Context Navigation

source: GTP/trunk/Lib/Vis/Preprocessing/src/Polygon3.cpp @ 648

Revision 648, 11.6 KB checked in by mattausch, 19 years ago (diff)
removed problems with bsp due to polygons equal to scene box faces. removing this polyogns in a preprocessing step. also using this for vsp bsp tree, because it is generally a good thing.

Rev	Line
[235]	1	#include "Polygon3.h"
	2	#include "Mesh.h"
[372]	3	#include "AxisAlignedBox3.h"
	4	#include "Ray.h"
[503]	5	#include "Triangle3.h"
[372]	6
	7	Polygon3::Polygon3():
	8	mMaterial(NULL), mParent(NULL), mPiercingRays(0)
[574]	9	{
	10	// mostly there will be triangles
	11	//mVertices.reserve(3);
	12	}
[372]	13
	14	Polygon3::Polygon3(const VertexContainer &vertices):
[574]	15	mMaterial(NULL), mParent(NULL), mPiercingRays(0)
	16	{
	17	mVertices.reserve(vertices.size());
	18	mVertices = vertices;
	19	}
[372]	20
[574]	21
[372]	22	Polygon3::Polygon3(MeshInstance *parent):
	23	mMaterial(NULL), mParent(parent), mPiercingRays(0)
	24	{}
	25
[574]	26
[372]	27	Polygon3::Polygon3(Face face, Mesh parentMesh):
	28	mMaterial(NULL), mParent(NULL), mPiercingRays(0)
	29	{
[574]	30	mVertices.reserve(face->mVertexIndices.size());
	31
[372]	32	VertexIndexContainer::iterator it = face->mVertexIndices.begin();
	33	for (; it != face->mVertexIndices.end(); ++it)
	34	{
	35	mVertices.push_back(parentMesh->mVertices[*it]);
	36	}
[574]	37
	38	mMaterial = parentMesh->mMaterial;
[372]	39	}
	40
[574]	41
[372]	42	Plane3 Polygon3::GetSupportingPlane() const
	43	{
	44	return Plane3(mVertices[0], mVertices[1], mVertices[2]);
	45	}
	46
[574]	47
[306]	48	Vector3 Polygon3::GetNormal() const
	49	{
[321]	50	return Normalize(CrossProd(mVertices[2] - mVertices[1],
	51	mVertices[0] - mVertices[1]));
[372]	52	}
	53
	54	void Polygon3::Split(const Plane3 &partition,
	55	Polygon3 &front,
[448]	56	Polygon3 &back,
	57	const float epsilon)
[372]	58	{
	59	Vector3 ptA = mVertices.back();
	60
[448]	61	int sideA = partition.Side(ptA, epsilon);
[372]	62
	63	VertexContainer::const_iterator it;
	64
[436]	65	Vector3 lastSplit;
	66
[372]	67	bool foundSplit = false;
[448]	68
	69	//-- find line - plane intersections
[372]	70	for (it = mVertices.begin(); it != mVertices.end(); ++ it)
	71	{
	72	Vector3 ptB = *it;
[448]	73	int sideB = partition.Side(ptB, epsilon);
[372]	74
	75	// vertices on different sides => split
[237]	76	if (sideB > 0)
	77	{
	78	if (sideA < 0)
[372]	79	{
	80	//-- plane - line intersection
	81	Vector3 splitPt = partition.FindIntersection(ptA, ptB);
	82
	83	// test if split point not too close to previous split point
[448]	84	if (!foundSplit \|\| (!EpsilonEqualV3(splitPt, lastSplit, epsilon)))
[372]	85	{
	86	// add vertex to both polygons
	87	front.mVertices.push_back(splitPt);
	88	back.mVertices.push_back(splitPt);
	89
[436]	90	lastSplit = splitPt;
[372]	91	foundSplit = true;
	92	}
	93	}
	94	front.mVertices.push_back(ptB);
	95	}
[237]	96	else if (sideB < 0)
	97	{
	98	if (sideA > 0)
[372]	99	{
	100	//-- plane - line intersection
	101	Vector3 splitPt = partition.FindIntersection(ptA, ptB);
	102	// test if split point not too close to other split point
	103	// test if split point not too close to previous split point
[448]	104	if (!foundSplit \|\| (!EpsilonEqualV3(splitPt, lastSplit, epsilon)))
[372]	105	{
	106	// add vertex to both polygons
	107	front.mVertices.push_back(splitPt);
	108	back.mVertices.push_back(splitPt);
	109
[436]	110	lastSplit = splitPt;
[372]	111	foundSplit = true;
	112	}
	113	}
	114	back.mVertices.push_back(ptB);
	115	}
	116	else
	117	{
	118	// vertex on plane => add vertex to both polygons
	119	front.mVertices.push_back(ptB);
	120	back.mVertices.push_back(ptB);
	121	}
	122
	123	ptA = ptB;
	124	sideA = sideB;
	125	}
	126	}
	127
[574]	128
[372]	129	float Polygon3::GetArea() const
	130	{
[306]	131	Vector3 v = CrossProd(mVertices.back(), mVertices.front());
	132
	133	for (int i=0; i < mVertices.size() - 1; ++i)
	134	v += CrossProd(mVertices[i], mVertices[i+1]);
	135
[544]	136	return 0.5f * fabs(DotProd(GetNormal(), v));
[372]	137	}
[235]	138
[574]	139
[448]	140	int Polygon3::Side(const Plane3 &plane,
	141	const float epsilon) const
[372]	142	{
[448]	143	int classification = ClassifyPlane(plane, epsilon);
[372]	144
	145	if (classification == BACK_SIDE)
	146	return -1;
	147	else if (classification == FRONT_SIDE)
	148	return 1;
[538]	149	// plane splits polygon
[372]	150	return 0;
	151	}
	152
[574]	153
[448]	154	int Polygon3::ClassifyPlane(const Plane3 &plane,
	155	const float epsilon) const
[372]	156	{
[574]	157	VertexContainer::const_iterator it, it_end = mVertices.end();
[372]	158
	159	bool onFrontSide = false;
	160	bool onBackSide = false;
	161
	162	int count = 0;
	163	// find possible line-plane intersections
[574]	164	for (it = mVertices.begin(); it != it_end; ++ it)
[372]	165	{
[448]	166	const int side = plane.Side(*it, epsilon);
[372]	167
	168	if (side > 0)
	169	onFrontSide = true;
	170	else if (side < 0)
	171	onBackSide = true;
	172
	173	//TODO: check if split goes through vertex
	174	if (onFrontSide && onBackSide) // split
	175	{
	176	return SPLIT;
	177	}
	178	// 3 vertices enough to decide coincident
	179	else if (((++ count) >= 3) && !onFrontSide && !onBackSide)
	180	{
	181	return COINCIDENT;
	182	}
	183	}
	184
	185	if (onBackSide)
	186	{
	187	return BACK_SIDE;
	188	}
	189	else if (onFrontSide)
	190	{
	191	return FRONT_SIDE;
	192	}
	193
	194	return COINCIDENT; // plane and polygon are coincident
	195	}
	196
	197
	198	Vector3
	199	Polygon3::Center() const
	200	{
	201	int i;
	202	Vector3 sum = mVertices[0];
	203	for (i=1; i < mVertices.size(); i++)
	204	sum += mVertices[i];
	205
	206	return sum/(float)i;
	207	}
	208
	209
	210	void
	211	Polygon3::Scale(const float scale)
	212	{
	213	int i;
	214	Vector3 center = Center();
	215	for (i=0; i < mVertices.size(); i++) {
	216	mVertices[i] = center + scale*(mVertices[i] - center);
	217	}
	218	}
	219
[448]	220	bool Polygon3::Valid(const float epsilon) const
[372]	221	{
	222	if (mVertices.size() < 3)
	223	return false;
	224
[574]	225	//TODO: remove for performance
[648]	226	#if 0
[574]	227	if (1)
[372]	228	{
[574]	229	// check if area exceeds certain size
	230	if (GetArea() < AREA_LIMIT)
	231	{
	232	Debug << "area too small: " << GetArea() << endl;
	233	return false;
	234	}
[372]	235	}
[645]	236
	237	if (1)
[574]	238	{
	239	Vector3 vtx = mVertices.back();
	240	VertexContainer::const_iterator it, it_end = mVertices.end();
[372]	241
[574]	242	for (it = mVertices.begin(); it != it_end; ++it)
[372]	243	{
[645]	244	if (EpsilonEqualV3(vtx, *it, 0.0001))
[574]	245	{
	246	//Debug << "Malformed vertices:\n" << *this << endl;
	247	return false;
	248	}
	249	vtx = *it;
[372]	250	}
	251	}
[574]	252	#endif
	253
[372]	254	return true;
	255	}
	256
[574]	257
[372]	258	void Polygon3::IncludeInBox(const PolygonContainer &polys, AxisAlignedBox3 &box)
	259	{
	260	PolygonContainer::const_iterator it, it_end = polys.end();
	261
	262	for (it = polys.begin(); it != it_end; ++ it)
	263	box.Include((it));
	264	}
	265
[574]	266
[314]	267	// int_lineseg returns 1 if the given line segment intersects a 2D
	268	// ray travelling in the positive X direction. This is used in the
	269	// Jordan curve computation for polygon intersection.
	270	inline int
	271	int_lineseg(float px,
	272	float py,
	273	float u1,
	274	float v1,
	275	float u2,
	276	float v2)
	277	{
	278	float t;
	279	float ydiff;
	280
	281	u1 -= px; u2 -= px; // translate line
	282	v1 -= py; v2 -= py;
	283
	284	if ((v1 > 0 && v2 > 0) \|\|
	285	(v1 < 0 && v2 < 0) \|\|
	286	(u1 < 0 && u2 < 0))
	287	return 0;
	288
	289	if (u1 > 0 && u2 > 0)
	290	return 1;
	291
	292	ydiff = v2 - v1;
	293
	294	if (fabs(ydiff) < Limits::Small)
	295	{ // denominator near 0
	296	if (((fabs(v1) > Limits::Small) \|\| (u1 > 0) \|\| (u2 > 0)))
	297	return 0;
	298	return 1;
	299	}
	300
	301	t = -v1 / ydiff; // Compute parameter
	302
	303	return (u1 + t * (u2 - u1)) > 0;
	304	}
	305
[574]	306
[314]	307	int Polygon3::CastRay(const Ray &ray, float &t, const float nearestT)
	308	{
	309	Plane3 plane = GetSupportingPlane();
	310	float dot = DotProd(plane.mNormal, ray.GetDir());
	311
	312	// Watch for near-zero denominator
	313	// ONLY single sided polygons!!!!!
	314	if (dot > -Limits::Small)
	315	// if (fabs(dot) < Limits::Small)
	316	return Ray::NO_INTERSECTION;
	317
	318	t = (-plane.mD - DotProd(plane.mNormal, ray.GetLoc())) / dot;
	319
	320	if (t <= Limits::Small)
	321	return Ray::INTERSECTION_OUT_OF_LIMITS;
	322
	323	if (t >= nearestT) {
	324	return Ray::INTERSECTION_OUT_OF_LIMITS; // no intersection was found
	325	}
	326
	327	int count = 0;
	328	float u, v, u1, v1, u2, v2;
	329	int i;
	330
	331	int paxis = plane.mNormal.DrivingAxis();
	332
	333	// Project the intersection point onto the coordinate plane
	334	// specified by which.
	335	ray.Extrap(t).ExtractVerts(&u, &v, paxis);
	336
	337	int size = (int)mVertices.size();
	338
	339	mVertices.back().ExtractVerts(&u1, &v1, paxis );
	340
	341	if (0 && size <= 4)
	342	{
	343	// assume a convex face
	344	for (i = 0; i < size; i++)
	345	{
	346	mVertices[i].ExtractVerts(&u2, &v2, paxis);
	347
	348	// line u1, v1, u2, v2
	349
	350	if ((v2 - v1)(u1 - u) > (u2 - u1)(v1 - v))
	351	return Ray::NO_INTERSECTION;
	352
	353	u1 = u2;
	354	v1 = v2;
	355	}
	356
	357	return Ray::INTERSECTION;
	358	}
	359
	360	// We're stuck with the Jordan curve computation. Count number
	361	// of intersections between the line segments the polygon comprises
	362	// with a ray originating at the point of intersection and
	363	// travelling in the positive X direction.
	364	for (i = 0; i < size; i++)
	365	{
	366	mVertices[i].ExtractVerts(&u2, &v2, paxis);
	367
	368	count += (int_lineseg(u, v, u1, v1, u2, v2) != 0);
	369
	370	u1 = u2;
	371	v1 = v2;
	372	}
	373
	374	// We hit polygon if number of intersections is odd.
	375	return (count & 1) ? Ray::INTERSECTION : Ray::NO_INTERSECTION;
	376	}
	377
[574]	378
[372]	379	void Polygon3::InheritRays(Polygon3 &front_piece,
	380	Polygon3 &back_piece) const
	381	{
	382	if (mPiercingRays.empty())
	383	return;
	384
	385	RayContainer::const_iterator it,
	386	it_end = mPiercingRays.end();
	387
	388	for (it = mPiercingRays.begin(); it != it_end; ++ it)
	389	{
	390	switch((*it)->GetId())
	391	{
	392	case Ray::BACK:
	393	back_piece.mPiercingRays.push_back(*it);
	394	break;
	395	case Ray::FRONT:
	396	front_piece.mPiercingRays.push_back(*it);
	397	break;
	398	case Ray::FRONT_BACK:
	399	back_piece.mPiercingRays.push_back(*it);
	400	break;
	401	case Ray::BACK_FRONT:
	402	front_piece.mPiercingRays.push_back(*it);
	403	break;
	404	default:
	405	break;
	406	}
	407	}
	408	}
	409
[574]	410
[448]	411	int Polygon3::ClassifyPlane(const PolygonContainer &polys,
	412	const Plane3 &plane,
	413	const float epsilon)
[372]	414	{
	415	PolygonContainer::const_iterator it;
	416
	417	bool onFrontSide = false;
	418	bool onBackSide = false;
	419
	420	// find intersections
	421	for (it = polys.begin(); it != polys.end(); ++ it)
	422	{
[448]	423	const int cf = (*it)->ClassifyPlane(plane, epsilon);
[372]	424
	425	if (cf == FRONT_SIDE)
	426	onFrontSide = true;
	427	else if (cf == BACK_SIDE)
	428	onBackSide = true;
	429
	430	if ((cf == SPLIT) \|\| (cf == COINCIDENT) \|\| (onFrontSide && onBackSide))
	431	{
	432	return SPLIT;
	433	}
	434	}
	435
	436	if (onBackSide)
	437	{
	438	return BACK_SIDE;
	439	}
	440	else if (onFrontSide)
	441	{
	442	return FRONT_SIDE;
	443	}
	444
	445	return SPLIT;
	446	}
	447
[574]	448
[375]	449	int Polygon3::ParentObjectsSize(const PolygonContainer &polys)
[372]	450	{
	451	int count = 0;
	452
	453	PolygonContainer::const_iterator it, it_end = polys.end();
	454
	455	MeshInstance::NewMail();
	456
	457	for (it = polys.begin(); it != it_end; ++ it)
	458	{
	459	if ((it)->mParent && !(it)->mParent->Mailed())
	460	{
	461	++ count;
	462	(*it)->mParent->Mail();
	463	}
	464	}
	465	return count;
[384]	466	}
	467
[574]	468
[384]	469	float Polygon3::GetArea(const PolygonContainer &cell)
	470	{
	471	float area = 0;
	472	PolygonContainer::const_iterator pit;
	473
	474	for (pit = cell.begin(); pit != cell.end(); ++ pit)
[448]	475	{
[384]	476	area += (*pit)->GetArea();
[448]	477	}
[396]	478
[384]	479	return area;
[396]	480	}
	481
	482
	483	Polygon3 *Polygon3::CreateReversePolygon() const
	484	{
	485	Polygon3 *revPoly = new Polygon3();
	486
	487	VertexContainer::const_reverse_iterator rit,
	488	rit_end = mVertices.rend();
	489
	490	for(rit = mVertices.rbegin(); rit != rit_end; ++ rit)
[448]	491	revPoly->mVertices.push_back(*rit);
	492
	493	return revPoly;
[503]	494	}
	495
	496
	497	void Polygon3::Triangulate(vector<Triangle3> &triangles)
	498	{
	499	int i = 1;
	500	int j = 0;
[508]	501	int k = (int)mVertices.size() - 1;
[503]	502	int count = 0;
	503
	504	while (i < k)
	505	{
	506	triangles.push_back(Triangle3(mVertices[i], mVertices[j], mVertices[k]));
	507
	508	if ((count ++) % 2)
	509	j = i ++;
	510	else
	511	j = k --;
	512	}
	513	}
[508]	514
	515
	516	void Polygon3::Triangulate(VertexIndexContainer &indices)
	517	{
	518	int i = 1;
	519	int j = 0;
	520	int k = (int)mVertices.size() - 1;
	521
	522	int count = 0;
	523
	524	while (i < k)
	525	{
	526	indices.push_back(k);
	527	indices.push_back(j);
	528	indices.push_back(i);
	529
	530	if ((count ++) % 2)
	531	j = i ++;
	532	else
	533	j = k --;
	534	}
	535	}
	536
	537
	538	void Polygon3::AddToMesh(Mesh &mesh)
	539	{
	540	const int n = (int)mesh.mVertices.size();
	541
	542	//-- add the vertices
	543	VertexContainer::const_iterator vit, vit_end = mVertices.end();
	544	for (vit = mVertices.begin(); vit != vit_end; ++ vit)
	545	{
	546	mesh.mVertices.push_back(*vit);
	547	}
	548
	549	// one quad => no triangulation necessary
	550	if ((int)mVertices.size() == 4)
	551	{
	552	mesh.AddFace(new Face(n, n + 1, n + 2, n + 3));
	553	}
	554	else
	555	{
	556	VertexIndexContainer indices;
	557	Triangulate(indices);
	558
	559	// add indices of triangle strip
	560	for (int i = 0; i < (int)indices.size(); i += 3)
	561	{
	562	Face *face = new Face(n + indices[i],
	563	n + indices[i + 1],
	564	n + indices[i + 2]);
	565	mesh.AddFace(face);
	566	}
	567	}
	568	}

Note: See TracBrowser for help on using the repository browser.

Download in other formats: