blender/extern/bullet/Bullet/NarrowPhaseCollision/GjkPairDetector.cpp

/*
Bullet Continuous Collision Detection and Physics Library
Copyright (c) 2003-2006 Erwin Coumans  http://continuousphysics.com/Bullet/

This software is provided 'as-is', without any express or implied warranty.
In no event will the authors be held liable for any damages arising from the use of this software.
Permission is granted to anyone to use this software for any purpose, 
including commercial applications, and to alter it and redistribute it freely, 
subject to the following restrictions:

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.
2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
3. This notice may not be removed or altered from any source distribution.
*/

#include "GjkPairDetector.h"
#include "CollisionShapes/ConvexShape.h"
#include "NarrowPhaseCollision/SimplexSolverInterface.h"
#include "NarrowPhaseCollision/ConvexPenetrationDepthSolver.h"

#if defined(DEBUG) || defined (_DEBUG)
#include <stdio.h> //for debug printf
#endif

static const SimdScalar rel_error = SimdScalar(1.0e-5);
SimdScalar rel_error2 = rel_error * rel_error;
float maxdist2 = 1.e30f;


int gGjkMaxIter=1000;

GjkPairDetector::GjkPairDetector(ConvexShape* objectA,ConvexShape* objectB,SimplexSolverInterface* simplexSolver,ConvexPenetrationDepthSolver*	penetrationDepthSolver)
:m_cachedSeparatingAxis(0.f,0.f,1.f),
m_penetrationDepthSolver(penetrationDepthSolver),
m_simplexSolver(simplexSolver),
m_minkowskiA(objectA),
m_minkowskiB(objectB),
m_ignoreMargin(false),
m_partId0(-1),
m_index0(-1),
m_partId1(-1),
m_index1(-1)
{
}

void GjkPairDetector::GetClosestPoints(const ClosestPointInput& input,Result& output,class IDebugDraw* debugDraw)
{
	SimdScalar distance=0.f;
	SimdVector3	normalInB(0.f,0.f,0.f);
	SimdVector3 pointOnA,pointOnB;

	float marginA = m_minkowskiA->GetMargin();
	float marginB = m_minkowskiB->GetMargin();

	//for CCD we don't use margins
	if (m_ignoreMargin)
	{
		marginA = 0.f;
		marginB = 0.f;
	}

int curIter = 0;

	bool isValid = false;
	bool checkSimplex = false;
	bool checkPenetration = true;

	{
		SimdScalar squaredDistance = SIMD_INFINITY;
		SimdScalar delta = 0.f;
		
		SimdScalar margin = marginA + marginB;
		
		

		m_simplexSolver->reset();
		
		while (true)
		{
			//rare failure case, perhaps deferate shapes?
			if (curIter++ > gGjkMaxIter)
			{
				#if defined(DEBUG) || defined (_DEBUG)
					printf("GjkPairDetector maxIter exceeded:%i\n",curIter);
					printf("sepAxis=(%f,%f,%f), squaredDistance = %f, shapeTypeA=%i,shapeTypeB=%i\n",
					m_cachedSeparatingAxis.getX(),
					m_cachedSeparatingAxis.getY(),
					m_cachedSeparatingAxis.getZ(),
					squaredDistance,
					m_minkowskiA->GetShapeType(),
					m_minkowskiB->GetShapeType());
				#endif
				break;

			}

			SimdVector3 seperatingAxisInA = (-m_cachedSeparatingAxis)* input.m_transformA.getBasis();
			SimdVector3 seperatingAxisInB = m_cachedSeparatingAxis* input.m_transformB.getBasis();

			SimdVector3 pInA = m_minkowskiA->LocalGetSupportingVertexWithoutMargin(seperatingAxisInA);
			SimdVector3 qInB = m_minkowskiB->LocalGetSupportingVertexWithoutMargin(seperatingAxisInB);
			SimdPoint3  pWorld = input.m_transformA(pInA);	
			SimdPoint3  qWorld = input.m_transformB(qInB);
			
			SimdVector3 w	= pWorld - qWorld;
			delta = m_cachedSeparatingAxis.dot(w);

			// potential exit, they don't overlap
			if ((delta > SimdScalar(0.0)) && (delta * delta > squaredDistance * input.m_maximumDistanceSquared)) 
			{
				checkPenetration = false;
				break;
			}

			//exit 0: the new point is already in the simplex, or we didn't come any closer
			if (m_simplexSolver->inSimplex(w))
			{
				checkSimplex = true;
				break;
			}
			// are we getting any closer ?
			if (squaredDistance - delta <= squaredDistance * rel_error2)
			{
				checkSimplex = true;
				break;
			}
			//add current vertex to simplex
			m_simplexSolver->addVertex(w, pWorld, qWorld);

			//calculate the closest point to the origin (update vector v)
			if (!m_simplexSolver->closest(m_cachedSeparatingAxis))
			{
				checkSimplex = true;
				break;
			}

			SimdScalar previousSquaredDistance = squaredDistance;
			squaredDistance = m_cachedSeparatingAxis.length2();
			
			//redundant m_simplexSolver->compute_points(pointOnA, pointOnB);

			//are we getting any closer ?
			if (previousSquaredDistance - squaredDistance <= SIMD_EPSILON * previousSquaredDistance) 
			{ 
				m_simplexSolver->backup_closest(m_cachedSeparatingAxis);
				checkSimplex = true;
				break;
			}
			bool check = (!m_simplexSolver->fullSimplex());
			//bool check = (!m_simplexSolver->fullSimplex() && squaredDistance > SIMD_EPSILON * m_simplexSolver->maxVertex());

			if (!check)
			{
				//do we need this backup_closest here ?
				m_simplexSolver->backup_closest(m_cachedSeparatingAxis);
				break;
			}
		}

		if (checkSimplex)
		{
			m_simplexSolver->compute_points(pointOnA, pointOnB);
			normalInB = pointOnA-pointOnB;
			float lenSqr = m_cachedSeparatingAxis.length2();
			//valid normal
			if (lenSqr > (SIMD_EPSILON*SIMD_EPSILON))
			{
				float rlen = 1.f / SimdSqrt(lenSqr );
				normalInB *= rlen; //normalize
				SimdScalar s = SimdSqrt(squaredDistance);
				ASSERT(s > SimdScalar(0.0));
				pointOnA -= m_cachedSeparatingAxis * (marginA / s);
				pointOnB += m_cachedSeparatingAxis * (marginB / s);
				distance = ((1.f/rlen) - margin);
				isValid = true;
			}
		}

		if (checkPenetration && !isValid)
		{
			//penetration case
		
			//if there is no way to handle penetrations, bail out
			if (m_penetrationDepthSolver)
			{
				// Penetration depth case.
				isValid = m_penetrationDepthSolver->CalcPenDepth( 
					*m_simplexSolver, 
					m_minkowskiA,m_minkowskiB,
					input.m_transformA,input.m_transformB,
					m_cachedSeparatingAxis, pointOnA, pointOnB,
					debugDraw
					);

				if (isValid)
				{
					normalInB = pointOnB-pointOnA;
					float lenSqr = normalInB.length2();
					if (lenSqr > (SIMD_EPSILON*SIMD_EPSILON))
					{
						normalInB /= SimdSqrt(lenSqr);
						distance = -(pointOnA-pointOnB).length();
					} else
					{
						isValid = false;
					}
				}
			}
		}
	}

	if (isValid)
	{
		output.SetShapeIdentifiers(m_partId0,m_index0,m_partId1,m_index1);

		output.AddContactPoint(
			normalInB,
			pointOnB,
			distance);
		//printf("gjk add:%f",distance);
	} 


}