords.data().begin());
74
75 const size_t nb_gauss_pts = gaussPts.size2();
76 normalsAtGaussPts.resize(nb_gauss_pts, 3);
77 tangentOneAtGaussPts.resize(nb_gauss_pts, 3);
78 tangentTwoAtGaussPts.resize(nb_gauss_pts, 3);
79 normalsAtGaussPts.clear();
80 tangentOneAtGaussPts.clear();
81 tangentTwoAtGaussPts.clear();
82
83 auto t_t1 = get_ftensor_from_mat_3d(tangentOneAtGaussPts);
84 auto t_t2 = get_ftensor_from_mat_3d(tangentTwoAtGaussPts);
85 auto t_normal = get_ftensor_from_mat_3d(normalsAtGaussPts);
86
87 FTensor::Number<0> N0;
88 FTensor::Number<1> N1;
89
90 auto t_diff = get_ftensor_n_diff();
91 for (int gg = 0; gg != nb_gauss_pts; ++gg) {
92 auto t_coords = get_ftensor_from_vec_3d(coords);
93 for (int nn = 0; nn != num_nodes; ++nn) {
94 t_t1(i) += t_coords(i) * t_diff(N0);
95 t_t2(i) += t_coords(i) * t_diff(N1);
96 ++t_diff;
97 ++t_coords;
98 }
99 t_normal(j) = FTensor::levi_civita(i, j, k) * t_t1(k) * t_t2(i);
100
101 ++t_t1;
102 ++t_t2;
103 ++t_normal;
104 }
105 } else {
106 SETERRQ(PETSC_COMM_SELF, MOFEM_NOT_IMPLEMENTED,
107 "Element type not implemented");
108 }
109
110 MoFEMFunctionReturn(0);
111}
112
113MoFEMErrorCode FaceElementForcesAndSourcesCore::calculateAreaAndNormal() {
114 MoFEMFunctionBegin;
115
116 EntityHandle ent = numeredEntFiniteElementPtr->getEnt();
117 CHKERR mField.get_moab().get_connectivity(ent, conn, num_nodes, true);
118 coords.resize(num_nodes * 3, false);
119 CHKERR mField.get_moab().get_coords(conn, num_nodes, &*coords.data().begin());
120 nOrmal.resize(3, false);
121 tangentOne.resize(3, false);
122 tangentTwo.resize(3, false);
123
124 auto calc_normal = [&](const double *diff_ptr) {
125 MoFEMFunctionBegin;
126 FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3> t_coords(
127 &coords[0], &coords[1], &coords[2]);
128 FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3> t_normal(
129 &nOrmal[0], &nOrmal[1], &nOrmal[2]);
130 FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3> t_t1(
131 &tangentOne[0], &tangentOne[1], &tangentOne[2]);
132 FTensor::Tensor1<FTensor::PackPtr<double *, 3>, 3> t_t2(
133 &tangentTwo[0], &tangentTwo[1], &tangentTwo[2]);
134 FTensor::Tensor1<FTensor::PackPtr<const double *, 2>, 2> t_diff(
135 diff_ptr, &diff_ptr[1]);
136
137 FTensor::Index<'i', 3> i;
138 FTensor::Index<'j', 3> j;
139 FTensor::Index<'k', 3> k;
140
141 FTensor::Number<0> N0;
142 FTensor::Number<1> N1;
143 t_t1(i) = 0;
144 t_t2(i) = 0;
145
146 for (int nn = 0; nn != num_nodes; ++nn) {
147 t_t1(i) += t_coords(i) * t_diff(N0);
148 t_t2(i) += t_coords(i) * t_diff(N1);
149 ++t_coords;
150 ++t_diff;
151 }
152 t_normal(j) = FTensor::levi_civita(i, j, k) * t_t1(k) * t_t2(i);
153 aRea = sqrt(t_normal(i) * t_normal(i));
154 MoFEMFunctionReturn(0);
155 };
156
157 const double *diff_ptr;
158 switch (numeredEntFiniteElementPtr->getEntType()) {
159 case MBTRI:
160 diff_ptr = Tools::diffShapeFunMBTRI.data();
161 CHKERR calc_normal(diff_ptr);
162 // FIXME: Normal should be divided not the area for triangle!!
163 aRea /= 2;
164 break;
165 case MBQUAD:
166 diff_ptr = Tools::diffShapeFunMBQUADAtCenter.data();
167 CHKERR calc_normal(diff_ptr);
168 break;
169 default:
170 SETERRQ(PETSC_COMM_SELF, MOFEM_NOT_IMPLEMENTED,
171 "Element type not implemented");
172 }
173
174 MoFEMFunctionReturn(0);
175}
176
177MoFEMErrorCode FaceElementForcesAndSourcesCore::setIntegrationPts() {
178 MoFEMFunctionBegin;
179 // Set integration points
180 int order_data = getMaxDataOrder();
181 int order_row = getMaxRowOrder();
182 int order_col = getMaxColOrder();
183
184 const auto type = numeredEntFiniteElementPtr->getEntType();
185
186 auto get_rule_by_type = [&]() {
187 switch (type) {
188 case MBQUAD:
189 return getRule(order_row + 1, order_col + 1, order_data + 1);
190 default:
191 return getRule(order_row, order_col, order_data);
192 }
193 };
194
195 const int rule = get_rule_by_type();
196
197 auto set_integration_pts_for_tri = [&]() {
198 MoFEMFunctionBegin;
199 if (rule < QUAD_2D_TABLE_SIZE) {
200 if (QUAD_2D_TABLE[rule]->dim != 2) {
201 SETERRQ(PETSC_COMM_SELF, MOFEM_DATA_INCONSISTENCY, "wrong dimension");
202 }
203 if (QUAD_2D_TABLE[rule]->order < rule) {
204 SETERRQ2(PETSC_COMM_SELF, MOFEM_DATA_INCONSISTENCY,
205 "wrong order %d != %d", QUAD_2D_TABLE[rule]->order, rule);
206 }
207 const size_t nb_gauss_pts = QUAD_2D_TABLE[rule]->npoints;
208 gaussPts.resize(3, nb_gauss_pts, false);
209 cblas_dcopy(nb_gauss_pts, &QUAD_2D_TABLE[rule]->points[1], 3,
210 &gaussPts(0, 0), 1);
211 cblas_dcopy(nb_gauss_pts, &QUAD_2D_TABLE[rule]->points[2], 3,
212 &gaussPts(1, 0), 1);
213 cblas_dcopy(nb_gauss_pts, QUAD_2D_TABLE[rule]->weights, 1,
214 &gaussPts(2, 0), 1);
215 dataH1.dataOnEntities[MBVERTEX][0].getN(NOBASE).resize(nb_gauss_pts, 3,
216 false);
217 double *shape_ptr =
218 &*dataH1.dataOnEntities[MBVERTEX][0].getN(NOBASE).data().begin();
219 cblas_dcopy(3 * nb_gauss_pts, QUAD_2D_TABLE[rule]->points, 1, shape_ptr,
220 1);
221 dataH1.dataOnEntities[MBVERTEX][0].getDiffN(NOBASE).resize(3, 2, false);
222 std::copy(
223 Tools::diffShapeFunMBTRI.begin(), Tools::diffShapeFunMBTRI.end(),
224 dataH1.dataOnEntities[MBVERTEX][0].getDiffN(NOBASE).data().begin());
225 } else {
226 SETERRQ2(PETSC_COMM_SELF, MOFEM_DATA_INCONSISTENCY,
227 "rule > quadrature order %d < %d", rule, QUAD_2D_TABLE_SIZE);
228 }
229 MoFEMFunctionReturn(0);
230 };
231
232 auto calc_base_for_tri = [&]() {
233 MoFEMFunctionBegin;
234 const size_t nb_gauss_pts = gaussPts.size2();
235 auto &base = dataH1.dataOnEntities[MBVERTEX][0].getN(NOBASE);
236 auto &diff_base = dataH1.dataOnEntities[MBVERTEX][0].getDiffN(NOBASE);
237 base.resize(nb_gauss_pts, 3, false);
238 diff_base.resize(3, 2, false);
239 CHKERR ShapeMBTRI(&*base.data().begin(), &gaussPts(0, 0), &gaussPts(1, 0),
240 nb_gauss_pts);
241 std::copy(
242 Tools::diffShapeFunMBTRI.begin(), Tools::diffShapeFunMBTRI.end(),
243 dataH1.dataOnEntities[MBVERTEX][0].getDiffN(NOBASE).data().begin());
244 MoFEMFunctionReturn(0);
245 };
246
247 auto calc_base_for_quad = [&]() {
248 MoFEMFunctionBegin;
249 const size_t nb_gauss_pts = gaussPts.size2();
250 auto &base = dataH1.dataOnEntities[MBVERTEX][0].getN(NOBASE);
251 auto &diff_base = dataH1.dataOnEntities[MBVERTEX][0].getDiffN(NOBASE);
252 base.resize(nb_gauss_pts, 4, false);
253 diff_base.resize(nb_gauss_pts, 8, false);
254 for (int gg = 0; gg != nb_gauss_pts; ++gg) {
255 const double ksi = gaussPts(0, gg);
256 const double zeta = gaussPts(1, gg);
257 base(gg, 0) = N_MBQUAD0(ksi, zeta);
258 base(gg, 1) = N_MBQUAD1(ksi, zeta);
259 base(gg, 2) = N_MBQUAD2(ksi, zeta);
260 base(gg, 3) = N_MBQUAD3(ksi, zeta);
261 diff_base(gg, 0) = diffN_MBQUAD0x(zeta);
262 diff_base(gg, 1) = diffN_MBQUAD0y(ksi);
263 diff_base(gg, 2) = diffN_MBQUAD1x(zeta);
264 diff_base(gg, 3) = diffN_MBQUAD1y(ksi);
265 diff_base(gg, 4) = diffN_MBQUAD2x(zeta);
266 diff_base(gg, 5) = diffN_MBQUAD2y(ksi);
267 diff_base(gg, 6) = diffN_MBQUAD3x(zeta);
268 diff_base(gg, 7) = diffN_MBQUAD3y(ksi);
269 }
270 MoFEMFunctionReturn(0);
271 };
272
273 if (rule >= 0) {
274 switch (type) {
275 case MBTRI:
276 CHKERR set_integration_pts_for_tri();
277 break;
278 case MBQUAD:
279 CHKERR Tools::outerProductOfEdgeIntegrationPtsForQuad(gaussPts, rule,
280 rule);
281 CHKERR calc_base_for_quad();
282 break;
283 default:
284 SETERRQ1(PETSC_COMM_SELF, MOFEM_NOT_IMPLEMENTED,
285 "Element type not implemented: %d", type);
286 }
287
288 } else {
289 // If rule is negative, set user defined integration points
290 CHKERR setGaussPts(order_row, order_col, order_data);
291 const size_t nb_gauss_pts = gaussPts.size2();
292 if (nb_gauss_pts) {
293 switch (type) {
294 case MBTRI:
295 CHKERR calc_base_for_tri();
296 break;
297 case MBQUAD:
298 CHKERR calc_base_for_quad();
299 break;
300 default:
301 SETERRQ1(PETSC_COMM_SELF, MOFEM_NOT_IMPLEMENTED,
302 "Element type not implemented: %d", type);
303 }
304 }
305 }
306 MoFEMFunctionReturn(0);
307}
308
309MoFEMErrorCode
310FaceElementForcesAndSourcesCore::getSpaceBaseAndOrderOnElement() {
311 MoFEMFunctionBegin;
312 // Get spaces order/base and sense of entities.
313
314 CHKERR getSpacesAndBaseOnEntities(dataH1);
315
316 // H1
317 if (dataH1.spacesOnEntities[MBEDGE].test(H1)) {
318 CHKERR getEntitySense<MBEDGE>(dataH1);
319 CHKERR getEntityDataOrder<MBEDGE>(dataH1, H1);
320 }
321 if (dataH1.spacesOnEntities[MBTRI].test(H1)) {
322 CHKERR getEntitySense<MBTRI>(dataH1);
323 CHKERR getEntityDataOrder<MBTRI>(dataH1, H1);
324 }
325 if (dataH1.spacesOnEntities[MBQUAD].test(H1)) {
326 CHKERR getEntitySense<MBQUAD>(dataH1);
327 CHKERR getEntityDataOrder<MBQUAD>(dataH1, H1);
328 }
329
330 // Hcurl
331 if (dataH1.spacesOnEntities[MBEDGE].test(HCURL)) {
332 CHKERR getEntitySense<MBEDGE>(dataHcurl);
333 CHKERR getEntityDataOrder<MBEDGE>(dataHcurl, HCURL);
334 dataHcurl.spacesOnEntities[MBEDGE].set(HCURL);
335 }
336 if (dataH1.spacesOnEntities[MBTRI].test(HCURL)) {
337 CHKERR getEntitySense<MBTRI>(dataHcurl);
338 CHKERR getEntityDataOrder<MBTRI>(dataHcurl, HCURL);
339 dataHcurl.spacesOnEntities[MBTRI].set(HCURL);
340 }
341 if (dataH1.spacesOnEntities[MBQUAD].test(HCURL)) {
342 CHKERR getEntitySense<MBQUAD>(dataHcurl);
343 CHKERR getEntityDataOrder<MBQUAD>(dataHcurl, HCURL);
344 dataHcurl.spacesOnEntities[MBQUAD].set(HCURL);
345 }
346
347 // Hdiv
348 if (dataH1.spacesOnEntities[MBTRI].test(HDIV)) {
349 CHKERR getEntitySense<MBTRI>(dataHdiv);
350 CHKERR getEntityDataOrder<MBTRI>(dataHdiv, HDIV);
351 dataHdiv.spacesOnEntities[MBTRI].set(HDIV);
352 }
353 if (dataH1.spacesOnEntities[MBQUAD].test(HDIV)) {
354 CHKERR getEntitySense<MBQUAD>(dataHdiv);
355 CHKERR getEntityDataOrder<MBQUAD>(dataHdiv, HDIV);
356 dataHdiv.spacesOnEntities[MBQUAD].set(HDIV);
357 }
358
359 // L2
360 if (dataH1.spacesOnEntities[MBTRI].test(L2)) {
361 CHKERR getEntitySense<MBTRI>(dataL2);
362 CHKERR getEntityDataOrder<MBTRI>(dataL2, L2);
363 dataL2.spacesOnEntities[MBTRI].set(L2);
364 }
365 if (dataH1.spacesOnEntities[MBQUAD].test(L2)) {
366 CHKERR getEntitySense<MBQUAD>(dataL2);
367 CHKERR getEntityDataOrder<MBQUAD>(dataL2, L2);
368 dataL2.spacesOnEntities[MBQUAD].set(L2);
369 }
370
371 MoFEMFunctionReturn(0);
372}
373
374MoFEMErrorCode
375FaceElementForcesAndSourcesCore::calculateCoordinatesAtGaussPts() {
376 MoFEMFunctionBeginHot;
377
378 const size_t nb_nodes =
379 dataH1.dataOnEntities[MBVERTEX][0].getN(NOBASE).size2();
380 double *shape_functions =
381 &*dataH1.dataOnEntities[MBVERTEX][0].getN(NOBASE).data().begin();
382 const size_t nb_gauss_pts = gaussPts.size2();
383 coordsAtGaussPts.resize(nb_gauss_pts, 3, false);
384 for (int gg = 0; gg != nb_gauss_pts; ++gg)
385 for (int dd = 0; dd != 3; ++dd)
386 coordsAtGaussPts(gg, dd) = cblas_ddot(
387 nb_nodes, &shape_functions[nb_nodes * gg], 1, &coords[dd], 3);
388
389 MoFEMFunctionReturnHot(0);
390}
391
392MoFEMErrorCode FaceElementForcesAndSourcesCore::UserDataOperator::setPtrFE(
393 ForcesAndSourcesCore *ptr) {
394 MoFEMFunctionBeginHot;
395 if (!(ptrFE = dynamic_cast<FaceElementForcesAndSourcesCore *>(ptr)))
396 SETERRQ(PETSC_COMM_SELF, MOFEM_DATA_INCONSISTENCY,
397 "User operator and finite element do not work together");
398 MoFEMFunctionReturnHot(0);
399}
400
401MoFEMErrorCode FaceElementForcesAndSourcesCore::operator()() {
402 MoFEMFunctionBegin;
403
404 const auto type = numeredEntFiniteElementPtr->getEntType();
405 if (type != lastEvaluatedElementEntityType) {
406 switch (type) {
407 case MBTRI:
408 getElementPolynomialBase() =
409 boost::shared_ptr<BaseFunction>(new TriPolynomialBase());
410 break;
411 case MBQUAD:
412 getElementPolynomialBase() =
413 boost::shared_ptr<BaseFunction>(new QuadPolynomialBase());
414 break;
415 default:
416 MoFEMFunctionReturnHot(0);
417 }
418 CHKERR createDataOnElement(type);
419 lastEvaluatedElementEntityType = type;
420 }
421
422 // Calculate normal and tangent vectors for face geometry
423 CHKERR calculateAreaAndNormal();
424 CHKERR getSpaceBaseAndOrderOnElement();
425
426 CHKERR setIntegrationPts();
427 if (gaussPts.size2() == 0)
428 MoFEMFunctionReturnHot(0);
429
430 CHKERR calculateCoordinatesAtGaussPts();
431 CHKERR calHierarchicalBaseFunctionsOnElement();
432 CHKERR calBernsteinBezierBaseFunctionsOnElement();
433 CHKERR calculateAreaAndNormalAtIntegrationPts();
434
435 // Iterate over operators
436 CHKERR loopOverOperators();
437
438 MoFEMFunctionReturn(0);
439}
440
441MoFEMErrorCode
442FaceElementForcesAndSourcesCore::UserDataOperator::loopSideVolumes(
443 const string fe_name, VolumeElementForcesAndSourcesCoreOnSide &fe_method) {
444 return loopSide(fe_name, &fe_method, 3);
445}
446
447} // namespace MoFEM
N1
static Number< 1 > N1
Definition: BasicFeTools.hpp:100
N0
static Number< 0 > N0
Definition: BasicFeTools.hpp:99
NOBASE
@ NOBASE
Definition: definitions.h:59
MoFEMFunctionReturnHot
#define MoFEMFunctionReturnHot(a)
Last executable line of each PETSc function used for error handling. Replaces return()
Definition: definitions.h:447
L2
@ L2
field with C-1 continuity
Definition: definitions.h:88
H1
@ H1
continuous field
Definition: definitions.h:85
HCURL
@ HCURL
field with continuous tangents
Definition: definitions.h:86
HDIV
@ HDIV
field with continuous normal traction
Definition: definitions.h:87
MoFEMFunctionBegin
#define MoFEMFunctionBegin
First executable line of each MoFEM function, used for error handling. Final line of MoFEM functions ...
Definition: definitions.h:346
MOFEM_DATA_INCONSISTENCY
@ MOFEM_DATA_INCONSISTENCY
Definition: definitions.h:31
MOFEM_NOT_IMPLEMENTED
@ MOFEM_NOT_IMPLEMENTED
Definition: definitions.h:32
MoFEMFunctionReturn
#define MoFEMFunctionReturn(a)
Last executable line of each PETSc function used for error handling. Replaces return()
Definition: definitions.h:416
CHKERR
#define CHKERR
Inline error check.
Definition: definitions.h:535
MoFEMFunctionBeginHot
#define MoFEMFunctionBeginHot
First executable line of each MoFEM function, used for error handling. Final line of MoFEM functions ...
Definition: definitions.h:440
dim
const int dim
Definition: elec_phys_2D.cpp:12
diffN_MBQUAD2y
#define diffN_MBQUAD2y(x)
Definition: fem_tools.h:66
diffN_MBQUAD1x
#define diffN_MBQUAD1x(y)
Definition: fem_tools.h:63
N_MBQUAD3
#define N_MBQUAD3(x, y)
quad shape function
Definition: fem_tools.h:60
diffN_MBQUAD0x
#define diffN_MBQUAD0x(y)
Definition: fem_tools.h:61
diffN_MBQUAD1y
#define diffN_MBQUAD1y(x)
Definition: fem_tools.h:64
diffN_MBQUAD3y
#define diffN_MBQUAD3y(x)
Definition: fem_tools.h:68
diffN_MBQUAD0y
#define diffN_MBQUAD0y(x)
Definition: fem_tools.h:62
N_MBQUAD0
#define N_MBQUAD0(x, y)
quad shape function
Definition: fem_tools.h:57
diffN_MBQUAD3x
#define diffN_MBQUAD3x(y)
Definition: fem_tools.h:67
diffN_MBQUAD2x
#define diffN_MBQUAD2x(y)
Definition: fem_tools.h:65
N_MBQUAD2
#define N_MBQUAD2(x, y)
quad shape function
Definition: fem_tools.h:59
N_MBQUAD1
#define N_MBQUAD1(x, y)
quad shape function
Definition: fem_tools.h:58
ShapeMBTRI
PetscErrorCode ShapeMBTRI(double *N, const double *X, const double *Y, const int G_DIM)
calculate shape functions on triangle
Definition: fem_tools.c:182
m
FTensor::Index< 'm', SPACE_DIM > m
Definition: fluid_structure_eigenproblem.cpp:65
order
int order
Definition: fluid_structure_eigenproblem.cpp:84
i
FTensor::Index< 'i', SPACE_DIM > i
Definition: hcurl_divergence_operator_2d.cpp:27
v
const double v
phase velocity of light in medium (cm/ns)
Definition: initial_diffusion.cpp:40
j
FTensor::Index< 'j', 3 > j
Definition: matrix_function.cpp:19
k
FTensor::Index< 'k', 3 > k
Definition: matrix_function.cpp:20
FTensor::levi_civita
constexpr std::enable_if<(Dim0<=2 &&Dim1<=2), Tensor2_Expr< Levi_Civita< T >, T, Dim0, Dim1, i, j > >::type levi_civita(const Index< i, Dim0 > &, const Index< j, Dim1 > &)
levi_civita functions to make for easy adhoc use
Definition: Levi_Civita.hpp:617
MoFEM::Exceptions::MoFEMErrorCode
PetscErrorCode MoFEMErrorCode
MoFEM/PETSc error code.
Definition: Exceptions.hpp:56
MoFEM
implementation of Data Operators for Forces and Sources
Definition: Common.hpp:10
zeta
double zeta
Viscous hardening.
Definition: plastic.cpp:170
QUAD_2D_TABLE_SIZE
#define QUAD_2D_TABLE_SIZE
Definition: quad.h:174
QUAD_2D_TABLE
static QUAD *const QUAD_2D_TABLE[]
Definition: quad.h:175
MoFEM::CoreInterface::get_moab
virtual moab::Interface & get_moab()=0
MoFEM::DeprecatedCoreInterface
Deprecated interface functions.
Definition: DeprecatedCoreInterface.hpp:16
MoFEM::EntitiesFieldData::spacesOnEntities
std::array< std::bitset< LASTSPACE >, MBMAXTYPE > spacesOnEntities
spaces on entity types
Definition: EntitiesFieldData.hpp:50
MoFEM::EntitiesFieldData::dataOnEntities
std::array< boost::ptr_vector< EntData >, MBMAXTYPE > dataOnEntities
Definition: EntitiesFieldData.hpp:56
MoFEM::FEMethod::numeredEntFiniteElementPtr
boost::shared_ptr< const NumeredEntFiniteElement > numeredEntFiniteElementPtr
Definition: LoopMethods.hpp:383
MoFEM::FaceElementForcesAndSourcesCore::calculateAreaAndNormal
virtual MoFEMErrorCode calculateAreaAndNormal()
Calculate element area and normal of the face.
Definition: FaceElementForcesAndSourcesCore.cpp:113
MoFEM::FaceElementForcesAndSourcesCore::operator()
MoFEMErrorCode operator()()
function is run for every finite element
Definition: FaceElementForcesAndSourcesCore.cpp:401
MoFEM::FaceElementForcesAndSourcesCore::getSpaceBaseAndOrderOnElement
virtual MoFEMErrorCode getSpaceBaseAndOrderOnElement()
Determine approximation space and order of base functions.
Definition: FaceElementForcesAndSourcesCore.cpp:310
MoFEM::FaceElementForcesAndSourcesCore::calculateAreaAndNormalAtIntegrationPts
virtual MoFEMErrorCode calculateAreaAndNormalAtIntegrationPts()
Calculate element area and normal of the face at integration points.
Definition: FaceElementForcesAndSourcesCore.cpp:15
MoFEM::FaceElementForcesAndSourcesCore::setIntegrationPts
virtual MoFEMErrorCode setIntegrationPts()
Set integration points.
Definition: FaceElementForcesAndSourcesCore.cpp:177
MoFEM::FaceElementForcesAndSourcesCore::calculateCoordinatesAtGaussPts
virtual MoFEMErrorCode calculateCoordinatesAtGaussPts()
Calculate coordinate at integration points.
Definition: FaceElementForcesAndSourcesCore.cpp:375
MoFEM::ForcesAndSourcesCore
structure to get information form mofem into EntitiesFieldData
Definition: ForcesAndSourcesCore.hpp:22
MoFEM::ForcesAndSourcesCore::loopOverOperators
MoFEMErrorCode loopOverOperators()
Iterate user data operators.
Definition: ForcesAndSourcesCore.cpp:1347
MoFEM::ForcesAndSourcesCore::getMaxRowOrder
int getMaxRowOrder() const
Get max order of approximation for field in rows.
Definition: ForcesAndSourcesCore.cpp:131
MoFEM::ForcesAndSourcesCore::getSpacesAndBaseOnEntities
MoFEMErrorCode getSpacesAndBaseOnEntities(EntitiesFieldData &data) const
Get field approximation space and base on entities.
Definition: ForcesAndSourcesCore.cpp:990
MoFEM::ForcesAndSourcesCore::setGaussPts
virtual MoFEMErrorCode setGaussPts(int order_row, int order_col, int order_data)
set user specific integration rule
Definition: ForcesAndSourcesCore.cpp:1926
MoFEM::ForcesAndSourcesCore::getElementPolynomialBase
auto & getElementPolynomialBase()
Get the Entity Polynomial Base object.
Definition: ForcesAndSourcesCore.hpp:90
MoFEM::ForcesAndSourcesCore::coordsAtGaussPts
MatrixDouble coordsAtGaussPts
coordinated at gauss points
Definition: ForcesAndSourcesCore.hpp:541
MoFEM::ForcesAndSourcesCore::getRule
virtual int getRule(int order_row, int order_col, int order_data)
another variant of getRule
Definition: ForcesAndSourcesCore.cpp:1920
MoFEM::ForcesAndSourcesCore::calHierarchicalBaseFunctionsOnElement
MoFEMErrorCode calHierarchicalBaseFunctionsOnElement()
Calculate base functions.
Definition: ForcesAndSourcesCore.cpp:1086
MoFEM::ForcesAndSourcesCore::gaussPts
MatrixDouble gaussPts
Matrix of integration points.
Definition: ForcesAndSourcesCore.hpp:109
MoFEM::ForcesAndSourcesCore::calBernsteinBezierBaseFunctionsOnElement
MoFEMErrorCode calBernsteinBezierBaseFunctionsOnElement()
Calculate Bernstein-Bezier base.
Definition: ForcesAndSourcesCore.cpp:1106
MoFEM::ForcesAndSourcesCore::getMaxColOrder
int getMaxColOrder() const
Get max order of approximation for field in columns.
Definition: ForcesAndSourcesCore.cpp:135
MoFEM::ForcesAndSourcesCore::lastEvaluatedElementEntityType
EntityType lastEvaluatedElementEntityType
Last evaluated type of element entity.
Definition: ForcesAndSourcesCore.hpp:489
MoFEM::ForcesAndSourcesCore::getMaxDataOrder
int getMaxDataOrder() const
Get max order of approximation for data fields.
Definition: ForcesAndSourcesCore.cpp:120
MoFEM::ForcesAndSourcesCore::createDataOnElement
MoFEMErrorCode createDataOnElement(EntityType type)
Create a entity data on element object.
Definition: ForcesAndSourcesCore.cpp:1305
MoFEM::QuadPolynomialBase
Calculate base functions on triangle.
Definition: QuadPolynomialBase.hpp:21
MoFEM::Tools::outerProductOfEdgeIntegrationPtsForQuad
static MoFEMErrorCode outerProductOfEdgeIntegrationPtsForQuad(MatrixDouble &pts, const int edge0, const int edge1)
Definition: Tools.cpp:577
MoFEM::Tools::diffShapeFunMBQUADAtCenter
static constexpr std::array< double, 8 > diffShapeFunMBQUADAtCenter
Definition: Tools.hpp:212
MoFEM::Tools::diffShapeFunMBTRI
static constexpr std::array< double, 6 > diffShapeFunMBTRI
Definition: Tools.hpp:104
MoFEM::TriPolynomialBase
Calculate base functions on triangle.
Definition: TriPolynomialBase.hpp:16
MoFEM::VolumeElementForcesAndSourcesCoreOnSide
Base volume element used to integrate on skeleton.
Definition: VolumeElementForcesAndSourcesCoreOnSide.hpp:23
QUAD_::npoints
int npoints
Definition: quad.h:29
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