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source: code/branches/questsystem5/src/bullet/BulletCollision/NarrowPhaseCollision/btVoronoiSimplexSolver.cpp @ 2961

Last change on this file since 2961 was 2908, checked in by dafrick, 16 years ago
Reverted to revision 2906 (because I'm too stupid to merge correctly, 2nd try will follow shortly. )
Property svn:eol-style set to `native`
File size: 17.0 KB

Rev	Line
[1963]	1
	2	/*
	3	Bullet Continuous Collision Detection and Physics Library
	4	Copyright (c) 2003-2006 Erwin Coumans http://continuousphysics.com/Bullet/
	5
	6	This software is provided 'as-is', without any express or implied warranty.
	7	In no event will the authors be held liable for any damages arising from the use of this software.
	8	Permission is granted to anyone to use this software for any purpose,
	9	including commercial applications, and to alter it and redistribute it freely,
	10	subject to the following restrictions:
	11
	12	1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required.
	13	2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
	14	3. This notice may not be removed or altered from any source distribution.
	15
	16	Elsevier CDROM license agreements grants nonexclusive license to use the software
	17	for any purpose, commercial or non-commercial as long as the following credit is included
	18	identifying the original source of the software:
	19
	20	Parts of the source are "from the book Real-Time Collision Detection by
	21	Christer Ericson, published by Morgan Kaufmann Publishers,
	22	(c) 2005 Elsevier Inc."
	23
	24	*/
	25
	26
	27	#include "btVoronoiSimplexSolver.h"
[2908]	28	#include <assert.h>
	29	//#include <stdio.h>
[1963]	30
	31	#define VERTA 0
	32	#define VERTB 1
	33	#define VERTC 2
	34	#define VERTD 3
	35
	36	#define CATCH_DEGENERATE_TETRAHEDRON 1
	37	void btVoronoiSimplexSolver::removeVertex(int index)
	38	{
	39
[2908]	40	assert(m_numVertices>0);
[1963]	41	m_numVertices--;
	42	m_simplexVectorW[index] = m_simplexVectorW[m_numVertices];
	43	m_simplexPointsP[index] = m_simplexPointsP[m_numVertices];
	44	m_simplexPointsQ[index] = m_simplexPointsQ[m_numVertices];
	45	}
	46
	47	void btVoronoiSimplexSolver::reduceVertices (const btUsageBitfield& usedVerts)
	48	{
	49	if ((numVertices() >= 4) && (!usedVerts.usedVertexD))
	50	removeVertex(3);
	51
	52	if ((numVertices() >= 3) && (!usedVerts.usedVertexC))
	53	removeVertex(2);
	54
	55	if ((numVertices() >= 2) && (!usedVerts.usedVertexB))
	56	removeVertex(1);
	57
	58	if ((numVertices() >= 1) && (!usedVerts.usedVertexA))
	59	removeVertex(0);
	60
	61	}
	62
	63
	64
	65
	66
	67	//clear the simplex, remove all the vertices
	68	void btVoronoiSimplexSolver::reset()
	69	{
	70	m_cachedValidClosest = false;
	71	m_numVertices = 0;
	72	m_needsUpdate = true;
	73	m_lastW = btVector3(btScalar(1e30),btScalar(1e30),btScalar(1e30));
	74	m_cachedBC.reset();
	75	}
	76
	77
	78
	79	//add a vertex
[2430]	80	void btVoronoiSimplexSolver::addVertex(const btVector3& w, const btVector3& p, const btVector3& q)
[1963]	81	{
	82	m_lastW = w;
	83	m_needsUpdate = true;
	84
	85	m_simplexVectorW[m_numVertices] = w;
	86	m_simplexPointsP[m_numVertices] = p;
	87	m_simplexPointsQ[m_numVertices] = q;
	88
	89	m_numVertices++;
	90	}
	91
	92	bool btVoronoiSimplexSolver::updateClosestVectorAndPoints()
	93	{
	94
	95	if (m_needsUpdate)
	96	{
	97	m_cachedBC.reset();
	98
	99	m_needsUpdate = false;
	100
	101	switch (numVertices())
	102	{
	103	case 0:
	104	m_cachedValidClosest = false;
	105	break;
	106	case 1:
	107	{
	108	m_cachedP1 = m_simplexPointsP[0];
	109	m_cachedP2 = m_simplexPointsQ[0];
	110	m_cachedV = m_cachedP1-m_cachedP2; //== m_simplexVectorW[0]
	111	m_cachedBC.reset();
	112	m_cachedBC.setBarycentricCoordinates(btScalar(1.),btScalar(0.),btScalar(0.),btScalar(0.));
	113	m_cachedValidClosest = m_cachedBC.isValid();
	114	break;
	115	};
	116	case 2:
	117	{
	118	//closest point origin from line segment
	119	const btVector3& from = m_simplexVectorW[0];
	120	const btVector3& to = m_simplexVectorW[1];
	121	btVector3 nearest;
	122
	123	btVector3 p (btScalar(0.),btScalar(0.),btScalar(0.));
	124	btVector3 diff = p - from;
	125	btVector3 v = to - from;
	126	btScalar t = v.dot(diff);
	127
	128	if (t > 0) {
	129	btScalar dotVV = v.dot(v);
	130	if (t < dotVV) {
	131	t /= dotVV;
	132	diff -= t*v;
	133	m_cachedBC.m_usedVertices.usedVertexA = true;
	134	m_cachedBC.m_usedVertices.usedVertexB = true;
	135	} else {
	136	t = 1;
	137	diff -= v;
	138	//reduce to 1 point
	139	m_cachedBC.m_usedVertices.usedVertexB = true;
	140	}
	141	} else
	142	{
	143	t = 0;
	144	//reduce to 1 point
	145	m_cachedBC.m_usedVertices.usedVertexA = true;
	146	}
	147	m_cachedBC.setBarycentricCoordinates(1-t,t);
	148	nearest = from + t*v;
	149
	150	m_cachedP1 = m_simplexPointsP[0] + t * (m_simplexPointsP[1] - m_simplexPointsP[0]);
	151	m_cachedP2 = m_simplexPointsQ[0] + t * (m_simplexPointsQ[1] - m_simplexPointsQ[0]);
	152	m_cachedV = m_cachedP1 - m_cachedP2;
	153
	154	reduceVertices(m_cachedBC.m_usedVertices);
	155
	156	m_cachedValidClosest = m_cachedBC.isValid();
	157	break;
	158	}
	159	case 3:
	160	{
	161	//closest point origin from triangle
	162	btVector3 p (btScalar(0.),btScalar(0.),btScalar(0.));
	163
	164	const btVector3& a = m_simplexVectorW[0];
	165	const btVector3& b = m_simplexVectorW[1];
	166	const btVector3& c = m_simplexVectorW[2];
	167
	168	closestPtPointTriangle(p,a,b,c,m_cachedBC);
	169	m_cachedP1 = m_simplexPointsP[0] * m_cachedBC.m_barycentricCoords[0] +
	170	m_simplexPointsP[1] * m_cachedBC.m_barycentricCoords[1] +
	171	m_simplexPointsP[2] * m_cachedBC.m_barycentricCoords[2];
	172
	173	m_cachedP2 = m_simplexPointsQ[0] * m_cachedBC.m_barycentricCoords[0] +
	174	m_simplexPointsQ[1] * m_cachedBC.m_barycentricCoords[1] +
	175	m_simplexPointsQ[2] * m_cachedBC.m_barycentricCoords[2];
	176
	177	m_cachedV = m_cachedP1-m_cachedP2;
	178
	179	reduceVertices (m_cachedBC.m_usedVertices);
	180	m_cachedValidClosest = m_cachedBC.isValid();
	181
	182	break;
	183	}
	184	case 4:
	185	{
	186
	187
	188	btVector3 p (btScalar(0.),btScalar(0.),btScalar(0.));
	189
	190	const btVector3& a = m_simplexVectorW[0];
	191	const btVector3& b = m_simplexVectorW[1];
	192	const btVector3& c = m_simplexVectorW[2];
	193	const btVector3& d = m_simplexVectorW[3];
	194
	195	bool hasSeperation = closestPtPointTetrahedron(p,a,b,c,d,m_cachedBC);
	196
	197	if (hasSeperation)
	198	{
	199
	200	m_cachedP1 = m_simplexPointsP[0] * m_cachedBC.m_barycentricCoords[0] +
	201	m_simplexPointsP[1] * m_cachedBC.m_barycentricCoords[1] +
	202	m_simplexPointsP[2] * m_cachedBC.m_barycentricCoords[2] +
	203	m_simplexPointsP[3] * m_cachedBC.m_barycentricCoords[3];
	204
	205	m_cachedP2 = m_simplexPointsQ[0] * m_cachedBC.m_barycentricCoords[0] +
	206	m_simplexPointsQ[1] * m_cachedBC.m_barycentricCoords[1] +
	207	m_simplexPointsQ[2] * m_cachedBC.m_barycentricCoords[2] +
	208	m_simplexPointsQ[3] * m_cachedBC.m_barycentricCoords[3];
	209
	210	m_cachedV = m_cachedP1-m_cachedP2;
	211	reduceVertices (m_cachedBC.m_usedVertices);
	212	} else
	213	{
	214	// printf("sub distance got penetration\n");
	215
	216	if (m_cachedBC.m_degenerate)
	217	{
	218	m_cachedValidClosest = false;
	219	} else
	220	{
	221	m_cachedValidClosest = true;
	222	//degenerate case == false, penetration = true + zero
	223	m_cachedV.setValue(btScalar(0.),btScalar(0.),btScalar(0.));
	224	}
	225	break;
	226	}
	227
	228	m_cachedValidClosest = m_cachedBC.isValid();
	229
	230	//closest point origin from tetrahedron
	231	break;
	232	}
	233	default:
	234	{
	235	m_cachedValidClosest = false;
	236	}
	237	};
	238	}
	239
	240	return m_cachedValidClosest;
	241
	242	}
	243
	244	//return/calculate the closest vertex
	245	bool btVoronoiSimplexSolver::closest(btVector3& v)
	246	{
	247	bool succes = updateClosestVectorAndPoints();
	248	v = m_cachedV;
	249	return succes;
	250	}
	251
	252
	253
	254	btScalar btVoronoiSimplexSolver::maxVertex()
	255	{
	256	int i, numverts = numVertices();
	257	btScalar maxV = btScalar(0.);
	258	for (i=0;i<numverts;i++)
	259	{
	260	btScalar curLen2 = m_simplexVectorW[i].length2();
	261	if (maxV < curLen2)
	262	maxV = curLen2;
	263	}
	264	return maxV;
	265	}
	266
	267
	268
	269	//return the current simplex
[2430]	270	int btVoronoiSimplexSolver::getSimplex(btVector3 pBuf, btVector3 qBuf, btVector3 *yBuf) const
[1963]	271	{
	272	int i;
	273	for (i=0;i<numVertices();i++)
	274	{
	275	yBuf[i] = m_simplexVectorW[i];
	276	pBuf[i] = m_simplexPointsP[i];
	277	qBuf[i] = m_simplexPointsQ[i];
	278	}
	279	return numVertices();
	280	}
	281
	282
	283
	284
	285	bool btVoronoiSimplexSolver::inSimplex(const btVector3& w)
	286	{
	287	bool found = false;
	288	int i, numverts = numVertices();
	289	//btScalar maxV = btScalar(0.);
	290
	291	//w is in the current (reduced) simplex
	292	for (i=0;i<numverts;i++)
	293	{
	294	if (m_simplexVectorW[i] == w)
	295	found = true;
	296	}
	297
	298	//check in case lastW is already removed
	299	if (w == m_lastW)
	300	return true;
	301
	302	return found;
	303	}
	304
	305	void btVoronoiSimplexSolver::backup_closest(btVector3& v)
	306	{
	307	v = m_cachedV;
	308	}
	309
	310
	311	bool btVoronoiSimplexSolver::emptySimplex() const
	312	{
	313	return (numVertices() == 0);
	314
	315	}
	316
[2430]	317	void btVoronoiSimplexSolver::compute_points(btVector3& p1, btVector3& p2)
[1963]	318	{
	319	updateClosestVectorAndPoints();
	320	p1 = m_cachedP1;
	321	p2 = m_cachedP2;
	322
	323	}
	324
	325
	326
	327
[2430]	328	bool btVoronoiSimplexSolver::closestPtPointTriangle(const btVector3& p, const btVector3& a, const btVector3& b, const btVector3& c,btSubSimplexClosestResult& result)
[1963]	329	{
	330	result.m_usedVertices.reset();
	331
	332	// Check if P in vertex region outside A
	333	btVector3 ab = b - a;
	334	btVector3 ac = c - a;
	335	btVector3 ap = p - a;
	336	btScalar d1 = ab.dot(ap);
	337	btScalar d2 = ac.dot(ap);
	338	if (d1 <= btScalar(0.0) && d2 <= btScalar(0.0))
	339	{
	340	result.m_closestPointOnSimplex = a;
	341	result.m_usedVertices.usedVertexA = true;
	342	result.setBarycentricCoordinates(1,0,0);
	343	return true;// a; // barycentric coordinates (1,0,0)
	344	}
	345
	346	// Check if P in vertex region outside B
	347	btVector3 bp = p - b;
	348	btScalar d3 = ab.dot(bp);
	349	btScalar d4 = ac.dot(bp);
	350	if (d3 >= btScalar(0.0) && d4 <= d3)
	351	{
	352	result.m_closestPointOnSimplex = b;
	353	result.m_usedVertices.usedVertexB = true;
	354	result.setBarycentricCoordinates(0,1,0);
	355
	356	return true; // b; // barycentric coordinates (0,1,0)
	357	}
	358	// Check if P in edge region of AB, if so return projection of P onto AB
	359	btScalar vc = d1d4 - d3d2;
	360	if (vc <= btScalar(0.0) && d1 >= btScalar(0.0) && d3 <= btScalar(0.0)) {
	361	btScalar v = d1 / (d1 - d3);
	362	result.m_closestPointOnSimplex = a + v * ab;
	363	result.m_usedVertices.usedVertexA = true;
	364	result.m_usedVertices.usedVertexB = true;
	365	result.setBarycentricCoordinates(1-v,v,0);
	366	return true;
	367	//return a + v * ab; // barycentric coordinates (1-v,v,0)
	368	}
	369
	370	// Check if P in vertex region outside C
	371	btVector3 cp = p - c;
	372	btScalar d5 = ab.dot(cp);
	373	btScalar d6 = ac.dot(cp);
	374	if (d6 >= btScalar(0.0) && d5 <= d6)
	375	{
	376	result.m_closestPointOnSimplex = c;
	377	result.m_usedVertices.usedVertexC = true;
	378	result.setBarycentricCoordinates(0,0,1);
	379	return true;//c; // barycentric coordinates (0,0,1)
	380	}
	381
	382	// Check if P in edge region of AC, if so return projection of P onto AC
	383	btScalar vb = d5d2 - d1d6;
	384	if (vb <= btScalar(0.0) && d2 >= btScalar(0.0) && d6 <= btScalar(0.0)) {
	385	btScalar w = d2 / (d2 - d6);
	386	result.m_closestPointOnSimplex = a + w * ac;
	387	result.m_usedVertices.usedVertexA = true;
	388	result.m_usedVertices.usedVertexC = true;
	389	result.setBarycentricCoordinates(1-w,0,w);
	390	return true;
	391	//return a + w * ac; // barycentric coordinates (1-w,0,w)
	392	}
	393
	394	// Check if P in edge region of BC, if so return projection of P onto BC
	395	btScalar va = d3d6 - d5d4;
	396	if (va <= btScalar(0.0) && (d4 - d3) >= btScalar(0.0) && (d5 - d6) >= btScalar(0.0)) {
	397	btScalar w = (d4 - d3) / ((d4 - d3) + (d5 - d6));
	398
	399	result.m_closestPointOnSimplex = b + w * (c - b);
	400	result.m_usedVertices.usedVertexB = true;
	401	result.m_usedVertices.usedVertexC = true;
	402	result.setBarycentricCoordinates(0,1-w,w);
	403	return true;
	404	// return b + w * (c - b); // barycentric coordinates (0,1-w,w)
	405	}
	406
	407	// P inside face region. Compute Q through its barycentric coordinates (u,v,w)
	408	btScalar denom = btScalar(1.0) / (va + vb + vc);
	409	btScalar v = vb * denom;
	410	btScalar w = vc * denom;
	411
	412	result.m_closestPointOnSimplex = a + ab * v + ac * w;
	413	result.m_usedVertices.usedVertexA = true;
	414	result.m_usedVertices.usedVertexB = true;
	415	result.m_usedVertices.usedVertexC = true;
	416	result.setBarycentricCoordinates(1-v-w,v,w);
	417
	418	return true;
	419	// return a + ab * v + ac * w; // = ua + vb + wc, u = va denom = btScalar(1.0) - v - w
	420
	421	}
	422
	423
	424
	425
	426
	427	/// Test if point p and d lie on opposite sides of plane through abc
[2430]	428	int btVoronoiSimplexSolver::pointOutsideOfPlane(const btVector3& p, const btVector3& a, const btVector3& b, const btVector3& c, const btVector3& d)
[1963]	429	{
	430	btVector3 normal = (b-a).cross(c-a);
	431
	432	btScalar signp = (p - a).dot(normal); // [AP AB AC]
	433	btScalar signd = (d - a).dot( normal); // [AD AB AC]
	434
	435	#ifdef CATCH_DEGENERATE_TETRAHEDRON
	436	#ifdef BT_USE_DOUBLE_PRECISION
	437	if (signd * signd < (btScalar(1e-8) * btScalar(1e-8)))
	438	{
	439	return -1;
	440	}
	441	#else
	442	if (signd * signd < (btScalar(1e-4) * btScalar(1e-4)))
	443	{
	444	// printf("affine dependent/degenerate\n");//
	445	return -1;
	446	}
	447	#endif
	448
	449	#endif
	450	// Points on opposite sides if expression signs are opposite
	451	return signp * signd < btScalar(0.);
	452	}
	453
	454
[2430]	455	bool btVoronoiSimplexSolver::closestPtPointTetrahedron(const btVector3& p, const btVector3& a, const btVector3& b, const btVector3& c, const btVector3& d, btSubSimplexClosestResult& finalResult)
[1963]	456	{
	457	btSubSimplexClosestResult tempResult;
	458
	459	// Start out assuming point inside all halfspaces, so closest to itself
	460	finalResult.m_closestPointOnSimplex = p;
	461	finalResult.m_usedVertices.reset();
	462	finalResult.m_usedVertices.usedVertexA = true;
	463	finalResult.m_usedVertices.usedVertexB = true;
	464	finalResult.m_usedVertices.usedVertexC = true;
	465	finalResult.m_usedVertices.usedVertexD = true;
	466
	467	int pointOutsideABC = pointOutsideOfPlane(p, a, b, c, d);
	468	int pointOutsideACD = pointOutsideOfPlane(p, a, c, d, b);
	469	int pointOutsideADB = pointOutsideOfPlane(p, a, d, b, c);
	470	int pointOutsideBDC = pointOutsideOfPlane(p, b, d, c, a);
	471
	472	if (pointOutsideABC < 0 \|\| pointOutsideACD < 0 \|\| pointOutsideADB < 0 \|\| pointOutsideBDC < 0)
	473	{
	474	finalResult.m_degenerate = true;
	475	return false;
	476	}
	477
	478	if (!pointOutsideABC && !pointOutsideACD && !pointOutsideADB && !pointOutsideBDC)
	479	{
	480	return false;
	481	}
	482
	483
	484	btScalar bestSqDist = FLT_MAX;
	485	// If point outside face abc then compute closest point on abc
	486	if (pointOutsideABC)
	487	{
	488	closestPtPointTriangle(p, a, b, c,tempResult);
[2430]	489	btVector3 q = tempResult.m_closestPointOnSimplex;
[1963]	490
	491	btScalar sqDist = (q - p).dot( q - p);
	492	// Update best closest point if (squared) distance is less than current best
	493	if (sqDist < bestSqDist) {
	494	bestSqDist = sqDist;
	495	finalResult.m_closestPointOnSimplex = q;
	496	//convert result bitmask!
	497	finalResult.m_usedVertices.reset();
	498	finalResult.m_usedVertices.usedVertexA = tempResult.m_usedVertices.usedVertexA;
	499	finalResult.m_usedVertices.usedVertexB = tempResult.m_usedVertices.usedVertexB;
	500	finalResult.m_usedVertices.usedVertexC = tempResult.m_usedVertices.usedVertexC;
	501	finalResult.setBarycentricCoordinates(
	502	tempResult.m_barycentricCoords[VERTA],
	503	tempResult.m_barycentricCoords[VERTB],
	504	tempResult.m_barycentricCoords[VERTC],
	505	0
	506	);
	507
	508	}
	509	}
	510
	511
	512	// Repeat test for face acd
	513	if (pointOutsideACD)
	514	{
	515	closestPtPointTriangle(p, a, c, d,tempResult);
[2430]	516	btVector3 q = tempResult.m_closestPointOnSimplex;
[1963]	517	//convert result bitmask!
	518
	519	btScalar sqDist = (q - p).dot( q - p);
	520	if (sqDist < bestSqDist)
	521	{
	522	bestSqDist = sqDist;
	523	finalResult.m_closestPointOnSimplex = q;
	524	finalResult.m_usedVertices.reset();
	525	finalResult.m_usedVertices.usedVertexA = tempResult.m_usedVertices.usedVertexA;
	526
	527	finalResult.m_usedVertices.usedVertexC = tempResult.m_usedVertices.usedVertexB;
	528	finalResult.m_usedVertices.usedVertexD = tempResult.m_usedVertices.usedVertexC;
	529	finalResult.setBarycentricCoordinates(
	530	tempResult.m_barycentricCoords[VERTA],
	531	0,
	532	tempResult.m_barycentricCoords[VERTB],
	533	tempResult.m_barycentricCoords[VERTC]
	534	);
	535
	536	}
	537	}
	538	// Repeat test for face adb
	539
	540
	541	if (pointOutsideADB)
	542	{
	543	closestPtPointTriangle(p, a, d, b,tempResult);
[2430]	544	btVector3 q = tempResult.m_closestPointOnSimplex;
[1963]	545	//convert result bitmask!
	546
	547	btScalar sqDist = (q - p).dot( q - p);
	548	if (sqDist < bestSqDist)
	549	{
	550	bestSqDist = sqDist;
	551	finalResult.m_closestPointOnSimplex = q;
	552	finalResult.m_usedVertices.reset();
	553	finalResult.m_usedVertices.usedVertexA = tempResult.m_usedVertices.usedVertexA;
	554	finalResult.m_usedVertices.usedVertexB = tempResult.m_usedVertices.usedVertexC;
	555
	556	finalResult.m_usedVertices.usedVertexD = tempResult.m_usedVertices.usedVertexB;
	557	finalResult.setBarycentricCoordinates(
	558	tempResult.m_barycentricCoords[VERTA],
	559	tempResult.m_barycentricCoords[VERTC],
	560	0,
	561	tempResult.m_barycentricCoords[VERTB]
	562	);
	563
	564	}
	565	}
	566	// Repeat test for face bdc
	567
	568
	569	if (pointOutsideBDC)
	570	{
	571	closestPtPointTriangle(p, b, d, c,tempResult);
[2430]	572	btVector3 q = tempResult.m_closestPointOnSimplex;
[1963]	573	//convert result bitmask!
	574	btScalar sqDist = (q - p).dot( q - p);
	575	if (sqDist < bestSqDist)
	576	{
	577	bestSqDist = sqDist;
	578	finalResult.m_closestPointOnSimplex = q;
	579	finalResult.m_usedVertices.reset();
	580	//
	581	finalResult.m_usedVertices.usedVertexB = tempResult.m_usedVertices.usedVertexA;
	582	finalResult.m_usedVertices.usedVertexC = tempResult.m_usedVertices.usedVertexC;
	583	finalResult.m_usedVertices.usedVertexD = tempResult.m_usedVertices.usedVertexB;
	584
	585	finalResult.setBarycentricCoordinates(
	586	0,
	587	tempResult.m_barycentricCoords[VERTA],
	588	tempResult.m_barycentricCoords[VERTC],
	589	tempResult.m_barycentricCoords[VERTB]
	590	);
	591
	592	}
	593	}
	594
	595	//help! we ended up full !
	596
	597	if (finalResult.m_usedVertices.usedVertexA &&
	598	finalResult.m_usedVertices.usedVertexB &&
	599	finalResult.m_usedVertices.usedVertexC &&
	600	finalResult.m_usedVertices.usedVertexD)
	601	{
	602	return true;
	603	}
	604
	605	return true;
	606	}
	607

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