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Mesh.cpp @ 2614

Revision 2614, 20.2 KB checked in by mattausch, 16 years ago (diff)
worked on dynamic objects

Line
1	#include "Ray.h"
2	#include "Mesh.h"
3	#include "MeshKdTree.h"
4	#include "Triangle3.h"
5	#include "ResourceManager.h"
6
7	using namespace std;
8
9	namespace GtpVisibilityPreprocessor {
10
11	bool MeshDebug = false;
12
13	//int Intersectable::sMailId = 1;//2147483647;
14	//int Intersectable::sReservedMailboxes = 1;
15
16	struct SortableVertex {
17
18	Vector3 vertex;
19
20	int originalId;
21	int newId;
22	int finalPos;
23
24	SortableVertex() {}
25
26	SortableVertex(const Vector3 &v,
27	const int id):
28	vertex(v),
29	originalId(id),
30	newId(id)
31	{}
32
33	friend bool operator<(const SortableVertex &a,
34	const SortableVertex &b)
35	{
36	if (a.vertex.x < b.vertex.x)
37	return true;
38	else
39	if (a.vertex.x > b.vertex.x)
40	return false;
41
42	if (a.vertex.y < b.vertex.y)
43	return true;
44	else
45	if (a.vertex.y > b.vertex.y)
46	return false;
47
48	if (a.vertex.z < b.vertex.z)
49	return true;
50	else
51	// if (a.z > b.z)
52	return false;
53
54	// return false;
55	}
56
57	};
58
59
60	Mesh::Mesh(const int vertices, const int faces):
61	mFaces(),
62	mMaterial(NULL),
63	mKdTree(NULL),
64	mVertices(),
65	mIsConvex(false),
66	mIsWatertight(false),
67	mId(0)
68	{
69	mVertices.reserve(vertices);
70	mFaces.reserve(faces);
71	}
72
73
74	void
75	Mesh::ComputeBoundingBox()
76	{
77
78	mBox.Initialize();
79	VertexContainer::const_iterator vi = mVertices.begin();
80	for (; vi != mVertices.end(); vi++) {
81	mBox.Include(*vi);
82	}
83	//mBox.Enlarge(1e-4f);
84	}
85
86	void
87	Mesh::Preprocess(bool cleanup)
88	{
89	if (cleanup)
90	Cleanup();
91
92	ComputeBoundingBox();
93
94	/** true if it is a watertight convex mesh
95	*/
96	mIsConvex = false;
97
98	if (mFaces.size() > MeshKdTree::mTermMinCost)
99	{
100	mKdTree = new MeshKdTree(this);
101	MeshKdLeaf root = (MeshKdLeaf )mKdTree->GetRoot();
102
103	for (int i = 0; i < mFaces.size(); i++)
104	root->mFaces.push_back(i);
105
106	//cout<<"KD";
107	cout<<"constructed mesh kd tree for " << (int)mFaces.size() << " faces" << endl;
108
109	mKdTree->Construct();
110
111	if (mKdTree->GetRoot()->IsLeaf())
112	{
113	cout<<"d";
114	delete mKdTree;
115	mKdTree = NULL;
116	}
117	}
118	}
119
120
121	void
122	Mesh::IndexVertices()
123	{
124	int i;
125	// check whether the vertices can be simplfied and reindexed
126	vector<SortableVertex> svertices(mVertices.size());
127
128	for (i=0; i < mVertices.size(); i++)
129	svertices[i] = SortableVertex(mVertices[i], i);
130
131	sort(svertices.begin(), svertices.end());
132
133	for (i=0; i < svertices.size() - 1; i++)
134	if (svertices[i].vertex == svertices[i+1].vertex)
135	svertices[i+1].newId = svertices[i].newId;
136
137	// remove the same vertices
138	int k = 0;
139	mVertices[0] = svertices[0].vertex;
140	svertices[0].finalPos = 0;
141
142	for (i=1; i < svertices.size(); i++) {
143	if (svertices[i].newId != svertices[i-1].newId)
144	k++;
145
146	mVertices[k] = svertices[i].vertex;
147	svertices[i].finalPos = k;
148	}
149
150	mVertices.resize(k + 1);
151
152	vector<int> remapBuffer(svertices.size());
153	for (i = 0; i < svertices.size(); i++)
154	remapBuffer[svertices[i].originalId] = svertices[i].finalPos;
155
156	// remap all faces
157
158	for (int faceIndex = 0; faceIndex < mFaces.size(); faceIndex++) {
159	Face *face = mFaces[faceIndex];
160	for (int i = 0; i < face->mVertexIndices.size(); i++) {
161	face->mVertexIndices[i] = remapBuffer[face->mVertexIndices[i]];
162	}
163	}
164	}
165
166	AxisAlignedBox3
167	Mesh::GetFaceBox(const int faceIndex)
168	{
169	Face *face = mFaces[faceIndex];
170	AxisAlignedBox3 box;
171	box.SetMin( mVertices[face->mVertexIndices[0]] );
172	box.SetMax(box.Min());
173	for (int i = 1; i < face->mVertexIndices.size(); i++) {
174	box.Include(mVertices[face->mVertexIndices[i]]);
175	}
176	return box;
177	}
178
179	int
180	Mesh::CastRayToFace(
181	const int faceIndex,
182	Ray &ray,
183	float &nearestT,
184	Vector3 &nearestNormal,
185	int &nearestFace,
186	Intersectable *instance
187	)
188	{
189	float t;
190	int hit = 0;
191	Vector3 normal;
192	if (RayFaceIntersection(faceIndex, ray, t, normal, nearestT) == Ray::INTERSECTION) {
193	switch (ray.GetType()) {
194	case Ray::GLOBAL_RAY:
195	ray.intersections.push_back(Ray::Intersection(t, normal, instance, faceIndex));
196	hit++;
197	break;
198	case Ray::LOCAL_RAY:
199	nearestT = t;
200	nearestNormal = normal;
201	nearestFace = faceIndex;
202	hit++;
203	break;
204	case Ray::LINE_SEGMENT:
205	if (t <= 1.0f) {
206	ray.intersections.push_back(Ray::Intersection(t, normal, instance, faceIndex));
207	hit++;
208	}
209	break;
210	}
211	}
212	return hit;
213	}
214
215	int
216	Mesh::CastRay(
217	Ray &ray,
218	MeshInstance *instance
219	)
220	{
221	if (mKdTree) {
222	return mKdTree->CastRay(ray, instance);
223	}
224
225	int faceIndex = 0;
226	int hits = 0;
227	float nearestT = MAX_FLOAT;
228	Vector3 nearestNormal;
229	int nearestFace = -1;
230
231	if (ray.GetType() == Ray::LOCAL_RAY && !ray.intersections.empty())
232	nearestT = ray.intersections[0].mT;
233
234
235	for ( ;
236	faceIndex < mFaces.size();
237	faceIndex++) {
238	hits += CastRayToFace(faceIndex,
239	ray,
240	nearestT,
241	nearestNormal,
242	nearestFace,
243	instance);
244	if (mIsConvex && nearestFace != -1)
245	break;
246	}
247
248	if ( hits && ray.GetType() == Ray::LOCAL_RAY ) {
249	if (!ray.intersections.empty())
250	ray.intersections[0] = Ray::Intersection(nearestT,
251	nearestNormal,
252	instance,
253	nearestFace);
254	else
255	ray.intersections.push_back(Ray::Intersection(nearestT,
256	nearestNormal,
257	instance,
258	nearestFace));
259	}
260
261	return hits;
262	}
263
264	int
265	Mesh::CastRayToSelectedFaces(
266	Ray &ray,
267	const vector<int> &faces,
268	Intersectable *instance
269	)
270	{
271	vector<int>::const_iterator fi;
272	int faceIndex = 0;
273	int hits = 0;
274	float nearestT = MAX_FLOAT;
275	Vector3 nearestNormal;
276	int nearestFace = -1;
277
278	if (ray.GetType() == Ray::LOCAL_RAY && ray.intersections.size())
279	nearestT = ray.intersections[0].mT;
280
281	for ( fi = faces.begin();
282	fi != faces.end();
283	fi++) {
284	hits += CastRayToFace(*fi, ray, nearestT, nearestNormal, nearestFace, instance);
285	if (mIsConvex && nearestFace != -1)
286	break;
287	}
288
289	if ( hits && ray.GetType() == Ray::LOCAL_RAY ) {
290	if (ray.intersections.size())
291	ray.intersections[0] = Ray::Intersection(nearestT, nearestNormal,instance, nearestFace);
292	else
293	ray.intersections.push_back(Ray::Intersection(nearestT, nearestNormal,instance, nearestFace));
294	}
295
296	return hits;
297	}
298
299
300	// int_lineseg returns 1 if the given line segment intersects a 2D
301	// ray travelling in the positive X direction. This is used in the
302	// Jordan curve computation for polygon intersection.
303	inline int
304	int_lineseg(float px,
305	float py,
306	float u1,
307	float v1,
308	float u2,
309	float v2)
310	{
311	float ydiff;
312
313	u1 -= px; u2 -= px; // translate line
314	v1 -= py; v2 -= py;
315
316	if ((v1 > 0 && v2 > 0) \|\|
317	(v1 < 0 && v2 < 0) \|\|
318	(u1 < 0 && u2 < 0))
319	return 0;
320
321	if (u1 > 0 && u2 > 0)
322	return 1;
323
324	ydiff = v2 - v1;
325	if (fabs(ydiff) < Limits::Small) { // denominator near 0
326	if (((fabs(v1) > Limits::Small) \|\|
327	(u1 > 0) \|\| (u2 > 0)))
328	return 0;
329	return 1;
330	}
331
332	double t = -v1 / ydiff; // Compute parameter
333
334	double thresh;
335
336	if (ydiff < 0.0f)
337	thresh = -1e-20;
338	else
339	thresh = 1e-20;
340
341
342	return (u1 + t * (u2 - u1)) > thresh; //-Limits::Small;
343	}
344
345
346
347	// intersection with the polygonal face of the mesh
348	int
349	Mesh::RayFaceIntersection(const int faceIndex,
350	const Ray &ray,
351	float &t,
352	Vector3 &normal,
353	const float nearestT
354	)
355	{
356	Face *face = mFaces[faceIndex];
357
358	Plane3 plane = GetFacePlane(faceIndex);
359	float dot = DotProd(plane.mNormal, ray.GetDir());
360
361	if (MeshDebug) {
362	cout<<endl<<endl;
363	cout<<"normal="<<plane.mNormal<<endl;
364	cout<<"dot="<<dot<<endl;
365	}
366
367
368	// Watch for near-zero denominator
369	// ONLY single sided polygons!!!!!
370	if (ray.mFlags & Ray::CULL_BACKFACES) {
371	if (dot > -Limits::Small)
372	// if (fabs(dot) < Limits::Small)
373	return Ray::NO_INTERSECTION;
374	} else {
375	if (fabs(dot) < Limits::Small)
376	return Ray::NO_INTERSECTION;
377	}
378
379	normal = plane.mNormal;
380
381	t = (-plane.mD - DotProd(plane.mNormal, ray.GetLoc())) / dot;
382
383	if (MeshDebug)
384	cout<<"t="<<t<<endl;
385
386	if (t <= Limits::Small)
387	return Ray::INTERSECTION_OUT_OF_LIMITS;
388
389	if ((ray.GetType() == Ray::LOCAL_RAY) && (t >= nearestT)) {
390	return Ray::INTERSECTION_OUT_OF_LIMITS; // no intersection was found
391	}
392
393	int count = 0;
394	float u, v, u1, v1, u2, v2;
395	int i;
396
397	int paxis = plane.mNormal.DrivingAxis();
398
399
400	// Project the intersection point onto the coordinate plane
401	// specified by which.
402	ray.Extrap(t).ExtractVerts(&u, &v, paxis);
403
404
405	int size = (int)face->mVertexIndices.size();
406
407	if (MeshDebug)
408	cout<<"size="<<size<<endl;
409
410	mVertices[face->mVertexIndices[size - 1]].
411	ExtractVerts(&u1, &v1, paxis );
412
413	//$$JB changed 12.4.2006 from 0 ^^
414	if (0 && size <= 4) {
415	// assume a convex face
416	for (i = 0; i < size; i++) {
417	mVertices[face->mVertexIndices[i]].ExtractVerts(&u2, &v2, paxis);
418	// line u1, v1, u2, v2
419	if ((v1 - v2)(u - u1) + (u2 - u1)(v - v1) > 0) {
420	if (MeshDebug)
421	cout<<"exit on "<<i<<endl;
422	return Ray::NO_INTERSECTION;
423	}
424	u1 = u2;
425	v1 = v2;
426	}
427
428	return Ray::INTERSECTION;
429	}
430
431	// We're stuck with the Jordan curve computation. Count number
432	// of intersections between the line segments the polygon comprises
433	// with a ray originating at the point of intersection and
434	// travelling in the positive X direction.
435	for (i = 0; i < size; i++) {
436	mVertices[face->mVertexIndices[i]].ExtractVerts(&u2, &v2, paxis);
437	count += (int_lineseg(u, v, u1, v1, u2, v2) != 0);
438	u1 = u2;
439	v1 = v2;
440	}
441
442	if (MeshDebug)
443	cout<<"count="<<count<<endl;
444
445	// We hit polygon if number of intersections is odd.
446	return (count & 1) ? Ray::INTERSECTION : Ray::NO_INTERSECTION;
447	}
448
449	int
450	Mesh::GetRandomSurfacePoint(Vector3 &point, Vector3 &normal)
451	{
452	//const int faceIndex = (int)RandomValue(0, (Real)((int)mFaces.size()-1));
453	const int faceIndex = (int)RandomValue(0, (Real)mFaces.size() - 0.5f);
454
455	// assume the face is convex and generate a convex combination
456	Face *face = mFaces[faceIndex];
457
458	point = Vector3(0,0,0);
459	float sum = 0.0f;
460
461	for (int i = 0; i < face->mVertexIndices.size(); i++) {
462	float r = RandomValue(0,1);
463	sum += r;
464	point += mVertices[face->mVertexIndices[i]]*r;
465	}
466	point *= 1.0f/sum;
467
468	normal = GetFacePlane(faceIndex).mNormal;
469
470	return faceIndex;
471	}
472
473	int
474	Mesh::GetRandomVisibleSurfacePoint(Vector3 &point,
475	Vector3 &normal,
476	const Vector3 &viewpoint,
477	const int maxTries)
478	{
479	Plane3 plane;
480	const int faceIndex = (int)RandomValue(0, (Real)mFaces.size() - 0.5f);
481	int tries;
482	for (tries = 0; tries < maxTries; tries++) {
483	Face *face = mFaces[faceIndex];
484	plane = GetFacePlane(faceIndex);
485
486	if (plane.Side(viewpoint) > 0) {
487	point = Vector3(0,0,0);
488	float sum = 0.0f;
489	// pickup a point inside this triangle
490	for (int i = 0; i < face->mVertexIndices.size(); i++) {
491	float r = RandomValue(0,1);
492	sum += r;
493	point += mVertices[face->mVertexIndices[i]]*r;
494	}
495	point *= 1.0f/sum;
496	break;
497	}
498	}
499
500	normal = plane.mNormal;
501	return (tries < maxTries) ? faceIndex + 1 : 0;
502	}
503
504
505	Plane3
506	Mesh::GetFacePlane(const int faceIndex) const
507	{
508	Face *face = mFaces[faceIndex];
509	return Plane3(mVertices[face->mVertexIndices[0]],
510	mVertices[face->mVertexIndices[1]],
511	mVertices[face->mVertexIndices[2]]);
512	}
513
514	bool
515	Mesh::ValidateFace(const int i)
516	{
517	Face *face = mFaces[i];
518
519	Plane3 plane = Plane3(mVertices[face->mVertexIndices[0]],
520	mVertices[face->mVertexIndices[1]],
521	mVertices[face->mVertexIndices[2]]);
522
523	if (!eq(Magnitude(plane.mNormal), 1.0f))
524	return false;
525
526	return true;
527	}
528
529
530	bool Mesh::CheckMesh() const
531	{
532	VertexContainer::const_iterator vit, vit_end = mVertices.end();
533
534	for (vit = mVertices.begin(); vit != vit_end; ++ vit)
535	{
536	for (int i = 0; i < 3; ++ i)
537	{
538	const float x = (*vit)[i];
539	if (x != x) // nan
540	//if (isnan((*vit)[i]))
541	{
542	cout << "warning: vertex is ill defined" << endl;
543	return false;
544	}
545	}
546	}
547	return true;
548	}
549
550
551	static void PrintFace(const Mesh *mesh, const int idx, ostream &app)
552	{
553	Face *face = mesh->mFaces[idx];
554
555	VertexIndexContainer::iterator it, it_end = face->mVertexIndices.end();
556
557	cout << "face " << idx << endl;
558	for (it = face->mVertexIndices.begin(); it != it_end; ++ it)
559	{
560	cout << (it) << ": " << mesh->mVertices[it] << " ";
561	}
562	cout << endl;
563	}
564
565
566	void Mesh::Print(ostream &app) const
567	{
568	VertexContainer::const_iterator vit, vit_end = mVertices.end();
569
570	for (vit = mVertices.begin(); vit != vit_end; ++ vit)
571	{
572	app << (*vit) << " ";
573	}
574	app << endl;
575
576	for (int i = 0; i < (int)mFaces.size(); ++ i)
577	{
578	PrintFace(this, i, app);
579	}
580	}
581
582
583	void
584	Mesh::Cleanup()
585	{
586	int toRemove = 0;
587	FaceContainer newFaces;
588	for (int i=0; i < mFaces.size(); i++)
589	if (ValidateFace(i)) {
590	newFaces.push_back(mFaces[i]);
591	} else {
592	cout<<"d";
593	delete mFaces[i];
594	toRemove++;
595	}
596
597	if (toRemove) {
598	mFaces = newFaces;
599	}
600
601	// cleanup vertices??
602	}
603
604
605	Vector3 Mesh::GetNormal(const int idx) const
606	{
607	return GetFacePlane(idx).mNormal;
608	}
609
610
611	void
612	Mesh::AddTriangle(const Triangle3 &triangle)
613	{
614	int index = (int)mVertices.size();
615
616	for (int i=0; i < 3; i++) {
617	mVertices.push_back(triangle.mVertices[i]);
618	}
619
620	AddFace(new Face(index + 0, index + 1, index + 2) );
621	}
622
623	void
624	Mesh::AddRectangle(const Rectangle3 &rect)
625	{
626	int index = (int)mVertices.size();
627
628	for (int i=0; i < 4; i++) {
629	mVertices.push_back(rect.mVertices[i]);
630	}
631
632	AddFace(new Face(index + 0, index + 1, index + 2, index + 3) );
633	}
634
635	void
636	Mesh::AssignRandomMaterial()
637	{
638	mMaterial = MaterialManager::GetSingleton()->CreateResource();
639
640	Material randMat = RandomMaterial();
641
642	mMaterial->mDiffuseColor = randMat.mDiffuseColor;
643	mMaterial->mSpecularColor = randMat.mSpecularColor;
644	mMaterial->mAmbientColor = randMat.mAmbientColor;
645	}
646
647
648	Mesh *CreateMeshFromBox(const AxisAlignedBox3 &box)
649	{
650	Mesh *mesh = MeshManager::GetSingleton()->CreateResource();
651
652	// add 8 vertices of the box
653	const int index = (int)mesh->mVertices.size();
654
655	for (int i=0; i < 8; ++ i)
656	{
657	Vector3 v;
658	box.GetVertex(i, v);
659	mesh->mVertices.push_back(v);
660	}
661
662	mesh->AddFace(new Face(index + 0, index + 1, index + 3, index + 2) );
663	mesh->AddFace(new Face(index + 0, index + 2, index + 6, index + 4) );
664	mesh->AddFace(new Face(index + 4, index + 6, index + 7, index + 5) );
665
666	mesh->AddFace(new Face(index + 3, index + 1, index + 5, index + 7) );
667	mesh->AddFace(new Face(index + 0, index + 4, index + 5, index + 1) );
668	mesh->AddFace(new Face(index + 2, index + 3, index + 7, index + 6) );
669
670	return mesh;
671	}
672
673
674	Mesh::Mesh(const int id, const int vertices, const int faces):
675	mFaces(),
676	mMaterial(NULL),
677	mKdTree(NULL),
678	mVertices(),
679	mIsConvex(false),
680	mIsWatertight(false),
681	mId(id)
682	{
683	mVertices.reserve(vertices);
684	mFaces.reserve(faces);
685	}
686
687
688	Mesh::Mesh(const int id):
689	mId(id), mVertices(), mFaces(), mMaterial(NULL), mKdTree(NULL)
690	{}
691
692
693	// apply transformation to each vertex
694	void Mesh::ApplyTransformation(const Matrix4x4 &m)
695	{
696	VertexContainer::iterator it, it_end = mVertices.end();
697
698	for (it = mVertices.begin(); it != it_end; ++ it)
699	{
700	(it) = m (*it);
701	}
702	}
703
704
705	Mesh::Mesh(const Mesh &rhs):
706	mKdTree(NULL)
707	{
708	mVertices = rhs.mVertices;
709	mFaces.reserve(rhs.mFaces.size());
710	mId = rhs.mId;
711	mMaterial = rhs.mMaterial;
712
713	FaceContainer::const_iterator it, it_end = rhs.mFaces.end();
714
715	for (it = rhs.mFaces.begin(); it != it_end; ++ it)
716	{
717	Face face = it;
718	mFaces.push_back(new Face(*face));
719	}
720	}
721
722
723	Mesh& Mesh::operator=(const Mesh& m)
724	{
725	if (this == &m)
726	return *this;
727
728	CLEAR_CONTAINER(mFaces);
729
730	mVertices = m.mVertices;
731	mFaces.reserve(m.mFaces.size());
732	mMaterial = m.mMaterial;
733	// note: we don't copy id on purpose
734	//mId = m.mId;
735
736	FaceContainer::const_iterator it, it_end = m.mFaces.end();
737
738	for (it = m.mFaces.begin(); it != it_end; ++ it)
739	{
740	Face face = it;
741	mFaces.push_back(new Face(*face));
742	}
743
744	return *this;
745	}
746
747
748	Mesh::~Mesh()
749	{
750	for (int i=0; i < mFaces.size(); ++ i)
751	delete mFaces[i];
752
753	DEL_PTR(mKdTree);
754	}
755
756
757	void Mesh::Clear()
758	{
759	mVertices.clear();
760	mFaces.clear();
761
762	DEL_PTR(mKdTree);
763	}
764
765
766
767	/********************************************************/
768	/* MeshInstance implementation */
769	/********************************************************/
770
771	int
772	MeshInstance::CastRay(
773	Ray &ray
774	)
775	{
776	int res = mMesh->CastRay(ray, this);
777
778	return res;
779	}
780
781	int
782	MeshInstance::CastRay(
783	Ray &ray,
784	const vector<int> &faces
785	)
786	{
787	return mMesh->CastRayToSelectedFaces(ray, faces, this);
788	}
789
790
791
792	int
793	MeshInstance::GetRandomSurfacePoint(Vector3 &point, Vector3 &normal)
794	{
795	return mMesh->GetRandomSurfacePoint(point, normal);
796	}
797
798	int
799	MeshInstance::GetRandomVisibleSurfacePoint(Vector3 &point,
800	Vector3 &normal,
801	const Vector3 &viewpoint,
802	const int maxTries)
803	{
804	return mMesh->GetRandomVisibleSurfacePoint(point, normal, viewpoint, maxTries);
805	}
806
807
808	void MeshInstance::SetMaterial(Material *mat)
809	{
810	mMaterial = mat;
811	}
812
813	Material *MeshInstance::GetMaterial() const
814	{
815	return mMaterial;
816	}
817
818
819	Vector3 MeshInstance::GetNormal(const int idx) const
820	{
821	return mMesh->GetNormal(idx);
822	}
823
824
825	int MeshInstance::GetRandomEdgePoint(Vector3 &point, Vector3 &normal)
826	{
827	// get random face
828	const int faceIdx = (int)RandomValue(0.0f, (float)mMesh->mFaces.size() - 0.5f);
829	Face *face = mMesh->mFaces[faceIdx];
830
831	// get random edge of face (hack: this is not uniform in the edges!
832	const int edgeIdx = (int)RandomValue(0.0f, (float)face->mVertexIndices.size() - 0.5f);
833
834	//cout << "idx = " << edgeIdx << " s: " << face->mVertexIndices.size() << endl;
835	const int vertexIdxA = face->mVertexIndices[edgeIdx];
836	const int vertexIdxB = face->mVertexIndices[(edgeIdx + 1) % (int)face->mVertexIndices.size()];
837
838	const Vector3 a = mMesh->mVertices[vertexIdxA];
839	const Vector3 b = mMesh->mVertices[vertexIdxB];
840
841	const float w = RandomValue(0.0f, 1.0f);
842
843	// get random point on edge
844	point = a * w + b * (1.0f - w);
845
846	//cout << "va " << a << " vb " << b << "p " << point << endl;
847	// hack: set normal of face as normal
848	normal = mMesh->GetFacePlane(faceIdx).mNormal;
849
850	return 1;
851	}
852
853
854	/*************************************************************/
855	/* TransformedMeshInstance implementation */
856	/*************************************************************/
857
858
859	TransformedMeshInstance::TransformedMeshInstance(Mesh *mesh):
860	MeshInstance(mesh)
861	{
862	mWorldTransform = IdentityMatrix();
863	}
864
865
866	int TransformedMeshInstance::GetRandomSurfacePoint(Vector3 &point, Vector3 &normal)
867	{
868	const int index = mMesh->GetRandomSurfacePoint(point, normal);
869	point = mWorldTransform * point;
870	normal = TransformNormal(mWorldTransform, normal);
871	return index;
872	}
873
874
875	int TransformedMeshInstance::CastRay(Ray &ray)
876	{
877	ray.ApplyTransform(Invert(mWorldTransform));
878
879	const int res = mMesh->CastRay(ray, this);
880	ray.ApplyTransform(mWorldTransform);
881
882	return res;
883	}
884
885
886	int TransformedMeshInstance::CastRay(Ray &ray, const vector<int> &faces)
887	{
888	ray.ApplyTransform(Invert(mWorldTransform));
889
890	const int res = mMesh->CastRayToSelectedFaces(ray, faces, this);
891	ray.ApplyTransform(mWorldTransform);
892
893	return res;
894	}
895
896
897	void TransformedMeshInstance::ApplyWorldTransform(const Matrix4x4 &m)
898	{
899	mWorldTransform = m * mWorldTransform;
900	}
901
902
903	void TransformedMeshInstance::LoadWorldTransform(const Matrix4x4 &m)
904	{
905	mWorldTransform = m;
906	}
907
908
909	void TransformedMeshInstance::GetWorldTransform(Matrix4x4 &m) const
910	{
911	m = mWorldTransform;
912	}
913
914
915	AxisAlignedBox3 TransformedMeshInstance::GetBox() const
916	{
917	return Transform(mMesh->mBox, mWorldTransform);
918	}
919
920
921	void TransformedMeshInstance::GetTransformedMesh(Mesh &transformedMesh) const
922	{
923	// copy mesh
924	transformedMesh = *mMesh;
925	transformedMesh.ApplyTransformation(mWorldTransform);
926	}
927
928
929	Vector3 TransformedMeshInstance::GetNormal(const int idx) const
930	{
931	Mesh mesh;
932	GetTransformedMesh(mesh);
933	return mesh.GetFacePlane(idx).mNormal;
934	}
935
936	}

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source: GTP/trunk/Lib/Vis/Preprocessing/src/Mesh.cpp @ 2614

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