Dune Core Modules (2.10.0)

subsamplingvtkwriter.hh
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1// SPDX-FileCopyrightText: Copyright © DUNE Project contributors, see file LICENSE.md in module root
2// SPDX-License-Identifier: LicenseRef-GPL-2.0-only-with-DUNE-exception
3// -*- tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*-
4// vi: set et ts=4 sw=2 sts=2:
5
6#ifndef DUNE_SUBSAMPLINGVTKWRITER_HH
7#define DUNE_SUBSAMPLINGVTKWRITER_HH
8
9#include <ostream>
10#include <memory>
11
12#include <dune/common/indent.hh>
13#include <dune/geometry/type.hh>
16#include <dune/grid/io/file/vtk/vtuwriter.hh>
17
24namespace Dune
25{
37 template< class GridView >
39 : public VTKWriter<GridView>
40 {
42 constexpr static int dim = GridView::dimension;
43 constexpr static int dimw = GridView::dimensionworld;
44 typedef typename GridView::Grid::ctype ctype;
45 typedef typename GridView::template Codim< 0 >::Entity Entity;
47 typedef typename Refinement::IndexVector IndexVector;
48 typedef typename Refinement::ElementIterator SubElementIterator;
49 typedef typename Refinement::VertexIterator SubVertexIterator;
50
51 typedef typename Base::CellIterator CellIterator;
52 typedef typename Base::FunctionIterator FunctionIterator;
53 using Base::cellBegin;
54 using Base::cellEnd;
55 using Base::celldata;
56 using Base::ncells;
57 using Base::ncorners;
58 using Base::nvertices;
59 using Base::outputtype;
60 using Base::vertexBegin;
61 using Base::vertexEnd;
62 using Base::vertexdata;
63
64 public:
80 explicit SubsamplingVTKWriter (const GridView &gridView,
81 Dune::RefinementIntervals intervals_, bool coerceToSimplex_ = false,
82 VTK::Precision coordPrecision = VTK::Precision::float32)
83 : Base(gridView, VTK::nonconforming, coordPrecision)
84 , intervals(intervals_), coerceToSimplex(coerceToSimplex_)
85 {
86 if(intervals_.intervals() < 1) {
87 DUNE_THROW(Dune::IOError,"SubsamplingVTKWriter: Refinement intervals must be larger than zero! (One interval means no subsampling)");
88 }
89 }
90
91 private:
92 GeometryType subsampledGeometryType(GeometryType geometryType)
93 {
94 return (geometryType.isCube() && !coerceToSimplex ? geometryType : GeometryTypes::simplex(dim));
95 }
96
97 template<typename SubIterator>
98 struct IteratorSelector
99 {};
100
101 SubElementIterator refinementBegin(const Refinement& refinement, Dune::RefinementIntervals intervals, IteratorSelector<SubElementIterator>)
102 {
103 return refinement.eBegin(intervals);
104 }
105
106 SubVertexIterator refinementBegin(const Refinement& refinement, Dune::RefinementIntervals intervals, IteratorSelector<SubVertexIterator>)
107 {
108 return refinement.vBegin(intervals);
109 }
110
111 SubElementIterator refinementEnd(const Refinement& refinement, Dune::RefinementIntervals intervals, IteratorSelector<SubElementIterator>)
112 {
113 return refinement.eEnd(intervals);
114 }
115
116 SubVertexIterator refinementEnd(const Refinement& refinement, Dune::RefinementIntervals intervals, IteratorSelector<SubVertexIterator>)
117 {
118 return refinement.vEnd(intervals);
119 }
120
121 template<typename Data, typename Iterator, typename SubIterator>
122 void writeData(VTK::VTUWriter& writer, const Data& data, const Iterator begin, const Iterator end, int nentries, IteratorSelector<SubIterator> sis)
123 {
124 for (auto it = data.begin(),
125 iend = data.end();
126 it != iend;
127 ++it)
128 {
129 const auto& f = *it;
130 VTK::FieldInfo fieldInfo = f.fieldInfo();
131 std::size_t writecomps = fieldInfo.size();
132 switch (fieldInfo.type())
133 {
135 break;
137 // vtk file format: a vector data always should have 3 comps (with
138 // 3rd comp = 0 in 2D case)
139 if (writecomps > 3)
140 DUNE_THROW(IOError,"Cannot write VTK vectors with more than 3 components (components was " << writecomps << ")");
141 writecomps = 3;
142 break;
144 DUNE_THROW(NotImplemented,"VTK output for tensors not implemented yet");
145 }
146 std::shared_ptr<VTK::DataArrayWriter> p
147 (writer.makeArrayWriter(f.name(), writecomps, nentries, fieldInfo.precision()));
148 if(!p->writeIsNoop())
149 for (Iterator eit = begin; eit!=end; ++eit)
150 {
151 const Entity & e = *eit;
152 f.bind(e);
153 Refinement &refinement =
154 buildRefinement<dim, ctype>(eit->type(),
155 subsampledGeometryType(eit->type()));
156 for(SubIterator sit = refinementBegin(refinement,intervals,sis),
157 send = refinementEnd(refinement,intervals,sis);
158 sit != send;
159 ++sit)
160 {
161 f.write(sit.coords(),*p);
162 // expand 2D-Vectors to 3D for VTK format
163 for(unsigned j = f.fieldInfo().size(); j < writecomps; j++)
164 p->write(0.0);
165 }
166 f.unbind();
167 }
168 }
169 }
170
171
172 protected:
174 virtual void countEntities(int &nvertices_, int &ncells_, int &ncorners_);
175
177 virtual void writeCellData(VTK::VTUWriter& writer);
178
180 virtual void writeVertexData(VTK::VTUWriter& writer);
181
183 virtual void writeGridPoints(VTK::VTUWriter& writer);
184
186 virtual void writeGridCells(VTK::VTUWriter& writer);
187
188 public:
190 using Base::addCellData;
191
192 private:
193 // hide addVertexData -- adding raw data directly without a VTKFunction
194 // currently does not make sense for subsampled meshes, as the higher order
195 // information is missing. See FS#676.
196 template<class V>
197 void addVertexData (const V& v, const std::string &name, int ncomps=1);
198 template<class V>
199 void addCellData (const V& v, const std::string &name, int ncomps=1);
200
202 bool coerceToSimplex;
203 };
204
206 template <class GridView>
207 void SubsamplingVTKWriter<GridView>::countEntities(int &nvertices_, int &ncells_, int &ncorners_)
208 {
209 nvertices_ = 0;
210 ncells_ = 0;
211 ncorners_ = 0;
212 for (CellIterator it=this->cellBegin(); it!=cellEnd(); ++it)
213 {
214 Refinement &refinement = buildRefinement<dim, ctype>(it->type(), subsampledGeometryType(it->type()));
215
216 ncells_ += refinement.nElements(intervals);
217 nvertices_ += refinement.nVertices(intervals);
218 ncorners_ += refinement.nElements(intervals) * refinement.eBegin(intervals).vertexIndices().size();
219 }
220 }
221
222
224 template <class GridView>
226 {
227 if(celldata.size() == 0)
228 return;
229
230 // Find the names of the first scalar and vector data fields.
231 // These will be marked as the default fields (the ones that ParaView shows
232 // when the file has just been opened).
233 std::string defaultScalarField, defaultVectorField;
234 std::tie(defaultScalarField, defaultVectorField) = this->getDataNames(celldata);
235
236 writer.beginCellData(defaultScalarField, defaultVectorField);
237 writeData(writer,celldata,cellBegin(),cellEnd(),ncells,IteratorSelector<SubElementIterator>());
238 writer.endCellData();
239 }
240
242 template <class GridView>
244 {
245 if(vertexdata.size() == 0)
246 return;
247
248 // Find the names of the first scalar and vector data fields.
249 // These will be marked as the default fields (the ones that ParaView shows
250 // when the file has just been opened).
251 std::string defaultScalarField, defaultVectorField;
252 std::tie(defaultScalarField, defaultVectorField) = this->getDataNames(vertexdata);
253
254 writer.beginPointData(defaultScalarField, defaultVectorField);
255 writeData(writer,vertexdata,cellBegin(),cellEnd(),nvertices,IteratorSelector<SubVertexIterator>());
256 writer.endPointData();
257 }
258
260 template <class GridView>
262 {
263 writer.beginPoints();
264
265 std::shared_ptr<VTK::DataArrayWriter> p
266 (writer.makeArrayWriter("Coordinates", 3, nvertices, this->coordPrecision()));
267 if(!p->writeIsNoop())
268 for (CellIterator i=cellBegin(); i!=cellEnd(); ++i)
269 {
270 Refinement &refinement =
271 buildRefinement<dim, ctype>(i->type(),
272 subsampledGeometryType(i->type()));
273 for(SubVertexIterator sit = refinement.vBegin(intervals),
274 send = refinement.vEnd(intervals);
275 sit != send; ++sit)
276 {
277 FieldVector<ctype, dimw> coords = i->geometry().global(sit.coords());
278 for (int j=0; j<std::min(int(dimw),3); j++)
279 p->write(coords[j]);
280 for (int j=std::min(int(dimw),3); j<3; j++)
281 p->write(0.0);
282 }
283 }
284 // free the VTK::DataArrayWriter before touching the stream
285 p.reset();
286
287 writer.endPoints();
288 }
289
291 template <class GridView>
293 {
294 writer.beginCells();
295
296 // connectivity
297 {
298 std::shared_ptr<VTK::DataArrayWriter> p1
299 (writer.makeArrayWriter("connectivity", 1, ncorners, VTK::Precision::int32));
300 // The offset within the index numbering
301 if(!p1->writeIsNoop()) {
302 int offset = 0;
303 for (CellIterator i=cellBegin(); i!=cellEnd(); ++i)
304 {
305 GeometryType coercedToType = subsampledGeometryType(i->type());
306 Refinement &refinement =
307 buildRefinement<dim, ctype>(i->type(), coercedToType);
308 for(SubElementIterator sit = refinement.eBegin(intervals),
309 send = refinement.eEnd(intervals);
310 sit != send; ++sit)
311 {
312 IndexVector indices = sit.vertexIndices();
313 for(unsigned int ii = 0; ii < indices.size(); ++ii)
314 p1->write(offset+indices[VTK::renumber(coercedToType, ii)]);
315 }
316 offset += refinement.nVertices(intervals);
317 }
318 }
319 }
320
321 // offsets
322 {
323 std::shared_ptr<VTK::DataArrayWriter> p2
324 (writer.makeArrayWriter("offsets", 1, ncells, VTK::Precision::int32));
325 if(!p2->writeIsNoop()) {
326 // The offset into the connectivity array
327 int offset = 0;
328 for (CellIterator i=cellBegin(); i!=cellEnd(); ++i)
329 {
330 Refinement &refinement =
331 buildRefinement<dim, ctype>(i->type(),
332 subsampledGeometryType(i->type()));
333 unsigned int verticesPerCell =
334 refinement.eBegin(intervals).vertexIndices().size();
335 for(int element = 0; element < refinement.nElements(intervals);
336 ++element)
337 {
338 offset += verticesPerCell;
339 p2->write(offset);
340 }
341 }
342 }
343 }
344
345 // types
346 if (dim>1)
347 {
348 std::shared_ptr<VTK::DataArrayWriter> p3
349 (writer.makeArrayWriter("types", 1, ncells, VTK::Precision::uint8));
350 if(!p3->writeIsNoop())
351 for (CellIterator it=cellBegin(); it!=cellEnd(); ++it)
352 {
353 GeometryType coerceTo = subsampledGeometryType(it->type());
354 Refinement &refinement =
355 buildRefinement<dim, ctype>(it->type(), coerceTo);
356 int vtktype = VTK::geometryType(coerceTo);
357 for(int i = 0; i < refinement.nElements(intervals); ++i)
358 p3->write(vtktype);
359 }
360 }
361
362 writer.endCells();
363 }
364}
365
366#endif // DUNE_SUBSAMPLINGVTKWRITER_HH
vector space out of a tensor product of fields.
Definition: fvector.hh:91
Unique label for each type of entities that can occur in DUNE grids.
Definition: type.hh:114
Grid view abstract base class.
Definition: gridview.hh:66
Default exception class for I/O errors.
Definition: exceptions.hh:231
Holds the number of refined intervals per axis needed for virtual and static refinement.
Definition: base.cc:94
Writer for the output of subsampled grid functions in the vtk format.
Definition: subsamplingvtkwriter.hh:40
virtual void writeGridPoints(VTK::VTUWriter &writer)
write the positions of vertices
Definition: subsamplingvtkwriter.hh:261
virtual void writeVertexData(VTK::VTUWriter &writer)
write vertex data
Definition: subsamplingvtkwriter.hh:243
SubsamplingVTKWriter(const GridView &gridView, Dune::RefinementIntervals intervals_, bool coerceToSimplex_=false, VTK::Precision coordPrecision=VTK::Precision::float32)
Construct a SubsamplingVTKWriter working on a specific GridView.
Definition: subsamplingvtkwriter.hh:80
virtual void countEntities(int &nvertices_, int &ncells_, int &ncorners_)
count the vertices, cells and corners
Definition: subsamplingvtkwriter.hh:207
virtual void writeCellData(VTK::VTUWriter &writer)
write cell data
Definition: subsamplingvtkwriter.hh:225
virtual void writeGridCells(VTK::VTUWriter &writer)
write the connectivity array
Definition: subsamplingvtkwriter.hh:292
Iterator over the grids elements.
Definition: vtkwriter.hh:385
Writer for the output of grid functions in the vtk format.
Definition: vtkwriter.hh:95
void addVertexData(const std::shared_ptr< const VTKFunction > &p)
Add a grid function that lives on the vertices of the grid to the visualization.
Definition: vtkwriter.hh:713
void addCellData(const std::shared_ptr< const VTKFunction > &p)
Add a grid function that lives on the cells of the grid to the visualization.
Definition: vtkwriter.hh:649
VTK::Precision coordPrecision() const
get the precision with which coordinates are written out
Definition: vtkwriter.hh:782
@ tensor
tensor field (always 3x3)
@ vector
vector-valued field (always 3D, will be padded if necessary)
Dump a .vtu/.vtp files contents to a stream.
Definition: vtuwriter.hh:98
DataArrayWriter * makeArrayWriter(const std::string &name, unsigned ncomps, unsigned nitems, Precision prec)
acquire a DataArrayWriter
Definition: vtuwriter.hh:380
void endCellData()
finish CellData section
Definition: vtuwriter.hh:220
void beginCells()
start section for the grid cells/PolyData lines
Definition: vtuwriter.hh:274
void endPointData()
finish PointData section
Definition: vtuwriter.hh:182
void beginCellData(const std::string &scalars="", const std::string &vectors="")
start CellData section
Definition: vtuwriter.hh:205
void beginPointData(const std::string &scalars="", const std::string &vectors="")
start PointData section
Definition: vtuwriter.hh:167
void endPoints()
finish section for the point coordinates
Definition: vtuwriter.hh:249
void endCells()
start section for the grid cells/PolyData lines
Definition: vtuwriter.hh:285
void beginPoints()
start section for the point coordinates
Definition: vtuwriter.hh:238
VirtualRefinement base class.
Definition: virtualrefinement.hh:283
VertexIterator vBegin(Dune::RefinementIntervals tag) const
Get an VertexIterator.
Definition: virtualrefinement.cc:38
ElementIterator eBegin(Dune::RefinementIntervals tag) const
Get an ElementIterator.
Definition: virtualrefinement.cc:54
virtual int nElements(Dune::RefinementIntervals tag) const =0
Get the number of Elements.
ElementIterator eEnd(Dune::RefinementIntervals tag) const
Get an ElementIterator.
Definition: virtualrefinement.cc:62
Codim< 0 >::SubEntityIterator ElementIterator
The ElementIterator of the VirtualRefinement.
Definition: virtualrefinement.hh:290
VertexIterator vEnd(Dune::RefinementIntervals tag) const
Get an VertexIterator.
Definition: virtualrefinement.cc:46
virtual int nVertices(Dune::RefinementIntervals tag) const =0
Get the number of Vertices.
std::vector< int > IndexVector
The IndexVector of the VirtualRefinement.
Definition: virtualrefinement.hh:303
Codim< dimension >::SubEntityIterator VertexIterator
The VertexIterator of the VirtualRefinement.
Definition: virtualrefinement.hh:288
Precision
which precision to use when writing out data to vtk files
Definition: common.hh:271
#define DUNE_THROW(E, m)
Definition: exceptions.hh:218
static constexpr int dimension
The dimension of the grid.
Definition: gridview.hh:134
static constexpr int dimensionworld
The dimension of the world the grid lives in.
Definition: gridview.hh:137
constexpr GeometryType simplex(unsigned int dim)
Returns a GeometryType representing a simplex of dimension dim.
Definition: type.hh:453
constexpr auto min
Function object that returns the smaller of the given values.
Definition: hybridutilities.hh:506
Utility class for handling nested indentation in output.
Dune namespace.
Definition: alignedallocator.hh:13
Static tag representing a codimension.
Definition: dimension.hh:24
A unique label for each type of element that can occur in a grid.
This file contains the virtual wrapper around refinement.
Provides file i/o for the visualization toolkit.
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