mesh_operations.cpp
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34 
35 /* Author: Ioan Sucan */
36 
39 
40 #include <cstdio>
41 #include <cmath>
42 #include <algorithm>
43 #include <set>
44 #include <float.h>
45 
48 
49 #include <assimp/scene.h>
50 #include <assimp/Importer.hpp>
51 #include <assimp/postprocess.h>
52 
53 #include <Eigen/Geometry>
54 
55 #include <boost/math/constants/constants.hpp>
56 
57 namespace shapes
58 {
59 namespace detail
60 {
61 namespace
62 {
64 struct LocalVertexType
65 {
66  LocalVertexType() : x(0.0), y(0.0), z(0.0)
67  {
68  }
69 
70  LocalVertexType(const Eigen::Vector3d& v) : x(v.x()), y(v.y()), z(v.z())
71  {
72  }
73 
74  double x, y, z;
75  unsigned int index;
76 };
77 
79 struct ltLocalVertexValue
80 {
81  bool operator()(const LocalVertexType& p1, const LocalVertexType& p2) const
82  {
83  if (p1.x < p2.x)
84  return true;
85  if (p1.x > p2.x)
86  return false;
87  if (p1.y < p2.y)
88  return true;
89  if (p1.y > p2.y)
90  return false;
91  if (p1.z < p2.z)
92  return true;
93  return false;
94  }
95 };
96 
98 struct ltLocalVertexIndex
99 {
100  bool operator()(const LocalVertexType& p1, const LocalVertexType& p2) const
101  {
102  return p1.index < p2.index;
103  }
104 };
105 }
106 }
107 
108 Mesh* createMeshFromVertices(const EigenSTL::vector_Vector3d& vertices, const std::vector<unsigned int>& triangles)
109 {
110  unsigned int nt = triangles.size() / 3;
111  Mesh* mesh = new Mesh(vertices.size(), nt);
112  for (unsigned int i = 0; i < vertices.size(); ++i)
113  {
114  mesh->vertices[3 * i] = vertices[i].x();
115  mesh->vertices[3 * i + 1] = vertices[i].y();
116  mesh->vertices[3 * i + 2] = vertices[i].z();
117  }
118 
119  std::copy(triangles.begin(), triangles.end(), mesh->triangles);
120  mesh->computeTriangleNormals();
121  mesh->computeVertexNormals();
122 
123  return mesh;
124 }
125 
127 {
128  if (source.size() < 3)
129  return NULL;
130 
131  if (source.size() % 3 != 0)
132  CONSOLE_BRIDGE_logError("The number of vertices to construct a mesh from is not divisible by 3. Probably "
133  "constructed triangles will not make sense.");
134 
135  std::set<detail::LocalVertexType, detail::ltLocalVertexValue> vertices;
136  std::vector<unsigned int> triangles;
137 
138  unsigned int n = source.size() / 3;
139  for (unsigned int i = 0; i < n; ++i)
140  {
141  // check if we have new vertices
142  unsigned int i3 = i * 3;
143  detail::LocalVertexType vt1(source[i3]);
144  std::set<detail::LocalVertexType, detail::ltLocalVertexValue>::iterator p1 = vertices.find(vt1);
145  if (p1 == vertices.end())
146  {
147  vt1.index = vertices.size();
148  vertices.insert(vt1);
149  }
150  else
151  vt1.index = p1->index;
152  triangles.push_back(vt1.index);
153 
154  detail::LocalVertexType vt2(source[++i3]);
155  std::set<detail::LocalVertexType, detail::ltLocalVertexValue>::iterator p2 = vertices.find(vt2);
156  if (p2 == vertices.end())
157  {
158  vt2.index = vertices.size();
159  vertices.insert(vt2);
160  }
161  else
162  vt2.index = p2->index;
163  triangles.push_back(vt2.index);
164 
165  detail::LocalVertexType vt3(source[++i3]);
166  std::set<detail::LocalVertexType, detail::ltLocalVertexValue>::iterator p3 = vertices.find(vt3);
167  if (p3 == vertices.end())
168  {
169  vt3.index = vertices.size();
170  vertices.insert(vt3);
171  }
172  else
173  vt3.index = p3->index;
174 
175  triangles.push_back(vt3.index);
176  }
177 
178  // sort our vertices
179  std::vector<detail::LocalVertexType> vt;
180  vt.insert(vt.end(), vertices.begin(), vertices.end());
181  std::sort(vt.begin(), vt.end(), detail::ltLocalVertexIndex());
182 
183  // copy the data to a mesh structure
184  unsigned int nt = triangles.size() / 3;
185 
186  Mesh* mesh = new Mesh(vt.size(), nt);
187  for (unsigned int i = 0; i < vt.size(); ++i)
188  {
189  unsigned int i3 = i * 3;
190  mesh->vertices[i3] = vt[i].x;
191  mesh->vertices[i3 + 1] = vt[i].y;
192  mesh->vertices[i3 + 2] = vt[i].z;
193  }
194 
195  std::copy(triangles.begin(), triangles.end(), mesh->triangles);
196  mesh->computeTriangleNormals();
197  mesh->computeVertexNormals();
198 
199  return mesh;
200 }
201 
202 Mesh* createMeshFromResource(const std::string& resource)
203 {
204  static const Eigen::Vector3d one(1.0, 1.0, 1.0);
205  return createMeshFromResource(resource, one);
206 }
207 
208 Mesh* createMeshFromBinary(const char* buffer, std::size_t size, const std::string& assimp_hint)
209 {
210  static const Eigen::Vector3d one(1.0, 1.0, 1.0);
211  return createMeshFromBinary(buffer, size, one, assimp_hint);
212 }
213 
214 Mesh* createMeshFromBinary(const char* buffer, std::size_t size, const Eigen::Vector3d& scale,
215  const std::string& assimp_hint)
216 {
217  if (!buffer || size < 1)
218  {
219  CONSOLE_BRIDGE_logWarn("Cannot construct mesh from empty binary buffer");
220  return NULL;
221  }
222 
223  // try to get a file extension
224  std::string hint;
225  std::size_t pos = assimp_hint.find_last_of(".");
226  if (pos != std::string::npos)
227  {
228  hint = assimp_hint.substr(pos + 1);
229  std::transform(hint.begin(), hint.end(), hint.begin(), ::tolower);
230  }
231  if (hint.empty())
232  hint = assimp_hint; // send entire file name as hint if no extension was found
233 
234  // Create an instance of the Importer class
235  Assimp::Importer importer;
236 
237  // Issue #38 fix: as part of the post-processing, we remove all other components in file but
238  // the meshes, as anyway the resulting shapes:Mesh object just receives vertices and triangles.
239  importer.SetPropertyInteger(AI_CONFIG_PP_RVC_FLAGS, aiComponent_NORMALS | aiComponent_TANGENTS_AND_BITANGENTS |
240  aiComponent_COLORS | aiComponent_TEXCOORDS |
241  aiComponent_BONEWEIGHTS | aiComponent_ANIMATIONS |
242  aiComponent_TEXTURES | aiComponent_LIGHTS |
243  aiComponent_CAMERAS | aiComponent_MATERIALS);
244 
245  // And have it read the given file with some post-processing
246  const aiScene* scene = importer.ReadFileFromMemory(reinterpret_cast<const void*>(buffer), size,
247  aiProcess_Triangulate | aiProcess_JoinIdenticalVertices |
248  aiProcess_SortByPType | aiProcess_RemoveComponent,
249  hint.c_str());
250  if (!scene)
251  return NULL;
252 
253  // Assimp enforces Y_UP convention by rotating models with different conventions.
254  // However, that behaviour is confusing and doesn't match the ROS convention
255  // where the Z axis is pointing up.
256  // Hopefully this doesn't undo legit use of the root node transformation...
257  // Note that this is also what RViz does internally.
258  scene->mRootNode->mTransformation = aiMatrix4x4();
259 
260  // These post processing steps flatten the root node transformation into child nodes,
261  // so they must be delayed until after clearing the root node transform above.
262  importer.ApplyPostProcessing(aiProcess_OptimizeMeshes | aiProcess_OptimizeGraph);
263 
264  return createMeshFromAsset(scene, scale, hint);
265 }
266 
267 Mesh* createMeshFromResource(const std::string& resource, const Eigen::Vector3d& scale)
268 {
271  try
272  {
273  res = retriever.get(resource);
274  }
276  {
277  CONSOLE_BRIDGE_logError("%s", e.what());
278  return NULL;
279  }
280 
281  if (res.size == 0)
282  {
283  CONSOLE_BRIDGE_logWarn("Retrieved empty mesh for resource '%s'", resource.c_str());
284  return NULL;
285  }
286 
287  Mesh* m = createMeshFromBinary(reinterpret_cast<const char*>(res.data.get()), res.size, scale, resource);
288  if (!m)
289  {
290  CONSOLE_BRIDGE_logWarn("Assimp reports no scene in %s.", resource.c_str());
291  CONSOLE_BRIDGE_logWarn("This could be because of a resource filename that is too long for the Assimp library, a "
292  "known bug. As a workaround shorten the filename/path.");
293  }
294  return m;
295 }
296 
297 namespace
298 {
299 void extractMeshData(const aiScene* scene, const aiNode* node, const aiMatrix4x4& parent_transform,
300  const Eigen::Vector3d& scale, EigenSTL::vector_Vector3d& vertices,
301  std::vector<unsigned int>& triangles)
302 {
303  aiMatrix4x4 transform = parent_transform;
304  transform *= node->mTransformation;
305  for (unsigned int j = 0; j < node->mNumMeshes; ++j)
306  {
307  const aiMesh* a = scene->mMeshes[node->mMeshes[j]];
308  unsigned int offset = vertices.size();
309  for (unsigned int i = 0; i < a->mNumVertices; ++i)
310  {
311  aiVector3D v = transform * a->mVertices[i];
312  vertices.push_back(Eigen::Vector3d(v.x * scale.x(), v.y * scale.y(), v.z * scale.z()));
313  }
314  for (unsigned int i = 0; i < a->mNumFaces; ++i)
315  if (a->mFaces[i].mNumIndices == 3)
316  {
317  triangles.push_back(offset + a->mFaces[i].mIndices[0]);
318  triangles.push_back(offset + a->mFaces[i].mIndices[1]);
319  triangles.push_back(offset + a->mFaces[i].mIndices[2]);
320  }
321  }
322 
323  for (unsigned int n = 0; n < node->mNumChildren; ++n)
324  extractMeshData(scene, node->mChildren[n], transform, scale, vertices, triangles);
325 }
326 }
327 
328 Mesh* createMeshFromAsset(const aiScene* scene, const std::string& resource_name)
329 {
330  static const Eigen::Vector3d one(1.0, 1.0, 1.0);
331  return createMeshFromAsset(scene, one, resource_name);
332 }
333 
334 Mesh* createMeshFromAsset(const aiScene* scene, const Eigen::Vector3d& scale, const std::string& resource_name)
335 {
336  if (!scene->HasMeshes())
337  {
338  CONSOLE_BRIDGE_logWarn("Assimp reports scene in %s has no meshes", resource_name.c_str());
339  return NULL;
340  }
341  EigenSTL::vector_Vector3d vertices;
342  std::vector<unsigned int> triangles;
343  extractMeshData(scene, scene->mRootNode, aiMatrix4x4(), scale, vertices, triangles);
344  if (vertices.empty())
345  {
346  CONSOLE_BRIDGE_logWarn("There are no vertices in the scene %s", resource_name.c_str());
347  return NULL;
348  }
349  if (triangles.empty())
350  {
351  CONSOLE_BRIDGE_logWarn("There are no triangles in the scene %s", resource_name.c_str());
352  return NULL;
353  }
354 
355  return createMeshFromVertices(vertices, triangles);
356 }
357 
359 {
360  if (shape->type == shapes::SPHERE)
361  return shapes::createMeshFromShape(static_cast<const shapes::Sphere&>(*shape));
362  else if (shape->type == shapes::BOX)
363  return shapes::createMeshFromShape(static_cast<const shapes::Box&>(*shape));
364  else if (shape->type == shapes::CYLINDER)
365  return shapes::createMeshFromShape(static_cast<const shapes::Cylinder&>(*shape));
366  else if (shape->type == shapes::CONE)
367  return shapes::createMeshFromShape(static_cast<const shapes::Cone&>(*shape));
368  else
369  CONSOLE_BRIDGE_logError("Conversion of shape of type '%s' to a mesh is not known", shapeStringName(shape).c_str());
370  return NULL;
371 }
372 
374 {
375  double x = box.size[0] / 2.0;
376  double y = box.size[1] / 2.0;
377  double z = box.size[2] / 2.0;
378 
379  // define vertices of box mesh
380  Mesh* result = new Mesh(8, 12);
381  result->vertices[0] = -x;
382  result->vertices[1] = -y;
383  result->vertices[2] = -z;
384 
385  result->vertices[3] = x;
386  result->vertices[4] = -y;
387  result->vertices[5] = -z;
388 
389  result->vertices[6] = x;
390  result->vertices[7] = -y;
391  result->vertices[8] = z;
392 
393  result->vertices[9] = -x;
394  result->vertices[10] = -y;
395  result->vertices[11] = z;
396 
397  result->vertices[12] = -x;
398  result->vertices[13] = y;
399  result->vertices[14] = z;
400 
401  result->vertices[15] = -x;
402  result->vertices[16] = y;
403  result->vertices[17] = -z;
404 
405  result->vertices[18] = x;
406  result->vertices[19] = y;
407  result->vertices[20] = z;
408 
409  result->vertices[21] = x;
410  result->vertices[22] = y;
411  result->vertices[23] = -z;
412 
413  static const unsigned int tri[] = { 0, 1, 2, 2, 3, 0, 4, 3, 2, 2, 6, 4, 7, 6, 2, 2, 1, 7,
414  3, 4, 5, 5, 0, 3, 0, 5, 7, 7, 1, 0, 7, 5, 4, 4, 6, 7 };
415  memcpy(result->triangles, tri, sizeof(unsigned int) * 36);
416  result->computeTriangleNormals();
417  result->computeVertexNormals();
418  return result;
419 }
420 
422 {
423  // this code is adapted from FCL
424  EigenSTL::vector_Vector3d vertices;
425  std::vector<unsigned int> triangles;
426 
427  const double r = sphere.radius;
428  const double pi = boost::math::constants::pi<double>();
429  const unsigned int seg = std::max<unsigned int>(6, 0.5 + 2.0 * pi * r / 0.01); // split the sphere longitudinally up
430  // to a resolution of 1 cm at the
431  // ecuator, or a minimum of 6 segments
432  const unsigned int ring = std::max<unsigned int>(6, 2.0 * r / 0.01); // split the sphere into rings along latitude,
433  // up to a height of at most 1 cm, or a minimum
434  // of 6 rings
435 
436  double phi, phid;
437  phid = pi * 2.0 / seg;
438  phi = 0.0;
439 
440  double theta, thetad;
441  thetad = pi / (ring + 1);
442  theta = 0;
443 
444  for (unsigned int i = 0; i < ring; ++i)
445  {
446  double theta_ = theta + thetad * (i + 1);
447  for (unsigned int j = 0; j < seg; ++j)
448  vertices.push_back(Eigen::Vector3d(r * sin(theta_) * cos(phi + j * phid), r * sin(theta_) * sin(phi + j * phid),
449  r * cos(theta_)));
450  }
451  vertices.push_back(Eigen::Vector3d(0.0, 0.0, r));
452  vertices.push_back(Eigen::Vector3d(0.0, 0.0, -r));
453 
454  for (unsigned int i = 0; i < ring - 1; ++i)
455  {
456  for (unsigned int j = 0; j < seg; ++j)
457  {
458  unsigned int a, b, c, d;
459  a = i * seg + j;
460  b = (j == seg - 1) ? (i * seg) : (i * seg + j + 1);
461  c = (i + 1) * seg + j;
462  d = (j == seg - 1) ? ((i + 1) * seg) : ((i + 1) * seg + j + 1);
463  triangles.push_back(a);
464  triangles.push_back(c);
465  triangles.push_back(b);
466  triangles.push_back(b);
467  triangles.push_back(c);
468  triangles.push_back(d);
469  }
470  }
471 
472  for (unsigned int j = 0; j < seg; ++j)
473  {
474  unsigned int a, b;
475  a = j;
476  b = (j == seg - 1) ? 0 : (j + 1);
477  triangles.push_back(ring * seg);
478  triangles.push_back(a);
479  triangles.push_back(b);
480 
481  a = (ring - 1) * seg + j;
482  b = (j == seg - 1) ? (ring - 1) * seg : ((ring - 1) * seg + j + 1);
483  triangles.push_back(a);
484  triangles.push_back(ring * seg + 1);
485  triangles.push_back(b);
486  }
487  return createMeshFromVertices(vertices, triangles);
488 }
489 
491 {
492  // this code is adapted from FCL
493  EigenSTL::vector_Vector3d vertices;
494  std::vector<unsigned int> triangles;
495 
496  // magic number defining how many triangles to construct for the unit cylinder; perhaps this should be a param
497  static unsigned int tot_for_unit_cylinder = 100;
498 
499  double r = cylinder.radius;
500  double h = cylinder.length;
501 
502  const double pi = boost::math::constants::pi<double>();
503  unsigned int tot = std::max<unsigned int>(6, ceil(tot_for_unit_cylinder * r));
504  double phid = pi * 2 / tot;
505 
506  double circle_edge = phid * r;
507  unsigned int h_num = ceil(std::abs(h) / circle_edge);
508 
509  double phi = 0;
510  double hd = h / h_num;
511 
512  for (unsigned int i = 0; i < tot; ++i)
513  vertices.push_back(Eigen::Vector3d(r * cos(phi + phid * i), r * sin(phi + phid * i), h / 2));
514 
515  for (unsigned int i = 0; i < h_num - 1; ++i)
516  for (unsigned int j = 0; j < tot; ++j)
517  vertices.push_back(Eigen::Vector3d(r * cos(phi + phid * j), r * sin(phi + phid * j), h / 2 - (i + 1) * hd));
518 
519  for (unsigned int i = 0; i < tot; ++i)
520  vertices.push_back(Eigen::Vector3d(r * cos(phi + phid * i), r * sin(phi + phid * i), -h / 2));
521 
522  vertices.push_back(Eigen::Vector3d(0, 0, h / 2));
523  vertices.push_back(Eigen::Vector3d(0, 0, -h / 2));
524 
525  for (unsigned int i = 0; i < tot; ++i)
526  {
527  triangles.push_back((h_num + 1) * tot);
528  triangles.push_back(i);
529  triangles.push_back((i == tot - 1) ? 0 : (i + 1));
530  }
531 
532  for (unsigned int i = 0; i < tot; ++i)
533  {
534  triangles.push_back((h_num + 1) * tot + 1);
535  triangles.push_back(h_num * tot + ((i == tot - 1) ? 0 : (i + 1)));
536  triangles.push_back(h_num * tot + i);
537  }
538 
539  for (unsigned int i = 0; i < h_num; ++i)
540  {
541  for (unsigned int j = 0; j < tot; ++j)
542  {
543  int a, b, c, d;
544  a = j;
545  b = (j == tot - 1) ? 0 : (j + 1);
546  c = j + tot;
547  d = (j == tot - 1) ? tot : (j + 1 + tot);
548 
549  int start = i * tot;
550  triangles.push_back(start + b);
551  triangles.push_back(start + a);
552  triangles.push_back(start + c);
553  triangles.push_back(start + b);
554  triangles.push_back(start + c);
555  triangles.push_back(start + d);
556  }
557  }
558  return createMeshFromVertices(vertices, triangles);
559 }
560 
562 {
563  // this code is adapted from FCL
564  EigenSTL::vector_Vector3d vertices;
565  std::vector<unsigned int> triangles;
566 
567  // magic number defining how many triangles to construct for the unit cylinder; perhaps this should be a param
568  static unsigned int tot_for_unit_cone = 100;
569 
570  double r = cone.radius;
571  double h = cone.length;
572 
573  const double pi = boost::math::constants::pi<double>();
574  unsigned int tot = tot_for_unit_cone * r;
575  double phid = pi * 2 / tot;
576 
577  double circle_edge = phid * r;
578  unsigned int h_num = ceil(h / circle_edge);
579 
580  double phi = 0;
581  double hd = h / h_num;
582 
583  for (unsigned int i = 0; i < h_num - 1; ++i)
584  {
585  double h_i = h / 2 - (i + 1) * hd;
586  double rh = r * (0.5 - h_i / h);
587  for (unsigned int j = 0; j < tot; ++j)
588  vertices.push_back(Eigen::Vector3d(rh * cos(phi + phid * j), rh * sin(phi + phid * j), h_i));
589  }
590 
591  for (unsigned int i = 0; i < tot; ++i)
592  vertices.push_back(Eigen::Vector3d(r * cos(phi + phid * i), r * sin(phi + phid * i), -h / 2));
593 
594  vertices.push_back(Eigen::Vector3d(0, 0, h / 2));
595  vertices.push_back(Eigen::Vector3d(0, 0, -h / 2));
596 
597  for (unsigned int i = 0; i < tot; ++i)
598  {
599  triangles.push_back(h_num * tot);
600  triangles.push_back(i);
601  triangles.push_back((i == tot - 1) ? 0 : (i + 1));
602  }
603 
604  for (unsigned int i = 0; i < tot; ++i)
605  {
606  triangles.push_back(h_num * tot + 1);
607  triangles.push_back((h_num - 1) * tot + ((i == tot - 1) ? 0 : (i + 1)));
608  triangles.push_back((h_num - 1) * tot + i);
609  }
610 
611  for (unsigned int i = 0; i < h_num - 1; ++i)
612  for (unsigned int j = 0; j < tot; ++j)
613  {
614  int a, b, c, d;
615  a = j;
616  b = (j == tot - 1) ? 0 : (j + 1);
617  c = j + tot;
618  d = (j == tot - 1) ? tot : (j + 1 + tot);
619 
620  int start = i * tot;
621  triangles.push_back(start + b);
622  triangles.push_back(start + a);
623  triangles.push_back(start + c);
624  triangles.push_back(start + b);
625  triangles.push_back(start + c);
626  triangles.push_back(start + d);
627  }
628  return createMeshFromVertices(vertices, triangles);
629 }
630 
631 namespace
632 {
633 inline void writeFloatToSTL(char*& ptr, float data)
634 {
635  memcpy(ptr, &data, sizeof(float));
636  ptr += sizeof(float);
637 }
638 inline void writeFloatToSTL(char*& ptr, double datad)
639 {
640  float data = datad;
641  memcpy(ptr, &data, sizeof(float));
642  ptr += sizeof(float);
643 }
644 }
645 
646 void writeSTLBinary(const Mesh* mesh, std::vector<char>& buffer)
647 {
648  buffer.resize(84 + mesh->triangle_count * 50);
649  memset(&buffer[0], 0, 80);
650  char* ptr = &buffer[80];
651  uint32_t nt = mesh->triangle_count;
652  memcpy(ptr, &nt, sizeof(uint32_t));
653  ptr += sizeof(uint32_t);
654  for (unsigned int i = 0; i < mesh->triangle_count; ++i)
655  {
656  unsigned int i3 = i * 3;
657 
658  if (mesh->triangle_normals)
659  {
660  writeFloatToSTL(ptr, mesh->triangle_normals[i3]);
661  writeFloatToSTL(ptr, mesh->triangle_normals[i3 + 1]);
662  writeFloatToSTL(ptr, mesh->triangle_normals[i3 + 2]);
663  }
664  else
665  {
666  memset(ptr, 0, sizeof(float) * 3);
667  ptr += sizeof(float) * 3;
668  }
669 
670  unsigned int index = mesh->triangles[i3] * 3;
671  writeFloatToSTL(ptr, mesh->vertices[index]);
672  writeFloatToSTL(ptr, mesh->vertices[index + 1]);
673  writeFloatToSTL(ptr, mesh->vertices[index + 2]);
674  index = mesh->triangles[i3 + 1] * 3;
675  writeFloatToSTL(ptr, mesh->vertices[index]);
676  writeFloatToSTL(ptr, mesh->vertices[index + 1]);
677  writeFloatToSTL(ptr, mesh->vertices[index + 2]);
678  index = mesh->triangles[i3 + 2] * 3;
679  writeFloatToSTL(ptr, mesh->vertices[index]);
680  writeFloatToSTL(ptr, mesh->vertices[index + 1]);
681  writeFloatToSTL(ptr, mesh->vertices[index + 2]);
682  memset(ptr, 0, 2);
683  ptr += 2;
684  }
685 }
686 }
#define CONSOLE_BRIDGE_logWarn(fmt,...)
d
Definition of various shapes. No properties such as position are included. These are simply the descr...
double radius
The radius of the cylinder.
Definition: shapes.h:146
Definition of a cylinder Length is along z axis. Origin is at center of mass.
Definition: shapes.h:127
std::vector< Eigen::Vector3d, Eigen::aligned_allocator< Eigen::Vector3d > > vector_Vector3d
double length
The length (height) of the cone.
Definition: shapes.h:166
double size[3]
x, y, z dimensions of the box (axis-aligned)
Definition: shapes.h:188
ShapeType type
The type of the shape.
Definition: shapes.h:102
double radius
The radius of the cone.
Definition: shapes.h:169
double length
The length of the cylinder.
Definition: shapes.h:143
unsigned int * triangles
The vertex indices for each triangle triangle k has vertices at index (3k, 3k+1, 3k+2) = (v1...
Definition: shapes.h:233
double y
Definition of a cone Tip is on positive z axis. Center of base is on negative z axis. Origin is halway between tip and center of base.
Definition: shapes.h:152
Mesh * createMeshFromVertices(const EigenSTL::vector_Vector3d &vertices, const std::vector< unsigned int > &triangles)
Load a mesh from a set of vertices.
unsigned int index
A basic definition of a shape. Shapes are considered centered at origin.
Definition: shapes.h:77
boost::shared_array< uint8_t > data
unsigned int triangle_count
The number of triangles formed with the vertices.
Definition: shapes.h:229
double z
double * vertices
The position for each vertex vertex k has values at index (3k, 3k+1, 3k+2) = (x,y,z)
Definition: shapes.h:226
double * triangle_normals
The normal to each triangle; unit vector represented as (x,y,z); If missing from the mesh...
Definition: shapes.h:237
void computeVertexNormals()
Compute vertex normals by averaging from adjacent triangle normals.
Definition: shapes.cpp:444
Definition of a sphere.
Definition: shapes.h:106
const std::string & shapeStringName(const Shape *shape)
Get the string name of the shape.
MemoryResource get(const std::string &url)
void computeTriangleNormals()
Compute the normals of each triangle from its vertices via cross product.
Definition: shapes.cpp:421
#define CONSOLE_BRIDGE_logError(fmt,...)
Mesh * createMeshFromResource(const std::string &resource)
Load a mesh from a resource that contains a mesh that can be loaded by assimp.
void writeSTLBinary(const Mesh *mesh, std::vector< char > &buffer)
Write the mesh to a buffer in STL format.
Definition of a triangle mesh By convention the "center" of the shape is at the origin. For a mesh this implies that the AABB of the mesh is centered at the origin. Some methods may not work with arbitrary meshes whose AABB is not centered at the origin.
Definition: shapes.h:196
Definition of a box Aligned with the XYZ axes.
Definition: shapes.h:174
Mesh * createMeshFromBinary(const char *buffer, std::size_t size, const std::string &assimp_hint=std::string())
Load a mesh from a binary stream that contains a mesh that can be loaded by assimp.
Mesh * createMeshFromAsset(const aiScene *scene, const Eigen::Vector3d &scale, const std::string &assimp_hint=std::string())
Load a mesh from an assimp datastructure.
double radius
The radius of the sphere.
Definition: shapes.h:122
Mesh * createMeshFromShape(const Shape *shape)
Construct a mesh from a primitive shape that is NOT already a mesh. This call allocates a new object...
double x
r


geometric_shapes
Author(s): Ioan Sucan , Gil Jones
autogenerated on Fri Jun 7 2019 21:59:29