OpenVDB 12.0.0
 
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VolumeToMesh.h
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1// Copyright Contributors to the OpenVDB Project
2// SPDX-License-Identifier: Apache-2.0
3
4/// @file VolumeToMesh.h
5///
6/// @brief Extract polygonal surfaces from scalar volumes.
7///
8/// @author Mihai Alden
9
10#ifndef OPENVDB_TOOLS_VOLUME_TO_MESH_HAS_BEEN_INCLUDED
11#define OPENVDB_TOOLS_VOLUME_TO_MESH_HAS_BEEN_INCLUDED
12
13#include <openvdb/Platform.h>
14#include <openvdb/math/Operators.h> // for ISGradient
16#include <openvdb/util/Util.h> // for INVALID_IDX
17#include <openvdb/util/Assert.h>
18#include <openvdb/openvdb.h>
19
20#include <tbb/blocked_range.h>
21#include <tbb/parallel_for.h>
22#include <tbb/parallel_reduce.h>
23#include <tbb/task_arena.h>
24
25#include <cmath> // for std::isfinite()
26#include <cstring> // for std::memset
27#include <map>
28#include <memory>
29#include <set>
30#include <type_traits>
31#include <vector>
32
33
34namespace openvdb {
36namespace OPENVDB_VERSION_NAME {
37namespace tools {
38
39
40////////////////////////////////////////
41
42
43// Wrapper functions for the VolumeToMesh converter
44
45
46/// @brief Uniformly mesh any scalar grid that has a continuous isosurface.
47///
48/// @param grid a scalar grid to mesh
49/// @param points output list of world space points
50/// @param quads output quad index list
51/// @param isovalue determines which isosurface to mesh
52///
53/// @throw TypeError if @a grid does not have a scalar value type
54template<typename GridType>
55void
57 const GridType& grid,
58 std::vector<Vec3s>& points,
59 std::vector<Vec4I>& quads,
60 double isovalue = 0.0);
61
62
63/// @brief Adaptively mesh any scalar grid that has a continuous isosurface.
64/// @details When converting to polygons, the adaptivity threshold determines
65/// how closely the isosurface is matched by the resulting mesh. Higher
66/// thresholds will allow more variation in polygon size, using fewer
67/// polygons to express the surface. Triangles will only be created for
68/// areas of the mesh which hit the adaptivity threshold and can't be
69/// represented as quads.
70/// @note Do not use this method just to get a triangle mesh - use the above
71/// method and post process the quad index list.
72///
73/// @param grid a scalar grid to mesh
74/// @param points output list of world space points
75/// @param triangles output triangle index list
76/// @param quads output quad index list
77/// @param isovalue determines which isosurface to mesh
78/// @param adaptivity surface adaptivity threshold [0 to 1]
79/// @param relaxDisorientedTriangles toggle relaxing disoriented triangles during
80/// adaptive meshing.
81///
82/// @throw TypeError if @a grid does not have a scalar value type
83template<typename GridType>
84void
86 const GridType& grid,
87 std::vector<Vec3s>& points,
88 std::vector<Vec3I>& triangles,
89 std::vector<Vec4I>& quads,
90 double isovalue = 0.0,
91 double adaptivity = 0.0,
92 bool relaxDisorientedTriangles = true);
93
94
95////////////////////////////////////////
96
97
98/// @brief Polygon flags, used for reference based meshing.
100
101
102/// @brief Collection of quads and triangles
104{
105public:
106
107 inline PolygonPool();
108 inline PolygonPool(const size_t numQuads, const size_t numTriangles);
109
110 inline void copy(const PolygonPool& rhs);
111
112 inline void resetQuads(size_t size);
113 inline void clearQuads();
114
115 inline void resetTriangles(size_t size);
116 inline void clearTriangles();
117
118
119 // polygon accessor methods
120
121 const size_t& numQuads() const { return mNumQuads; }
122
123 openvdb::Vec4I& quad(size_t n) { return mQuads[n]; }
124 const openvdb::Vec4I& quad(size_t n) const { return mQuads[n]; }
125
126
127 const size_t& numTriangles() const { return mNumTriangles; }
128
129 openvdb::Vec3I& triangle(size_t n) { return mTriangles[n]; }
130 const openvdb::Vec3I& triangle(size_t n) const { return mTriangles[n]; }
131
132
133 // polygon flags accessor methods
134
135 char& quadFlags(size_t n) { return mQuadFlags[n]; }
136 const char& quadFlags(size_t n) const { return mQuadFlags[n]; }
137
138 char& triangleFlags(size_t n) { return mTriangleFlags[n]; }
139 const char& triangleFlags(size_t n) const { return mTriangleFlags[n]; }
140
141
142 // reduce the polygon containers, n has to
143 // be smaller than the current container size.
144
145 inline bool trimQuads(const size_t n, bool reallocate = false);
146 inline bool trimTrinagles(const size_t n, bool reallocate = false);
147
148private:
149 // disallow copy by assignment
150 void operator=(const PolygonPool&) {}
151
152 size_t mNumQuads, mNumTriangles;
153 std::unique_ptr<openvdb::Vec4I[]> mQuads;
154 std::unique_ptr<openvdb::Vec3I[]> mTriangles;
155 std::unique_ptr<char[]> mQuadFlags, mTriangleFlags;
156};
157
158
159/// @{
160/// @brief Point and primitive list types.
161using PointList = std::unique_ptr<openvdb::Vec3s[]>;
162using PolygonPoolList = std::unique_ptr<PolygonPool[]>;
163/// @}
164
165
166////////////////////////////////////////
167
168
169/// @brief Mesh any scalar grid that has a continuous isosurface.
171{
172
173 /// @param isovalue Determines which isosurface to mesh.
174 /// @param adaptivity Adaptivity threshold [0 to 1]
175 /// @param relaxDisorientedTriangles Toggle relaxing disoriented triangles during
176 /// adaptive meshing.
177 VolumeToMesh(double isovalue = 0, double adaptivity = 0, bool relaxDisorientedTriangles = true);
178
179 //////////
180
181 /// @{
182 // Mesh data accessors
183
184 size_t pointListSize() const { return mPointListSize; }
185 PointList& pointList() { return mPoints; }
186 const PointList& pointList() const { return mPoints; }
187
188 size_t polygonPoolListSize() const { return mPolygonPoolListSize; }
189 PolygonPoolList& polygonPoolList() { return mPolygons; }
190 const PolygonPoolList& polygonPoolList() const { return mPolygons; }
191
192 std::vector<uint8_t>& pointFlags() { return mPointFlags; }
193 const std::vector<uint8_t>& pointFlags() const { return mPointFlags; }
194 /// @}
195
196
197 //////////
198
199
200 /// @brief Main call
201 /// @note Call with scalar typed grid.
202 template<typename InputGridType>
203 void operator()(const InputGridType&);
204
205
206 //////////
207
208
209 /// @brief When surfacing fractured SDF fragments, the original unfractured
210 /// SDF grid can be used to eliminate seam lines and tag polygons that are
211 /// coincident with the reference surface with the @c POLYFLAG_EXTERIOR
212 /// flag and polygons that are in proximity to the seam lines with the
213 /// @c POLYFLAG_FRACTURE_SEAM flag. (The performance cost for using this
214 /// reference based scheme compared to the regular meshing scheme is
215 /// approximately 15% for the first fragment and neglect-able for
216 /// subsequent fragments.)
217 ///
218 /// @note Attributes from the original asset such as uv coordinates, normals etc.
219 /// are typically transferred to polygons that are marked with the
220 /// @c POLYFLAG_EXTERIOR flag. Polygons that are not marked with this flag
221 /// are interior to reference surface and might need projected UV coordinates
222 /// or a different material. Polygons marked as @c POLYFLAG_FRACTURE_SEAM can
223 /// be used to drive secondary elements such as debris and dust in a FX pipeline.
224 ///
225 /// @param grid reference surface grid of @c GridT type.
226 /// @param secAdaptivity Secondary adaptivity threshold [0 to 1]. Used in regions
227 /// that do not exist in the reference grid. (Parts of the
228 /// fragment surface that are not coincident with the
229 /// reference surface.)
230 void setRefGrid(const GridBase::ConstPtr& grid, double secAdaptivity = 0);
231
232
233 /// @param mask A boolean grid whose active topology defines the region to mesh.
234 /// @param invertMask Toggle to mesh the complement of the mask.
235 /// @note The mask's tree configuration has to match @c GridT's tree configuration.
236 void setSurfaceMask(const GridBase::ConstPtr& mask, bool invertMask = false);
237
238 /// @param grid A scalar grid used as a spatial multiplier for the adaptivity threshold.
239 /// @note The grid's tree configuration has to match @c GridT's tree configuration.
240 void setSpatialAdaptivity(const GridBase::ConstPtr& grid);
241
242
243 /// @param tree A boolean tree whose active topology defines the adaptivity mask.
244 /// @note The tree configuration has to match @c GridT's tree configuration.
245 void setAdaptivityMask(const TreeBase::ConstPtr& tree);
246
247private:
248 // Disallow copying
250 VolumeToMesh& operator=(const VolumeToMesh&);
251
252
253 PointList mPoints;
254 PolygonPoolList mPolygons;
255
256 size_t mPointListSize, mSeamPointListSize, mPolygonPoolListSize;
257 double mIsovalue, mPrimAdaptivity, mSecAdaptivity;
258
259 GridBase::ConstPtr mRefGrid, mSurfaceMaskGrid, mAdaptivityGrid;
260 TreeBase::ConstPtr mAdaptivityMaskTree;
261
262 TreeBase::Ptr mRefSignTree, mRefIdxTree;
263
264 bool mInvertSurfaceMask, mRelaxDisorientedTriangles;
265
266 std::unique_ptr<uint32_t[]> mQuantizedSeamPoints;
267 std::vector<uint8_t> mPointFlags;
268}; // struct VolumeToMesh
269
270
271////////////////////////////////////////
272
273
274/// @brief Given a set of tangent elements, @c points with corresponding @c normals,
275/// this method returns the intersection point of all tangent elements.
276///
277/// @note Used to extract surfaces with sharp edges and corners from volume data,
278/// see the following paper for details: "Feature Sensitive Surface
279/// Extraction from Volume Data, Kobbelt et al. 2001".
281 const std::vector<Vec3d>& points,
282 const std::vector<Vec3d>& normals)
283{
284 using Mat3d = math::Mat3d;
285
286 Vec3d avgPos(0.0);
287
288 if (points.empty()) return avgPos;
289
290 for (size_t n = 0, N = points.size(); n < N; ++n) {
291 avgPos += points[n];
292 }
293
294 avgPos /= double(points.size());
295
296 // Unique components of the 3x3 A^TA matrix, where A is
297 // the matrix of normals.
298 double m00=0,m01=0,m02=0,
299 m11=0,m12=0,
300 m22=0;
301
302 // The rhs vector, A^Tb, where b = n dot p
303 Vec3d rhs(0.0);
304
305 for (size_t n = 0, N = points.size(); n < N; ++n) {
306
307 const Vec3d& n_ref = normals[n];
308
309 // A^TA
310 m00 += n_ref[0] * n_ref[0]; // diagonal
311 m11 += n_ref[1] * n_ref[1];
312 m22 += n_ref[2] * n_ref[2];
313
314 m01 += n_ref[0] * n_ref[1]; // Upper-tri
315 m02 += n_ref[0] * n_ref[2];
316 m12 += n_ref[1] * n_ref[2];
317
318 // A^Tb (centered around the origin)
319 rhs += n_ref * n_ref.dot(points[n] - avgPos);
320 }
321
322 Mat3d A(m00,m01,m02,
323 m01,m11,m12,
324 m02,m12,m22);
325
326 /*
327 // Inverse
328 const double det = A.det();
329 if (det > 0.01) {
330 Mat3d A_inv = A.adjoint();
331 A_inv *= (1.0 / det);
332
333 return avgPos + A_inv * rhs;
334 }
335 */
336
337 // Compute the pseudo inverse
338
339 math::Mat3d eigenVectors;
340 Vec3d eigenValues;
341
342 diagonalizeSymmetricMatrix(A, eigenVectors, eigenValues, 300);
343
345
346
347 double tolerance = std::max(std::abs(eigenValues[0]), std::abs(eigenValues[1]));
348 tolerance = std::max(tolerance, std::abs(eigenValues[2]));
349 tolerance *= 0.01;
350
351 int clamped = 0;
352 for (int i = 0; i < 3; ++i ) {
353 if (std::abs(eigenValues[i]) < tolerance) {
354 D[i][i] = 0.0;
355 ++clamped;
356 } else {
357 D[i][i] = 1.0 / eigenValues[i];
358 }
359 }
360
361 // Assemble the pseudo inverse and calc. the intersection point
362 if (clamped < 3) {
363 Mat3d pseudoInv = eigenVectors * D * eigenVectors.transpose();
364 return avgPos + pseudoInv * rhs;
365 }
366
367 return avgPos;
368}
369
370
371////////////////////////////////////////////////////////////////////////////////
372////////////////////////////////////////////////////////////////////////////////
373
374
375// Internal utility objects and implementation details
376
377/// @cond OPENVDB_DOCS_INTERNAL
378
379namespace volume_to_mesh_internal {
380
381template<typename ValueType>
382struct FillArray
383{
384 FillArray(ValueType* array, const ValueType& v) : mArray(array), mValue(v) { }
385
386 void operator()(const tbb::blocked_range<size_t>& range) const {
387 const ValueType v = mValue;
388 for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
389 mArray[n] = v;
390 }
391 }
392
393 ValueType * const mArray;
394 const ValueType mValue;
395};
396
397
398template<typename ValueType>
399inline void
400fillArray(ValueType* array, const ValueType& val, const size_t length)
401{
402 const auto grainSize = std::max<size_t>(
403 length / tbb::this_task_arena::max_concurrency(), 1024);
404 const tbb::blocked_range<size_t> range(0, length, grainSize);
405 tbb::parallel_for(range, FillArray<ValueType>(array, val), tbb::simple_partitioner());
406}
407
408
409/// @brief Bit-flags used to classify cells.
410enum { SIGNS = 0xFF, EDGES = 0xE00, INSIDE = 0x100,
411 XEDGE = 0x200, YEDGE = 0x400, ZEDGE = 0x800, SEAM = 0x1000};
412
413
414/// @brief Used to quickly determine if a given cell is adaptable.
415const bool sAdaptable[256] = {
416 1,1,1,1,1,0,1,1,1,1,0,1,1,1,1,1,1,1,0,1,0,0,0,1,0,1,0,1,0,1,0,1,
417 1,0,1,1,0,0,1,1,0,0,0,1,0,0,1,1,1,1,1,1,0,0,1,1,0,1,0,1,0,0,0,1,
418 1,0,0,0,1,0,1,1,0,0,0,0,1,1,1,1,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,
419 1,0,1,1,1,0,1,1,0,0,0,0,1,0,1,1,1,1,1,1,1,0,1,1,0,0,0,0,0,0,0,1,
420 1,0,0,0,0,0,0,0,1,1,0,1,1,1,1,1,1,1,0,1,0,0,0,0,1,1,0,1,1,1,0,1,
421 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,1,1,1,1,0,0,0,0,1,1,0,1,0,0,0,1,
422 1,0,0,0,1,0,1,0,1,1,0,0,1,1,1,1,1,1,0,0,1,0,0,0,1,1,0,0,1,1,0,1,
423 1,0,1,0,1,0,1,0,1,0,0,0,1,0,1,1,1,1,1,1,1,0,1,1,1,1,0,1,1,1,1,1};
424
425
426/// @brief Contains the ambiguous face index for certain cell configuration.
427const unsigned char sAmbiguousFace[256] = {
428 0,0,0,0,0,5,0,0,0,0,5,0,0,0,0,0,0,0,1,0,0,5,1,0,4,0,0,0,4,0,0,0,
429 0,1,0,0,2,0,0,0,0,1,5,0,2,0,0,0,0,0,0,0,2,0,0,0,4,0,0,0,0,0,0,0,
430 0,0,2,2,0,5,0,0,3,3,0,0,0,0,0,0,6,6,0,0,6,0,0,0,0,0,0,0,0,0,0,0,
431 0,1,0,0,0,0,0,0,3,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,
432 0,4,0,4,3,0,3,0,0,0,5,0,0,0,0,0,0,0,1,0,3,0,0,0,0,0,0,0,0,0,0,0,
433 6,0,6,0,0,0,0,0,6,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,
434 0,4,2,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,
435 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0};
436
437
438/// @brief Lookup table for different cell sign configurations. The first entry specifies
439/// the total number of points that need to be generated inside a cell and the
440/// remaining 12 entries indicate different edge groups.
441const unsigned char sEdgeGroupTable[256][13] = {
442 {0,0,0,0,0,0,0,0,0,0,0,0,0},{1,1,0,0,1,0,0,0,0,1,0,0,0},{1,1,1,0,0,0,0,0,0,0,1,0,0},
443 {1,0,1,0,1,0,0,0,0,1,1,0,0},{1,0,1,1,0,0,0,0,0,0,0,1,0},{1,1,1,1,1,0,0,0,0,1,0,1,0},
444 {1,1,0,1,0,0,0,0,0,0,1,1,0},{1,0,0,1,1,0,0,0,0,1,1,1,0},{1,0,0,1,1,0,0,0,0,0,0,0,1},
445 {1,1,0,1,0,0,0,0,0,1,0,0,1},{1,1,1,1,1,0,0,0,0,0,1,0,1},{1,0,1,1,0,0,0,0,0,1,1,0,1},
446 {1,0,1,0,1,0,0,0,0,0,0,1,1},{1,1,1,0,0,0,0,0,0,1,0,1,1},{1,1,0,0,1,0,0,0,0,0,1,1,1},
447 {1,0,0,0,0,0,0,0,0,1,1,1,1},{1,0,0,0,0,1,0,0,1,1,0,0,0},{1,1,0,0,1,1,0,0,1,0,0,0,0},
448 {1,1,1,0,0,1,0,0,1,1,1,0,0},{1,0,1,0,1,1,0,0,1,0,1,0,0},{2,0,1,1,0,2,0,0,2,2,0,1,0},
449 {1,1,1,1,1,1,0,0,1,0,0,1,0},{1,1,0,1,0,1,0,0,1,1,1,1,0},{1,0,0,1,1,1,0,0,1,0,1,1,0},
450 {1,0,0,1,1,1,0,0,1,1,0,0,1},{1,1,0,1,0,1,0,0,1,0,0,0,1},{2,2,1,1,2,1,0,0,1,2,1,0,1},
451 {1,0,1,1,0,1,0,0,1,0,1,0,1},{1,0,1,0,1,1,0,0,1,1,0,1,1},{1,1,1,0,0,1,0,0,1,0,0,1,1},
452 {2,1,0,0,1,2,0,0,2,1,2,2,2},{1,0,0,0,0,1,0,0,1,0,1,1,1},{1,0,0,0,0,1,1,0,0,0,1,0,0},
453 {1,1,0,0,1,1,1,0,0,1,1,0,0},{1,1,1,0,0,1,1,0,0,0,0,0,0},{1,0,1,0,1,1,1,0,0,1,0,0,0},
454 {1,0,1,1,0,1,1,0,0,0,1,1,0},{2,2,2,1,1,1,1,0,0,1,2,1,0},{1,1,0,1,0,1,1,0,0,0,0,1,0},
455 {1,0,0,1,1,1,1,0,0,1,0,1,0},{2,0,0,2,2,1,1,0,0,0,1,0,2},{1,1,0,1,0,1,1,0,0,1,1,0,1},
456 {1,1,1,1,1,1,1,0,0,0,0,0,1},{1,0,1,1,0,1,1,0,0,1,0,0,1},{1,0,1,0,1,1,1,0,0,0,1,1,1},
457 {2,1,1,0,0,2,2,0,0,2,1,2,2},{1,1,0,0,1,1,1,0,0,0,0,1,1},{1,0,0,0,0,1,1,0,0,1,0,1,1},
458 {1,0,0,0,0,0,1,0,1,1,1,0,0},{1,1,0,0,1,0,1,0,1,0,1,0,0},{1,1,1,0,0,0,1,0,1,1,0,0,0},
459 {1,0,1,0,1,0,1,0,1,0,0,0,0},{1,0,1,1,0,0,1,0,1,1,1,1,0},{2,1,1,2,2,0,2,0,2,0,1,2,0},
460 {1,1,0,1,0,0,1,0,1,1,0,1,0},{1,0,0,1,1,0,1,0,1,0,0,1,0},{1,0,0,1,1,0,1,0,1,1,1,0,1},
461 {1,1,0,1,0,0,1,0,1,0,1,0,1},{2,1,2,2,1,0,2,0,2,1,0,0,2},{1,0,1,1,0,0,1,0,1,0,0,0,1},
462 {2,0,2,0,2,0,1,0,1,2,2,1,1},{2,2,2,0,0,0,1,0,1,0,2,1,1},{2,2,0,0,2,0,1,0,1,2,0,1,1},
463 {1,0,0,0,0,0,1,0,1,0,0,1,1},{1,0,0,0,0,0,1,1,0,0,0,1,0},{2,1,0,0,1,0,2,2,0,1,0,2,0},
464 {1,1,1,0,0,0,1,1,0,0,1,1,0},{1,0,1,0,1,0,1,1,0,1,1,1,0},{1,0,1,1,0,0,1,1,0,0,0,0,0},
465 {1,1,1,1,1,0,1,1,0,1,0,0,0},{1,1,0,1,0,0,1,1,0,0,1,0,0},{1,0,0,1,1,0,1,1,0,1,1,0,0},
466 {1,0,0,1,1,0,1,1,0,0,0,1,1},{1,1,0,1,0,0,1,1,0,1,0,1,1},{2,1,2,2,1,0,1,1,0,0,1,2,1},
467 {2,0,1,1,0,0,2,2,0,2,2,1,2},{1,0,1,0,1,0,1,1,0,0,0,0,1},{1,1,1,0,0,0,1,1,0,1,0,0,1},
468 {1,1,0,0,1,0,1,1,0,0,1,0,1},{1,0,0,0,0,0,1,1,0,1,1,0,1},{1,0,0,0,0,1,1,1,1,1,0,1,0},
469 {1,1,0,0,1,1,1,1,1,0,0,1,0},{2,1,1,0,0,2,2,1,1,1,2,1,0},{2,0,2,0,2,1,1,2,2,0,1,2,0},
470 {1,0,1,1,0,1,1,1,1,1,0,0,0},{2,2,2,1,1,2,2,1,1,0,0,0,0},{2,2,0,2,0,1,1,2,2,2,1,0,0},
471 {2,0,0,1,1,2,2,1,1,0,2,0,0},{2,0,0,1,1,1,1,2,2,1,0,1,2},{2,2,0,2,0,2,2,1,1,0,0,2,1},
472 {4,3,2,2,3,4,4,1,1,3,4,2,1},{3,0,2,2,0,1,1,3,3,0,1,2,3},{2,0,2,0,2,2,2,1,1,2,0,0,1},
473 {2,1,1,0,0,1,1,2,2,0,0,0,2},{3,1,0,0,1,2,2,3,3,1,2,0,3},{2,0,0,0,0,1,1,2,2,0,1,0,2},
474 {1,0,0,0,0,1,0,1,0,0,1,1,0},{1,1,0,0,1,1,0,1,0,1,1,1,0},{1,1,1,0,0,1,0,1,0,0,0,1,0},
475 {1,0,1,0,1,1,0,1,0,1,0,1,0},{1,0,1,1,0,1,0,1,0,0,1,0,0},{2,1,1,2,2,2,0,2,0,2,1,0,0},
476 {1,1,0,1,0,1,0,1,0,0,0,0,0},{1,0,0,1,1,1,0,1,0,1,0,0,0},{1,0,0,1,1,1,0,1,0,0,1,1,1},
477 {2,2,0,2,0,1,0,1,0,1,2,2,1},{2,2,1,1,2,2,0,2,0,0,0,1,2},{2,0,2,2,0,1,0,1,0,1,0,2,1},
478 {1,0,1,0,1,1,0,1,0,0,1,0,1},{2,2,2,0,0,1,0,1,0,1,2,0,1},{1,1,0,0,1,1,0,1,0,0,0,0,1},
479 {1,0,0,0,0,1,0,1,0,1,0,0,1},{1,0,0,0,0,0,0,1,1,1,1,1,0},{1,1,0,0,1,0,0,1,1,0,1,1,0},
480 {1,1,1,0,0,0,0,1,1,1,0,1,0},{1,0,1,0,1,0,0,1,1,0,0,1,0},{1,0,1,1,0,0,0,1,1,1,1,0,0},
481 {2,2,2,1,1,0,0,1,1,0,2,0,0},{1,1,0,1,0,0,0,1,1,1,0,0,0},{1,0,0,1,1,0,0,1,1,0,0,0,0},
482 {2,0,0,2,2,0,0,1,1,2,2,2,1},{2,1,0,1,0,0,0,2,2,0,1,1,2},{3,2,1,1,2,0,0,3,3,2,0,1,3},
483 {2,0,1,1,0,0,0,2,2,0,0,1,2},{2,0,1,0,1,0,0,2,2,1,1,0,2},{2,1,1,0,0,0,0,2,2,0,1,0,2},
484 {2,1,0,0,1,0,0,2,2,1,0,0,2},{1,0,0,0,0,0,0,1,1,0,0,0,1},{1,0,0,0,0,0,0,1,1,0,0,0,1},
485 {1,1,0,0,1,0,0,1,1,1,0,0,1},{2,1,1,0,0,0,0,2,2,0,1,0,2},{1,0,1,0,1,0,0,1,1,1,1,0,1},
486 {1,0,1,1,0,0,0,1,1,0,0,1,1},{2,1,1,2,2,0,0,1,1,1,0,1,2},{1,1,0,1,0,0,0,1,1,0,1,1,1},
487 {2,0,0,1,1,0,0,2,2,2,2,2,1},{1,0,0,1,1,0,0,1,1,0,0,0,0},{1,1,0,1,0,0,0,1,1,1,0,0,0},
488 {1,1,1,1,1,0,0,1,1,0,1,0,0},{1,0,1,1,0,0,0,1,1,1,1,0,0},{1,0,1,0,1,0,0,1,1,0,0,1,0},
489 {1,1,1,0,0,0,0,1,1,1,0,1,0},{1,1,0,0,1,0,0,1,1,0,1,1,0},{1,0,0,0,0,0,0,1,1,1,1,1,0},
490 {1,0,0,0,0,1,0,1,0,1,0,0,1},{1,1,0,0,1,1,0,1,0,0,0,0,1},{1,1,1,0,0,1,0,1,0,1,1,0,1},
491 {1,0,1,0,1,1,0,1,0,0,1,0,1},{1,0,1,1,0,1,0,1,0,1,0,1,1},{2,2,2,1,1,2,0,2,0,0,0,2,1},
492 {2,1,0,1,0,2,0,2,0,1,2,2,1},{2,0,0,2,2,1,0,1,0,0,1,1,2},{1,0,0,1,1,1,0,1,0,1,0,0,0},
493 {1,1,0,1,0,1,0,1,0,0,0,0,0},{2,1,2,2,1,2,0,2,0,1,2,0,0},{1,0,1,1,0,1,0,1,0,0,1,0,0},
494 {1,0,1,0,1,1,0,1,0,1,0,1,0},{1,1,1,0,0,1,0,1,0,0,0,1,0},{2,2,0,0,2,1,0,1,0,2,1,1,0},
495 {1,0,0,0,0,1,0,1,0,0,1,1,0},{1,0,0,0,0,1,1,1,1,0,1,0,1},{2,1,0,0,1,2,1,1,2,2,1,0,1},
496 {1,1,1,0,0,1,1,1,1,0,0,0,1},{2,0,2,0,2,1,2,2,1,1,0,0,2},{2,0,1,1,0,1,2,2,1,0,1,2,1},
497 {4,1,1,3,3,2,4,4,2,2,1,4,3},{2,2,0,2,0,2,1,1,2,0,0,1,2},{3,0,0,1,1,2,3,3,2,2,0,3,1},
498 {1,0,0,1,1,1,1,1,1,0,1,0,0},{2,2,0,2,0,1,2,2,1,1,2,0,0},{2,2,1,1,2,2,1,1,2,0,0,0,0},
499 {2,0,1,1,0,2,1,1,2,2,0,0,0},{2,0,2,0,2,2,1,1,2,0,2,1,0},{3,1,1,0,0,3,2,2,3,3,1,2,0},
500 {2,1,0,0,1,1,2,2,1,0,0,2,0},{2,0,0,0,0,2,1,1,2,2,0,1,0},{1,0,0,0,0,0,1,1,0,1,1,0,1},
501 {1,1,0,0,1,0,1,1,0,0,1,0,1},{1,1,1,0,0,0,1,1,0,1,0,0,1},{1,0,1,0,1,0,1,1,0,0,0,0,1},
502 {2,0,2,2,0,0,1,1,0,2,2,1,2},{3,1,1,2,2,0,3,3,0,0,1,3,2},{2,1,0,1,0,0,2,2,0,1,0,2,1},
503 {2,0,0,1,1,0,2,2,0,0,0,2,1},{1,0,0,1,1,0,1,1,0,1,1,0,0},{1,1,0,1,0,0,1,1,0,0,1,0,0},
504 {2,2,1,1,2,0,1,1,0,2,0,0,0},{1,0,1,1,0,0,1,1,0,0,0,0,0},{2,0,1,0,1,0,2,2,0,1,1,2,0},
505 {2,1,1,0,0,0,2,2,0,0,1,2,0},{2,1,0,0,1,0,2,2,0,1,0,2,0},{1,0,0,0,0,0,1,1,0,0,0,1,0},
506 {1,0,0,0,0,0,1,0,1,0,0,1,1},{1,1,0,0,1,0,1,0,1,1,0,1,1},{1,1,1,0,0,0,1,0,1,0,1,1,1},
507 {2,0,2,0,2,0,1,0,1,1,1,2,2},{1,0,1,1,0,0,1,0,1,0,0,0,1},{2,2,2,1,1,0,2,0,2,2,0,0,1},
508 {1,1,0,1,0,0,1,0,1,0,1,0,1},{2,0,0,2,2,0,1,0,1,1,1,0,2},{1,0,0,1,1,0,1,0,1,0,0,1,0},
509 {1,1,0,1,0,0,1,0,1,1,0,1,0},{2,2,1,1,2,0,2,0,2,0,2,1,0},{2,0,2,2,0,0,1,0,1,1,1,2,0},
510 {1,0,1,0,1,0,1,0,1,0,0,0,0},{1,1,1,0,0,0,1,0,1,1,0,0,0},{1,1,0,0,1,0,1,0,1,0,1,0,0},
511 {1,0,0,0,0,0,1,0,1,1,1,0,0},{1,0,0,0,0,1,1,0,0,1,0,1,1},{1,1,0,0,1,1,1,0,0,0,0,1,1},
512 {2,2,2,0,0,1,1,0,0,2,1,2,2},{2,0,1,0,1,2,2,0,0,0,2,1,1},{1,0,1,1,0,1,1,0,0,1,0,0,1},
513 {2,1,1,2,2,1,1,0,0,0,0,0,2},{2,1,0,1,0,2,2,0,0,1,2,0,1},{2,0,0,2,2,1,1,0,0,0,1,0,2},
514 {1,0,0,1,1,1,1,0,0,1,0,1,0},{1,1,0,1,0,1,1,0,0,0,0,1,0},{3,1,2,2,1,3,3,0,0,1,3,2,0},
515 {2,0,1,1,0,2,2,0,0,0,2,1,0},{1,0,1,0,1,1,1,0,0,1,0,0,0},{1,1,1,0,0,1,1,0,0,0,0,0,0},
516 {2,2,0,0,2,1,1,0,0,2,1,0,0},{1,0,0,0,0,1,1,0,0,0,1,0,0},{1,0,0,0,0,1,0,0,1,0,1,1,1},
517 {2,2,0,0,2,1,0,0,1,1,2,2,2},{1,1,1,0,0,1,0,0,1,0,0,1,1},{2,0,1,0,1,2,0,0,2,2,0,1,1},
518 {1,0,1,1,0,1,0,0,1,0,1,0,1},{3,1,1,3,3,2,0,0,2,2,1,0,3},{1,1,0,1,0,1,0,0,1,0,0,0,1},
519 {2,0,0,2,2,1,0,0,1,1,0,0,2},{1,0,0,1,1,1,0,0,1,0,1,1,0},{2,1,0,1,0,2,0,0,2,2,1,1,0},
520 {2,1,2,2,1,1,0,0,1,0,0,2,0},{2,0,1,1,0,2,0,0,2,2,0,1,0},{1,0,1,0,1,1,0,0,1,0,1,0,0},
521 {2,1,1,0,0,2,0,0,2,2,1,0,0},{1,1,0,0,1,1,0,0,1,0,0,0,0},{1,0,0,0,0,1,0,0,1,1,0,0,0},
522 {1,0,0,0,0,0,0,0,0,1,1,1,1},{1,1,0,0,1,0,0,0,0,0,1,1,1},{1,1,1,0,0,0,0,0,0,1,0,1,1},
523 {1,0,1,0,1,0,0,0,0,0,0,1,1},{1,0,1,1,0,0,0,0,0,1,1,0,1},{2,1,1,2,2,0,0,0,0,0,1,0,2},
524 {1,1,0,1,0,0,0,0,0,1,0,0,1},{1,0,0,1,1,0,0,0,0,0,0,0,1},{1,0,0,1,1,0,0,0,0,1,1,1,0},
525 {1,1,0,1,0,0,0,0,0,0,1,1,0},{2,1,2,2,1,0,0,0,0,1,0,2,0},{1,0,1,1,0,0,0,0,0,0,0,1,0},
526 {1,0,1,0,1,0,0,0,0,1,1,0,0},{1,1,1,0,0,0,0,0,0,0,1,0,0},{1,1,0,0,1,0,0,0,0,1,0,0,0},
527 {0,0,0,0,0,0,0,0,0,0,0,0,0}};
528
529////////////////////////////////////////
530
531inline bool
532isPlanarQuad(
533 const Vec3d& p0, const Vec3d& p1,
534 const Vec3d& p2, const Vec3d& p3,
535 const double epsilon = 0.001)
536{
537 // compute representative plane
538 Vec3d normal = (p2-p0).cross(p1-p3);
539 normal.normalize();
540 const Vec3d centroid = (p0 + p1 + p2 + p3);
541 const double d = centroid.dot(normal) * 0.25;
542
543
544 // test vertice distance to plane
545 double absDist = std::abs(p0.dot(normal) - d);
546 if (absDist > epsilon) return false;
547
548 absDist = std::abs(p1.dot(normal) - d);
549 if (absDist > epsilon) return false;
550
551 absDist = std::abs(p2.dot(normal) - d);
552 if (absDist > epsilon) return false;
553
554 absDist = std::abs(p3.dot(normal) - d);
555 if (absDist > epsilon) return false;
556
557 return true;
558}
559
560
561////////////////////////////////////////
562
563
564/// @{
565/// @brief Utility methods for point quantization.
566
567enum {
568 MASK_FIRST_10_BITS = 0x000003FF,
569 MASK_DIRTY_BIT = 0x80000000,
570 MASK_INVALID_BIT = 0x40000000
571};
572
573inline uint32_t
574packPoint(const Vec3d& v)
575{
576 uint32_t data = 0;
577
578 // values are expected to be in the [0.0 to 1.0] range.
579 OPENVDB_ASSERT(!(v.x() > 1.0) && !(v.y() > 1.0) && !(v.z() > 1.0));
580 OPENVDB_ASSERT(!(v.x() < 0.0) && !(v.y() < 0.0) && !(v.z() < 0.0));
581
582 data |= (uint32_t(v.x() * 1023.0) & MASK_FIRST_10_BITS) << 20;
583 data |= (uint32_t(v.y() * 1023.0) & MASK_FIRST_10_BITS) << 10;
584 data |= (uint32_t(v.z() * 1023.0) & MASK_FIRST_10_BITS);
585
586 return data;
587}
588
589inline Vec3d
590unpackPoint(uint32_t data)
591{
592 Vec3d v;
593 v.z() = double(data & MASK_FIRST_10_BITS) * 0.0009775171;
594 data = data >> 10;
595 v.y() = double(data & MASK_FIRST_10_BITS) * 0.0009775171;
596 data = data >> 10;
597 v.x() = double(data & MASK_FIRST_10_BITS) * 0.0009775171;
598
599 return v;
600}
601
602/// @}
603
604////////////////////////////////////////
605
606template<typename T>
607inline bool isBoolValue() { return false; }
608
609template<>
610inline bool isBoolValue<bool>() { return true; }
611
612template<typename T>
613inline bool isInsideValue(T value, T isovalue) { return value < isovalue; }
614
615template<>
616inline bool isInsideValue<bool>(bool value, bool /*isovalue*/) { return value; }
617
618
619/// @brief Minor wrapper around the Leaf API to avoid atomic access with
620/// delayed loading.
621template <typename LeafT,
622 bool IsBool = std::is_same<typename LeafT::ValueType, bool>::value>
623struct LeafBufferAccessor
624{
625 using T = typename LeafT::ValueType;
626 LeafBufferAccessor(const LeafT& leaf) : mData(leaf.buffer().data()) {}
627 inline T get(const Index idx) const { return mData[idx]; }
628 const T* const mData;
629};
630
631template <typename LeafT>
632struct LeafBufferAccessor<LeafT, true>
633{
634 using T = bool;
635 LeafBufferAccessor(const LeafT& leaf) : mLeaf(leaf) {}
636 inline T get(const Index idx) const { return mLeaf.getValue(idx); }
637 const LeafT& mLeaf;
638};
639
640
641/// @brief Whether a coordinate does not lie at the positive edge of a leaf node.
642template <typename LeafT>
643bool isInternalLeafCoord(const Coord& ijk)
644{
645 return
646 ijk[0] < int(LeafT::DIM - 1) &&
647 ijk[1] < int(LeafT::DIM - 1) &&
648 ijk[2] < int(LeafT::DIM - 1);
649}
650
651
652/// @brief Extracts the eight corner values for a cell starting at the given @ijk coordinate.
653template<typename AccessorT, typename ValueT>
654inline void
655getCellVertexValues(const AccessorT& accessor,
656 Coord ijk,
657 std::array<ValueT, 8>& values)
658{
659 values[0] = ValueT(accessor.getValue(ijk)); // i, j, k
660 ++ijk[0];
661 values[1] = ValueT(accessor.getValue(ijk)); // i+1, j, k
662 ++ijk[2];
663 values[2] = ValueT(accessor.getValue(ijk)); // i+1, j, k+1
664 --ijk[0];
665 values[3] = ValueT(accessor.getValue(ijk)); // i, j, k+1
666 --ijk[2]; ++ijk[1];
667 values[4] = ValueT(accessor.getValue(ijk)); // i, j+1, k
668 ++ijk[0];
669 values[5] = ValueT(accessor.getValue(ijk)); // i+1, j+1, k
670 ++ijk[2];
671 values[6] = ValueT(accessor.getValue(ijk)); // i+1, j+1, k+1
672 --ijk[0];
673 values[7] = ValueT(accessor.getValue(ijk)); // i, j+1, k+1
674}
675
676
677/// @brief Extracts the eight corner values for a cell starting at the given @ijk coordinate.
678template<typename LeafT, typename ValueT>
679inline void
680getCellVertexValues(const LeafT& leaf,
681 const Index offset,
682 std::array<ValueT, 8>& values)
683{
684 const LeafBufferAccessor<LeafT> acc(leaf);
685
686 values[0] = ValueT(acc.get(offset)); // i, j, k
687 values[3] = ValueT(acc.get(offset + 1)); // i, j, k+1
688 values[4] = ValueT(acc.get(offset + LeafT::DIM)); // i, j+1, k
689 values[7] = ValueT(acc.get(offset + LeafT::DIM + 1)); // i, j+1, k+1
690 values[1] = ValueT(acc.get(offset + (LeafT::DIM * LeafT::DIM))); // i+1, j, k
691 values[2] = ValueT(acc.get(offset + (LeafT::DIM * LeafT::DIM) + 1)); // i+1, j, k+1
692 values[5] = ValueT(acc.get(offset + (LeafT::DIM * LeafT::DIM) + LeafT::DIM)); // i+1, j+1, k
693 values[6] = ValueT(acc.get(offset + (LeafT::DIM * LeafT::DIM) + LeafT::DIM + 1)); // i+1, j+1, k+1
694}
695
696
697template<typename ValueType>
698inline uint8_t
699computeSignFlags(const std::array<ValueType, 8>& values, const ValueType iso)
700{
701 unsigned signs = 0;
702 signs |= isInsideValue(values[0], iso) ? 1u : 0u;
703 signs |= isInsideValue(values[1], iso) ? 2u : 0u;
704 signs |= isInsideValue(values[2], iso) ? 4u : 0u;
705 signs |= isInsideValue(values[3], iso) ? 8u : 0u;
706 signs |= isInsideValue(values[4], iso) ? 16u : 0u;
707 signs |= isInsideValue(values[5], iso) ? 32u : 0u;
708 signs |= isInsideValue(values[6], iso) ? 64u : 0u;
709 signs |= isInsideValue(values[7], iso) ? 128u : 0u;
710 return uint8_t(signs);
711}
712
713
714/// @brief General method that computes the cell-sign configuration at the given
715/// @c ijk coordinate.
716template<typename AccessorT>
717inline uint8_t
718evalCellSigns(const AccessorT& accessor, const Coord& ijk, typename AccessorT::ValueType iso)
719{
720 unsigned signs = 0;
721 Coord coord = ijk; // i, j, k
722 if (isInsideValue(accessor.getValue(coord), iso)) signs |= 1u;
723 coord[0] += 1; // i+1, j, k
724 if (isInsideValue(accessor.getValue(coord), iso)) signs |= 2u;
725 coord[2] += 1; // i+1, j, k+1
726 if (isInsideValue(accessor.getValue(coord), iso)) signs |= 4u;
727 coord[0] = ijk[0]; // i, j, k+1
728 if (isInsideValue(accessor.getValue(coord), iso)) signs |= 8u;
729 coord[1] += 1; coord[2] = ijk[2]; // i, j+1, k
730 if (isInsideValue(accessor.getValue(coord), iso)) signs |= 16u;
731 coord[0] += 1; // i+1, j+1, k
732 if (isInsideValue(accessor.getValue(coord), iso)) signs |= 32u;
733 coord[2] += 1; // i+1, j+1, k+1
734 if (isInsideValue(accessor.getValue(coord), iso)) signs |= 64u;
735 coord[0] = ijk[0]; // i, j+1, k+1
736 if (isInsideValue(accessor.getValue(coord), iso)) signs |= 128u;
737 return uint8_t(signs);
738}
739
740
741/// @brief Leaf node optimized method that computes the cell-sign configuration
742/// at the given local @c offset
743template<typename LeafT>
744inline uint8_t
745evalCellSigns(const LeafT& leaf, const Index offset, typename LeafT::ValueType iso)
746{
747 const LeafBufferAccessor<LeafT> acc(leaf);
748
749 unsigned signs = 0;
750 if (isInsideValue(acc.get(offset), iso)) signs |= 1u; // i, j, k
751 if (isInsideValue(acc.get(offset + (LeafT::DIM * LeafT::DIM)), iso)) signs |= 2u; // i+1, j, k
752 if (isInsideValue(acc.get(offset + (LeafT::DIM * LeafT::DIM) + 1), iso)) signs |= 4u; // i+1, j, k+1
753 if (isInsideValue(acc.get(offset + 1), iso)) signs |= 8u; // i, j, k+1
754 if (isInsideValue(acc.get(offset + LeafT::DIM), iso)) signs |= 16u; // i, j+1, k
755 if (isInsideValue(acc.get(offset + (LeafT::DIM * LeafT::DIM) + LeafT::DIM), iso)) signs |= 32u; // i+1, j+1, k
756 if (isInsideValue(acc.get(offset + (LeafT::DIM * LeafT::DIM) + LeafT::DIM + 1), iso)) signs |= 64u; // i+1, j+1, k+1
757 if (isInsideValue(acc.get(offset + LeafT::DIM + 1), iso)) signs |= 128u; // i, j+1, k+1
758 return uint8_t(signs);
759}
760
761
762/// @brief Used to correct topological ambiguities related to two adjacent cells
763/// that share an ambiguous face.
764template<class AccessorT>
765inline void
766correctCellSigns(uint8_t& signs,
767 const uint8_t face,
768 const AccessorT& acc,
769 Coord ijk,
770 const typename AccessorT::ValueType iso)
771{
772 switch (int(face)) {
773 case 1:
774 ijk[2] -= 1;
775 if (sAmbiguousFace[evalCellSigns(acc, ijk, iso)] == 3) signs = uint8_t(~signs);
776 break;
777 case 2:
778 ijk[0] += 1;
779 if (sAmbiguousFace[evalCellSigns(acc, ijk, iso)] == 4) signs = uint8_t(~signs);
780 break;
781 case 3:
782 ijk[2] += 1;
783 if (sAmbiguousFace[evalCellSigns(acc, ijk, iso)] == 1) signs = uint8_t(~signs);
784 break;
785 case 4:
786 ijk[0] -= 1;
787 if (sAmbiguousFace[evalCellSigns(acc, ijk, iso)] == 2) signs = uint8_t(~signs);
788 break;
789 case 5:
790 ijk[1] -= 1;
791 if (sAmbiguousFace[evalCellSigns(acc, ijk, iso)] == 6) signs = uint8_t(~signs);
792 break;
793 case 6:
794 ijk[1] += 1;
795 if (sAmbiguousFace[evalCellSigns(acc, ijk, iso)] == 5) signs = uint8_t(~signs);
796 break;
797 default:
798 break;
799 }
800}
801
802
803template<class AccessorT>
804inline bool
805isNonManifold(const AccessorT& accessor, const Coord& ijk,
806 typename AccessorT::ValueType isovalue, const int dim)
807{
808 const int hDim = dim >> 1;
809 bool m, p[8]; // Corner signs
810
811 Coord coord = ijk; // i, j, k
812 p[0] = isInsideValue(accessor.getValue(coord), isovalue);
813 coord[0] += dim; // i+dim, j, k
814 p[1] = isInsideValue(accessor.getValue(coord), isovalue);
815 coord[2] += dim; // i+dim, j, k+dim
816 p[2] = isInsideValue(accessor.getValue(coord), isovalue);
817 coord[0] = ijk[0]; // i, j, k+dim
818 p[3] = isInsideValue(accessor.getValue(coord), isovalue);
819 coord[1] += dim; coord[2] = ijk[2]; // i, j+dim, k
820 p[4] = isInsideValue(accessor.getValue(coord), isovalue);
821 coord[0] += dim; // i+dim, j+dim, k
822 p[5] = isInsideValue(accessor.getValue(coord), isovalue);
823 coord[2] += dim; // i+dim, j+dim, k+dim
824 p[6] = isInsideValue(accessor.getValue(coord), isovalue);
825 coord[0] = ijk[0]; // i, j+dim, k+dim
826 p[7] = isInsideValue(accessor.getValue(coord), isovalue);
827
828 // Check if the corner sign configuration is ambiguous
829 unsigned signs = 0;
830 if (p[0]) signs |= 1u;
831 if (p[1]) signs |= 2u;
832 if (p[2]) signs |= 4u;
833 if (p[3]) signs |= 8u;
834 if (p[4]) signs |= 16u;
835 if (p[5]) signs |= 32u;
836 if (p[6]) signs |= 64u;
837 if (p[7]) signs |= 128u;
838 if (!sAdaptable[signs]) return true;
839
840 // Manifold check
841
842 // Evaluate edges
843 const int i = ijk[0], ip = ijk[0] + hDim, ipp = ijk[0] + dim;
844 const int j = ijk[1], jp = ijk[1] + hDim, jpp = ijk[1] + dim;
845 const int k = ijk[2], kp = ijk[2] + hDim, kpp = ijk[2] + dim;
846
847 // edge 1
848 coord.reset(ip, j, k);
849 m = isInsideValue(accessor.getValue(coord), isovalue);
850 if (p[0] != m && p[1] != m) return true;
851
852 // edge 2
853 coord.reset(ipp, j, kp);
854 m = isInsideValue(accessor.getValue(coord), isovalue);
855 if (p[1] != m && p[2] != m) return true;
856
857 // edge 3
858 coord.reset(ip, j, kpp);
859 m = isInsideValue(accessor.getValue(coord), isovalue);
860 if (p[2] != m && p[3] != m) return true;
861
862 // edge 4
863 coord.reset(i, j, kp);
864 m = isInsideValue(accessor.getValue(coord), isovalue);
865 if (p[0] != m && p[3] != m) return true;
866
867 // edge 5
868 coord.reset(ip, jpp, k);
869 m = isInsideValue(accessor.getValue(coord), isovalue);
870 if (p[4] != m && p[5] != m) return true;
871
872 // edge 6
873 coord.reset(ipp, jpp, kp);
874 m = isInsideValue(accessor.getValue(coord), isovalue);
875 if (p[5] != m && p[6] != m) return true;
876
877 // edge 7
878 coord.reset(ip, jpp, kpp);
879 m = isInsideValue(accessor.getValue(coord), isovalue);
880 if (p[6] != m && p[7] != m) return true;
881
882 // edge 8
883 coord.reset(i, jpp, kp);
884 m = isInsideValue(accessor.getValue(coord), isovalue);
885 if (p[7] != m && p[4] != m) return true;
886
887 // edge 9
888 coord.reset(i, jp, k);
889 m = isInsideValue(accessor.getValue(coord), isovalue);
890 if (p[0] != m && p[4] != m) return true;
891
892 // edge 10
893 coord.reset(ipp, jp, k);
894 m = isInsideValue(accessor.getValue(coord), isovalue);
895 if (p[1] != m && p[5] != m) return true;
896
897 // edge 11
898 coord.reset(ipp, jp, kpp);
899 m = isInsideValue(accessor.getValue(coord), isovalue);
900 if (p[2] != m && p[6] != m) return true;
901
902
903 // edge 12
904 coord.reset(i, jp, kpp);
905 m = isInsideValue(accessor.getValue(coord), isovalue);
906 if (p[3] != m && p[7] != m) return true;
907
908
909 // Evaluate faces
910
911 // face 1
912 coord.reset(ip, jp, k);
913 m = isInsideValue(accessor.getValue(coord), isovalue);
914 if (p[0] != m && p[1] != m && p[4] != m && p[5] != m) return true;
915
916 // face 2
917 coord.reset(ipp, jp, kp);
918 m = isInsideValue(accessor.getValue(coord), isovalue);
919 if (p[1] != m && p[2] != m && p[5] != m && p[6] != m) return true;
920
921 // face 3
922 coord.reset(ip, jp, kpp);
923 m = isInsideValue(accessor.getValue(coord), isovalue);
924 if (p[2] != m && p[3] != m && p[6] != m && p[7] != m) return true;
925
926 // face 4
927 coord.reset(i, jp, kp);
928 m = isInsideValue(accessor.getValue(coord), isovalue);
929 if (p[0] != m && p[3] != m && p[4] != m && p[7] != m) return true;
930
931 // face 5
932 coord.reset(ip, j, kp);
933 m = isInsideValue(accessor.getValue(coord), isovalue);
934 if (p[0] != m && p[1] != m && p[2] != m && p[3] != m) return true;
935
936 // face 6
937 coord.reset(ip, jpp, kp);
938 m = isInsideValue(accessor.getValue(coord), isovalue);
939 if (p[4] != m && p[5] != m && p[6] != m && p[7] != m) return true;
940
941 // test cube center
942 coord.reset(ip, jp, kp);
943 m = isInsideValue(accessor.getValue(coord), isovalue);
944 if (p[0] != m && p[1] != m && p[2] != m && p[3] != m &&
945 p[4] != m && p[5] != m && p[6] != m && p[7] != m) return true;
946
947 return false;
948}
949
950
951////////////////////////////////////////
952
953
954template <class LeafType>
955inline void
956mergeVoxels(LeafType& leaf, const Coord& start, const int dim, const int regionId)
957{
958 Coord ijk;
959 const Coord end = start.offsetBy(dim);
960
961 for (ijk[0] = start[0]; ijk[0] < end[0]; ++ijk[0]) {
962 for (ijk[1] = start[1]; ijk[1] < end[1]; ++ijk[1]) {
963 for (ijk[2] = start[2]; ijk[2] < end[2]; ++ijk[2]) {
964 leaf.setValueOnly(ijk, regionId);
965 }
966 }
967 }
968}
969
970
971// Note that we must use ValueType::value_type or else Visual C++ gets confused
972// thinking that it is a constructor.
973template <class LeafType>
974inline bool
975isMergeable(const LeafType& leaf,
976 const Coord& start,
977 const int dim,
978 typename LeafType::ValueType::value_type adaptivity)
979{
980 if (adaptivity < 1e-6) return false;
981
982 using VecT = typename LeafType::ValueType;
983 Coord ijk;
984 const Coord end = start.offsetBy(dim);
985
986 std::vector<VecT> norms;
987 for (ijk[0] = start[0]; ijk[0] < end[0]; ++ijk[0]) {
988 for (ijk[1] = start[1]; ijk[1] < end[1]; ++ijk[1]) {
989 for (ijk[2] = start[2]; ijk[2] < end[2]; ++ijk[2]) {
990 if (!leaf.isValueOn(ijk)) continue;
991 norms.push_back(leaf.getValue(ijk));
992 }
993 }
994 }
995
996 const size_t N = norms.size();
997 for (size_t ni = 0; ni < N; ++ni) {
998 VecT n_i = norms[ni];
999 for (size_t nj = 0; nj < N; ++nj) {
1000 VecT n_j = norms[nj];
1001 if ((1.0 - n_i.dot(n_j)) > adaptivity) return false;
1002 }
1003 }
1004 return true;
1005}
1006
1007
1008////////////////////////////////////////
1009
1010
1011/// linear interpolation.
1012inline double evalZeroCrossing(double v0, double v1, double iso) { return (iso - v0) / (v1 - v0); }
1013
1014
1015/// @brief Computes the average cell point for a given edge group.
1016inline Vec3d
1017computePoint(const std::array<double, 8>& values,
1018 const unsigned char signs,
1019 const unsigned char edgeGroup,
1020 const double iso)
1021{
1022 Vec3d avg(0.0, 0.0, 0.0);
1023 int samples = 0;
1024
1025 if (sEdgeGroupTable[signs][1] == edgeGroup) { // Edged: 0 - 1
1026 avg[0] += evalZeroCrossing(values[0], values[1], iso);
1027 ++samples;
1028 }
1029
1030 if (sEdgeGroupTable[signs][2] == edgeGroup) { // Edged: 1 - 2
1031 avg[0] += 1.0;
1032 avg[2] += evalZeroCrossing(values[1], values[2], iso);
1033 ++samples;
1034 }
1035
1036 if (sEdgeGroupTable[signs][3] == edgeGroup) { // Edged: 3 - 2
1037 avg[0] += evalZeroCrossing(values[3], values[2], iso);
1038 avg[2] += 1.0;
1039 ++samples;
1040 }
1041
1042 if (sEdgeGroupTable[signs][4] == edgeGroup) { // Edged: 0 - 3
1043 avg[2] += evalZeroCrossing(values[0], values[3], iso);
1044 ++samples;
1045 }
1046
1047 if (sEdgeGroupTable[signs][5] == edgeGroup) { // Edged: 4 - 5
1048 avg[0] += evalZeroCrossing(values[4], values[5], iso);
1049 avg[1] += 1.0;
1050 ++samples;
1051 }
1052
1053 if (sEdgeGroupTable[signs][6] == edgeGroup) { // Edged: 5 - 6
1054 avg[0] += 1.0;
1055 avg[1] += 1.0;
1056 avg[2] += evalZeroCrossing(values[5], values[6], iso);
1057 ++samples;
1058 }
1059
1060 if (sEdgeGroupTable[signs][7] == edgeGroup) { // Edged: 7 - 6
1061 avg[0] += evalZeroCrossing(values[7], values[6], iso);
1062 avg[1] += 1.0;
1063 avg[2] += 1.0;
1064 ++samples;
1065 }
1066
1067 if (sEdgeGroupTable[signs][8] == edgeGroup) { // Edged: 4 - 7
1068 avg[1] += 1.0;
1069 avg[2] += evalZeroCrossing(values[4], values[7], iso);
1070 ++samples;
1071 }
1072
1073 if (sEdgeGroupTable[signs][9] == edgeGroup) { // Edged: 0 - 4
1074 avg[1] += evalZeroCrossing(values[0], values[4], iso);
1075 ++samples;
1076 }
1077
1078 if (sEdgeGroupTable[signs][10] == edgeGroup) { // Edged: 1 - 5
1079 avg[0] += 1.0;
1080 avg[1] += evalZeroCrossing(values[1], values[5], iso);
1081 ++samples;
1082 }
1083
1084 if (sEdgeGroupTable[signs][11] == edgeGroup) { // Edged: 2 - 6
1085 avg[0] += 1.0;
1086 avg[1] += evalZeroCrossing(values[2], values[6], iso);
1087 avg[2] += 1.0;
1088 ++samples;
1089 }
1090
1091 if (sEdgeGroupTable[signs][12] == edgeGroup) { // Edged: 3 - 7
1092 avg[1] += evalZeroCrossing(values[3], values[7], iso);
1093 avg[2] += 1.0;
1094 ++samples;
1095 }
1096
1097 if (samples > 1) {
1098 const double w = 1.0 / double(samples);
1099 avg *= w;
1100 }
1101
1102 return avg;
1103}
1104
1105
1106/// @brief Computes the average cell point for a given edge group, ignoring edge
1107/// samples present in the @c signsMask configuration.
1108inline int
1109computeMaskedPoint(Vec3d& avg,
1110 const std::array<double, 8>& values,
1111 const unsigned char signs,
1112 const unsigned char signsMask,
1113 const unsigned char edgeGroup,
1114 const double iso)
1115{
1116 avg = Vec3d(0.0, 0.0, 0.0);
1117 int samples = 0;
1118
1119 if (sEdgeGroupTable[signs][1] == edgeGroup &&
1120 sEdgeGroupTable[signsMask][1] == 0) { // Edged: 0 - 1
1121 avg[0] += evalZeroCrossing(values[0], values[1], iso);
1122 ++samples;
1123 }
1124
1125 if (sEdgeGroupTable[signs][2] == edgeGroup &&
1126 sEdgeGroupTable[signsMask][2] == 0) { // Edged: 1 - 2
1127 avg[0] += 1.0;
1128 avg[2] += evalZeroCrossing(values[1], values[2], iso);
1129 ++samples;
1130 }
1131
1132 if (sEdgeGroupTable[signs][3] == edgeGroup &&
1133 sEdgeGroupTable[signsMask][3] == 0) { // Edged: 3 - 2
1134 avg[0] += evalZeroCrossing(values[3], values[2], iso);
1135 avg[2] += 1.0;
1136 ++samples;
1137 }
1138
1139 if (sEdgeGroupTable[signs][4] == edgeGroup &&
1140 sEdgeGroupTable[signsMask][4] == 0) { // Edged: 0 - 3
1141 avg[2] += evalZeroCrossing(values[0], values[3], iso);
1142 ++samples;
1143 }
1144
1145 if (sEdgeGroupTable[signs][5] == edgeGroup &&
1146 sEdgeGroupTable[signsMask][5] == 0) { // Edged: 4 - 5
1147 avg[0] += evalZeroCrossing(values[4], values[5], iso);
1148 avg[1] += 1.0;
1149 ++samples;
1150 }
1151
1152 if (sEdgeGroupTable[signs][6] == edgeGroup &&
1153 sEdgeGroupTable[signsMask][6] == 0) { // Edged: 5 - 6
1154 avg[0] += 1.0;
1155 avg[1] += 1.0;
1156 avg[2] += evalZeroCrossing(values[5], values[6], iso);
1157 ++samples;
1158 }
1159
1160 if (sEdgeGroupTable[signs][7] == edgeGroup &&
1161 sEdgeGroupTable[signsMask][7] == 0) { // Edged: 7 - 6
1162 avg[0] += evalZeroCrossing(values[7], values[6], iso);
1163 avg[1] += 1.0;
1164 avg[2] += 1.0;
1165 ++samples;
1166 }
1167
1168 if (sEdgeGroupTable[signs][8] == edgeGroup &&
1169 sEdgeGroupTable[signsMask][8] == 0) { // Edged: 4 - 7
1170 avg[1] += 1.0;
1171 avg[2] += evalZeroCrossing(values[4], values[7], iso);
1172 ++samples;
1173 }
1174
1175 if (sEdgeGroupTable[signs][9] == edgeGroup &&
1176 sEdgeGroupTable[signsMask][9] == 0) { // Edged: 0 - 4
1177 avg[1] += evalZeroCrossing(values[0], values[4], iso);
1178 ++samples;
1179 }
1180
1181 if (sEdgeGroupTable[signs][10] == edgeGroup &&
1182 sEdgeGroupTable[signsMask][10] == 0) { // Edged: 1 - 5
1183 avg[0] += 1.0;
1184 avg[1] += evalZeroCrossing(values[1], values[5], iso);
1185 ++samples;
1186 }
1187
1188 if (sEdgeGroupTable[signs][11] == edgeGroup &&
1189 sEdgeGroupTable[signsMask][11] == 0) { // Edged: 2 - 6
1190 avg[0] += 1.0;
1191 avg[1] += evalZeroCrossing(values[2], values[6], iso);
1192 avg[2] += 1.0;
1193 ++samples;
1194 }
1195
1196 if (sEdgeGroupTable[signs][12] == edgeGroup &&
1197 sEdgeGroupTable[signsMask][12] == 0) { // Edged: 3 - 7
1198 avg[1] += evalZeroCrossing(values[3], values[7], iso);
1199 avg[2] += 1.0;
1200 ++samples;
1201 }
1202
1203 if (samples > 1) {
1204 const double w = 1.0 / double(samples);
1205 avg *= w;
1206 }
1207
1208 return samples;
1209}
1210
1211
1212/// @brief Computes the average cell point for a given edge group, by computing
1213/// convex weights based on the distance from the sample point @c p.
1214inline Vec3d
1215computeWeightedPoint(const Vec3d& p,
1216 const std::array<double, 8>& values,
1217 const unsigned char signs,
1218 const unsigned char edgeGroup,
1219 const double iso)
1220{
1221 std::vector<Vec3d> samples;
1222 samples.reserve(8);
1223
1224 Vec3d avg(0.0, 0.0, 0.0);
1225
1226 if (sEdgeGroupTable[signs][1] == edgeGroup) { // Edged: 0 - 1
1227 avg[0] = evalZeroCrossing(values[0], values[1], iso);
1228 avg[1] = 0.0;
1229 avg[2] = 0.0;
1230
1231 samples.push_back(avg);
1232 }
1233
1234 if (sEdgeGroupTable[signs][2] == edgeGroup) { // Edged: 1 - 2
1235 avg[0] = 1.0;
1236 avg[1] = 0.0;
1237 avg[2] = evalZeroCrossing(values[1], values[2], iso);
1238
1239 samples.push_back(avg);
1240 }
1241
1242 if (sEdgeGroupTable[signs][3] == edgeGroup) { // Edged: 3 - 2
1243 avg[0] = evalZeroCrossing(values[3], values[2], iso);
1244 avg[1] = 0.0;
1245 avg[2] = 1.0;
1246
1247 samples.push_back(avg);
1248 }
1249
1250 if (sEdgeGroupTable[signs][4] == edgeGroup) { // Edged: 0 - 3
1251 avg[0] = 0.0;
1252 avg[1] = 0.0;
1253 avg[2] = evalZeroCrossing(values[0], values[3], iso);
1254
1255 samples.push_back(avg);
1256 }
1257
1258 if (sEdgeGroupTable[signs][5] == edgeGroup) { // Edged: 4 - 5
1259 avg[0] = evalZeroCrossing(values[4], values[5], iso);
1260 avg[1] = 1.0;
1261 avg[2] = 0.0;
1262
1263 samples.push_back(avg);
1264 }
1265
1266 if (sEdgeGroupTable[signs][6] == edgeGroup) { // Edged: 5 - 6
1267 avg[0] = 1.0;
1268 avg[1] = 1.0;
1269 avg[2] = evalZeroCrossing(values[5], values[6], iso);
1270
1271 samples.push_back(avg);
1272 }
1273
1274 if (sEdgeGroupTable[signs][7] == edgeGroup) { // Edged: 7 - 6
1275 avg[0] = evalZeroCrossing(values[7], values[6], iso);
1276 avg[1] = 1.0;
1277 avg[2] = 1.0;
1278
1279 samples.push_back(avg);
1280 }
1281
1282 if (sEdgeGroupTable[signs][8] == edgeGroup) { // Edged: 4 - 7
1283 avg[0] = 0.0;
1284 avg[1] = 1.0;
1285 avg[2] = evalZeroCrossing(values[4], values[7], iso);
1286
1287 samples.push_back(avg);
1288 }
1289
1290 if (sEdgeGroupTable[signs][9] == edgeGroup) { // Edged: 0 - 4
1291 avg[0] = 0.0;
1292 avg[1] = evalZeroCrossing(values[0], values[4], iso);
1293 avg[2] = 0.0;
1294
1295 samples.push_back(avg);
1296 }
1297
1298 if (sEdgeGroupTable[signs][10] == edgeGroup) { // Edged: 1 - 5
1299 avg[0] = 1.0;
1300 avg[1] = evalZeroCrossing(values[1], values[5], iso);
1301 avg[2] = 0.0;
1302
1303 samples.push_back(avg);
1304 }
1305
1306 if (sEdgeGroupTable[signs][11] == edgeGroup) { // Edged: 2 - 6
1307 avg[0] = 1.0;
1308 avg[1] = evalZeroCrossing(values[2], values[6], iso);
1309 avg[2] = 1.0;
1310
1311 samples.push_back(avg);
1312 }
1313
1314 if (sEdgeGroupTable[signs][12] == edgeGroup) { // Edged: 3 - 7
1315 avg[0] = 0.0;
1316 avg[1] = evalZeroCrossing(values[3], values[7], iso);
1317 avg[2] = 1.0;
1318
1319 samples.push_back(avg);
1320 }
1321
1322 OPENVDB_ASSERT(!samples.empty());
1323 if (samples.size() == 1) {
1324 return samples.front();
1325 }
1326
1327 std::vector<double> weights;
1328 weights.reserve(samples.size());
1329
1330 for (const Vec3d& s : samples) {
1331 weights.emplace_back((s-p).lengthSqr());
1332 }
1333
1334 double minWeight = weights.front();
1335 double maxWeight = weights.front();
1336
1337 for (size_t i = 1, I = weights.size(); i < I; ++i) {
1338 minWeight = std::min(minWeight, weights[i]);
1339 maxWeight = std::max(maxWeight, weights[i]);
1340 }
1341
1342 const double offset = maxWeight + minWeight * 0.1;
1343 for (size_t i = 0, I = weights.size(); i < I; ++i) {
1344 weights[i] = offset - weights[i];
1345 }
1346
1347 double weightSum = 0.0;
1348 for (size_t i = 0, I = weights.size(); i < I; ++i) {
1349 weightSum += weights[i];
1350 }
1351
1352 avg.setZero();
1353 for (size_t i = 0, I = samples.size(); i < I; ++i) {
1354 avg += samples[i] * (weights[i] / weightSum);
1355 }
1356
1357 return avg;
1358}
1359
1360
1361/// @brief Computes the average cell points defined by the sign configuration
1362/// @c signs and the given corner values @c values.
1363inline size_t
1364computeCellPoints(std::array<Vec3d, 4>& points,
1365 const std::array<double, 8>& values,
1366 const unsigned char signs,
1367 const double iso)
1368{
1369 size_t offset = 0;
1370 for (size_t n = 1, N = sEdgeGroupTable[signs][0] + 1; n < N; ++n, ++offset) {
1371 OPENVDB_ASSERT(offset < 4);
1372 points[offset] = computePoint(values, signs, uint8_t(n), iso);
1373 }
1374 return offset;
1375}
1376
1377
1378/// @brief Given a sign configuration @c lhsSigns and an edge group @c groupId,
1379/// finds the corresponding edge group in a different sign configuration
1380/// @c rhsSigns. Returns -1 if no match is found.
1381inline int
1382matchEdgeGroup(unsigned char groupId, unsigned char lhsSigns, unsigned char rhsSigns)
1383{
1384 int id = -1;
1385 for (size_t i = 1; i <= 12; ++i) {
1386 if (sEdgeGroupTable[lhsSigns][i] == groupId && sEdgeGroupTable[rhsSigns][i] != 0) {
1387 id = sEdgeGroupTable[rhsSigns][i];
1388 break;
1389 }
1390 }
1391 return id;
1392}
1393
1394
1395/// @brief Computes the average cell points defined by the sign configuration
1396/// @c signs and the given corner values @c values. Combines data from
1397/// two different level sets to eliminate seam lines when meshing
1398/// fractured segments.
1399inline size_t
1400computeCellPoints(std::array<Vec3d, 4>& points,
1401 std::array<bool, 4>& weightedPointMask,
1402 const std::array<double, 8>& lhsValues,
1403 const std::array<double, 8>& rhsValues,
1404 const unsigned char lhsSigns,
1405 const unsigned char rhsSigns,
1406 const double iso,
1407 const size_t pointIdx,
1408 const uint32_t * seamPointArray)
1409{
1410 size_t offset = 0;
1411 for (size_t n = 1, N = sEdgeGroupTable[lhsSigns][0] + 1; n < N; ++n, ++offset)
1412 {
1413 OPENVDB_ASSERT(offset < 4);
1414 const int id = matchEdgeGroup(uint8_t(n), lhsSigns, rhsSigns);
1415
1416 if (id != -1) {
1417
1418 const unsigned char e = uint8_t(id);
1419 const uint32_t quantizedPoint = seamPointArray[pointIdx + (id - 1)];
1420
1421 if ((quantizedPoint & MASK_DIRTY_BIT) && !(quantizedPoint & MASK_INVALID_BIT)) {
1422 const Vec3d p = unpackPoint(quantizedPoint);
1423 points[offset] = computeWeightedPoint(p, rhsValues, rhsSigns, e, iso);
1424 weightedPointMask[offset] = true;
1425 } else {
1426 points[offset] = computePoint(rhsValues, rhsSigns, e, iso);
1427 weightedPointMask[offset] = false;
1428 }
1429
1430 } else {
1431 points[offset] = computePoint(lhsValues, lhsSigns, uint8_t(n), iso);
1432 weightedPointMask[offset] = false;
1433 }
1434 }
1435 return offset;
1436}
1437
1438
1439template <typename InputTreeType>
1440struct ComputePoints
1441{
1442 using InputLeafNodeType = typename InputTreeType::LeafNodeType;
1443 using InputValueType = typename InputLeafNodeType::ValueType;
1444
1445 using Int16TreeType = typename InputTreeType::template ValueConverter<Int16>::Type;
1446 using Int16LeafNodeType = typename Int16TreeType::LeafNodeType;
1447
1448 using Index32TreeType = typename InputTreeType::template ValueConverter<Index32>::Type;
1449 using Index32LeafNodeType = typename Index32TreeType::LeafNodeType;
1450
1451 ComputePoints(Vec3s * pointArray,
1452 const InputTreeType& inputTree,
1453 const std::vector<Index32LeafNodeType*>& pointIndexLeafNodes,
1454 const std::vector<Int16LeafNodeType*>& signFlagsLeafNodes,
1455 const std::unique_ptr<Index32[]>& leafNodeOffsets,
1456 const math::Transform& xform,
1457 const double iso);
1458
1459 void setRefData(const InputTreeType& refInputTree,
1460 const Index32TreeType& refPointIndexTree,
1461 const Int16TreeType& refSignFlagsTree,
1462 const uint32_t * quantizedSeamLinePoints,
1463 uint8_t * seamLinePointsFlags);
1464
1465 void operator()(const tbb::blocked_range<size_t>&) const;
1466
1467private:
1468 Vec3s * const mPoints;
1469 InputTreeType const * const mInputTree;
1470 Index32LeafNodeType * const * const mPointIndexNodes;
1471 Int16LeafNodeType const * const * const mSignFlagsNodes;
1472 Index32 const * const mNodeOffsets;
1473 math::Transform const mTransform;
1474 double const mIsovalue;
1475 // reference meshing data
1476 InputTreeType const * mRefInputTree;
1477 Index32TreeType const * mRefPointIndexTree;
1478 Int16TreeType const * mRefSignFlagsTree;
1479 uint32_t const * mQuantizedSeamLinePoints;
1480 uint8_t * mSeamLinePointsFlags;
1481}; // struct ComputePoints
1482
1483
1484template <typename InputTreeType>
1485ComputePoints<InputTreeType>::ComputePoints(
1486 Vec3s * pointArray,
1487 const InputTreeType& inputTree,
1488 const std::vector<Index32LeafNodeType*>& pointIndexLeafNodes,
1489 const std::vector<Int16LeafNodeType*>& signFlagsLeafNodes,
1490 const std::unique_ptr<Index32[]>& leafNodeOffsets,
1491 const math::Transform& xform,
1492 const double iso)
1493 : mPoints(pointArray)
1494 , mInputTree(&inputTree)
1495 , mPointIndexNodes(pointIndexLeafNodes.data())
1496 , mSignFlagsNodes(signFlagsLeafNodes.data())
1497 , mNodeOffsets(leafNodeOffsets.get())
1498 , mTransform(xform)
1499 , mIsovalue(iso)
1500 , mRefInputTree(nullptr)
1501 , mRefPointIndexTree(nullptr)
1502 , mRefSignFlagsTree(nullptr)
1503 , mQuantizedSeamLinePoints(nullptr)
1504 , mSeamLinePointsFlags(nullptr)
1505{
1506}
1507
1508template <typename InputTreeType>
1509void
1510ComputePoints<InputTreeType>::setRefData(
1511 const InputTreeType& refInputTree,
1512 const Index32TreeType& refPointIndexTree,
1513 const Int16TreeType& refSignFlagsTree,
1514 const uint32_t * quantizedSeamLinePoints,
1515 uint8_t * seamLinePointsFlags)
1516{
1517 mRefInputTree = &refInputTree;
1518 mRefPointIndexTree = &refPointIndexTree;
1519 mRefSignFlagsTree = &refSignFlagsTree;
1520 mQuantizedSeamLinePoints = quantizedSeamLinePoints;
1521 mSeamLinePointsFlags = seamLinePointsFlags;
1522}
1523
1524template <typename InputTreeType>
1525void
1526ComputePoints<InputTreeType>::operator()(const tbb::blocked_range<size_t>& range) const
1527{
1528 using InputTreeAccessor = tree::ValueAccessor<const InputTreeType>;
1529 using Index32TreeAccessor = tree::ValueAccessor<const Index32TreeType>;
1530 using Int16TreeAccessor = tree::ValueAccessor<const Int16TreeType>;
1531
1532 using IndexType = typename Index32TreeType::ValueType;
1533
1534 using IndexArray = std::vector<Index>;
1535 using IndexArrayMap = std::map<IndexType, IndexArray>;
1536
1537 InputTreeAccessor inputAcc(*mInputTree);
1538
1539 Vec3d xyz;
1540 Coord ijk;
1541 std::array<Vec3d, 4> points;
1542 std::array<bool, 4> weightedPointMask;
1543 std::array<double, 8> values, refValues;
1544 const double iso = mIsovalue;
1545
1546 // reference data accessors
1547
1548 std::unique_ptr<InputTreeAccessor> refInputAcc;
1549 std::unique_ptr<Index32TreeAccessor> refPointIndexAcc;
1550 std::unique_ptr<Int16TreeAccessor> refSignFlagsAcc;
1551
1552 const bool hasReferenceData = mRefInputTree && mRefPointIndexTree && mRefSignFlagsTree;
1553
1554 if (hasReferenceData) {
1555 refInputAcc.reset(new InputTreeAccessor(*mRefInputTree));
1556 refPointIndexAcc.reset(new Index32TreeAccessor(*mRefPointIndexTree));
1557 refSignFlagsAcc.reset(new Int16TreeAccessor(*mRefSignFlagsTree));
1558 }
1559
1560 for (size_t n = range.begin(), N = range.end(); n != N; ++n)
1561 {
1562 Index32LeafNodeType& pointIndexNode = *mPointIndexNodes[n];
1563 const Coord& origin = pointIndexNode.origin();
1564
1565 const Int16LeafNodeType& signFlagsNode = *mSignFlagsNodes[n];
1566 const InputLeafNodeType * inputNode = inputAcc.probeConstLeaf(origin);
1567
1568 // get reference data
1569 const InputLeafNodeType * refInputNode = nullptr;
1570 const Index32LeafNodeType * refPointIndexNode = nullptr;
1571 const Int16LeafNodeType * refSignFlagsNode = nullptr;
1572
1573 if (hasReferenceData) {
1574 refInputNode = refInputAcc->probeConstLeaf(origin);
1575 refPointIndexNode = refPointIndexAcc->probeConstLeaf(origin);
1576 refSignFlagsNode = refSignFlagsAcc->probeConstLeaf(origin);
1577 }
1578
1579 IndexType pointOffset = IndexType(mNodeOffsets[n]);
1580 IndexArrayMap regions;
1581
1582 auto* const pidxData = pointIndexNode.buffer().data();
1583 const auto* const sfData = signFlagsNode.buffer().data();
1584
1585 for (auto it = pointIndexNode.beginValueOn(); it; ++it)
1586 {
1587 const Index offset = it.pos();
1588 IndexType& id = pidxData[offset];
1589
1590 if (id != 0) {
1591 if (id != IndexType(util::INVALID_IDX)) {
1592 regions[id].push_back(offset);
1593 }
1594 continue;
1595 }
1596
1597 id = pointOffset;
1598
1599 const Int16 flags = sfData[offset];
1600 const uint8_t signs = uint8_t(SIGNS & flags);
1601 uint8_t refSigns = 0;
1602
1603 if ((flags & SEAM) && refPointIndexNode && refSignFlagsNode) {
1604 if (refSignFlagsNode->isValueOn(offset)) {
1605 refSigns = uint8_t(SIGNS & refSignFlagsNode->getValue(offset));
1606 }
1607 }
1608
1609 ijk = Index32LeafNodeType::offsetToLocalCoord(offset);
1610
1611 const bool inclusiveCell = inputNode && isInternalLeafCoord<InputLeafNodeType>(ijk);
1612
1613 ijk += origin;
1614
1615 if (inclusiveCell) getCellVertexValues(*inputNode, offset, values);
1616 else getCellVertexValues(inputAcc, ijk, values);
1617
1618 size_t count, weightcount;
1619
1620 if (refSigns == 0) {
1621 count = computeCellPoints(points, values, signs, iso);
1622 weightcount = 0;
1623 } else {
1624 if (inclusiveCell && refInputNode) {
1625 getCellVertexValues(*refInputNode, offset, refValues);
1626 } else {
1627 getCellVertexValues(*refInputAcc, ijk, refValues);
1628 }
1629 count = computeCellPoints(points, weightedPointMask, values, refValues, signs, refSigns,
1630 iso, refPointIndexNode->getValue(offset), mQuantizedSeamLinePoints);
1631 weightcount = count;
1632 }
1633
1634 xyz = ijk.asVec3d();
1635
1636 for (size_t i = 0; i < count; ++i) {
1637
1638 Vec3d& point = points[i];
1639
1640 // Checks for both NaN and inf vertex positions, i.e. any value that is not finite.
1641 if (!std::isfinite(point[0]) ||
1642 !std::isfinite(point[1]) ||
1643 !std::isfinite(point[2]))
1644 {
1646 "VolumeToMesh encountered NaNs or infs in the input VDB!"
1647 " Hint: Check the input and consider using the \"Diagnostics\" tool "
1648 "to detect and resolve the NaNs.");
1649 }
1650
1651 point += xyz;
1652 point = mTransform.indexToWorld(point);
1653
1654 Vec3s& pos = mPoints[pointOffset];
1655 pos[0] = float(point[0]);
1656 pos[1] = float(point[1]);
1657 pos[2] = float(point[2]);
1658
1659 if (mSeamLinePointsFlags && weightcount && weightedPointMask[i]) {
1660 mSeamLinePointsFlags[pointOffset] = uint8_t(1);
1661 }
1662
1663 ++pointOffset;
1664 }
1665 }
1666
1667 // generate collapsed region points
1668 for (auto it = regions.begin(); it != regions.end(); ++it)
1669 {
1670 Vec3d avg(0.0);
1671
1672 const IndexArray& voxels = it->second;
1673 for (size_t i = 0, I = voxels.size(); i < I; ++i) {
1674
1675 const Index offset = voxels[i];
1676 ijk = Index32LeafNodeType::offsetToLocalCoord(offset);
1677
1678 const bool inclusiveCell = inputNode && isInternalLeafCoord<InputLeafNodeType>(ijk);
1679
1680 ijk += origin;
1681
1682 pidxData[offset] = pointOffset;
1683
1684 const uint8_t signs = uint8_t(SIGNS & sfData[offset]);
1685
1686 if (inclusiveCell) getCellVertexValues(*inputNode, offset, values);
1687 else getCellVertexValues(inputAcc, ijk, values);
1688
1689 computeCellPoints(points, values, signs, iso);
1690
1691 avg[0] += double(ijk[0]) + points[0][0];
1692 avg[1] += double(ijk[1]) + points[0][1];
1693 avg[2] += double(ijk[2]) + points[0][2];
1694 }
1695
1696 if (voxels.size() > 1) {
1697 const double w = 1.0 / double(voxels.size());
1698 avg *= w;
1699 }
1700
1701 avg = mTransform.indexToWorld(avg);
1702
1703 Vec3s& pos = mPoints[pointOffset];
1704 pos[0] = float(avg[0]);
1705 pos[1] = float(avg[1]);
1706 pos[2] = float(avg[2]);
1707
1708 ++pointOffset;
1709 }
1710 }
1711} // ComputePoints::operator()
1712
1713
1714////////////////////////////////////////
1715
1716
1717template <typename InputTreeType>
1718struct SeamLineWeights
1719{
1720 using InputLeafNodeType = typename InputTreeType::LeafNodeType;
1721 using InputValueType = typename InputLeafNodeType::ValueType;
1722
1723 using Int16TreeType = typename InputTreeType::template ValueConverter<Int16>::Type;
1724 using Int16LeafNodeType = typename Int16TreeType::LeafNodeType;
1725
1726 using Index32TreeType = typename InputTreeType::template ValueConverter<Index32>::Type;
1727 using Index32LeafNodeType = typename Index32TreeType::LeafNodeType;
1728
1729 SeamLineWeights(const std::vector<Int16LeafNodeType*>& signFlagsLeafNodes,
1730 const InputTreeType& inputTree,
1731 const Index32TreeType& refPointIndexTree,
1732 const Int16TreeType& refSignFlagsTree,
1733 uint32_t * quantizedPoints,
1734 InputValueType iso)
1735 : mSignFlagsNodes(signFlagsLeafNodes.data())
1736 , mInputTree(&inputTree)
1737 , mRefPointIndexTree(&refPointIndexTree)
1738 , mRefSignFlagsTree(&refSignFlagsTree)
1739 , mQuantizedPoints(quantizedPoints)
1740 , mIsovalue(iso)
1741 {
1742 }
1743
1744 void operator()(const tbb::blocked_range<size_t>& range) const
1745 {
1746 tree::ValueAccessor<const InputTreeType> inputTreeAcc(*mInputTree);
1747 tree::ValueAccessor<const Index32TreeType> pointIndexTreeAcc(*mRefPointIndexTree);
1748 tree::ValueAccessor<const Int16TreeType> signFlagsTreeAcc(*mRefSignFlagsTree);
1749
1750 std::array<double, 8> values;
1751 const double iso = double(mIsovalue);
1752 Coord ijk;
1753 Vec3d pos;
1754
1755 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
1756
1757 const Int16LeafNodeType& signFlagsNode = *mSignFlagsNodes[n];
1758 const Coord& origin = signFlagsNode.origin();
1759
1760 const Int16LeafNodeType * refSignNode = signFlagsTreeAcc.probeConstLeaf(origin);
1761 if (!refSignNode) continue;
1762
1763 const Index32LeafNodeType* refPointIndexNode =
1764 pointIndexTreeAcc.probeConstLeaf(origin);
1765 if (!refPointIndexNode) continue;
1766
1767 const InputLeafNodeType* inputNode = inputTreeAcc.probeConstLeaf(origin);
1768
1769 const auto* const sfData = signFlagsNode.buffer().data();
1770 const auto* const rfIdxData = refPointIndexNode->buffer().data();
1771 const auto* const rsData = refSignNode->buffer().data();
1772
1773 for (auto it = signFlagsNode.cbeginValueOn(); it; ++it)
1774 {
1775 const Index offset = it.pos();
1776 const Int16 flags = sfData[offset];
1777
1778 ijk = Index32LeafNodeType::offsetToLocalCoord(offset);
1779
1780 const bool inclusiveCell = inputNode && isInternalLeafCoord<InputLeafNodeType>(ijk);
1781
1782 ijk += origin;
1783
1784 if ((flags & SEAM) && refSignNode->isValueOn(offset)) {
1785
1786 const uint8_t lhsSigns = uint8_t(SIGNS & flags);
1787 const uint8_t rhsSigns = uint8_t(SIGNS & rsData[offset]);
1788
1789 if (inclusiveCell) getCellVertexValues(*inputNode, offset, values);
1790 else getCellVertexValues(inputTreeAcc, ijk, values);
1791
1792 for (unsigned i = 1, I = sEdgeGroupTable[lhsSigns][0] + 1; i < I; ++i) {
1793
1794 const int id = matchEdgeGroup(uint8_t(i), lhsSigns, rhsSigns);
1795
1796 if (id != -1) {
1797
1798 uint32_t& data = mQuantizedPoints[rfIdxData[offset] + (id - 1)];
1799
1800 if (!(data & MASK_DIRTY_BIT)) {
1801
1802 const int samples = computeMaskedPoint(
1803 pos, values, lhsSigns, rhsSigns, uint8_t(i), iso);
1804
1805 if (samples > 0) data = packPoint(pos);
1806 else data = MASK_INVALID_BIT;
1807
1808 data |= MASK_DIRTY_BIT;
1809 }
1810 }
1811 } // end point group loop
1812 }
1813 } // end value on loop
1814 } // end leaf node loop
1815 }
1816
1817private:
1818 Int16LeafNodeType const * const * const mSignFlagsNodes;
1819 InputTreeType const * const mInputTree;
1820 Index32TreeType const * const mRefPointIndexTree;
1821 Int16TreeType const * const mRefSignFlagsTree;
1822 uint32_t * const mQuantizedPoints;
1823 InputValueType const mIsovalue;
1824}; // struct SeamLineWeights
1825
1826
1827template <typename TreeType>
1828struct SetSeamLineFlags
1829{
1830 using LeafNodeType = typename TreeType::LeafNodeType;
1831
1832 SetSeamLineFlags(const std::vector<LeafNodeType*>& signFlagsLeafNodes,
1833 const TreeType& refSignFlagsTree)
1834 : mSignFlagsNodes(signFlagsLeafNodes.data())
1835 , mRefSignFlagsTree(&refSignFlagsTree)
1836 {
1837 }
1838
1839 void operator()(const tbb::blocked_range<size_t>& range) const
1840 {
1841 tree::ValueAccessor<const TreeType> refSignFlagsTreeAcc(*mRefSignFlagsTree);
1842
1843 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
1844
1845 LeafNodeType& signFlagsNode = *mSignFlagsNodes[n];
1846 const Coord& origin = signFlagsNode.origin();
1847
1848 const LeafNodeType* refSignNode = refSignFlagsTreeAcc.probeConstLeaf(origin);
1849 if (!refSignNode) continue;
1850
1851 const auto* const rsData = refSignNode->buffer().data();
1852 auto* const sfData = signFlagsNode.buffer().data();
1853
1854 for (auto it = signFlagsNode.cbeginValueOn(); it; ++it) {
1855 const Index offset = it.pos();
1856
1857 const uint8_t rhsSigns = uint8_t(rsData[offset] & SIGNS);
1858
1859 if (sEdgeGroupTable[rhsSigns][0] > 0) {
1860
1861 typename LeafNodeType::ValueType& value = sfData[offset];
1862 const uint8_t lhsSigns = uint8_t(value & SIGNS);
1863
1864 if (rhsSigns != lhsSigns) {
1865 value |= SEAM;
1866 }
1867 }
1868
1869 } // end value on loop
1870
1871 } // end leaf node loop
1872 }
1873
1874private:
1875 LeafNodeType * const * const mSignFlagsNodes;
1876 TreeType const * const mRefSignFlagsTree;
1877}; // struct SetSeamLineFlags
1878
1879
1880template <typename BoolTreeType, typename SignDataType>
1881struct TransferSeamLineFlags
1882{
1883 using BoolLeafNodeType = typename BoolTreeType::LeafNodeType;
1884
1885 using SignDataTreeType = typename BoolTreeType::template ValueConverter<SignDataType>::Type;
1886 using SignDataLeafNodeType = typename SignDataTreeType::LeafNodeType;
1887
1888 TransferSeamLineFlags(const std::vector<SignDataLeafNodeType*>& signFlagsLeafNodes,
1889 const BoolTreeType& maskTree)
1890 : mSignFlagsNodes(signFlagsLeafNodes.data())
1891 , mMaskTree(&maskTree)
1892 {
1893 }
1894
1895 void operator()(const tbb::blocked_range<size_t>& range) const
1896 {
1897 tree::ValueAccessor<const BoolTreeType> maskAcc(*mMaskTree);
1898
1899 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
1900
1901 SignDataLeafNodeType& signFlagsNode = *mSignFlagsNodes[n];
1902 const Coord& origin = signFlagsNode.origin();
1903
1904 const BoolLeafNodeType * maskNode = maskAcc.probeConstLeaf(origin);
1905 if (!maskNode) continue;
1906
1907 auto* const sfData = signFlagsNode.buffer().data();
1908
1909 for (auto it = signFlagsNode.cbeginValueOn(); it; ++it) {
1910 const Index offset = it.pos();
1911
1912 if (maskNode->isValueOn(offset)) {
1913 sfData[offset] |= SEAM;
1914 }
1915 } // end value on loop
1916 } // end leaf node loop
1917 }
1918
1919private:
1920 SignDataLeafNodeType * const * const mSignFlagsNodes;
1921 BoolTreeType const * const mMaskTree;
1922}; // struct TransferSeamLineFlags
1923
1924
1925template <typename TreeType>
1926struct MaskSeamLineVoxels
1927{
1928 using LeafNodeType = typename TreeType::LeafNodeType;
1929 using BoolTreeType = typename TreeType::template ValueConverter<bool>::Type;
1930
1931 MaskSeamLineVoxels(const std::vector<LeafNodeType*>& signFlagsLeafNodes,
1932 const TreeType& signFlagsTree,
1933 BoolTreeType& mask)
1934 : mSignFlagsNodes(signFlagsLeafNodes.data())
1935 , mSignFlagsTree(&signFlagsTree)
1936 , mTempMask(false)
1937 , mMask(&mask)
1938 {
1939 }
1940
1941 MaskSeamLineVoxels(MaskSeamLineVoxels& rhs, tbb::split)
1942 : mSignFlagsNodes(rhs.mSignFlagsNodes)
1943 , mSignFlagsTree(rhs.mSignFlagsTree)
1944 , mTempMask(false)
1945 , mMask(&mTempMask)
1946 {
1947 }
1948
1949 void join(MaskSeamLineVoxels& rhs) { mMask->merge(*rhs.mMask); }
1950
1951 void operator()(const tbb::blocked_range<size_t>& range)
1952 {
1953 using ValueOnCIter = typename LeafNodeType::ValueOnCIter;
1954 using ValueType = typename LeafNodeType::ValueType;
1955
1956 tree::ValueAccessor<const TreeType> signFlagsAcc(*mSignFlagsTree);
1957 tree::ValueAccessor<BoolTreeType> maskAcc(*mMask);
1958 Coord ijk;
1959
1960 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
1961
1962 LeafNodeType& signFlagsNode = *mSignFlagsNodes[n];
1963 auto* const sfData = signFlagsNode.buffer().data();
1964
1965 for (ValueOnCIter it = signFlagsNode.cbeginValueOn(); it; ++it) {
1966
1967 const ValueType flags = sfData[it.pos()];
1968
1969 if (!(flags & SEAM) && (flags & EDGES)) {
1970
1971 ijk = it.getCoord();
1972
1973 bool isSeamLineVoxel = false;
1974
1975 if (flags & XEDGE) {
1976 ijk[1] -= 1;
1977 isSeamLineVoxel = (signFlagsAcc.getValue(ijk) & SEAM);
1978 ijk[2] -= 1;
1979 isSeamLineVoxel = isSeamLineVoxel || (signFlagsAcc.getValue(ijk) & SEAM);
1980 ijk[1] += 1;
1981 isSeamLineVoxel = isSeamLineVoxel || (signFlagsAcc.getValue(ijk) & SEAM);
1982 ijk[2] += 1;
1983 }
1984
1985 if (!isSeamLineVoxel && flags & YEDGE) {
1986 ijk[2] -= 1;
1987 isSeamLineVoxel = isSeamLineVoxel || (signFlagsAcc.getValue(ijk) & SEAM);
1988 ijk[0] -= 1;
1989 isSeamLineVoxel = isSeamLineVoxel || (signFlagsAcc.getValue(ijk) & SEAM);
1990 ijk[2] += 1;
1991 isSeamLineVoxel = isSeamLineVoxel || (signFlagsAcc.getValue(ijk) & SEAM);
1992 ijk[0] += 1;
1993 }
1994
1995 if (!isSeamLineVoxel && flags & ZEDGE) {
1996 ijk[1] -= 1;
1997 isSeamLineVoxel = isSeamLineVoxel || (signFlagsAcc.getValue(ijk) & SEAM);
1998 ijk[0] -= 1;
1999 isSeamLineVoxel = isSeamLineVoxel || (signFlagsAcc.getValue(ijk) & SEAM);
2000 ijk[1] += 1;
2001 isSeamLineVoxel = isSeamLineVoxel || (signFlagsAcc.getValue(ijk) & SEAM);
2002 ijk[0] += 1;
2003 }
2004
2005 if (isSeamLineVoxel) {
2006 maskAcc.setValue(it.getCoord(), true);
2007 }
2008 }
2009 } // end value on loop
2010
2011 } // end leaf node loop
2012 }
2013
2014private:
2015 LeafNodeType * const * const mSignFlagsNodes;
2016 TreeType const * const mSignFlagsTree;
2017 BoolTreeType mTempMask;
2018 BoolTreeType * const mMask;
2019}; // struct MaskSeamLineVoxels
2020
2021
2022template<typename SignDataTreeType>
2023inline void
2024markSeamLineData(SignDataTreeType& signFlagsTree, const SignDataTreeType& refSignFlagsTree)
2025{
2026 using SignDataType = typename SignDataTreeType::ValueType;
2027 using SignDataLeafNodeType = typename SignDataTreeType::LeafNodeType;
2028 using BoolTreeType = typename SignDataTreeType::template ValueConverter<bool>::Type;
2029
2030 std::vector<SignDataLeafNodeType*> signFlagsLeafNodes;
2031 signFlagsTree.getNodes(signFlagsLeafNodes);
2032
2033 const tbb::blocked_range<size_t> nodeRange(0, signFlagsLeafNodes.size());
2034
2035 tbb::parallel_for(nodeRange,
2036 SetSeamLineFlags<SignDataTreeType>(signFlagsLeafNodes, refSignFlagsTree));
2037
2038 BoolTreeType seamLineMaskTree(false);
2039
2040 MaskSeamLineVoxels<SignDataTreeType>
2041 maskSeamLine(signFlagsLeafNodes, signFlagsTree, seamLineMaskTree);
2042
2043 tbb::parallel_reduce(nodeRange, maskSeamLine);
2044
2045 tbb::parallel_for(nodeRange,
2046 TransferSeamLineFlags<BoolTreeType, SignDataType>(signFlagsLeafNodes, seamLineMaskTree));
2047}
2048
2049
2050////////////////////////////////////////
2051
2052
2053template <typename InputGridType>
2054struct MergeVoxelRegions
2055{
2056 using InputTreeType = typename InputGridType::TreeType;
2057 using InputLeafNodeType = typename InputTreeType::LeafNodeType;
2058 using InputValueType = typename InputLeafNodeType::ValueType;
2059
2060 using FloatTreeType = typename InputTreeType::template ValueConverter<float>::Type;
2061 using FloatLeafNodeType = typename FloatTreeType::LeafNodeType;
2062 using FloatGridType = Grid<FloatTreeType>;
2063
2064 using Int16TreeType = typename InputTreeType::template ValueConverter<Int16>::Type;
2065 using Int16LeafNodeType = typename Int16TreeType::LeafNodeType;
2066
2067 using Index32TreeType = typename InputTreeType::template ValueConverter<Index32>::Type;
2068 using Index32LeafNodeType = typename Index32TreeType::LeafNodeType;
2069
2070 using BoolTreeType = typename InputTreeType::template ValueConverter<bool>::Type;
2071 using BoolLeafNodeType = typename BoolTreeType::LeafNodeType;
2072
2073 using MaskTreeType = typename InputTreeType::template ValueConverter<ValueMask>::Type;
2074 using MaskLeafNodeType = typename MaskTreeType::LeafNodeType;
2075
2076 MergeVoxelRegions(const InputGridType& inputGrid,
2077 const Index32TreeType& pointIndexTree,
2078 const std::vector<Index32LeafNodeType*>& pointIndexLeafNodes,
2079 const std::vector<Int16LeafNodeType*>& signFlagsLeafNodes,
2080 InputValueType iso,
2081 float adaptivity,
2082 bool invertSurfaceOrientation);
2083
2084 void setSpatialAdaptivity(const FloatGridType& grid)
2085 {
2086 mSpatialAdaptivityTree = &grid.tree();
2087 mSpatialAdaptivityTransform = &grid.transform();
2088 }
2089
2090 void setAdaptivityMask(const BoolTreeType& mask)
2091 {
2092 mMaskTree = &mask;
2093 }
2094
2095 void setRefSignFlagsData(const Int16TreeType& signFlagsData, float internalAdaptivity)
2096 {
2097 mRefSignFlagsTree = &signFlagsData;
2098 mInternalAdaptivity = internalAdaptivity;
2099 }
2100
2101 void operator()(const tbb::blocked_range<size_t>&) const;
2102
2103private:
2104 InputTreeType const * const mInputTree;
2105 math::Transform const * const mInputTransform;
2106
2107 Index32TreeType const * const mPointIndexTree;
2108 Index32LeafNodeType * const * const mPointIndexNodes;
2109 Int16LeafNodeType const * const * const mSignFlagsNodes;
2110
2111 InputValueType mIsovalue;
2112 float mSurfaceAdaptivity, mInternalAdaptivity;
2113 bool mInvertSurfaceOrientation;
2114
2115 FloatTreeType const * mSpatialAdaptivityTree;
2116 BoolTreeType const * mMaskTree;
2117 Int16TreeType const * mRefSignFlagsTree;
2118 math::Transform const * mSpatialAdaptivityTransform;
2119}; // struct MergeVoxelRegions
2120
2121
2122template <typename InputGridType>
2123MergeVoxelRegions<InputGridType>::MergeVoxelRegions(
2124 const InputGridType& inputGrid,
2125 const Index32TreeType& pointIndexTree,
2126 const std::vector<Index32LeafNodeType*>& pointIndexLeafNodes,
2127 const std::vector<Int16LeafNodeType*>& signFlagsLeafNodes,
2128 InputValueType iso,
2129 float adaptivity,
2130 bool invertSurfaceOrientation)
2131 : mInputTree(&inputGrid.tree())
2132 , mInputTransform(&inputGrid.transform())
2133 , mPointIndexTree(&pointIndexTree)
2134 , mPointIndexNodes(pointIndexLeafNodes.data())
2135 , mSignFlagsNodes(signFlagsLeafNodes.data())
2136 , mIsovalue(iso)
2137 , mSurfaceAdaptivity(adaptivity)
2138 , mInternalAdaptivity(adaptivity)
2139 , mInvertSurfaceOrientation(invertSurfaceOrientation)
2140 , mSpatialAdaptivityTree(nullptr)
2141 , mMaskTree(nullptr)
2142 , mRefSignFlagsTree(nullptr)
2143 , mSpatialAdaptivityTransform(nullptr)
2144{
2145}
2146
2147
2148template <typename InputGridType>
2149void
2150MergeVoxelRegions<InputGridType>::operator()(const tbb::blocked_range<size_t>& range) const
2151{
2152 using Vec3sType = math::Vec3<float>;
2153 using Vec3sLeafNodeType = typename InputLeafNodeType::template ValueConverter<Vec3sType>::Type;
2154
2155 using InputTreeAccessor = tree::ValueAccessor<const InputTreeType>;
2156 using FloatTreeAccessor = tree::ValueAccessor<const FloatTreeType>;
2157 using Index32TreeAccessor = tree::ValueAccessor<const Index32TreeType>;
2158 using Int16TreeAccessor = tree::ValueAccessor<const Int16TreeType>;
2159 using BoolTreeAccessor = tree::ValueAccessor<const BoolTreeType>;
2160
2161 std::unique_ptr<FloatTreeAccessor> spatialAdaptivityAcc;
2162 if (mSpatialAdaptivityTree && mSpatialAdaptivityTransform) {
2163 spatialAdaptivityAcc.reset(new FloatTreeAccessor(*mSpatialAdaptivityTree));
2164 }
2165
2166 std::unique_ptr<BoolTreeAccessor> maskAcc;
2167 if (mMaskTree) {
2168 maskAcc.reset(new BoolTreeAccessor(*mMaskTree));
2169 }
2170
2171 std::unique_ptr<Int16TreeAccessor> refSignFlagsAcc;
2172 if (mRefSignFlagsTree) {
2173 refSignFlagsAcc.reset(new Int16TreeAccessor(*mRefSignFlagsTree));
2174 }
2175
2176 InputTreeAccessor inputAcc(*mInputTree);
2177 Index32TreeAccessor pointIndexAcc(*mPointIndexTree);
2178
2179 MaskLeafNodeType mask;
2180
2181 const bool invertGradientDir = mInvertSurfaceOrientation || isBoolValue<InputValueType>();
2182 std::unique_ptr<Vec3sLeafNodeType> gradientNode;
2183
2184 Coord ijk, end;
2185 const int LeafDim = InputLeafNodeType::DIM;
2186
2187 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
2188
2189 mask.setValuesOff();
2190
2191 const Int16LeafNodeType& signFlagsNode = *mSignFlagsNodes[n];
2192 Index32LeafNodeType& pointIndexNode = *mPointIndexNodes[n];
2193
2194 const Coord& origin = pointIndexNode.origin();
2195 end = origin.offsetBy(LeafDim);
2196
2197 // Mask off seam line adjacent voxels
2198 if (maskAcc) {
2199 const BoolLeafNodeType* maskLeaf = maskAcc->probeConstLeaf(origin);
2200 if (maskLeaf != nullptr) {
2201 for (auto it = maskLeaf->cbeginValueOn(); it; ++it)
2202 {
2203 mask.setActiveState(it.getCoord() & ~1u, true);
2204 }
2205 }
2206 }
2207
2208 float adaptivity = (refSignFlagsAcc && !refSignFlagsAcc->probeConstLeaf(origin)) ?
2209 mInternalAdaptivity : mSurfaceAdaptivity;
2210
2211 bool useGradients = adaptivity < 1.0f;
2212
2213 // Set region adaptivity
2214 FloatLeafNodeType adaptivityLeaf(origin, adaptivity);
2215
2216 if (spatialAdaptivityAcc) {
2217 useGradients = false;
2218 for (Index offset = 0; offset < FloatLeafNodeType::NUM_VALUES; ++offset) {
2219 ijk = adaptivityLeaf.offsetToGlobalCoord(offset);
2220 ijk = mSpatialAdaptivityTransform->worldToIndexCellCentered(
2221 mInputTransform->indexToWorld(ijk));
2222 float weight = spatialAdaptivityAcc->getValue(ijk);
2223 float adaptivityValue = weight * adaptivity;
2224 if (adaptivityValue < 1.0f) useGradients = true;
2225 adaptivityLeaf.setValueOnly(offset, adaptivityValue);
2226 }
2227 }
2228
2229 // Mask off ambiguous voxels
2230 for (auto it = signFlagsNode.cbeginValueOn(); it; ++it) {
2231 const Int16 flags = it.getValue();
2232 const unsigned char signs = static_cast<unsigned char>(SIGNS & int(flags));
2233
2234 if ((flags & SEAM) || !sAdaptable[signs] || sEdgeGroupTable[signs][0] > 1) {
2235
2236 mask.setActiveState(it.getCoord() & ~1u, true);
2237
2238 } else if (flags & EDGES) {
2239
2240 bool maskRegion = false;
2241
2242 ijk = it.getCoord();
2243 if (!pointIndexAcc.isValueOn(ijk)) maskRegion = true;
2244
2245 if (!maskRegion && flags & XEDGE) {
2246 ijk[1] -= 1;
2247 if (!maskRegion && !pointIndexAcc.isValueOn(ijk)) maskRegion = true;
2248 ijk[2] -= 1;
2249 if (!maskRegion && !pointIndexAcc.isValueOn(ijk)) maskRegion = true;
2250 ijk[1] += 1;
2251 if (!maskRegion && !pointIndexAcc.isValueOn(ijk)) maskRegion = true;
2252 ijk[2] += 1;
2253 }
2254
2255 if (!maskRegion && flags & YEDGE) {
2256 ijk[2] -= 1;
2257 if (!maskRegion && !pointIndexAcc.isValueOn(ijk)) maskRegion = true;
2258 ijk[0] -= 1;
2259 if (!maskRegion && !pointIndexAcc.isValueOn(ijk)) maskRegion = true;
2260 ijk[2] += 1;
2261 if (!maskRegion && !pointIndexAcc.isValueOn(ijk)) maskRegion = true;
2262 ijk[0] += 1;
2263 }
2264
2265 if (!maskRegion && flags & ZEDGE) {
2266 ijk[1] -= 1;
2267 if (!maskRegion && !pointIndexAcc.isValueOn(ijk)) maskRegion = true;
2268 ijk[0] -= 1;
2269 if (!maskRegion && !pointIndexAcc.isValueOn(ijk)) maskRegion = true;
2270 ijk[1] += 1;
2271 if (!maskRegion && !pointIndexAcc.isValueOn(ijk)) maskRegion = true;
2272 ijk[0] += 1;
2273 }
2274
2275 if (maskRegion) {
2276 mask.setActiveState(it.getCoord() & ~1u, true);
2277 }
2278 }
2279 }
2280
2281 // Mask off topologically ambiguous 2x2x2 voxel sub-blocks
2282 int dim = 2;
2283 for (ijk[0] = origin[0]; ijk[0] < end[0]; ijk[0] += dim) {
2284 for (ijk[1] = origin[1]; ijk[1] < end[1]; ijk[1] += dim) {
2285 for (ijk[2] = origin[2]; ijk[2] < end[2]; ijk[2] += dim) {
2286 if (!mask.isValueOn(ijk) && isNonManifold(inputAcc, ijk, mIsovalue, dim)) {
2287 mask.setActiveState(ijk, true);
2288 }
2289 }
2290 }
2291 }
2292
2293 // Compute the gradient for the remaining voxels
2294
2295 if (useGradients) {
2296
2297 if (gradientNode) {
2298 gradientNode->setValuesOff();
2299 } else {
2300 gradientNode.reset(new Vec3sLeafNodeType());
2301 }
2302
2303 for (auto it = signFlagsNode.cbeginValueOn(); it; ++it)
2304 {
2305 ijk = it.getCoord();
2306 if (!mask.isValueOn(ijk & ~1u))
2307 {
2308 Vec3sType dir(math::ISGradient<math::CD_2ND>::result(inputAcc, ijk));
2309 dir.normalize();
2310
2311 if (invertGradientDir) {
2312 dir = -dir;
2313 }
2314
2315 gradientNode->setValueOn(it.pos(), dir);
2316 }
2317 }
2318 }
2319
2320 // Merge regions
2321 int regionId = 1;
2322 for ( ; dim <= LeafDim; dim = dim << 1) {
2323 const unsigned coordMask = ~((dim << 1) - 1);
2324 for (ijk[0] = origin[0]; ijk[0] < end[0]; ijk[0] += dim) {
2325 for (ijk[1] = origin[1]; ijk[1] < end[1]; ijk[1] += dim) {
2326 for (ijk[2] = origin[2]; ijk[2] < end[2]; ijk[2] += dim) {
2327
2328 adaptivity = adaptivityLeaf.getValue(ijk);
2329
2330 if (mask.isValueOn(ijk)
2331 || isNonManifold(inputAcc, ijk, mIsovalue, dim)
2332 || (useGradients && !isMergeable(*gradientNode, ijk, dim, adaptivity)))
2333 {
2334 mask.setActiveState(ijk & coordMask, true);
2335 } else {
2336 mergeVoxels(pointIndexNode, ijk, dim, regionId++);
2337 }
2338 }
2339 }
2340 }
2341 }
2342 }
2343} // MergeVoxelRegions::operator()
2344
2345
2346////////////////////////////////////////
2347
2348
2349// Constructs qudas
2350struct UniformPrimBuilder
2351{
2352 UniformPrimBuilder(): mIdx(0), mPolygonPool(nullptr) {}
2353
2354 void init(const size_t upperBound, PolygonPool& quadPool)
2355 {
2356 mPolygonPool = &quadPool;
2357 mPolygonPool->resetQuads(upperBound);
2358 mIdx = 0;
2359 }
2360
2361 template<typename IndexType>
2362 void addPrim(const math::Vec4<IndexType>& verts, bool reverse, char flags = 0)
2363 {
2364 if (!reverse) {
2365 mPolygonPool->quad(mIdx) = verts;
2366 } else {
2367 Vec4I& quad = mPolygonPool->quad(mIdx);
2368 quad[0] = verts[3];
2369 quad[1] = verts[2];
2370 quad[2] = verts[1];
2371 quad[3] = verts[0];
2372 }
2373 mPolygonPool->quadFlags(mIdx) = flags;
2374 ++mIdx;
2375 }
2376
2377 void done()
2378 {
2379 mPolygonPool->trimQuads(mIdx);
2380 }
2381
2382private:
2383 size_t mIdx;
2384 PolygonPool* mPolygonPool;
2385};
2386
2387
2388// Constructs qudas and triangles
2389struct AdaptivePrimBuilder
2390{
2391 AdaptivePrimBuilder() : mQuadIdx(0), mTriangleIdx(0), mPolygonPool(nullptr) {}
2392
2393 void init(const size_t upperBound, PolygonPool& polygonPool)
2394 {
2395 mPolygonPool = &polygonPool;
2396 mPolygonPool->resetQuads(upperBound);
2397 mPolygonPool->resetTriangles(upperBound);
2398
2399 mQuadIdx = 0;
2400 mTriangleIdx = 0;
2401 }
2402
2403 template<typename IndexType>
2404 void addPrim(const math::Vec4<IndexType>& verts, bool reverse, char flags = 0)
2405 {
2406 if (verts[0] != verts[1] && verts[0] != verts[2] && verts[0] != verts[3]
2407 && verts[1] != verts[2] && verts[1] != verts[3] && verts[2] != verts[3]) {
2408 mPolygonPool->quadFlags(mQuadIdx) = flags;
2409 addQuad(verts, reverse);
2410 } else if (
2411 verts[0] == verts[3] &&
2412 verts[1] != verts[2] &&
2413 verts[1] != verts[0] &&
2414 verts[2] != verts[0]) {
2415 mPolygonPool->triangleFlags(mTriangleIdx) = flags;
2416 addTriangle(verts[0], verts[1], verts[2], reverse);
2417 } else if (
2418 verts[1] == verts[2] &&
2419 verts[0] != verts[3] &&
2420 verts[0] != verts[1] &&
2421 verts[3] != verts[1]) {
2422 mPolygonPool->triangleFlags(mTriangleIdx) = flags;
2423 addTriangle(verts[0], verts[1], verts[3], reverse);
2424 } else if (
2425 verts[0] == verts[1] &&
2426 verts[2] != verts[3] &&
2427 verts[2] != verts[0] &&
2428 verts[3] != verts[0]) {
2429 mPolygonPool->triangleFlags(mTriangleIdx) = flags;
2430 addTriangle(verts[0], verts[2], verts[3], reverse);
2431 } else if (
2432 verts[2] == verts[3] &&
2433 verts[0] != verts[1] &&
2434 verts[0] != verts[2] &&
2435 verts[1] != verts[2]) {
2436 mPolygonPool->triangleFlags(mTriangleIdx) = flags;
2437 addTriangle(verts[0], verts[1], verts[2], reverse);
2438 }
2439 }
2440
2441
2442 void done()
2443 {
2444 mPolygonPool->trimQuads(mQuadIdx, /*reallocate=*/true);
2445 mPolygonPool->trimTrinagles(mTriangleIdx, /*reallocate=*/true);
2446 }
2447
2448private:
2449
2450 template<typename IndexType>
2451 void addQuad(const math::Vec4<IndexType>& verts, bool reverse)
2452 {
2453 if (!reverse) {
2454 mPolygonPool->quad(mQuadIdx) = verts;
2455 } else {
2456 Vec4I& quad = mPolygonPool->quad(mQuadIdx);
2457 quad[0] = verts[3];
2458 quad[1] = verts[2];
2459 quad[2] = verts[1];
2460 quad[3] = verts[0];
2461 }
2462 ++mQuadIdx;
2463 }
2464
2465 void addTriangle(unsigned v0, unsigned v1, unsigned v2, bool reverse)
2466 {
2467 Vec3I& prim = mPolygonPool->triangle(mTriangleIdx);
2468
2469 prim[1] = v1;
2470
2471 if (!reverse) {
2472 prim[0] = v0;
2473 prim[2] = v2;
2474 } else {
2475 prim[0] = v2;
2476 prim[2] = v0;
2477 }
2478 ++mTriangleIdx;
2479 }
2480
2481 size_t mQuadIdx, mTriangleIdx;
2482 PolygonPool *mPolygonPool;
2483};
2484
2485
2486template<typename SignAccT, typename IdxAccT, typename PrimBuilder>
2487inline void
2488constructPolygons(
2489 bool invertSurfaceOrientation,
2490 Int16 flags,
2491 Int16 refFlags,
2492 const Vec3i& offsets,
2493 const Coord& ijk,
2494 const SignAccT& signAcc,
2495 const IdxAccT& idxAcc,
2496 PrimBuilder& mesher)
2497{
2498 using IndexType = typename IdxAccT::ValueType;
2499
2500 IndexType v0 = IndexType(util::INVALID_IDX);
2501 const bool isActive = idxAcc.probeValue(ijk, v0);
2502 if (isActive == false || v0 == IndexType(util::INVALID_IDX)) return;
2503
2504 char tag[2];
2505 tag[0] = (flags & SEAM) ? POLYFLAG_FRACTURE_SEAM : 0;
2506 tag[1] = tag[0] | char(POLYFLAG_EXTERIOR);
2507
2508 bool isInside = flags & INSIDE;
2509
2510 isInside = invertSurfaceOrientation ? !isInside : isInside;
2511
2512 Coord coord = ijk;
2513 math::Vec4<IndexType> quad(0,0,0,0);
2514
2515 if (flags & XEDGE) {
2516
2517 quad[0] = v0 + offsets[0];
2518
2519 // i, j-1, k
2520 coord[1]--;
2521 bool activeValues = idxAcc.probeValue(coord, quad[1]);
2522 uint8_t cell = uint8_t(SIGNS & signAcc.getValue(coord));
2523 quad[1] += sEdgeGroupTable[cell][0] > 1 ? sEdgeGroupTable[cell][5] - 1 : 0;
2524
2525 // i, j-1, k-1
2526 coord[2]--;
2527 activeValues = activeValues && idxAcc.probeValue(coord, quad[2]);
2528 cell = uint8_t(SIGNS & signAcc.getValue(coord));
2529 quad[2] += sEdgeGroupTable[cell][0] > 1 ? sEdgeGroupTable[cell][7] - 1 : 0;
2530
2531 // i, j, k-1
2532 coord[1]++;
2533 activeValues = activeValues && idxAcc.probeValue(coord, quad[3]);
2534 cell = uint8_t(SIGNS & signAcc.getValue(coord));
2535 quad[3] += sEdgeGroupTable[cell][0] > 1 ? sEdgeGroupTable[cell][3] - 1 : 0;
2536
2537 if (activeValues) {
2538 mesher.addPrim(quad, isInside, tag[bool(refFlags & XEDGE)]);
2539 }
2540
2541 coord[2]++; // i, j, k
2542 }
2543
2544
2545 if (flags & YEDGE) {
2546
2547 quad[0] = v0 + offsets[1];
2548
2549 // i, j, k-1
2550 coord[2]--;
2551 bool activeValues = idxAcc.probeValue(coord, quad[1]);
2552 uint8_t cell = uint8_t(SIGNS & signAcc.getValue(coord));
2553 quad[1] += sEdgeGroupTable[cell][0] > 1 ? sEdgeGroupTable[cell][12] - 1 : 0;
2554
2555 // i-1, j, k-1
2556 coord[0]--;
2557 activeValues = activeValues && idxAcc.probeValue(coord, quad[2]);
2558 cell = uint8_t(SIGNS & signAcc.getValue(coord));
2559 quad[2] += sEdgeGroupTable[cell][0] > 1 ? sEdgeGroupTable[cell][11] - 1 : 0;
2560
2561 // i-1, j, k
2562 coord[2]++;
2563 activeValues = activeValues && idxAcc.probeValue(coord, quad[3]);
2564 cell = uint8_t(SIGNS & signAcc.getValue(coord));
2565 quad[3] += sEdgeGroupTable[cell][0] > 1 ? sEdgeGroupTable[cell][10] - 1 : 0;
2566
2567 if (activeValues) {
2568 mesher.addPrim(quad, isInside, tag[bool(refFlags & YEDGE)]);
2569 }
2570
2571 coord[0]++; // i, j, k
2572 }
2573
2574
2575 if (flags & ZEDGE) {
2576
2577 quad[0] = v0 + offsets[2];
2578
2579 // i, j-1, k
2580 coord[1]--;
2581 bool activeValues = idxAcc.probeValue(coord, quad[1]);
2582 uint8_t cell = uint8_t(SIGNS & signAcc.getValue(coord));
2583 quad[1] += sEdgeGroupTable[cell][0] > 1 ? sEdgeGroupTable[cell][8] - 1 : 0;
2584
2585 // i-1, j-1, k
2586 coord[0]--;
2587 activeValues = activeValues && idxAcc.probeValue(coord, quad[2]);
2588 cell = uint8_t(SIGNS & signAcc.getValue(coord));
2589 quad[2] += sEdgeGroupTable[cell][0] > 1 ? sEdgeGroupTable[cell][6] - 1 : 0;
2590
2591 // i-1, j, k
2592 coord[1]++;
2593 activeValues = activeValues && idxAcc.probeValue(coord, quad[3]);
2594 cell = uint8_t(SIGNS & signAcc.getValue(coord));
2595 quad[3] += sEdgeGroupTable[cell][0] > 1 ? sEdgeGroupTable[cell][2] - 1 : 0;
2596
2597 if (activeValues) {
2598 mesher.addPrim(quad, !isInside, tag[bool(refFlags & ZEDGE)]);
2599 }
2600 }
2601}
2602
2603
2604////////////////////////////////////////
2605
2606
2607template<typename InputTreeType>
2608struct MaskTileBorders
2609{
2610 using InputValueType = typename InputTreeType::ValueType;
2611 using BoolTreeType = typename InputTreeType::template ValueConverter<bool>::Type;
2612
2613
2614 MaskTileBorders(const InputTreeType& inputTree, InputValueType iso,
2615 BoolTreeType& mask, const Vec4i* tileArray)
2616 : mInputTree(&inputTree)
2617 , mIsovalue(iso)
2618 , mTempMask(false)
2619 , mMask(&mask)
2620 , mTileArray(tileArray)
2621 {
2622 }
2623
2624 MaskTileBorders(MaskTileBorders& rhs, tbb::split)
2625 : mInputTree(rhs.mInputTree)
2626 , mIsovalue(rhs.mIsovalue)
2627 , mTempMask(false)
2628 , mMask(&mTempMask)
2629 , mTileArray(rhs.mTileArray)
2630 {
2631 }
2632
2633 void join(MaskTileBorders& rhs) { mMask->merge(*rhs.mMask); }
2634
2635 void operator()(const tbb::blocked_range<size_t>&);
2636
2637private:
2638 InputTreeType const * const mInputTree;
2639 InputValueType const mIsovalue;
2640 BoolTreeType mTempMask;
2641 BoolTreeType * const mMask;
2642 Vec4i const * const mTileArray;
2643}; // MaskTileBorders
2644
2645
2646template<typename InputTreeType>
2647void
2648MaskTileBorders<InputTreeType>::operator()(const tbb::blocked_range<size_t>& range)
2649{
2650 tree::ValueAccessor<const InputTreeType> inputTreeAcc(*mInputTree);
2651
2652 CoordBBox region, bbox;
2653 Coord ijk, nijk;
2654
2655 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
2656
2657 const Vec4i& tile = mTileArray[n];
2658
2659 bbox.min()[0] = tile[0];
2660 bbox.min()[1] = tile[1];
2661 bbox.min()[2] = tile[2];
2662 bbox.max() = bbox.min();
2663 bbox.max().offset(tile[3]);
2664
2665 InputValueType value = mInputTree->background();
2666
2667 const bool isInside = isInsideValue(inputTreeAcc.getValue(bbox.min()), mIsovalue);
2668 const int valueDepth = inputTreeAcc.getValueDepth(bbox.min());
2669
2670 // eval x-edges
2671
2672 ijk = bbox.max();
2673 nijk = ijk;
2674 ++nijk[0];
2675
2676 bool processRegion = true;
2677 if (valueDepth >= inputTreeAcc.getValueDepth(nijk)) {
2678 processRegion = isInside != isInsideValue(inputTreeAcc.getValue(nijk), mIsovalue);
2679 }
2680
2681 if (processRegion) {
2682 region = bbox;
2683 region.expand(1);
2684 region.min()[0] = region.max()[0] = ijk[0];
2685 mMask->fill(region, false);
2686 }
2687
2688
2689 ijk = bbox.min();
2690 --ijk[0];
2691
2692 processRegion = true;
2693 if (valueDepth >= inputTreeAcc.getValueDepth(ijk)) {
2694 processRegion = (!inputTreeAcc.probeValue(ijk, value)
2695 && isInside != isInsideValue(value, mIsovalue));
2696 }
2697
2698 if (processRegion) {
2699 region = bbox;
2700 region.expand(1);
2701 region.min()[0] = region.max()[0] = ijk[0];
2702 mMask->fill(region, false);
2703 }
2704
2705
2706 // eval y-edges
2707
2708 ijk = bbox.max();
2709 nijk = ijk;
2710 ++nijk[1];
2711
2712 processRegion = true;
2713 if (valueDepth >= inputTreeAcc.getValueDepth(nijk)) {
2714 processRegion = isInside != isInsideValue(inputTreeAcc.getValue(nijk), mIsovalue);
2715 }
2716
2717 if (processRegion) {
2718 region = bbox;
2719 region.expand(1);
2720 region.min()[1] = region.max()[1] = ijk[1];
2721 mMask->fill(region, false);
2722 }
2723
2724
2725 ijk = bbox.min();
2726 --ijk[1];
2727
2728 processRegion = true;
2729 if (valueDepth >= inputTreeAcc.getValueDepth(ijk)) {
2730 processRegion = (!inputTreeAcc.probeValue(ijk, value)
2731 && isInside != isInsideValue(value, mIsovalue));
2732 }
2733
2734 if (processRegion) {
2735 region = bbox;
2736 region.expand(1);
2737 region.min()[1] = region.max()[1] = ijk[1];
2738 mMask->fill(region, false);
2739 }
2740
2741
2742 // eval z-edges
2743
2744 ijk = bbox.max();
2745 nijk = ijk;
2746 ++nijk[2];
2747
2748 processRegion = true;
2749 if (valueDepth >= inputTreeAcc.getValueDepth(nijk)) {
2750 processRegion = isInside != isInsideValue(inputTreeAcc.getValue(nijk), mIsovalue);
2751 }
2752
2753 if (processRegion) {
2754 region = bbox;
2755 region.expand(1);
2756 region.min()[2] = region.max()[2] = ijk[2];
2757 mMask->fill(region, false);
2758 }
2759
2760 ijk = bbox.min();
2761 --ijk[2];
2762
2763 processRegion = true;
2764 if (valueDepth >= inputTreeAcc.getValueDepth(ijk)) {
2765 processRegion = (!inputTreeAcc.probeValue(ijk, value)
2766 && isInside != isInsideValue(value, mIsovalue));
2767 }
2768
2769 if (processRegion) {
2770 region = bbox;
2771 region.expand(1);
2772 region.min()[2] = region.max()[2] = ijk[2];
2773 mMask->fill(region, false);
2774 }
2775 }
2776} // MaskTileBorders::operator()
2777
2778
2779template<typename InputTreeType>
2780inline void
2781maskActiveTileBorders(const InputTreeType& inputTree,
2782 const typename InputTreeType::ValueType iso,
2783 typename InputTreeType::template ValueConverter<bool>::Type& mask)
2784{
2785 typename InputTreeType::ValueOnCIter tileIter(inputTree);
2786 tileIter.setMaxDepth(InputTreeType::ValueOnCIter::LEAF_DEPTH - 1);
2787
2788 size_t tileCount = 0;
2789 for ( ; tileIter; ++tileIter) {
2790 ++tileCount;
2791 }
2792
2793 if (tileCount > 0) {
2794 std::unique_ptr<Vec4i[]> tiles(new Vec4i[tileCount]);
2795
2796 CoordBBox bbox;
2797 size_t index = 0;
2798
2799 tileIter = inputTree.cbeginValueOn();
2800 tileIter.setMaxDepth(InputTreeType::ValueOnCIter::LEAF_DEPTH - 1);
2801
2802 for (; tileIter; ++tileIter) {
2803 Vec4i& tile = tiles[index++];
2804 tileIter.getBoundingBox(bbox);
2805 tile[0] = bbox.min()[0];
2806 tile[1] = bbox.min()[1];
2807 tile[2] = bbox.min()[2];
2808 tile[3] = bbox.max()[0] - bbox.min()[0];
2809 }
2810
2811 MaskTileBorders<InputTreeType> op(inputTree, iso, mask, tiles.get());
2812 tbb::parallel_reduce(tbb::blocked_range<size_t>(0, tileCount), op);
2813 }
2814}
2815
2816
2817////////////////////////////////////////
2818
2819
2820// Utility class for the volumeToMesh wrapper
2821class PointListCopy
2822{
2823public:
2824 PointListCopy(const PointList& pointsIn, std::vector<Vec3s>& pointsOut)
2825 : mPointsIn(pointsIn) , mPointsOut(pointsOut)
2826 {
2827 }
2828
2829 void operator()(const tbb::blocked_range<size_t>& range) const
2830 {
2831 for (size_t n = range.begin(); n < range.end(); ++n) {
2832 mPointsOut[n] = mPointsIn[n];
2833 }
2834 }
2835
2836private:
2837 const PointList& mPointsIn;
2838 std::vector<Vec3s>& mPointsOut;
2839};
2840
2841
2842////////////////////////////////////////////////////////////////////////////////
2843////////////////////////////////////////////////////////////////////////////////
2844
2845
2846struct LeafNodeVoxelOffsets
2847{
2848 using IndexVector = std::vector<Index>;
2849
2850 template<typename LeafNodeType>
2851 void constructOffsetList();
2852
2853 /// Return internal core voxel offsets.
2854 const IndexVector& core() const { return mCore; }
2855
2856
2857 /// Return front face voxel offsets.
2858 const IndexVector& minX() const { return mMinX; }
2859
2860 /// Return back face voxel offsets.
2861 const IndexVector& maxX() const { return mMaxX; }
2862
2863
2864 /// Return bottom face voxel offsets.
2865 const IndexVector& minY() const { return mMinY; }
2866
2867 /// Return top face voxel offsets.
2868 const IndexVector& maxY() const { return mMaxY; }
2869
2870
2871 /// Return left face voxel offsets.
2872 const IndexVector& minZ() const { return mMinZ; }
2873
2874 /// Return right face voxel offsets.
2875 const IndexVector& maxZ() const { return mMaxZ; }
2876
2877
2878 /// Return voxel offsets with internal neighbours in x + 1.
2879 const IndexVector& internalNeighborsX() const { return mInternalNeighborsX; }
2880
2881 /// Return voxel offsets with internal neighbours in y + 1.
2882 const IndexVector& internalNeighborsY() const { return mInternalNeighborsY; }
2883
2884 /// Return voxel offsets with internal neighbours in z + 1.
2885 const IndexVector& internalNeighborsZ() const { return mInternalNeighborsZ; }
2886
2887
2888private:
2889 IndexVector mCore, mMinX, mMaxX, mMinY, mMaxY, mMinZ, mMaxZ,
2890 mInternalNeighborsX, mInternalNeighborsY, mInternalNeighborsZ;
2891}; // struct LeafNodeOffsets
2892
2893
2894template<typename LeafNodeType>
2895inline void
2896LeafNodeVoxelOffsets::constructOffsetList()
2897{
2898 // internal core voxels
2899 mCore.clear();
2900 mCore.reserve((LeafNodeType::DIM - 2) * (LeafNodeType::DIM - 2));
2901
2902 for (Index x = 1; x < (LeafNodeType::DIM - 1); ++x) {
2903 const Index offsetX = x << (2 * LeafNodeType::LOG2DIM);
2904 for (Index y = 1; y < (LeafNodeType::DIM - 1); ++y) {
2905 const Index offsetXY = offsetX + (y << LeafNodeType::LOG2DIM);
2906 for (Index z = 1; z < (LeafNodeType::DIM - 1); ++z) {
2907 mCore.push_back(offsetXY + z);
2908 }
2909 }
2910 }
2911
2912 // internal neighbors in x + 1
2913 mInternalNeighborsX.clear();
2914 mInternalNeighborsX.reserve(LeafNodeType::SIZE - (LeafNodeType::DIM * LeafNodeType::DIM));
2915
2916 for (Index x = 0; x < (LeafNodeType::DIM - 1); ++x) {
2917 const Index offsetX = x << (2 * LeafNodeType::LOG2DIM);
2918 for (Index y = 0; y < LeafNodeType::DIM; ++y) {
2919 const Index offsetXY = offsetX + (y << LeafNodeType::LOG2DIM);
2920 for (Index z = 0; z < LeafNodeType::DIM; ++z) {
2921 mInternalNeighborsX.push_back(offsetXY + z);
2922 }
2923 }
2924 }
2925
2926 // internal neighbors in y + 1
2927 mInternalNeighborsY.clear();
2928 mInternalNeighborsY.reserve(LeafNodeType::SIZE - (LeafNodeType::DIM * LeafNodeType::DIM));
2929
2930 for (Index x = 0; x < LeafNodeType::DIM; ++x) {
2931 const Index offsetX = x << (2 * LeafNodeType::LOG2DIM);
2932 for (Index y = 0; y < (LeafNodeType::DIM - 1); ++y) {
2933 const Index offsetXY = offsetX + (y << LeafNodeType::LOG2DIM);
2934 for (Index z = 0; z < LeafNodeType::DIM; ++z) {
2935 mInternalNeighborsY.push_back(offsetXY + z);
2936 }
2937 }
2938 }
2939
2940 // internal neighbors in z + 1
2941 mInternalNeighborsZ.clear();
2942 mInternalNeighborsZ.reserve(LeafNodeType::SIZE - (LeafNodeType::DIM * LeafNodeType::DIM));
2943
2944 for (Index x = 0; x < LeafNodeType::DIM; ++x) {
2945 const Index offsetX = x << (2 * LeafNodeType::LOG2DIM);
2946 for (Index y = 0; y < LeafNodeType::DIM; ++y) {
2947 const Index offsetXY = offsetX + (y << LeafNodeType::LOG2DIM);
2948 for (Index z = 0; z < (LeafNodeType::DIM - 1); ++z) {
2949 mInternalNeighborsZ.push_back(offsetXY + z);
2950 }
2951 }
2952 }
2953
2954 // min x
2955 mMinX.clear();
2956 mMinX.reserve(LeafNodeType::DIM * LeafNodeType::DIM);
2957 {
2958 for (Index y = 0; y < LeafNodeType::DIM; ++y) {
2959 const Index offsetXY = (y << LeafNodeType::LOG2DIM);
2960 for (Index z = 0; z < LeafNodeType::DIM; ++z) {
2961 mMinX.push_back(offsetXY + z);
2962 }
2963 }
2964 }
2965
2966 // max x
2967 mMaxX.clear();
2968 mMaxX.reserve(LeafNodeType::DIM * LeafNodeType::DIM);
2969 {
2970 const Index offsetX = (LeafNodeType::DIM - 1) << (2 * LeafNodeType::LOG2DIM);
2971 for (Index y = 0; y < LeafNodeType::DIM; ++y) {
2972 const Index offsetXY = offsetX + (y << LeafNodeType::LOG2DIM);
2973 for (Index z = 0; z < LeafNodeType::DIM; ++z) {
2974 mMaxX.push_back(offsetXY + z);
2975 }
2976 }
2977 }
2978
2979 // min y
2980 mMinY.clear();
2981 mMinY.reserve(LeafNodeType::DIM * LeafNodeType::DIM);
2982 {
2983 for (Index x = 0; x < LeafNodeType::DIM; ++x) {
2984 const Index offsetX = x << (2 * LeafNodeType::LOG2DIM);
2985 for (Index z = 0; z < (LeafNodeType::DIM - 1); ++z) {
2986 mMinY.push_back(offsetX + z);
2987 }
2988 }
2989 }
2990
2991 // max y
2992 mMaxY.clear();
2993 mMaxY.reserve(LeafNodeType::DIM * LeafNodeType::DIM);
2994 {
2995 const Index offsetY = (LeafNodeType::DIM - 1) << LeafNodeType::LOG2DIM;
2996 for (Index x = 0; x < LeafNodeType::DIM; ++x) {
2997 const Index offsetX = x << (2 * LeafNodeType::LOG2DIM);
2998 for (Index z = 0; z < (LeafNodeType::DIM - 1); ++z) {
2999 mMaxY.push_back(offsetX + offsetY + z);
3000 }
3001 }
3002 }
3003
3004 // min z
3005 mMinZ.clear();
3006 mMinZ.reserve(LeafNodeType::DIM * LeafNodeType::DIM);
3007 {
3008 for (Index x = 0; x < LeafNodeType::DIM; ++x) {
3009 const Index offsetX = x << (2 * LeafNodeType::LOG2DIM);
3010 for (Index y = 0; y < LeafNodeType::DIM; ++y) {
3011 const Index offsetXY = offsetX + (y << LeafNodeType::LOG2DIM);
3012 mMinZ.push_back(offsetXY);
3013 }
3014 }
3015 }
3016
3017 // max z
3018 mMaxZ.clear();
3019 mMaxZ.reserve(LeafNodeType::DIM * LeafNodeType::DIM);
3020 {
3021 for (Index x = 0; x < LeafNodeType::DIM; ++x) {
3022 const Index offsetX = x << (2 * LeafNodeType::LOG2DIM);
3023 for (Index y = 0; y < LeafNodeType::DIM; ++y) {
3024 const Index offsetXY = offsetX + (y << LeafNodeType::LOG2DIM);
3025 mMaxZ.push_back(offsetXY + (LeafNodeType::DIM - 1));
3026 }
3027 }
3028 }
3029}
3030
3031
3032////////////////////////////////////////
3033
3034
3035/// Utility method to marks all voxels that share an edge.
3036template<typename AccessorT, int _AXIS>
3037struct VoxelEdgeAccessor
3038{
3039 enum { AXIS = _AXIS };
3040 AccessorT& acc;
3041
3042 VoxelEdgeAccessor(AccessorT& _acc) : acc(_acc) {}
3043
3044 void set(Coord ijk) {
3045 if (_AXIS == 0) { // x + 1 edge
3046 acc.setActiveState(ijk);
3047 --ijk[1]; // set i, j-1, k
3048 acc.setActiveState(ijk);
3049 --ijk[2]; // set i, j-1, k-1
3050 acc.setActiveState(ijk);
3051 ++ijk[1]; // set i, j, k-1
3052 acc.setActiveState(ijk);
3053 } else if (_AXIS == 1) { // y + 1 edge
3054 acc.setActiveState(ijk);
3055 --ijk[2]; // set i, j, k-1
3056 acc.setActiveState(ijk);
3057 --ijk[0]; // set i-1, j, k-1
3058 acc.setActiveState(ijk);
3059 ++ijk[2]; // set i-1, j, k
3060 acc.setActiveState(ijk);
3061 } else { // z + 1 edge
3062 acc.setActiveState(ijk);
3063 --ijk[1]; // set i, j-1, k
3064 acc.setActiveState(ijk);
3065 --ijk[0]; // set i-1, j-1, k
3066 acc.setActiveState(ijk);
3067 ++ijk[1]; // set i-1, j, k
3068 acc.setActiveState(ijk);
3069 }
3070 }
3071};
3072
3073
3074/// Utility method to check for sign changes along the x + 1, y + 1 or z + 1 directions.
3075/// The direction is determined by the @a edgeAcc parameter. Only voxels that have internal
3076/// neighbours are evaluated.
3077template<typename VoxelEdgeAcc, typename LeafNodeT>
3078void
3079evalInternalVoxelEdges(VoxelEdgeAcc& edgeAcc,
3080 const LeafNodeT& leafnode,
3081 const LeafNodeVoxelOffsets& voxels,
3082 const typename LeafNodeT::ValueType iso)
3083{
3084 Index nvo = 1; // neighbour voxel offset, z + 1 direction assumed initially.
3085 const std::vector<Index>* offsets = &voxels.internalNeighborsZ();
3086
3087 if (VoxelEdgeAcc::AXIS == 0) { // x + 1 direction
3088 nvo = LeafNodeT::DIM * LeafNodeT::DIM;
3089 offsets = &voxels.internalNeighborsX();
3090 } else if (VoxelEdgeAcc::AXIS == 1) { // y + 1 direction
3091 nvo = LeafNodeT::DIM;
3092 offsets = &voxels.internalNeighborsY();
3093 }
3094
3095 const LeafBufferAccessor<LeafNodeT> lhsAcc(leafnode);
3096
3097 for (size_t n = 0, N = offsets->size(); n < N; ++n) {
3098 const Index& pos = (*offsets)[n];
3099 const bool isActive = leafnode.isValueOn(pos) || leafnode.isValueOn(pos + nvo);
3100 if (isActive && (isInsideValue(lhsAcc.get(pos), iso) !=
3101 isInsideValue(lhsAcc.get((pos + nvo)), iso))) {
3102 edgeAcc.set(leafnode.offsetToGlobalCoord(pos));
3103 }
3104 }
3105}
3106
3107
3108/// Utility method to check for sign changes along the x + 1, y + 1 or z + 1 directions.
3109/// The direction is determined by the @a edgeAcc parameter. All voxels that reside in the
3110/// specified leafnode face: back, top or right are evaluated.
3111template<typename LeafNodeT, typename TreeAcc, typename VoxelEdgeAcc>
3112void
3113evalExternalVoxelEdges(VoxelEdgeAcc& edgeAcc,
3114 const TreeAcc& acc,
3115 const LeafNodeT& lhsNode,
3116 const LeafNodeVoxelOffsets& voxels,
3117 const typename LeafNodeT::ValueType iso)
3118{
3119 const std::vector<Index>* lhsOffsets = &voxels.maxX();
3120 const std::vector<Index>* rhsOffsets = &voxels.minX();
3121 Coord ijk = lhsNode.origin();
3122
3123 if (VoxelEdgeAcc::AXIS == 0) { // back leafnode face
3124 ijk[0] += LeafNodeT::DIM;
3125 } else if (VoxelEdgeAcc::AXIS == 1) { // top leafnode face
3126 ijk[1] += LeafNodeT::DIM;
3127 lhsOffsets = &voxels.maxY();
3128 rhsOffsets = &voxels.minY();
3129 } else if (VoxelEdgeAcc::AXIS == 2) { // right leafnode face
3130 ijk[2] += LeafNodeT::DIM;
3131 lhsOffsets = &voxels.maxZ();
3132 rhsOffsets = &voxels.minZ();
3133 }
3134
3135 typename LeafNodeT::ValueType value;
3136 const LeafNodeT* rhsNodePt = acc.probeConstLeaf(ijk);
3137
3138 const LeafBufferAccessor<LeafNodeT> lhsAcc(lhsNode);
3139
3140 if (rhsNodePt) {
3141 const LeafBufferAccessor<LeafNodeT> rhsAcc(*rhsNodePt);
3142
3143 for (size_t n = 0, N = lhsOffsets->size(); n < N; ++n) {
3144 const Index& pos = (*lhsOffsets)[n];
3145 bool isActive = lhsNode.isValueOn(pos) || rhsNodePt->isValueOn((*rhsOffsets)[n]);
3146 if (isActive && (isInsideValue(lhsAcc.get(pos), iso) !=
3147 isInsideValue(rhsAcc.get((*rhsOffsets)[n]), iso))) {
3148 edgeAcc.set(lhsNode.offsetToGlobalCoord(pos));
3149 }
3150 }
3151 } else if (!acc.probeValue(ijk, value)) {
3152 const bool inside = isInsideValue(value, iso);
3153 for (size_t n = 0, N = lhsOffsets->size(); n < N; ++n) {
3154 const Index& pos = (*lhsOffsets)[n];
3155 if (lhsNode.isValueOn(pos) && (inside != isInsideValue(lhsAcc.get(pos), iso))) {
3156 edgeAcc.set(lhsNode.offsetToGlobalCoord(pos));
3157 }
3158 }
3159 }
3160}
3161
3162
3163/// Utility method to check for sign changes along the x - 1, y - 1 or z - 1 directions.
3164/// The direction is determined by the @a edgeAcc parameter. All voxels that reside in the
3165/// specified leafnode face: front, bottom or left are evaluated.
3166template<typename LeafNodeT, typename TreeAcc, typename VoxelEdgeAcc>
3167void
3168evalExternalVoxelEdgesInv(VoxelEdgeAcc& edgeAcc,
3169 const TreeAcc& acc,
3170 const LeafNodeT& leafnode,
3171 const LeafNodeVoxelOffsets& voxels,
3172 const typename LeafNodeT::ValueType iso)
3173{
3174 Coord ijk = leafnode.origin();
3175 if (VoxelEdgeAcc::AXIS == 0) --ijk[0]; // front leafnode face
3176 else if (VoxelEdgeAcc::AXIS == 1) --ijk[1]; // bottom leafnode face
3177 else if (VoxelEdgeAcc::AXIS == 2) --ijk[2]; // left leafnode face
3178
3179 typename LeafNodeT::ValueType value;
3180 if (!acc.probeConstLeaf(ijk) && !acc.probeValue(ijk, value)) {
3181
3182 const std::vector<Index>* offsets = &voxels.internalNeighborsX();
3183 if (VoxelEdgeAcc::AXIS == 1) offsets = &voxels.internalNeighborsY();
3184 else if (VoxelEdgeAcc::AXIS == 2) offsets = &voxels.internalNeighborsZ();
3185
3186 const LeafBufferAccessor<LeafNodeT> lhsAcc(leafnode);
3187
3188 const bool inside = isInsideValue(value, iso);
3189 for (size_t n = 0, N = offsets->size(); n < N; ++n) {
3190
3191 const Index& pos = (*offsets)[n];
3192 if (leafnode.isValueOn(pos)
3193 && (inside != isInsideValue(lhsAcc.get(pos), iso)))
3194 {
3195 ijk = leafnode.offsetToGlobalCoord(pos);
3196 if (VoxelEdgeAcc::AXIS == 0) --ijk[0];
3197 else if (VoxelEdgeAcc::AXIS == 1) --ijk[1];
3198 else if (VoxelEdgeAcc::AXIS == 2) --ijk[2];
3199
3200 edgeAcc.set(ijk);
3201 }
3202 }
3203 }
3204}
3205
3206
3207template<typename InputTreeType>
3208struct IdentifyIntersectingVoxels
3209{
3210 using InputLeafNodeType = typename InputTreeType::LeafNodeType;
3211 using InputValueType = typename InputLeafNodeType::ValueType;
3212
3213 using BoolTreeType = typename InputTreeType::template ValueConverter<bool>::Type;
3214
3215 IdentifyIntersectingVoxels(
3216 const InputTreeType& inputTree,
3217 const std::vector<const InputLeafNodeType*>& inputLeafNodes,
3218 const LeafNodeVoxelOffsets& offsets,
3219 BoolTreeType& intersectionTree,
3220 InputValueType iso);
3221
3222 IdentifyIntersectingVoxels(IdentifyIntersectingVoxels&, tbb::split);
3223 void operator()(const tbb::blocked_range<size_t>&);
3224 void join(const IdentifyIntersectingVoxels& rhs) {
3225 mIntersectionAccessor.tree().merge(rhs.mIntersectionAccessor.tree());
3226 }
3227
3228private:
3229 tree::ValueAccessor<const InputTreeType> mInputAccessor;
3230 InputLeafNodeType const * const * const mInputNodes;
3231
3232 BoolTreeType mIntersectionTree;
3233 tree::ValueAccessor<BoolTreeType> mIntersectionAccessor;
3234
3235 const LeafNodeVoxelOffsets& mOffsets;
3236 const InputValueType mIsovalue;
3237}; // struct IdentifyIntersectingVoxels
3238
3239
3240template<typename InputTreeType>
3241IdentifyIntersectingVoxels<InputTreeType>::IdentifyIntersectingVoxels(
3242 const InputTreeType& inputTree,
3243 const std::vector<const InputLeafNodeType*>& inputLeafNodes,
3244 const LeafNodeVoxelOffsets& offsets,
3245 BoolTreeType& intersectionTree,
3246 InputValueType iso)
3247 : mInputAccessor(inputTree)
3248 , mInputNodes(inputLeafNodes.data())
3249 , mIntersectionTree(false)
3250 , mIntersectionAccessor(intersectionTree)
3251 , mOffsets(offsets)
3252 , mIsovalue(iso)
3253{
3254}
3255
3256
3257template<typename InputTreeType>
3258IdentifyIntersectingVoxels<InputTreeType>::IdentifyIntersectingVoxels(
3259 IdentifyIntersectingVoxels& rhs, tbb::split)
3260 : mInputAccessor(rhs.mInputAccessor.tree())
3261 , mInputNodes(rhs.mInputNodes)
3262 , mIntersectionTree(false)
3263 , mIntersectionAccessor(mIntersectionTree) // use local tree.
3264 , mOffsets(rhs.mOffsets)
3265 , mIsovalue(rhs.mIsovalue)
3266{
3267}
3268
3269
3270template<typename InputTreeType>
3271void
3272IdentifyIntersectingVoxels<InputTreeType>::operator()(const tbb::blocked_range<size_t>& range)
3273{
3274 VoxelEdgeAccessor<tree::ValueAccessor<BoolTreeType>, 0> xEdgeAcc(mIntersectionAccessor);
3275 VoxelEdgeAccessor<tree::ValueAccessor<BoolTreeType>, 1> yEdgeAcc(mIntersectionAccessor);
3276 VoxelEdgeAccessor<tree::ValueAccessor<BoolTreeType>, 2> zEdgeAcc(mIntersectionAccessor);
3277
3278 for (size_t n = range.begin(); n != range.end(); ++n) {
3279
3280 const InputLeafNodeType& node = *mInputNodes[n];
3281
3282 // internal x + 1 voxel edges
3283 evalInternalVoxelEdges(xEdgeAcc, node, mOffsets, mIsovalue);
3284 // internal y + 1 voxel edges
3285 evalInternalVoxelEdges(yEdgeAcc, node, mOffsets, mIsovalue);
3286 // internal z + 1 voxel edges
3287 evalInternalVoxelEdges(zEdgeAcc, node, mOffsets, mIsovalue);
3288
3289 // external x + 1 voxels edges (back face)
3290 evalExternalVoxelEdges(xEdgeAcc, mInputAccessor, node, mOffsets, mIsovalue);
3291 // external y + 1 voxels edges (top face)
3292 evalExternalVoxelEdges(yEdgeAcc, mInputAccessor, node, mOffsets, mIsovalue);
3293 // external z + 1 voxels edges (right face)
3294 evalExternalVoxelEdges(zEdgeAcc, mInputAccessor, node, mOffsets, mIsovalue);
3295
3296 // The remaining edges are only checked if the leafnode neighbour, in the
3297 // corresponding direction, is an inactive tile.
3298
3299 // external x - 1 voxels edges (front face)
3300 evalExternalVoxelEdgesInv(xEdgeAcc, mInputAccessor, node, mOffsets, mIsovalue);
3301 // external y - 1 voxels edges (bottom face)
3302 evalExternalVoxelEdgesInv(yEdgeAcc, mInputAccessor, node, mOffsets, mIsovalue);
3303 // external z - 1 voxels edges (left face)
3304 evalExternalVoxelEdgesInv(zEdgeAcc, mInputAccessor, node, mOffsets, mIsovalue);
3305 }
3306} // IdentifyIntersectingVoxels::operator()
3307
3308
3309template<typename InputTreeType>
3310inline void
3311identifySurfaceIntersectingVoxels(
3312 typename InputTreeType::template ValueConverter<bool>::Type& intersectionTree,
3313 const InputTreeType& inputTree,
3314 typename InputTreeType::ValueType isovalue)
3315{
3316 using InputLeafNodeType = typename InputTreeType::LeafNodeType;
3317
3318 std::vector<const InputLeafNodeType*> inputLeafNodes;
3319 inputTree.getNodes(inputLeafNodes);
3320
3321 LeafNodeVoxelOffsets offsets;
3322 offsets.constructOffsetList<InputLeafNodeType>();
3323
3324 IdentifyIntersectingVoxels<InputTreeType> op(
3325 inputTree, inputLeafNodes, offsets, intersectionTree, isovalue);
3326
3327 tbb::parallel_reduce(tbb::blocked_range<size_t>(0, inputLeafNodes.size()), op);
3328
3329 maskActiveTileBorders(inputTree, isovalue, intersectionTree);
3330}
3331
3332
3333////////////////////////////////////////
3334
3335
3336template<typename InputTreeType>
3337struct MaskIntersectingVoxels
3338{
3339 using InputLeafNodeType = typename InputTreeType::LeafNodeType;
3340 using InputValueType = typename InputLeafNodeType::ValueType;
3341
3342 using BoolTreeType = typename InputTreeType::template ValueConverter<bool>::Type;
3343 using BoolLeafNodeType = typename BoolTreeType::LeafNodeType;
3344
3345 MaskIntersectingVoxels(
3346 const InputTreeType& inputTree,
3347 const std::vector<BoolLeafNodeType*>& nodes,
3348 BoolTreeType& intersectionTree,
3349 InputValueType iso);
3350
3351 MaskIntersectingVoxels(MaskIntersectingVoxels&, tbb::split);
3352 void operator()(const tbb::blocked_range<size_t>&);
3353 void join(const MaskIntersectingVoxels& rhs) {
3354 mIntersectionAccessor.tree().merge(rhs.mIntersectionAccessor.tree());
3355 }
3356
3357private:
3358 tree::ValueAccessor<const InputTreeType> mInputAccessor;
3359 BoolLeafNodeType const * const * const mNodes;
3360
3361 BoolTreeType mIntersectionTree;
3362 tree::ValueAccessor<BoolTreeType> mIntersectionAccessor;
3363
3364 const InputValueType mIsovalue;
3365}; // struct MaskIntersectingVoxels
3366
3367
3368template<typename InputTreeType>
3369MaskIntersectingVoxels<InputTreeType>::MaskIntersectingVoxels(
3370 const InputTreeType& inputTree,
3371 const std::vector<BoolLeafNodeType*>& nodes,
3372 BoolTreeType& intersectionTree,
3373 InputValueType iso)
3374 : mInputAccessor(inputTree)
3375 , mNodes(nodes.data())
3376 , mIntersectionTree(false)
3377 , mIntersectionAccessor(intersectionTree)
3378 , mIsovalue(iso)
3379{
3380}
3381
3382
3383template<typename InputTreeType>
3384MaskIntersectingVoxels<InputTreeType>::MaskIntersectingVoxels(
3385 MaskIntersectingVoxels& rhs, tbb::split)
3386 : mInputAccessor(rhs.mInputAccessor.tree())
3387 , mNodes(rhs.mNodes)
3388 , mIntersectionTree(false)
3389 , mIntersectionAccessor(mIntersectionTree) // use local tree.
3390 , mIsovalue(rhs.mIsovalue)
3391{
3392}
3393
3394
3395template<typename InputTreeType>
3396void
3397MaskIntersectingVoxels<InputTreeType>::operator()(const tbb::blocked_range<size_t>& range)
3398{
3399 VoxelEdgeAccessor<tree::ValueAccessor<BoolTreeType>, 0> xEdgeAcc(mIntersectionAccessor);
3400 VoxelEdgeAccessor<tree::ValueAccessor<BoolTreeType>, 1> yEdgeAcc(mIntersectionAccessor);
3401 VoxelEdgeAccessor<tree::ValueAccessor<BoolTreeType>, 2> zEdgeAcc(mIntersectionAccessor);
3402
3403 Coord ijk;
3404
3405 for (size_t n = range.begin(); n != range.end(); ++n) {
3406
3407 const BoolLeafNodeType& node = *mNodes[n];
3408
3409 for (auto it = node.cbeginValueOn(); it; ++it) {
3410
3411 if (!it.getValue()) {
3412
3413 ijk = it.getCoord();
3414
3415 const bool inside = isInsideValue(mInputAccessor.getValue(ijk), mIsovalue);
3416
3417 if (inside != isInsideValue(mInputAccessor.getValue(ijk.offsetBy(1, 0, 0)), mIsovalue)) {
3418 xEdgeAcc.set(ijk);
3419 }
3420
3421 if (inside != isInsideValue(mInputAccessor.getValue(ijk.offsetBy(0, 1, 0)), mIsovalue)) {
3422 yEdgeAcc.set(ijk);
3423 }
3424
3425 if (inside != isInsideValue(mInputAccessor.getValue(ijk.offsetBy(0, 0, 1)), mIsovalue)) {
3426 zEdgeAcc.set(ijk);
3427 }
3428 }
3429 }
3430 }
3431} // MaskIntersectingVoxels::operator()
3432
3433
3434template<typename BoolTreeType>
3435struct MaskBorderVoxels
3436{
3437 using BoolLeafNodeType = typename BoolTreeType::LeafNodeType;
3438
3439 MaskBorderVoxels(const BoolTreeType& maskTree,
3440 const std::vector<BoolLeafNodeType*>& maskNodes,
3441 BoolTreeType& borderTree)
3442 : mMaskTree(&maskTree)
3443 , mMaskNodes(maskNodes.data())
3444 , mTmpBorderTree(false)
3445 , mBorderTree(&borderTree) {}
3446
3447 MaskBorderVoxels(MaskBorderVoxels& rhs, tbb::split)
3448 : mMaskTree(rhs.mMaskTree)
3449 , mMaskNodes(rhs.mMaskNodes)
3450 , mTmpBorderTree(false)
3451 , mBorderTree(&mTmpBorderTree) {}
3452
3453 void join(MaskBorderVoxels& rhs) { mBorderTree->merge(*rhs.mBorderTree); }
3454
3455 void operator()(const tbb::blocked_range<size_t>& range)
3456 {
3457 tree::ValueAccessor<const BoolTreeType> maskAcc(*mMaskTree);
3458 tree::ValueAccessor<BoolTreeType> borderAcc(*mBorderTree);
3459 Coord ijk;
3460
3461 for (size_t n = range.begin(); n != range.end(); ++n) {
3462
3463 const BoolLeafNodeType& node = *mMaskNodes[n];
3464
3465 for (auto it = node.cbeginValueOn(); it; ++it) {
3466
3467 ijk = it.getCoord();
3468
3469 const bool lhs = it.getValue();
3470 bool rhs = lhs;
3471
3472 bool isEdgeVoxel = false;
3473
3474 ijk[2] += 1; // i, j, k+1
3475 isEdgeVoxel = (maskAcc.probeValue(ijk, rhs) && lhs != rhs);
3476
3477 ijk[1] += 1; // i, j+1, k+1
3478 isEdgeVoxel = isEdgeVoxel || (maskAcc.probeValue(ijk, rhs) && lhs != rhs);
3479
3480 ijk[0] += 1; // i+1, j+1, k+1
3481 isEdgeVoxel = isEdgeVoxel || (maskAcc.probeValue(ijk, rhs) && lhs != rhs);
3482
3483 ijk[1] -= 1; // i+1, j, k+1
3484 isEdgeVoxel = isEdgeVoxel || (maskAcc.probeValue(ijk, rhs) && lhs != rhs);
3485
3486
3487 ijk[2] -= 1; // i+1, j, k
3488 isEdgeVoxel = isEdgeVoxel || (maskAcc.probeValue(ijk, rhs) && lhs != rhs);
3489
3490 ijk[1] += 1; // i+1, j+1, k
3491 isEdgeVoxel = isEdgeVoxel || (maskAcc.probeValue(ijk, rhs) && lhs != rhs);
3492
3493 ijk[0] -= 1; // i, j+1, k
3494 isEdgeVoxel = isEdgeVoxel || (maskAcc.probeValue(ijk, rhs) && lhs != rhs);
3495
3496 if (isEdgeVoxel) {
3497 ijk[1] -= 1; // i, j, k
3498 borderAcc.setValue(ijk, true);
3499 }
3500 }
3501 }
3502 }
3503
3504private:
3505 BoolTreeType const * const mMaskTree;
3506 BoolLeafNodeType const * const * const mMaskNodes;
3507
3508 BoolTreeType mTmpBorderTree;
3509 BoolTreeType * const mBorderTree;
3510}; // struct MaskBorderVoxels
3511
3512
3513template<typename BoolTreeType>
3514struct SyncMaskValues
3515{
3516 using BoolLeafNodeType = typename BoolTreeType::LeafNodeType;
3517
3518 SyncMaskValues(const std::vector<BoolLeafNodeType*>& nodes, const BoolTreeType& mask)
3519 : mNodes(nodes.data())
3520 , mMaskTree(&mask) {}
3521
3522 void operator()(const tbb::blocked_range<size_t>& range) const
3523 {
3524 using ValueOnIter = typename BoolLeafNodeType::ValueOnIter;
3525
3526 tree::ValueAccessor<const BoolTreeType> maskTreeAcc(*mMaskTree);
3527
3528 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
3529
3530 BoolLeafNodeType& node = *mNodes[n];
3531
3532 const BoolLeafNodeType * maskNode = maskTreeAcc.probeConstLeaf(node.origin());
3533
3534 if (maskNode) {
3535 for (ValueOnIter it = node.beginValueOn(); it; ++it) {
3536 const Index pos = it.pos();
3537 if (maskNode->getValue(pos)) {
3538 node.setValueOnly(pos, true);
3539 }
3540 }
3541 }
3542 }
3543 }
3544
3545private:
3546 BoolLeafNodeType * const * const mNodes;
3547 BoolTreeType const * const mMaskTree;
3548}; // struct SyncMaskValues
3549
3550
3551////////////////////////////////////////
3552
3553
3554template<typename BoolTreeType>
3555struct MaskSurface
3556{
3557 using BoolLeafNodeType = typename BoolTreeType::LeafNodeType;
3558
3559 MaskSurface(const std::vector<BoolLeafNodeType*>& nodes,
3560 const BoolTreeType& mask,
3561 const math::Transform& inputTransform,
3562 const math::Transform& maskTransform,
3563 const bool invert)
3564 : mNodes(nodes.data())
3565 , mMaskTree(&mask)
3566 , mInputTransform(inputTransform)
3567 , mMaskTransform(maskTransform)
3568 , mMatchingTransforms(mInputTransform == mMaskTransform)
3569 , mInvertMask(invert) {}
3570
3571 void operator()(const tbb::blocked_range<size_t>& range) const
3572 {
3573 using ValueOnIter = typename BoolLeafNodeType::ValueOnIter;
3574
3575 tree::ValueAccessor<const BoolTreeType> maskTreeAcc(*mMaskTree);
3576
3577 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
3578
3579 BoolLeafNodeType& node = *mNodes[n];
3580
3581 if (mMatchingTransforms) {
3582
3583 const BoolLeafNodeType * maskNode = maskTreeAcc.probeConstLeaf(node.origin());
3584
3585 if (maskNode) {
3586
3587 for (ValueOnIter it = node.beginValueOn(); it; ++it) {
3588 const Index pos = it.pos();
3589 if (maskNode->isValueOn(pos) == mInvertMask) {
3590 node.setValueOnly(pos, true);
3591 }
3592 }
3593
3594 } else {
3595
3596 if (maskTreeAcc.isValueOn(node.origin()) == mInvertMask) {
3597 for (ValueOnIter it = node.beginValueOn(); it; ++it) {
3598 node.setValueOnly(it.pos(), true);
3599 }
3600 }
3601
3602 }
3603
3604 } else {
3605
3606 Coord ijk;
3607
3608 for (ValueOnIter it = node.beginValueOn(); it; ++it) {
3609
3610 ijk = mMaskTransform.worldToIndexCellCentered(
3611 mInputTransform.indexToWorld(it.getCoord()));
3612
3613 if (maskTreeAcc.isValueOn(ijk) == mInvertMask) {
3614 node.setValueOnly(it.pos(), true);
3615 }
3616 }
3617
3618 }
3619 }
3620 }
3621
3622private:
3623 BoolLeafNodeType * const * const mNodes;
3624 BoolTreeType const * const mMaskTree;
3625 const math::Transform& mInputTransform;
3626 const math::Transform& mMaskTransform;
3627 const bool mMatchingTransforms;
3628 const bool mInvertMask;
3629}; // struct MaskSurface
3630
3631
3632template<typename InputGridType>
3633inline void
3634applySurfaceMask(
3635 typename InputGridType::TreeType::template ValueConverter<bool>::Type& intersectionTree,
3636 typename InputGridType::TreeType::template ValueConverter<bool>::Type& borderTree,
3637 const InputGridType& inputGrid,
3638 const GridBase::ConstPtr& maskGrid,
3639 const bool invertMask,
3640 const typename InputGridType::ValueType isovalue)
3641{
3642 using InputTreeType = typename InputGridType::TreeType;
3643 using BoolTreeType = typename InputTreeType::template ValueConverter<bool>::Type;
3644 using BoolLeafNodeType = typename BoolTreeType::LeafNodeType;
3645 using BoolGridType = Grid<BoolTreeType>;
3646
3647 if (!maskGrid) return;
3648 if (maskGrid->type() != BoolGridType::gridType()) return;
3649
3650 const math::Transform& transform = inputGrid.transform();
3651 const InputTreeType& inputTree = inputGrid.tree();
3652
3653 const BoolGridType * surfaceMask = static_cast<const BoolGridType*>(maskGrid.get());
3654
3655 const BoolTreeType& maskTree = surfaceMask->tree();
3656 const math::Transform& maskTransform = surfaceMask->transform();
3657
3658 // mark masked voxels
3659
3660 std::vector<BoolLeafNodeType*> intersectionLeafNodes;
3661 intersectionTree.getNodes(intersectionLeafNodes);
3662
3663 const tbb::blocked_range<size_t> intersectionRange(0, intersectionLeafNodes.size());
3664
3665 tbb::parallel_for(intersectionRange,
3666 MaskSurface<BoolTreeType>(
3667 intersectionLeafNodes, maskTree, transform, maskTransform, invertMask));
3668
3669
3670 // mask surface-mask border
3671
3672 MaskBorderVoxels<BoolTreeType> borderOp(
3673 intersectionTree, intersectionLeafNodes, borderTree);
3674 tbb::parallel_reduce(intersectionRange, borderOp);
3675
3676
3677 // recompute isosurface intersection mask
3678
3679 BoolTreeType tmpIntersectionTree(false);
3680
3681 MaskIntersectingVoxels<InputTreeType> op(
3682 inputTree, intersectionLeafNodes, tmpIntersectionTree, isovalue);
3683
3684 tbb::parallel_reduce(intersectionRange, op);
3685
3686 std::vector<BoolLeafNodeType*> tmpIntersectionLeafNodes;
3687 tmpIntersectionTree.getNodes(tmpIntersectionLeafNodes);
3688
3689 tbb::parallel_for(tbb::blocked_range<size_t>(0, tmpIntersectionLeafNodes.size()),
3690 SyncMaskValues<BoolTreeType>(tmpIntersectionLeafNodes, intersectionTree));
3691
3692 intersectionTree.clear();
3693 intersectionTree.merge(tmpIntersectionTree);
3694}
3695
3696
3697////////////////////////////////////////
3698
3699
3700template<typename InputTreeType>
3701struct ComputeAuxiliaryData
3702{
3703 using InputLeafNodeType = typename InputTreeType::LeafNodeType;
3704 using InputValueType = typename InputLeafNodeType::ValueType;
3705
3706 using BoolLeafNodeType = tree::LeafNode<bool, InputLeafNodeType::LOG2DIM>;
3707
3708 using Int16TreeType = typename InputTreeType::template ValueConverter<Int16>::Type;
3709 using Index32TreeType = typename InputTreeType::template ValueConverter<Index32>::Type;
3710
3711
3712 ComputeAuxiliaryData(const InputTreeType& inputTree,
3713 const std::vector<const BoolLeafNodeType*>& intersectionLeafNodes,
3714 Int16TreeType& signFlagsTree,
3715 Index32TreeType& pointIndexTree,
3716 InputValueType iso);
3717
3718 ComputeAuxiliaryData(ComputeAuxiliaryData&, tbb::split);
3719 void operator()(const tbb::blocked_range<size_t>&);
3720 void join(const ComputeAuxiliaryData& rhs) {
3721 mSignFlagsAccessor.tree().merge(rhs.mSignFlagsAccessor.tree());
3722 mPointIndexAccessor.tree().merge(rhs.mPointIndexAccessor.tree());
3723 }
3724
3725private:
3726 tree::ValueAccessor<const InputTreeType> mInputAccessor;
3727 BoolLeafNodeType const * const * const mIntersectionNodes;
3728
3729 Int16TreeType mSignFlagsTree;
3730 tree::ValueAccessor<Int16TreeType> mSignFlagsAccessor;
3731 Index32TreeType mPointIndexTree;
3732 tree::ValueAccessor<Index32TreeType> mPointIndexAccessor;
3733
3734 const InputValueType mIsovalue;
3735};
3736
3737
3738template<typename InputTreeType>
3739ComputeAuxiliaryData<InputTreeType>::ComputeAuxiliaryData(
3740 const InputTreeType& inputTree,
3741 const std::vector<const BoolLeafNodeType*>& intersectionLeafNodes,
3742 Int16TreeType& signFlagsTree,
3743 Index32TreeType& pointIndexTree,
3744 InputValueType iso)
3745 : mInputAccessor(inputTree)
3746 , mIntersectionNodes(intersectionLeafNodes.data())
3747 , mSignFlagsTree(0)
3748 , mSignFlagsAccessor(signFlagsTree)
3749 , mPointIndexTree(std::numeric_limits<Index32>::max())
3750 , mPointIndexAccessor(pointIndexTree)
3751 , mIsovalue(iso)
3752{
3753 pointIndexTree.root().setBackground(std::numeric_limits<Index32>::max(), false);
3754}
3755
3756
3757template<typename InputTreeType>
3758ComputeAuxiliaryData<InputTreeType>::ComputeAuxiliaryData(ComputeAuxiliaryData& rhs, tbb::split)
3759 : mInputAccessor(rhs.mInputAccessor.tree())
3760 , mIntersectionNodes(rhs.mIntersectionNodes)
3761 , mSignFlagsTree(0)
3762 , mSignFlagsAccessor(mSignFlagsTree)
3763 , mPointIndexTree(std::numeric_limits<Index32>::max())
3764 , mPointIndexAccessor(mPointIndexTree)
3765 , mIsovalue(rhs.mIsovalue)
3766{
3767}
3768
3769
3770template<typename InputTreeType>
3771void
3772ComputeAuxiliaryData<InputTreeType>::operator()(const tbb::blocked_range<size_t>& range)
3773{
3774 using Int16LeafNodeType = typename Int16TreeType::LeafNodeType;
3775
3776 Coord ijk;
3777 std::array<InputValueType, 8> cellVertexValues;
3778 std::unique_ptr<Int16LeafNodeType> signsNodePt(nullptr);
3779
3780 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
3781
3782 const BoolLeafNodeType& maskNode = *mIntersectionNodes[n];
3783 const Coord& origin = maskNode.origin();
3784
3785 const InputLeafNodeType* leafPt = mInputAccessor.probeConstLeaf(origin);
3786
3787 if (!signsNodePt.get()) signsNodePt.reset(new Int16LeafNodeType(origin, 0));
3788 else signsNodePt->setOrigin(origin);
3789
3790 bool updatedNode = false;
3791
3792 for (auto it = maskNode.cbeginValueOn(); it; ++it) {
3793
3794 const Index pos = it.pos();
3795 ijk = BoolLeafNodeType::offsetToLocalCoord(pos);
3796
3797 const bool inclusiveCell = leafPt && isInternalLeafCoord<InputLeafNodeType>(ijk);
3798
3799 if (inclusiveCell) getCellVertexValues(*leafPt, pos, cellVertexValues);
3800 else getCellVertexValues(mInputAccessor, origin + ijk, cellVertexValues);
3801
3802 uint8_t signFlags = computeSignFlags(cellVertexValues, mIsovalue);
3803
3804 if (signFlags != 0 && signFlags != 0xFF) {
3805
3806 const bool inside = signFlags & 0x1;
3807
3808 int edgeFlags = inside ? INSIDE : 0;
3809
3810 if (!it.getValue()) {
3811 edgeFlags |= inside != ((signFlags & 0x02) != 0) ? XEDGE : 0;
3812 edgeFlags |= inside != ((signFlags & 0x10) != 0) ? YEDGE : 0;
3813 edgeFlags |= inside != ((signFlags & 0x08) != 0) ? ZEDGE : 0;
3814 }
3815
3816 const uint8_t ambiguousCellFlags = sAmbiguousFace[signFlags];
3817 if (ambiguousCellFlags != 0) {
3818 correctCellSigns(signFlags, ambiguousCellFlags, mInputAccessor,
3819 origin + ijk, mIsovalue);
3820 }
3821
3822 edgeFlags |= int(signFlags);
3823
3824 signsNodePt->setValueOn(pos, Int16(edgeFlags));
3825 updatedNode = true;
3826 }
3827 }
3828
3829 if (updatedNode) {
3830 typename Index32TreeType::LeafNodeType* idxNode =
3831 mPointIndexAccessor.touchLeaf(origin);
3832 idxNode->topologyUnion(*signsNodePt);
3833
3834 // zero fill
3835 auto* const idxData = idxNode->buffer().data();
3836 for (auto it = idxNode->beginValueOn(); it; ++it) {
3837 idxData[it.pos()] = 0;
3838 }
3839
3840 mSignFlagsAccessor.addLeaf(signsNodePt.release());
3841 }
3842 }
3843} // ComputeAuxiliaryData::operator()
3844
3845
3846template<typename InputTreeType>
3847inline void
3848computeAuxiliaryData(
3849 typename InputTreeType::template ValueConverter<Int16>::Type& signFlagsTree,
3850 typename InputTreeType::template ValueConverter<Index32>::Type& pointIndexTree,
3851 const typename InputTreeType::template ValueConverter<bool>::Type& intersectionTree,
3852 const InputTreeType& inputTree,
3853 typename InputTreeType::ValueType isovalue)
3854{
3855 using BoolTreeType = typename InputTreeType::template ValueConverter<bool>::Type;
3856 using BoolLeafNodeType = typename BoolTreeType::LeafNodeType;
3857
3858 std::vector<const BoolLeafNodeType*> intersectionLeafNodes;
3859 intersectionTree.getNodes(intersectionLeafNodes);
3860
3861 ComputeAuxiliaryData<InputTreeType> op(
3862 inputTree, intersectionLeafNodes, signFlagsTree, pointIndexTree, isovalue);
3863
3864 tbb::parallel_reduce(tbb::blocked_range<size_t>(0, intersectionLeafNodes.size()), op);
3865}
3866
3867
3868////////////////////////////////////////
3869
3870
3871template<Index32 LeafNodeLog2Dim>
3872struct LeafNodePointCount
3873{
3874 using Int16LeafNodeType = tree::LeafNode<Int16, LeafNodeLog2Dim>;
3875
3876 LeafNodePointCount(const std::vector<Int16LeafNodeType*>& leafNodes,
3877 std::unique_ptr<Index32[]>& leafNodeCount)
3878 : mLeafNodes(leafNodes.data())
3879 , mData(leafNodeCount.get()) {}
3880
3881 void operator()(const tbb::blocked_range<size_t>& range) const {
3882
3883 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
3884
3885 Index32 count = 0;
3886
3887 Int16 const * p = mLeafNodes[n]->buffer().data();
3888 Int16 const * const endP = p + Int16LeafNodeType::SIZE;
3889
3890 while (p < endP) {
3891 count += Index32(sEdgeGroupTable[(SIGNS & *p)][0]);
3892 ++p;
3893 }
3894
3895 mData[n] = count;
3896 }
3897 }
3898
3899private:
3900 Int16LeafNodeType * const * const mLeafNodes;
3901 Index32 *mData;
3902}; // struct LeafNodePointCount
3903
3904
3905template<typename PointIndexLeafNode>
3906struct AdaptiveLeafNodePointCount
3907{
3908 using Int16LeafNodeType = tree::LeafNode<Int16, PointIndexLeafNode::LOG2DIM>;
3909
3910 AdaptiveLeafNodePointCount(const std::vector<PointIndexLeafNode*>& pointIndexNodes,
3911 const std::vector<Int16LeafNodeType*>& signDataNodes,
3912 std::unique_ptr<Index32[]>& leafNodeCount)
3913 : mPointIndexNodes(pointIndexNodes.data())
3914 , mSignDataNodes(signDataNodes.data())
3915 , mData(leafNodeCount.get()) {}
3916
3917 void operator()(const tbb::blocked_range<size_t>& range) const
3918 {
3919 using IndexType = typename PointIndexLeafNode::ValueType;
3920
3921 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
3922
3923 const PointIndexLeafNode& node = *mPointIndexNodes[n];
3924 const Int16LeafNodeType& signNode = *mSignDataNodes[n];
3925
3926 size_t count = 0;
3927
3928 std::set<IndexType> uniqueRegions;
3929
3930 for (typename PointIndexLeafNode::ValueOnCIter it = node.cbeginValueOn(); it; ++it) {
3931
3932 IndexType id = it.getValue();
3933
3934 if (id == 0) {
3935 count += size_t(sEdgeGroupTable[(SIGNS & signNode.getValue(it.pos()))][0]);
3936 } else if (id != IndexType(util::INVALID_IDX)) {
3937 uniqueRegions.insert(id);
3938 }
3939 }
3940
3941 mData[n] = Index32(count + uniqueRegions.size());
3942 }
3943 }
3944
3945private:
3946 PointIndexLeafNode const * const * const mPointIndexNodes;
3947 Int16LeafNodeType const * const * const mSignDataNodes;
3948 Index32 *mData;
3949}; // struct AdaptiveLeafNodePointCount
3950
3951
3952template<typename PointIndexLeafNode>
3953struct MapPoints
3954{
3955 using Int16LeafNodeType = tree::LeafNode<Int16, PointIndexLeafNode::LOG2DIM>;
3956
3957 MapPoints(const std::vector<PointIndexLeafNode*>& pointIndexNodes,
3958 const std::vector<Int16LeafNodeType*>& signDataNodes,
3959 std::unique_ptr<Index32[]>& leafNodeCount)
3960 : mPointIndexNodes(pointIndexNodes.data())
3961 , mSignDataNodes(signDataNodes.data())
3962 , mData(leafNodeCount.get()) {}
3963
3964 void operator()(const tbb::blocked_range<size_t>& range) const {
3965
3966 for (size_t n = range.begin(), N = range.end(); n != N; ++n) {
3967
3968 const Int16LeafNodeType& signNode = *mSignDataNodes[n];
3969 PointIndexLeafNode& indexNode = *mPointIndexNodes[n];
3970
3971 Index32 pointOffset = mData[n];
3972
3973 for (auto it = indexNode.beginValueOn(); it; ++it) {
3974 const Index pos = it.pos();
3975 indexNode.setValueOnly(pos, pointOffset);
3976 const int signs = SIGNS & int(signNode.getValue(pos));
3977 pointOffset += Index32(sEdgeGroupTable[signs][0]);
3978 }
3979 }
3980 }
3981
3982private:
3983 PointIndexLeafNode * const * const mPointIndexNodes;
3984 Int16LeafNodeType const * const * const mSignDataNodes;
3985 Index32 * const mData;
3986}; // struct MapPoints
3987
3988
3989template<typename TreeType, typename PrimBuilder>
3990struct ComputePolygons
3991{
3992 using Int16TreeType = typename TreeType::template ValueConverter<Int16>::Type;
3993 using Int16LeafNodeType = typename Int16TreeType::LeafNodeType;
3994
3995 using Index32TreeType = typename TreeType::template ValueConverter<Index32>::Type;
3996 using Index32LeafNodeType = typename Index32TreeType::LeafNodeType;
3997
3998 ComputePolygons(
3999 const std::vector<Int16LeafNodeType*>& signFlagsLeafNodes,
4000 const Int16TreeType& signFlagsTree,
4001 const Index32TreeType& idxTree,
4002 PolygonPoolList& polygons,
4003 bool invertSurfaceOrientation);
4004
4005 void setRefSignTree(const Int16TreeType * r) { mRefSignFlagsTree = r; }
4006
4007 void operator()(const tbb::blocked_range<size_t>&) const;
4008
4009private:
4010 Int16LeafNodeType * const * const mSignFlagsLeafNodes;
4011 Int16TreeType const * const mSignFlagsTree;
4012 Int16TreeType const * mRefSignFlagsTree;
4013 Index32TreeType const * const mIndexTree;
4014 PolygonPoolList * const mPolygonPoolList;
4015 bool const mInvertSurfaceOrientation;
4016}; // struct ComputePolygons
4017
4018
4019template<typename TreeType, typename PrimBuilder>
4020ComputePolygons<TreeType, PrimBuilder>::ComputePolygons(
4021 const std::vector<Int16LeafNodeType*>& signFlagsLeafNodes,
4022 const Int16TreeType& signFlagsTree,
4023 const Index32TreeType& idxTree,
4024 PolygonPoolList& polygons,
4025 bool invertSurfaceOrientation)
4026 : mSignFlagsLeafNodes(signFlagsLeafNodes.data())
4027 , mSignFlagsTree(&signFlagsTree)
4028 , mRefSignFlagsTree(nullptr)
4029 , mIndexTree(&idxTree)
4030 , mPolygonPoolList(&polygons)
4031 , mInvertSurfaceOrientation(invertSurfaceOrientation)
4032{
4033}
4034
4035template<typename InputTreeType, typename PrimBuilder>
4036void
4037ComputePolygons<InputTreeType, PrimBuilder>::operator()(const tbb::blocked_range<size_t>& range) const
4038{
4039 using Int16ValueAccessor = tree::ValueAccessor<const Int16TreeType>;
4040 Int16ValueAccessor signAcc(*mSignFlagsTree);
4041
4043
4044 const bool invertSurfaceOrientation = mInvertSurfaceOrientation;
4045
4046 PrimBuilder mesher;
4047 size_t edgeCount;
4048 Coord ijk, origin;
4049
4050 // reference data
4051 std::unique_ptr<Int16ValueAccessor> refSignAcc;
4052 if (mRefSignFlagsTree) refSignAcc.reset(new Int16ValueAccessor(*mRefSignFlagsTree));
4053
4054 for (size_t n = range.begin(); n != range.end(); ++n) {
4055
4056 const Int16LeafNodeType& node = *mSignFlagsLeafNodes[n];
4057 origin = node.origin();
4058
4059 // Get an upper bound on the number of primitives.
4060 edgeCount = 0;
4061 typename Int16LeafNodeType::ValueOnCIter iter = node.cbeginValueOn();
4062 for (; iter; ++iter) {
4063 if (iter.getValue() & XEDGE) ++edgeCount;
4064 if (iter.getValue() & YEDGE) ++edgeCount;
4065 if (iter.getValue() & ZEDGE) ++edgeCount;
4066 }
4067
4068 if (edgeCount == 0) continue;
4069
4070 mesher.init(edgeCount, (*mPolygonPoolList)[n]);
4071
4072 const Int16LeafNodeType *signleafPt = signAcc.probeConstLeaf(origin);
4073 const Index32LeafNodeType *idxLeafPt = idxAcc.probeConstLeaf(origin);
4074
4075 if (!signleafPt || !idxLeafPt) continue;
4076
4077 const Int16LeafNodeType *refSignLeafPt = nullptr;
4078 if (refSignAcc) refSignLeafPt = refSignAcc->probeConstLeaf(origin);
4079
4080 Vec3i offsets;
4081
4082 for (iter = node.cbeginValueOn(); iter; ++iter) {
4083 ijk = iter.getCoord();
4084
4085 const Int16 flags = iter.getValue();
4086 if (!(flags & 0xE00)) continue;
4087
4088 Int16 refFlags = 0;
4089 if (refSignLeafPt) {
4090 refFlags = refSignLeafPt->getValue(iter.pos());
4091 }
4092
4093 const uint8_t cell = uint8_t(SIGNS & flags);
4094
4095 if (sEdgeGroupTable[cell][0] > 1) {
4096 offsets[0] = (sEdgeGroupTable[cell][1] - 1);
4097 offsets[1] = (sEdgeGroupTable[cell][9] - 1);
4098 offsets[2] = (sEdgeGroupTable[cell][4] - 1);
4099 }
4100 else {
4101 offsets.setZero();
4102 }
4103
4104 if (ijk[0] > origin[0] && ijk[1] > origin[1] && ijk[2] > origin[2]) {
4105 constructPolygons(invertSurfaceOrientation,
4106 flags, refFlags, offsets, ijk, *signleafPt, *idxLeafPt, mesher);
4107 } else {
4108 constructPolygons(invertSurfaceOrientation,
4109 flags, refFlags, offsets, ijk, signAcc, idxAcc, mesher);
4110 }
4111 }
4112
4113 mesher.done();
4114 }
4115
4116} // ComputePolygons::operator()
4117
4118
4119////////////////////////////////////////
4120
4121
4122template<typename T>
4123struct CopyArray
4124{
4125 CopyArray(T * outputArray, const T * inputArray, size_t outputOffset = 0)
4126 : mOutputArray(outputArray), mInputArray(inputArray), mOutputOffset(outputOffset)
4127 {
4128 }
4129
4130 void operator()(const tbb::blocked_range<size_t>& inputArrayRange) const
4131 {
4132 const size_t offset = mOutputOffset;
4133 for (size_t n = inputArrayRange.begin(), N = inputArrayRange.end(); n < N; ++n) {
4134 mOutputArray[offset + n] = mInputArray[n];
4135 }
4136 }
4137
4138private:
4139 T * const mOutputArray;
4140 T const * const mInputArray;
4141 size_t const mOutputOffset;
4142}; // struct CopyArray
4143
4144
4145struct FlagAndCountQuadsToSubdivide
4146{
4147 FlagAndCountQuadsToSubdivide(PolygonPoolList& polygons,
4148 const std::vector<uint8_t>& pointFlags,
4149 std::unique_ptr<openvdb::Vec3s[]>& points,
4150 std::unique_ptr<unsigned[]>& numQuadsToDivide)
4151 : mPolygonPoolList(&polygons)
4152 , mPointFlags(pointFlags.data())
4153 , mPoints(points.get())
4154 , mNumQuadsToDivide(numQuadsToDivide.get())
4155 {
4156 }
4157
4158 void operator()(const tbb::blocked_range<size_t>& range) const
4159 {
4160 for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
4161
4162 PolygonPool& polygons = (*mPolygonPoolList)[n];
4163
4164 unsigned count = 0;
4165
4166 // count and tag nonplanar seam line quads.
4167 for (size_t i = 0, I = polygons.numQuads(); i < I; ++i) {
4168
4169 char& flags = polygons.quadFlags(i);
4170
4171 if ((flags & POLYFLAG_FRACTURE_SEAM) && !(flags & POLYFLAG_EXTERIOR)) {
4172
4173 Vec4I& quad = polygons.quad(i);
4174
4175 const bool edgePoly = mPointFlags[quad[0]] || mPointFlags[quad[1]]
4176 || mPointFlags[quad[2]] || mPointFlags[quad[3]];
4177
4178 if (!edgePoly) continue;
4179
4180 const Vec3s& p0 = mPoints[quad[0]];
4181 const Vec3s& p1 = mPoints[quad[1]];
4182 const Vec3s& p2 = mPoints[quad[2]];
4183 const Vec3s& p3 = mPoints[quad[3]];
4184
4185 if (!isPlanarQuad(p0, p1, p2, p3, 1e-6f)) {
4186 flags |= POLYFLAG_SUBDIVIDED;
4187 count++;
4188 }
4189 }
4190 }
4191
4192 mNumQuadsToDivide[n] = count;
4193 }
4194 }
4195
4196private:
4197 PolygonPoolList * const mPolygonPoolList;
4198 uint8_t const * const mPointFlags;
4199 Vec3s const * const mPoints;
4200 unsigned * const mNumQuadsToDivide;
4201}; // struct FlagAndCountQuadsToSubdivide
4202
4203
4204struct SubdivideQuads
4205{
4206 SubdivideQuads(PolygonPoolList& polygons,
4207 const std::unique_ptr<openvdb::Vec3s[]>& points,
4208 size_t pointCount,
4209 std::unique_ptr<openvdb::Vec3s[]>& centroids,
4210 std::unique_ptr<unsigned[]>& numQuadsToDivide,
4211 std::unique_ptr<unsigned[]>& centroidOffsets)
4212 : mPolygonPoolList(&polygons)
4213 , mPoints(points.get())
4214 , mCentroids(centroids.get())
4215 , mNumQuadsToDivide(numQuadsToDivide.get())
4216 , mCentroidOffsets(centroidOffsets.get())
4217 , mPointCount(pointCount)
4218 {
4219 }
4220
4221 void operator()(const tbb::blocked_range<size_t>& range) const
4222 {
4223 for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
4224
4225 PolygonPool& polygons = (*mPolygonPoolList)[n];
4226
4227 const size_t nonplanarCount = size_t(mNumQuadsToDivide[n]);
4228
4229 if (nonplanarCount > 0) {
4230
4231 PolygonPool tmpPolygons;
4232 tmpPolygons.resetQuads(polygons.numQuads() - nonplanarCount);
4233 tmpPolygons.resetTriangles(polygons.numTriangles() + size_t(4) * nonplanarCount);
4234
4235 size_t offset = mCentroidOffsets[n];
4236
4237 size_t triangleIdx = 0;
4238
4239 for (size_t i = 0, I = polygons.numQuads(); i < I; ++i) {
4240
4241 const char quadFlags = polygons.quadFlags(i);
4242 if (!(quadFlags & POLYFLAG_SUBDIVIDED)) continue;
4243
4244 unsigned newPointIdx = unsigned(offset + mPointCount);
4245
4246 openvdb::Vec4I& quad = polygons.quad(i);
4247
4248 mCentroids[offset] = (mPoints[quad[0]] + mPoints[quad[1]] +
4249 mPoints[quad[2]] + mPoints[quad[3]]) * 0.25f;
4250
4251 ++offset;
4252
4253 {
4254 Vec3I& triangle = tmpPolygons.triangle(triangleIdx);
4255
4256 triangle[0] = quad[0];
4257 triangle[1] = newPointIdx;
4258 triangle[2] = quad[3];
4259
4260 tmpPolygons.triangleFlags(triangleIdx) = quadFlags;
4261 }
4262
4263 ++triangleIdx;
4264
4265 {
4266 Vec3I& triangle = tmpPolygons.triangle(triangleIdx);
4267
4268 triangle[0] = quad[0];
4269 triangle[1] = quad[1];
4270 triangle[2] = newPointIdx;
4271
4272 tmpPolygons.triangleFlags(triangleIdx) = quadFlags;
4273 }
4274
4275 ++triangleIdx;
4276
4277 {
4278 Vec3I& triangle = tmpPolygons.triangle(triangleIdx);
4279
4280 triangle[0] = quad[1];
4281 triangle[1] = quad[2];
4282 triangle[2] = newPointIdx;
4283
4284 tmpPolygons.triangleFlags(triangleIdx) = quadFlags;
4285 }
4286
4287
4288 ++triangleIdx;
4289
4290 {
4291 Vec3I& triangle = tmpPolygons.triangle(triangleIdx);
4292
4293 triangle[0] = quad[2];
4294 triangle[1] = quad[3];
4295 triangle[2] = newPointIdx;
4296
4297 tmpPolygons.triangleFlags(triangleIdx) = quadFlags;
4298 }
4299
4300 ++triangleIdx;
4301
4302 quad[0] = util::INVALID_IDX; // mark for deletion
4303 }
4304
4305
4306 for (size_t i = 0, I = polygons.numTriangles(); i < I; ++i) {
4307 tmpPolygons.triangle(triangleIdx) = polygons.triangle(i);
4308 tmpPolygons.triangleFlags(triangleIdx) = polygons.triangleFlags(i);
4309 ++triangleIdx;
4310 }
4311
4312 size_t quadIdx = 0;
4313 for (size_t i = 0, I = polygons.numQuads(); i < I; ++i) {
4314 openvdb::Vec4I& quad = polygons.quad(i);
4315
4316 if (quad[0] != util::INVALID_IDX) { // ignore invalid quads
4317 tmpPolygons.quad(quadIdx) = quad;
4318 tmpPolygons.quadFlags(quadIdx) = polygons.quadFlags(i);
4319 ++quadIdx;
4320 }
4321 }
4322
4323 polygons.copy(tmpPolygons);
4324 }
4325 }
4326 }
4327
4328private:
4329 PolygonPoolList * const mPolygonPoolList;
4330 Vec3s const * const mPoints;
4331 Vec3s * const mCentroids;
4332 unsigned * const mNumQuadsToDivide;
4333 unsigned * const mCentroidOffsets;
4334 size_t const mPointCount;
4335}; // struct SubdivideQuads
4336
4337
4338inline void
4339subdivideNonplanarSeamLineQuads(
4340 PolygonPoolList& polygonPoolList,
4341 size_t polygonPoolListSize,
4342 PointList& pointList,
4343 size_t& pointListSize,
4344 std::vector<uint8_t>& pointFlags)
4345{
4346 const tbb::blocked_range<size_t> polygonPoolListRange(0, polygonPoolListSize);
4347
4348 std::unique_ptr<unsigned[]> numQuadsToDivide(new unsigned[polygonPoolListSize]);
4349
4350 tbb::parallel_for(polygonPoolListRange,
4351 FlagAndCountQuadsToSubdivide(polygonPoolList, pointFlags, pointList, numQuadsToDivide));
4352
4353 std::unique_ptr<unsigned[]> centroidOffsets(new unsigned[polygonPoolListSize]);
4354
4355 size_t centroidCount = 0;
4356
4357 {
4358 unsigned sum = 0;
4359 for (size_t n = 0, N = polygonPoolListSize; n < N; ++n) {
4360 centroidOffsets[n] = sum;
4361 sum += numQuadsToDivide[n];
4362 }
4363 centroidCount = size_t(sum);
4364 }
4365
4366 std::unique_ptr<Vec3s[]> centroidList(new Vec3s[centroidCount]);
4367
4368 tbb::parallel_for(polygonPoolListRange,
4369 SubdivideQuads(polygonPoolList, pointList, pointListSize,
4370 centroidList, numQuadsToDivide, centroidOffsets));
4371
4372 if (centroidCount > 0) {
4373
4374 const size_t newPointListSize = centroidCount + pointListSize;
4375
4376 std::unique_ptr<openvdb::Vec3s[]> newPointList(new openvdb::Vec3s[newPointListSize]);
4377
4378 tbb::parallel_for(tbb::blocked_range<size_t>(0, pointListSize),
4379 CopyArray<Vec3s>(newPointList.get(), pointList.get()));
4380
4381 tbb::parallel_for(tbb::blocked_range<size_t>(0, newPointListSize - pointListSize),
4382 CopyArray<Vec3s>(newPointList.get(), centroidList.get(), pointListSize));
4383
4384 pointListSize = newPointListSize;
4385 pointList.swap(newPointList);
4386 pointFlags.resize(pointListSize, 0);
4387 }
4388}
4389
4390
4391struct ReviseSeamLineFlags
4392{
4393 ReviseSeamLineFlags(PolygonPoolList& polygons,
4394 const std::vector<uint8_t>& pointFlags)
4395 : mPolygonPoolList(&polygons)
4396 , mPointFlags(pointFlags.data())
4397 {
4398 }
4399
4400 void operator()(const tbb::blocked_range<size_t>& range) const
4401 {
4402 for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
4403
4404 PolygonPool& polygons = (*mPolygonPoolList)[n];
4405
4406 for (size_t i = 0, I = polygons.numQuads(); i < I; ++i) {
4407
4408 char& flags = polygons.quadFlags(i);
4409
4410 if (flags & POLYFLAG_FRACTURE_SEAM) {
4411
4412 openvdb::Vec4I& verts = polygons.quad(i);
4413
4414 const bool hasSeamLinePoint =
4415 mPointFlags[verts[0]] || mPointFlags[verts[1]] ||
4416 mPointFlags[verts[2]] || mPointFlags[verts[3]];
4417
4418 if (!hasSeamLinePoint) {
4419 flags &= ~POLYFLAG_FRACTURE_SEAM;
4420 }
4421 }
4422 } // end quad loop
4423
4424 for (size_t i = 0, I = polygons.numTriangles(); i < I; ++i) {
4425
4426 char& flags = polygons.triangleFlags(i);
4427
4428 if (flags & POLYFLAG_FRACTURE_SEAM) {
4429
4430 openvdb::Vec3I& verts = polygons.triangle(i);
4431
4432 const bool hasSeamLinePoint =
4433 mPointFlags[verts[0]] || mPointFlags[verts[1]] || mPointFlags[verts[2]];
4434
4435 if (!hasSeamLinePoint) {
4436 flags &= ~POLYFLAG_FRACTURE_SEAM;
4437 }
4438
4439 }
4440 } // end triangle loop
4441
4442 } // end polygon pool loop
4443 }
4444
4445private:
4446 PolygonPoolList * const mPolygonPoolList;
4447 uint8_t const * const mPointFlags;
4448}; // struct ReviseSeamLineFlags
4449
4450
4451inline void
4452reviseSeamLineFlags(PolygonPoolList& polygonPoolList, size_t polygonPoolListSize,
4453 std::vector<uint8_t>& pointFlags)
4454{
4455 tbb::parallel_for(tbb::blocked_range<size_t>(0, polygonPoolListSize),
4456 ReviseSeamLineFlags(polygonPoolList, pointFlags));
4457}
4458
4459
4460////////////////////////////////////////
4461
4462
4463template<typename InputTreeType>
4464struct MaskDisorientedTrianglePoints
4465{
4466 MaskDisorientedTrianglePoints(const InputTreeType& inputTree, const PolygonPoolList& polygons,
4467 const PointList& pointList, std::unique_ptr<uint8_t[]>& pointMask,
4468 const math::Transform& transform, bool invertSurfaceOrientation)
4469 : mInputTree(&inputTree)
4470 , mPolygonPoolList(&polygons)
4471 , mPointList(&pointList)
4472 , mPointMask(pointMask.get())
4473 , mTransform(transform)
4474 , mInvertSurfaceOrientation(invertSurfaceOrientation)
4475 {
4476 }
4477
4478 void operator()(const tbb::blocked_range<size_t>& range) const
4479 {
4480 using ValueType = typename InputTreeType::LeafNodeType::ValueType;
4481
4482 tree::ValueAccessor<const InputTreeType> inputAcc(*mInputTree);
4483 Vec3s centroid, normal;
4484 Coord ijk;
4485
4486 const bool invertGradientDir = mInvertSurfaceOrientation || isBoolValue<ValueType>();
4487
4488 for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
4489
4490 const PolygonPool& polygons = (*mPolygonPoolList)[n];
4491
4492 for (size_t i = 0, I = polygons.numTriangles(); i < I; ++i) {
4493
4494 const Vec3I& verts = polygons.triangle(i);
4495
4496 const Vec3s& v0 = (*mPointList)[verts[0]];
4497 const Vec3s& v1 = (*mPointList)[verts[1]];
4498 const Vec3s& v2 = (*mPointList)[verts[2]];
4499
4500 normal = (v2 - v0).cross((v1 - v0));
4501 normal.normalize();
4502
4503 centroid = (v0 + v1 + v2) * (1.0f / 3.0f);
4504 ijk = mTransform.worldToIndexCellCentered(centroid);
4505
4506 Vec3s dir( math::ISGradient<math::CD_2ND>::result(inputAcc, ijk) );
4507 dir.normalize();
4508
4509 if (invertGradientDir) {
4510 dir = -dir;
4511 }
4512
4513 // check if the angle is obtuse
4514 if (dir.dot(normal) < -0.5f) {
4515 // Concurrent writes to same memory address can occur, but
4516 // all threads are writing the same value and char is atomic.
4517 // (It is extremely rare that disoriented triangles share points,
4518 // false sharing related performance impacts are not a concern.)
4519 mPointMask[verts[0]] = 1;
4520 mPointMask[verts[1]] = 1;
4521 mPointMask[verts[2]] = 1;
4522 }
4523
4524 } // end triangle loop
4525
4526 } // end polygon pool loop
4527 }
4528
4529private:
4530 InputTreeType const * const mInputTree;
4531 PolygonPoolList const * const mPolygonPoolList;
4532 PointList const * const mPointList;
4533 uint8_t * const mPointMask;
4534 math::Transform const mTransform;
4535 bool const mInvertSurfaceOrientation;
4536}; // struct MaskDisorientedTrianglePoints
4537
4538
4539template<typename InputTree>
4540inline void
4541relaxDisorientedTriangles(
4542 bool invertSurfaceOrientation,
4543 const InputTree& inputTree,
4544 const math::Transform& transform,
4545 PolygonPoolList& polygonPoolList,
4546 size_t polygonPoolListSize,
4547 PointList& pointList,
4548 const size_t pointListSize)
4549{
4550 const tbb::blocked_range<size_t> polygonPoolListRange(0, polygonPoolListSize);
4551
4552 std::unique_ptr<uint8_t[]> pointMask(new uint8_t[pointListSize]);
4553 fillArray(pointMask.get(), uint8_t(0), pointListSize);
4554
4555 tbb::parallel_for(polygonPoolListRange,
4556 MaskDisorientedTrianglePoints<InputTree>(
4557 inputTree, polygonPoolList, pointList, pointMask, transform, invertSurfaceOrientation));
4558
4559 std::unique_ptr<uint8_t[]> pointUpdates(new uint8_t[pointListSize]);
4560 fillArray(pointUpdates.get(), uint8_t(0), pointListSize);
4561
4562 std::unique_ptr<Vec3s[]> newPoints(new Vec3s[pointListSize]);
4563 fillArray(newPoints.get(), Vec3s(0.0f, 0.0f, 0.0f), pointListSize);
4564
4565 for (size_t n = 0, N = polygonPoolListSize; n < N; ++n) {
4566
4567 PolygonPool& polygons = polygonPoolList[n];
4568
4569 for (size_t i = 0, I = polygons.numQuads(); i < I; ++i) {
4570 openvdb::Vec4I& verts = polygons.quad(i);
4571
4572 for (int v = 0; v < 4; ++v) {
4573
4574 const unsigned pointIdx = verts[v];
4575
4576 if (pointMask[pointIdx] == 1) {
4577
4578 newPoints[pointIdx] +=
4579 pointList[verts[0]] + pointList[verts[1]] +
4580 pointList[verts[2]] + pointList[verts[3]];
4581
4582 pointUpdates[pointIdx] = uint8_t(pointUpdates[pointIdx] + 4);
4583 }
4584 }
4585 }
4586
4587 for (size_t i = 0, I = polygons.numTriangles(); i < I; ++i) {
4588 openvdb::Vec3I& verts = polygons.triangle(i);
4589
4590 for (int v = 0; v < 3; ++v) {
4591
4592 const unsigned pointIdx = verts[v];
4593
4594 if (pointMask[pointIdx] == 1) {
4595 newPoints[pointIdx] +=
4596 pointList[verts[0]] + pointList[verts[1]] + pointList[verts[2]];
4597
4598 pointUpdates[pointIdx] = uint8_t(pointUpdates[pointIdx] + 3);
4599 }
4600 }
4601 }
4602 }
4603
4604 for (size_t n = 0, N = pointListSize; n < N; ++n) {
4605 if (pointUpdates[n] > 0) {
4606 const double weight = 1.0 / double(pointUpdates[n]);
4607 pointList[n] = newPoints[n] * float(weight);
4608 }
4609 }
4610}
4611
4612
4613template<typename GridType>
4614void
4615doVolumeToMesh(
4616 const GridType& grid,
4617 std::vector<Vec3s>& points,
4618 std::vector<Vec3I>& triangles,
4619 std::vector<Vec4I>& quads,
4620 double isovalue,
4621 double adaptivity,
4622 bool relaxDisorientedTriangles)
4623{
4624 static_assert(std::is_scalar<typename GridType::ValueType>::value,
4625 "volume to mesh conversion is supported only for scalar grids");
4626
4627 VolumeToMesh mesher(isovalue, adaptivity, relaxDisorientedTriangles);
4628 mesher(grid);
4629
4630 // Preallocate the point list
4631 points.clear();
4632 points.resize(mesher.pointListSize());
4633
4634 { // Copy points
4635 volume_to_mesh_internal::PointListCopy ptnCpy(mesher.pointList(), points);
4636 tbb::parallel_for(tbb::blocked_range<size_t>(0, points.size()), ptnCpy);
4637 mesher.pointList().reset(nullptr);
4638 }
4639
4640 PolygonPoolList& polygonPoolList = mesher.polygonPoolList();
4641
4642 { // Preallocate primitive lists
4643 size_t numQuads = 0, numTriangles = 0;
4644 for (size_t n = 0, N = mesher.polygonPoolListSize(); n < N; ++n) {
4645 openvdb::tools::PolygonPool& polygons = polygonPoolList[n];
4646 numTriangles += polygons.numTriangles();
4647 numQuads += polygons.numQuads();
4648 }
4649
4650 triangles.clear();
4651 triangles.resize(numTriangles);
4652 quads.clear();
4653 quads.resize(numQuads);
4654 }
4655
4656 // Copy primitives
4657 size_t qIdx = 0, tIdx = 0;
4658 for (size_t n = 0, N = mesher.polygonPoolListSize(); n < N; ++n) {
4659 openvdb::tools::PolygonPool& polygons = polygonPoolList[n];
4660
4661 for (size_t i = 0, I = polygons.numQuads(); i < I; ++i) {
4662 quads[qIdx++] = polygons.quad(i);
4663 }
4664
4665 for (size_t i = 0, I = polygons.numTriangles(); i < I; ++i) {
4666 triangles[tIdx++] = polygons.triangle(i);
4667 }
4668 }
4669}
4670
4671
4672} // volume_to_mesh_internal namespace
4673
4674/// @endcond
4675
4676////////////////////////////////////////
4677
4678
4679inline
4681 : mNumQuads(0)
4682 , mNumTriangles(0)
4683 , mQuads(nullptr)
4684 , mTriangles(nullptr)
4685 , mQuadFlags(nullptr)
4686 , mTriangleFlags(nullptr)
4687{
4688}
4689
4690
4691inline
4693 : mNumQuads(numQuads)
4694 , mNumTriangles(numTriangles)
4695 , mQuads(new openvdb::Vec4I[mNumQuads])
4696 , mTriangles(new openvdb::Vec3I[mNumTriangles])
4697 , mQuadFlags(new char[mNumQuads])
4698 , mTriangleFlags(new char[mNumTriangles])
4699{
4700}
4701
4702
4703inline void
4705{
4706 resetQuads(rhs.numQuads());
4708
4709 for (size_t i = 0; i < mNumQuads; ++i) {
4710 mQuads[i] = rhs.mQuads[i];
4711 mQuadFlags[i] = rhs.mQuadFlags[i];
4712 }
4713
4714 for (size_t i = 0; i < mNumTriangles; ++i) {
4715 mTriangles[i] = rhs.mTriangles[i];
4716 mTriangleFlags[i] = rhs.mTriangleFlags[i];
4717 }
4718}
4719
4720
4721inline void
4723{
4724 mNumQuads = size;
4725 mQuads.reset(new openvdb::Vec4I[mNumQuads]);
4726 mQuadFlags.reset(new char[mNumQuads]);
4727}
4728
4729
4730inline void
4732{
4733 mNumQuads = 0;
4734 mQuads.reset(nullptr);
4735 mQuadFlags.reset(nullptr);
4736}
4737
4738
4739inline void
4741{
4742 mNumTriangles = size;
4743 mTriangles.reset(new openvdb::Vec3I[mNumTriangles]);
4744 mTriangleFlags.reset(new char[mNumTriangles]);
4745}
4746
4747
4748inline void
4750{
4751 mNumTriangles = 0;
4752 mTriangles.reset(nullptr);
4753 mTriangleFlags.reset(nullptr);
4754}
4755
4756
4757inline bool
4758PolygonPool::trimQuads(const size_t n, bool reallocate)
4759{
4760 if (!(n < mNumQuads)) return false;
4761
4762 if (reallocate) {
4763
4764 if (n == 0) {
4765 mQuads.reset(nullptr);
4766 } else {
4767
4768 std::unique_ptr<openvdb::Vec4I[]> quads(new openvdb::Vec4I[n]);
4769 std::unique_ptr<char[]> flags(new char[n]);
4770
4771 for (size_t i = 0; i < n; ++i) {
4772 quads[i] = mQuads[i];
4773 flags[i] = mQuadFlags[i];
4774 }
4775
4776 mQuads.swap(quads);
4777 mQuadFlags.swap(flags);
4778 }
4779 }
4780
4781 mNumQuads = n;
4782 return true;
4783}
4784
4785
4786inline bool
4787PolygonPool::trimTrinagles(const size_t n, bool reallocate)
4788{
4789 if (!(n < mNumTriangles)) return false;
4790
4791 if (reallocate) {
4792
4793 if (n == 0) {
4794 mTriangles.reset(nullptr);
4795 } else {
4796
4797 std::unique_ptr<openvdb::Vec3I[]> triangles(new openvdb::Vec3I[n]);
4798 std::unique_ptr<char[]> flags(new char[n]);
4799
4800 for (size_t i = 0; i < n; ++i) {
4801 triangles[i] = mTriangles[i];
4802 flags[i] = mTriangleFlags[i];
4803 }
4804
4805 mTriangles.swap(triangles);
4806 mTriangleFlags.swap(flags);
4807 }
4808 }
4809
4810 mNumTriangles = n;
4811 return true;
4812}
4813
4814
4815////////////////////////////////////////
4816
4817
4818inline
4819VolumeToMesh::VolumeToMesh(double isovalue, double adaptivity, bool relaxDisorientedTriangles)
4820 : mPoints(nullptr)
4821 , mPolygons()
4822 , mPointListSize(0)
4823 , mSeamPointListSize(0)
4824 , mPolygonPoolListSize(0)
4825 , mIsovalue(isovalue)
4826 , mPrimAdaptivity(adaptivity)
4827 , mSecAdaptivity(0.0)
4828 , mRefGrid(GridBase::ConstPtr())
4829 , mSurfaceMaskGrid(GridBase::ConstPtr())
4830 , mAdaptivityGrid(GridBase::ConstPtr())
4831 , mAdaptivityMaskTree(TreeBase::ConstPtr())
4832 , mRefSignTree(TreeBase::Ptr())
4833 , mRefIdxTree(TreeBase::Ptr())
4834 , mInvertSurfaceMask(false)
4835 , mRelaxDisorientedTriangles(relaxDisorientedTriangles)
4836 , mQuantizedSeamPoints(nullptr)
4837 , mPointFlags(0)
4838{
4839}
4840
4841
4842inline void
4843VolumeToMesh::setRefGrid(const GridBase::ConstPtr& grid, double secAdaptivity)
4844{
4845 mRefGrid = grid;
4846 mSecAdaptivity = secAdaptivity;
4847
4848 // Clear out old auxiliary data
4849 mRefSignTree = TreeBase::Ptr();
4850 mRefIdxTree = TreeBase::Ptr();
4851 mSeamPointListSize = 0;
4852 mQuantizedSeamPoints.reset(nullptr);
4853}
4854
4855
4856inline void
4858{
4859 mSurfaceMaskGrid = mask;
4860 mInvertSurfaceMask = invertMask;
4861}
4862
4863
4864inline void
4866{
4867 mAdaptivityGrid = grid;
4868}
4869
4870
4871inline void
4873{
4874 mAdaptivityMaskTree = tree;
4875}
4876
4877
4878template<typename InputGridType>
4879inline void
4880VolumeToMesh::operator()(const InputGridType& inputGrid)
4881{
4882 // input data types
4883
4884 using InputTreeType = typename InputGridType::TreeType;
4885 using InputLeafNodeType = typename InputTreeType::LeafNodeType;
4886 using InputValueType = typename InputLeafNodeType::ValueType;
4887
4888 // auxiliary data types
4889
4890 using FloatTreeType = typename InputTreeType::template ValueConverter<float>::Type;
4891 using FloatGridType = Grid<FloatTreeType>;
4892 using BoolTreeType = typename InputTreeType::template ValueConverter<bool>::Type;
4893 using Int16TreeType = typename InputTreeType::template ValueConverter<Int16>::Type;
4894 using Int16LeafNodeType = typename Int16TreeType::LeafNodeType;
4895 using Index32TreeType = typename InputTreeType::template ValueConverter<Index32>::Type;
4896 using Index32LeafNodeType = typename Index32TreeType::LeafNodeType;
4897
4898 // clear old data
4899 mPointListSize = 0;
4900 mPoints.reset();
4901 mPolygonPoolListSize = 0;
4902 mPolygons.reset();
4903 mPointFlags.clear();
4904
4905 // settings
4906
4907 const math::Transform& transform = inputGrid.transform();
4908 const InputValueType isovalue = InputValueType(mIsovalue);
4909 const float adaptivityThreshold = float(mPrimAdaptivity);
4910 const bool adaptive = mPrimAdaptivity > 1e-7 || mSecAdaptivity > 1e-7;
4911
4912 // The default surface orientation is setup for level set and bool/mask grids.
4913 // Boolean grids are handled correctly by their value type. Signed distance fields,
4914 // unsigned distance fields and fog volumes have the same value type but use different
4915 // inside value classifications.
4916 const bool invertSurfaceOrientation = (!volume_to_mesh_internal::isBoolValue<InputValueType>()
4917 && (inputGrid.getGridClass() != openvdb::GRID_LEVEL_SET));
4918
4919 // references, masks and auxiliary data
4920
4921 const InputTreeType& inputTree = inputGrid.tree();
4922
4923 BoolTreeType intersectionTree(false), adaptivityMask(false);
4924
4925 if (mAdaptivityMaskTree && mAdaptivityMaskTree->type() == BoolTreeType::treeType()) {
4926 const BoolTreeType *refAdaptivityMask=
4927 static_cast<const BoolTreeType*>(mAdaptivityMaskTree.get());
4928 adaptivityMask.topologyUnion(*refAdaptivityMask);
4929 }
4930
4931 Int16TreeType signFlagsTree(0);
4932 Index32TreeType pointIndexTree(std::numeric_limits<Index32>::max());
4933
4934
4935 // collect auxiliary data
4936
4937 volume_to_mesh_internal::identifySurfaceIntersectingVoxels(
4938 intersectionTree, inputTree, isovalue);
4939
4940 volume_to_mesh_internal::applySurfaceMask(intersectionTree, adaptivityMask,
4941 inputGrid, mSurfaceMaskGrid, mInvertSurfaceMask, isovalue);
4942
4943 if (intersectionTree.empty()) return;
4944
4945 volume_to_mesh_internal::computeAuxiliaryData(
4946 signFlagsTree, pointIndexTree, intersectionTree, inputTree, isovalue);
4947
4948 intersectionTree.clear();
4949
4950 std::vector<Index32LeafNodeType*> pointIndexLeafNodes;
4951 pointIndexTree.getNodes(pointIndexLeafNodes);
4952
4953 std::vector<Int16LeafNodeType*> signFlagsLeafNodes;
4954 signFlagsTree.getNodes(signFlagsLeafNodes);
4955
4956 const tbb::blocked_range<size_t> auxiliaryLeafNodeRange(0, signFlagsLeafNodes.size());
4957
4958
4959 // optionally collect auxiliary data from a reference volume.
4960
4961 Int16TreeType* refSignFlagsTree = nullptr;
4962 Index32TreeType* refPointIndexTree = nullptr;
4963 InputTreeType const* refInputTree = nullptr;
4964
4965 if (mRefGrid && mRefGrid->type() == InputGridType::gridType()) {
4966
4967 const InputGridType* refGrid = static_cast<const InputGridType*>(mRefGrid.get());
4968 refInputTree = &refGrid->tree();
4969
4970 if (!mRefSignTree && !mRefIdxTree) {
4971
4972 // first time, collect and cache auxiliary data.
4973
4974 typename Int16TreeType::Ptr refSignFlagsTreePt(new Int16TreeType(0));
4975 typename Index32TreeType::Ptr refPointIndexTreePt(
4976 new Index32TreeType(std::numeric_limits<Index32>::max()));
4977
4978 BoolTreeType refIntersectionTree(false);
4979
4980 volume_to_mesh_internal::identifySurfaceIntersectingVoxels(
4981 refIntersectionTree, *refInputTree, isovalue);
4982
4983 volume_to_mesh_internal::computeAuxiliaryData(*refSignFlagsTreePt,
4984 *refPointIndexTreePt, refIntersectionTree, *refInputTree, isovalue);
4985
4986 mRefSignTree = refSignFlagsTreePt;
4987 mRefIdxTree = refPointIndexTreePt;
4988 }
4989
4990 if (mRefSignTree && mRefIdxTree) {
4991
4992 // get cached auxiliary data
4993
4994 refSignFlagsTree = static_cast<Int16TreeType*>(mRefSignTree.get());
4995 refPointIndexTree = static_cast<Index32TreeType*>(mRefIdxTree.get());
4996 }
4997
4998
4999 if (refSignFlagsTree && refPointIndexTree) {
5000
5001 // generate seam line sample points
5002
5003 volume_to_mesh_internal::markSeamLineData(signFlagsTree, *refSignFlagsTree);
5004
5005 if (mSeamPointListSize == 0) {
5006
5007 // count unique points on reference surface
5008
5009 std::vector<Int16LeafNodeType*> refSignFlagsLeafNodes;
5010 refSignFlagsTree->getNodes(refSignFlagsLeafNodes);
5011
5012 std::unique_ptr<Index32[]> leafNodeOffsets(
5013 new Index32[refSignFlagsLeafNodes.size()]);
5014
5015 tbb::parallel_for(tbb::blocked_range<size_t>(0, refSignFlagsLeafNodes.size()),
5016 volume_to_mesh_internal::LeafNodePointCount<Int16LeafNodeType::LOG2DIM>(
5017 refSignFlagsLeafNodes, leafNodeOffsets));
5018
5019 {
5020 Index32 count = 0;
5021 for (size_t n = 0, N = refSignFlagsLeafNodes.size(); n < N; ++n) {
5022 const Index32 tmp = leafNodeOffsets[n];
5023 leafNodeOffsets[n] = count;
5024 count += tmp;
5025 }
5026 mSeamPointListSize = size_t(count);
5027 }
5028
5029 if (mSeamPointListSize != 0) {
5030
5031 mQuantizedSeamPoints.reset(new uint32_t[mSeamPointListSize]);
5032
5033 std::memset(mQuantizedSeamPoints.get(), 0, sizeof(uint32_t) * mSeamPointListSize);
5034
5035 std::vector<Index32LeafNodeType*> refPointIndexLeafNodes;
5036 refPointIndexTree->getNodes(refPointIndexLeafNodes);
5037
5038 tbb::parallel_for(tbb::blocked_range<size_t>(0, refPointIndexLeafNodes.size()),
5039 volume_to_mesh_internal::MapPoints<Index32LeafNodeType>(
5040 refPointIndexLeafNodes, refSignFlagsLeafNodes, leafNodeOffsets));
5041 }
5042 }
5043
5044 if (mSeamPointListSize != 0) {
5045
5046 tbb::parallel_for(auxiliaryLeafNodeRange,
5047 volume_to_mesh_internal::SeamLineWeights<InputTreeType>(
5048 signFlagsLeafNodes, inputTree, *refPointIndexTree, *refSignFlagsTree,
5049 mQuantizedSeamPoints.get(), isovalue));
5050 }
5051 }
5052 }
5053
5054 const bool referenceMeshing = refSignFlagsTree && refPointIndexTree && refInputTree;
5055
5056
5057 // adapt and count unique points
5058
5059 std::unique_ptr<Index32[]> leafNodeOffsets(new Index32[signFlagsLeafNodes.size()]);
5060
5061 if (adaptive) {
5062 volume_to_mesh_internal::MergeVoxelRegions<InputGridType> mergeOp(
5063 inputGrid, pointIndexTree, pointIndexLeafNodes, signFlagsLeafNodes,
5064 isovalue, adaptivityThreshold, invertSurfaceOrientation);
5065
5066 if (mAdaptivityGrid && mAdaptivityGrid->type() == FloatGridType::gridType()) {
5067 const FloatGridType* adaptivityGrid =
5068 static_cast<const FloatGridType*>(mAdaptivityGrid.get());
5069 mergeOp.setSpatialAdaptivity(*adaptivityGrid);
5070 }
5071
5072 if (!adaptivityMask.empty()) {
5073 mergeOp.setAdaptivityMask(adaptivityMask);
5074 }
5075
5076 if (referenceMeshing) {
5077 mergeOp.setRefSignFlagsData(*refSignFlagsTree, float(mSecAdaptivity));
5078 }
5079
5080 tbb::parallel_for(auxiliaryLeafNodeRange, mergeOp);
5081
5082 volume_to_mesh_internal::AdaptiveLeafNodePointCount<Index32LeafNodeType>
5083 op(pointIndexLeafNodes, signFlagsLeafNodes, leafNodeOffsets);
5084
5085 tbb::parallel_for(auxiliaryLeafNodeRange, op);
5086
5087 } else {
5088
5089 volume_to_mesh_internal::LeafNodePointCount<Int16LeafNodeType::LOG2DIM>
5090 op(signFlagsLeafNodes, leafNodeOffsets);
5091
5092 tbb::parallel_for(auxiliaryLeafNodeRange, op);
5093 }
5094
5095
5096 {
5097 Index32 pointCount = 0;
5098 for (size_t n = 0, N = signFlagsLeafNodes.size(); n < N; ++n) {
5099 const Index32 tmp = leafNodeOffsets[n];
5100 leafNodeOffsets[n] = pointCount;
5101 pointCount += tmp;
5102 }
5103
5104 mPointListSize = size_t(pointCount);
5105 mPoints.reset(new openvdb::Vec3s[mPointListSize]);
5106 mPointFlags.clear();
5107 }
5108
5109
5110 // compute points
5111
5112 {
5113 volume_to_mesh_internal::ComputePoints<InputTreeType>
5114 op(mPoints.get(), inputTree, pointIndexLeafNodes,
5115 signFlagsLeafNodes, leafNodeOffsets, transform, mIsovalue);
5116
5117 if (referenceMeshing) {
5118 mPointFlags.resize(mPointListSize);
5119 op.setRefData(*refInputTree, *refPointIndexTree, *refSignFlagsTree,
5120 mQuantizedSeamPoints.get(), mPointFlags.data());
5121 }
5122
5123 tbb::parallel_for(auxiliaryLeafNodeRange, op);
5124 }
5125
5126
5127 // compute polygons
5128
5129 mPolygonPoolListSize = signFlagsLeafNodes.size();
5130 mPolygons.reset(new PolygonPool[mPolygonPoolListSize]);
5131
5132 if (adaptive) {
5133
5134 using PrimBuilder = volume_to_mesh_internal::AdaptivePrimBuilder;
5135
5136 volume_to_mesh_internal::ComputePolygons<Int16TreeType, PrimBuilder>
5137 op(signFlagsLeafNodes, signFlagsTree, pointIndexTree,
5138 mPolygons, invertSurfaceOrientation);
5139
5140 if (referenceMeshing) {
5141 op.setRefSignTree(refSignFlagsTree);
5142 }
5143
5144 tbb::parallel_for(auxiliaryLeafNodeRange, op);
5145
5146 } else {
5147
5148 using PrimBuilder = volume_to_mesh_internal::UniformPrimBuilder;
5149
5150 volume_to_mesh_internal::ComputePolygons<Int16TreeType, PrimBuilder>
5151 op(signFlagsLeafNodes, signFlagsTree, pointIndexTree,
5152 mPolygons, invertSurfaceOrientation);
5153
5154 if (referenceMeshing) {
5155 op.setRefSignTree(refSignFlagsTree);
5156 }
5157
5158 tbb::parallel_for(auxiliaryLeafNodeRange, op);
5159 }
5160
5161
5162 signFlagsTree.clear();
5163 pointIndexTree.clear();
5164
5165
5166 if (adaptive && mRelaxDisorientedTriangles) {
5167 volume_to_mesh_internal::relaxDisorientedTriangles(invertSurfaceOrientation,
5168 inputTree, transform, mPolygons, mPolygonPoolListSize, mPoints, mPointListSize);
5169 }
5170
5171
5172 if (referenceMeshing) {
5173 volume_to_mesh_internal::subdivideNonplanarSeamLineQuads(
5174 mPolygons, mPolygonPoolListSize, mPoints, mPointListSize, mPointFlags);
5175
5176 volume_to_mesh_internal::reviseSeamLineFlags(mPolygons, mPolygonPoolListSize, mPointFlags);
5177 }
5178
5179}
5180
5181
5182////////////////////////////////////////
5183
5184
5185template<typename GridType>
5187 const GridType& grid,
5188 std::vector<Vec3s>& points,
5189 std::vector<Vec3I>& triangles,
5190 std::vector<Vec4I>& quads,
5191 double isovalue,
5192 double adaptivity,
5193 bool relaxDisorientedTriangles)
5194{
5195 volume_to_mesh_internal::doVolumeToMesh(grid, points, triangles, quads,
5196 isovalue, adaptivity, relaxDisorientedTriangles);
5197}
5198
5199template<typename GridType>
5201 const GridType& grid,
5202 std::vector<Vec3s>& points,
5203 std::vector<Vec4I>& quads,
5204 double isovalue)
5205{
5206 std::vector<Vec3I> triangles;
5207 volumeToMesh(grid, points, triangles, quads, isovalue, 0.0, true);
5208}
5209
5210
5211////////////////////////////////////////
5212
5213
5214// Explicit Template Instantiation
5215
5216#ifdef OPENVDB_USE_EXPLICIT_INSTANTIATION
5217
5218#ifdef OPENVDB_INSTANTIATE_VOLUMETOMESH
5220#endif
5221
5222#define _FUNCTION(TreeT) \
5223 void volumeToMesh(const Grid<TreeT>&, std::vector<Vec3s>&, std::vector<Vec4I>&, double)
5225#undef _FUNCTION
5226
5227#define _FUNCTION(TreeT) \
5228 void volumeToMesh(const Grid<TreeT>&, std::vector<Vec3s>&, std::vector<Vec3I>&, std::vector<Vec4I>&, double, double, bool)
5230#undef _FUNCTION
5231
5232#endif // OPENVDB_USE_EXPLICIT_INSTANTIATION
5233
5234
5235} // namespace tools
5236} // namespace OPENVDB_VERSION_NAME
5237} // namespace openvdb
5238
5239#endif // OPENVDB_TOOLS_VOLUME_TO_MESH_HAS_BEEN_INCLUDED
#define OPENVDB_ASSERT(X)
Definition Assert.h:41
ValueAccessors are designed to help accelerate accesses into the OpenVDB Tree structures by storing c...
Abstract base class for typed grids.
Definition Grid.h:78
SharedPtr< const GridBase > ConstPtr
Definition Grid.h:81
Container class that associates a tree with a transform and metadata.
Definition Grid.h:571
void clear() override
Empty this grid, so that all voxels become inactive background voxels.
Definition Grid.h:727
Definition Exceptions.h:65
Axis-aligned bounding box of signed integer coordinates.
Definition Coord.h:252
Signed (x, y, z) 32-bit integer coordinates.
Definition Coord.h:26
Coord offsetBy(Int32 dx, Int32 dy, Int32 dz) const
Definition Coord.h:92
Coord & reset(Int32 x, Int32 y, Int32 z)
Reset all three coordinates with the specified arguments.
Definition Coord.h:70
Mat3 transpose() const
returns transpose of this
Definition Mat3.h:454
static const Mat3< double > & identity()
Definition Mat3.h:121
Definition Transform.h:40
Definition Vec3.h:25
T dot(const Vec3< T > &v) const
Dot product.
Definition Vec3.h:192
T & z()
Definition Vec3.h:88
bool normalize(T eps=T(1.0e-7))
this = normalized this
Definition Vec3.h:363
Definition Vec4.h:25
Collection of quads and triangles.
Definition VolumeToMesh.h:104
void copy(const PolygonPool &rhs)
Definition VolumeToMesh.h:4704
const openvdb::Vec3I & triangle(size_t n) const
Definition VolumeToMesh.h:130
void resetQuads(size_t size)
Definition VolumeToMesh.h:4722
const size_t & numTriangles() const
Definition VolumeToMesh.h:127
void clearQuads()
Definition VolumeToMesh.h:4731
void clearTriangles()
Definition VolumeToMesh.h:4749
const char & quadFlags(size_t n) const
Definition VolumeToMesh.h:136
openvdb::Vec4I & quad(size_t n)
Definition VolumeToMesh.h:123
openvdb::Vec3I & triangle(size_t n)
Definition VolumeToMesh.h:129
char & triangleFlags(size_t n)
Definition VolumeToMesh.h:138
const size_t & numQuads() const
Definition VolumeToMesh.h:121
bool trimTrinagles(const size_t n, bool reallocate=false)
Definition VolumeToMesh.h:4787
const char & triangleFlags(size_t n) const
Definition VolumeToMesh.h:139
void resetTriangles(size_t size)
Definition VolumeToMesh.h:4740
const openvdb::Vec4I & quad(size_t n) const
Definition VolumeToMesh.h:124
PolygonPool()
Definition VolumeToMesh.h:4680
char & quadFlags(size_t n)
Definition VolumeToMesh.h:135
bool trimQuads(const size_t n, bool reallocate=false)
Definition VolumeToMesh.h:4758
SharedPtr< TreeBase > Ptr
Definition Tree.h:40
SharedPtr< const TreeBase > ConstPtr
Definition Tree.h:41
Mat3< double > Mat3d
Definition Mat3.h:834
Vec3< double > Vec3d
Definition Vec3.h:665
Vec4< int32_t > Vec4i
Definition Vec4.h:559
Vec3< int32_t > Vec3i
Definition Vec3.h:662
Vec3< float > Vec3s
Definition Vec3.h:664
std::vector< Index > IndexArray
Definition PointMoveImpl.h:88
Definition AttributeArray.h:42
Index64 pointCount(const PointDataTreeT &tree, const FilterT &filter=NullFilter(), const bool inCoreOnly=false, const bool threaded=true)
Count the total number of points in a PointDataTree.
Definition PointCountImpl.h:18
const std::enable_if<!VecTraits< T >::IsVec, T >::type & max(const T &a, const T &b)
Definition Composite.h:110
OutGridT const XformOp bool bool
Definition ValueTransformer.h:610
void volumeToMesh(const GridType &grid, std::vector< Vec3s > &points, std::vector< Vec4I > &quads, double isovalue=0.0)
Uniformly mesh any scalar grid that has a continuous isosurface.
Definition VolumeToMesh.h:5200
@ POLYFLAG_FRACTURE_SEAM
Definition VolumeToMesh.h:99
@ POLYFLAG_EXTERIOR
Definition VolumeToMesh.h:99
@ POLYFLAG_SUBDIVIDED
Definition VolumeToMesh.h:99
std::unique_ptr< openvdb::Vec3s[]> PointList
Point and primitive list types.
Definition VolumeToMesh.h:161
OutGridT XformOp & op
Definition ValueTransformer.h:140
std::unique_ptr< PolygonPool[]> PolygonPoolList
Point and primitive list types.
Definition VolumeToMesh.h:162
Vec3d findFeaturePoint(const std::vector< Vec3d > &points, const std::vector< Vec3d > &normals)
Given a set of tangent elements, points with corresponding normals, this method returns the intersect...
Definition VolumeToMesh.h:280
Definition PointDataGrid.h:170
ValueAccessorImpl< TreeType, IsSafe, MutexType, openvdb::make_index_sequence< CacheLevels > > ValueAccessor
Default alias for a ValueAccessor. This is simply a helper alias for the generic definition but takes...
Definition ValueAccessor.h:86
constexpr Index32 INVALID_IDX
Definition Util.h:19
Index32 Index
Definition Types.h:54
math::Vec4< Index32 > Vec4I
Definition Types.h:88
int16_t Int16
Definition Types.h:55
@ GRID_LEVEL_SET
Definition Types.h:455
uint32_t Index32
Definition Types.h:52
math::Vec3< Index32 > Vec3I
Definition Types.h:73
tree::TreeBase TreeBase
Definition Grid.h:26
Definition Exceptions.h:13
#define OPENVDB_THROW(exception, message)
Definition Exceptions.h:74
static Vec3< typename Accessor::ValueType > result(const Accessor &grid, const Coord &ijk)
Definition Operators.h:103
Mesh any scalar grid that has a continuous isosurface.
Definition VolumeToMesh.h:171
VolumeToMesh(double isovalue=0, double adaptivity=0, bool relaxDisorientedTriangles=true)
Definition VolumeToMesh.h:4819
void setRefGrid(const GridBase::ConstPtr &grid, double secAdaptivity=0)
When surfacing fractured SDF fragments, the original unfractured SDF grid can be used to eliminate se...
Definition VolumeToMesh.h:4843
PolygonPoolList & polygonPoolList()
Definition VolumeToMesh.h:189
PointList & pointList()
Definition VolumeToMesh.h:185
size_t polygonPoolListSize() const
Definition VolumeToMesh.h:188
std::vector< uint8_t > & pointFlags()
Definition VolumeToMesh.h:192
size_t pointListSize() const
Definition VolumeToMesh.h:184
const PointList & pointList() const
Definition VolumeToMesh.h:186
const PolygonPoolList & polygonPoolList() const
Definition VolumeToMesh.h:190
void setSpatialAdaptivity(const GridBase::ConstPtr &grid)
Definition VolumeToMesh.h:4865
void operator()(const InputGridType &)
Main call.
Definition VolumeToMesh.h:4880
void setSurfaceMask(const GridBase::ConstPtr &mask, bool invertMask=false)
Definition VolumeToMesh.h:4857
void setAdaptivityMask(const TreeBase::ConstPtr &tree)
Definition VolumeToMesh.h:4872
const std::vector< uint8_t > & pointFlags() const
Definition VolumeToMesh.h:193
#define OPENVDB_VERSION_NAME
The version namespace name for this library version.
Definition version.h.in:121
#define OPENVDB_USE_VERSION_NAMESPACE
Definition version.h.in:218
#define OPENVDB_NUMERIC_TREE_INSTANTIATE(Function)
Definition version.h.in:163