Preparation to add signed distance field collision detection.

btMiniSDF is based on https://github.com/InteractiveComputerGraphics/Discregrid
2018-04-08 21:10:03 -07:00
parent 380e59be6a
commit 698836d54e
7 changed files with 858 additions and 14 deletions
--- a/examples/ExampleBrowser/CollisionShape2TriangleMesh.cpp
+++ b/examples/ExampleBrowser/CollisionShape2TriangleMesh.cpp
@@ -184,9 +184,15 @@ void CollisionShape2TriangleMesh(btCollisionShape* collisionShape, const btTrans
 						CollisionShape2TriangleMesh(compound->getChildShape(i),childWorldTrans,vertexPositions,vertexNormals,indicesOut);
 					}
 				} else
 				{
 					if (collisionShape->getShapeType()==SDF_SHAPE_PROXYTYPE)
 					{
 						//not yet
 					} else
 					{
 						btAssert(0);
 					}
 				}
 			}
 		}
--- a/src/BulletCollision/BroadphaseCollision/btBroadphaseProxy.h
+++ b/src/BulletCollision/BroadphaseCollision/btBroadphaseProxy.h
@@ -66,6 +66,7 @@ CONCAVE_SHAPES_START_HERE,
 	EMPTY_SHAPE_PROXYTYPE,
 	STATIC_PLANE_PROXYTYPE,
 	CUSTOM_CONCAVE_SHAPE_TYPE,
 	SDF_SHAPE_PROXYTYPE=CUSTOM_CONCAVE_SHAPE_TYPE,
 CONCAVE_SHAPES_END_HERE,
 	COMPOUND_SHAPE_PROXYTYPE,
--- a/src/BulletCollision/CollisionDispatch/btConvexConcaveCollisionAlgorithm.cpp
+++ b/src/BulletCollision/CollisionDispatch/btConvexConcaveCollisionAlgorithm.cpp
@@ -27,6 +27,7 @@ subject to the following restrictions:
 #include "LinearMath/btIDebugDraw.h"
 #include "BulletCollision/NarrowPhaseCollision/btSubSimplexConvexCast.h"
 #include "BulletCollision/CollisionDispatch/btCollisionObjectWrapper.h"
 #include "BulletCollision/CollisionShapes/btSdfCollisionShape.h"
 btConvexConcaveCollisionAlgorithm::btConvexConcaveCollisionAlgorithm( const btCollisionAlgorithmConstructionInfo& ci, const btCollisionObjectWrapper* body0Wrap,const btCollisionObjectWrapper* body1Wrap,bool isSwapped)
 : btActivatingCollisionAlgorithm(ci,body0Wrap,body1Wrap),
@@ -201,10 +202,61 @@ void btConvexConcaveCollisionAlgorithm::processCollision (const btCollisionObjec
 	const btCollisionObjectWrapper* triBodyWrap = m_isSwapped ? body0Wrap : body1Wrap;
 	if (triBodyWrap->getCollisionShape()->isConcave())
 	{
 		if (triBodyWrap->getCollisionShape()->getShapeType()==SDF_SHAPE_PROXYTYPE)
 		{
 			btSdfCollisionShape* sdfShape = (btSdfCollisionShape*)triBodyWrap->getCollisionShape();
 			if (convexBodyWrap->getCollisionShape()->isConvex())
 			{
 				btConvexShape* convex = (btConvexShape*)convexBodyWrap->getCollisionShape();
 				btAlignedObjectArray<btVector3> queryVertices;
 				if (convex->isPolyhedral())
 				{
 					btPolyhedralConvexShape* poly = (btPolyhedralConvexShape*) convex;
 					for (int v=0;v<poly->getNumVertices();v++)
 					{
 						btVector3 vtx;
 						poly->getVertex(v,vtx);
 						queryVertices.push_back(vtx);
 					}
 				}
 				if (convex->getShapeType()==SPHERE_SHAPE_PROXYTYPE)
 				{
 					queryVertices.push_back(btVector3(0,0,0));
 				}
 				if (queryVertices.size())
 				{
 					resultOut->setPersistentManifold(m_btConvexTriangleCallback.m_manifoldPtr);
 					//m_btConvexTriangleCallback.m_manifoldPtr->clearManifold();
 					btPolyhedralConvexShape* poly = (btPolyhedralConvexShape*) convex;
 					for (int v=0;v<queryVertices.size();v++)
 					{
 						const btVector3& vtx = queryVertices[v];
 						btVector3 vtxWorldSpace = convexBodyWrap->getWorldTransform()*vtx;
 						btVector3 vtxInSdf = triBodyWrap->getWorldTransform().invXform(vtxWorldSpace);
 						btVector3 normalLocal;
 						btScalar dist;
 						if (sdfShape->queryPoint(vtxInSdf,dist, normalLocal))
 						{
 							if (dist<=SIMD_EPSILON)
 							{
 								normalLocal.safeNormalize();
 								btVector3 normal = triBodyWrap->getWorldTransform().getBasis()*normalLocal;
 								resultOut->addContactPoint(normal,vtxWorldSpace-normal*dist, dist);
 							}
 						}
 					}
 					resultOut->refreshContactPoints();
 				}
 			}
 		} else
 		{
 			const btConcaveShape* concaveShape = static_cast<const btConcaveShape*>( triBodyWrap->getCollisionShape());
 			if (convexBodyWrap->getCollisionShape()->isConvex())
@@ -223,6 +275,7 @@ void btConvexConcaveCollisionAlgorithm::processCollision (const btCollisionObjec
 				m_btConvexTriangleCallback.clearWrapperData();
 			}
 		}
 	}
--- a/src/BulletCollision/CollisionShapes/btMiniSDF.cpp
+++ b/src/BulletCollision/CollisionShapes/btMiniSDF.cpp
@@ -0,0 +1,521 @@
 #include "btMiniSDF.h"
 #include "LinearMath/btAlignedObjectArray.h"
 struct btSdfDataStream
 {
 	const char* m_data;
 	int m_size;
 	int m_currentOffset;
 	btSdfDataStream(const char* data, int size)
 		:m_data(data),
 		m_size(size),
 		m_currentOffset(0)
 	{
 	}
 	template<class T> bool read(T& val)
 	{
 		int bytes = sizeof(T);
 		if (m_currentOffset+bytes<=m_size)
 		{
 			char* dest = (char*)&val;
 			memcpy(dest,&m_data[m_currentOffset],bytes);
 			m_currentOffset+=bytes;
 			return true;
 		}
 		btAssert(0);
 		return false;
 	}
 };
 bool btMiniSDF::load(const char* data, int size)
 {
 		int fileSize = -1;
 		btSdfDataStream ds(data,size);
 		{
 			double buf[6];
 			ds.read(buf);
 			m_domain.m_min[0] = buf[0];
 			m_domain.m_min[1] = buf[1];
 			m_domain.m_min[2] = buf[2];
 			m_domain.m_min[3] = 0;
 			m_domain.m_max[0] = buf[3];
 			m_domain.m_max[1] = buf[4];
 			m_domain.m_max[2] = buf[5];
 			m_domain.m_max[3] = 0;
 		}
 		{
 			unsigned int buf2[3];
 			ds.read(buf2);
 			m_resolution[0] = buf2[0];
 			m_resolution[1] = buf2[1];
 			m_resolution[2] = buf2[2];
 		}
 		{
 			double buf[3];
 			ds.read(buf);
 			m_cell_size[0] = buf[0];
 			m_cell_size[1] = buf[1];
 			m_cell_size[2] = buf[2];
 		}
 		{
 			double buf[3];
 			ds.read(buf);
 			m_inv_cell_size[0] = buf[0];
 			m_inv_cell_size[1] = buf[1];
 			m_inv_cell_size[2] = buf[2];
 		}
 		{
 			unsigned long long int cells;
 			ds.read(cells);
 			m_n_cells = cells;
 		}
 		{
 			unsigned long long int fields;
 			ds.read(fields);
 			m_n_fields = fields;
 		}
 		unsigned long long int nodes0;
 		std::size_t n_nodes0;
 		ds.read(nodes0);
 		n_nodes0 = nodes0;
 		m_nodes.resize(n_nodes0);
 		for (unsigned int i=0;i<n_nodes0;i++)
 		{
 			unsigned long long int n_nodes1;
 			ds.read(n_nodes1);
 			btAlignedObjectArray<double>& nodes = m_nodes[i];
 			nodes.resize(n_nodes1);
 			for ( int j=0;j<nodes.size();j++)
 			{
 				double& node = nodes[j];
 				ds.read(node);
 			}
 		}
 		unsigned long long int n_cells0;
 		ds.read(n_cells0);
 		m_cells.resize(n_cells0);
 		for (int i=0;i<n_cells0;i++)
 		{
 			unsigned long long int n_cells1;
 			btAlignedObjectArray<btCell32 >& cells = m_cells[i];
 			ds.read(n_cells1);
 			cells.resize(n_cells1);
 			for (int j=0;j<n_cells1;j++)
 			{
 				btCell32& cell = cells[j];
 				ds.read(cell);
 			}
 		}
 		{
 			unsigned long long int n_cell_maps0;
 			ds.read(n_cell_maps0);
 			m_cell_map.resize(n_cell_maps0);
 			for (int i=0;i<n_cell_maps0;i++)
 			{
 				unsigned long long int n_cell_maps1;
 				btAlignedObjectArray<unsigned int>& cell_maps = m_cell_map[i];
 				ds.read(n_cell_maps1);
 				cell_maps.resize(n_cell_maps1);
 				for (int j=0;j<n_cell_maps1;j++)
 				{
 					unsigned int& cell_map = cell_maps[j];
 					ds.read(cell_map);
 				}
 			}
 		}
 		m_isValid = (ds.m_currentOffset == ds.m_size);
 		return m_isValid;
 }
 unsigned int btMiniSDF::multiToSingleIndex(btMultiIndex const & ijk) const
 {
 	return m_resolution[1] * m_resolution[0] * ijk.ijk[2] + m_resolution[0] * ijk.ijk[1] + ijk.ijk[0];
 }
 btAlignedBox3d
 btMiniSDF::subdomain(btMultiIndex const& ijk) const
 {
 	btAssert(m_isValid);
 	btVector3 tmp;
 	tmp.m_floats[0] = m_cell_size[0]*(double)ijk.ijk[0];
 	tmp.m_floats[1] = m_cell_size[1]*(double)ijk.ijk[1];
 	tmp.m_floats[2] = m_cell_size[2]*(double)ijk.ijk[2];
 	btVector3 origin = m_domain.min() + tmp;
 	btAlignedBox3d box = btAlignedBox3d (origin, origin + m_cell_size);
 	return box;
 }
 btMultiIndex
 btMiniSDF::singleToMultiIndex(unsigned int l) const
 {
 	btAssert(m_isValid);
 	unsigned int n01 = m_resolution[0] * m_resolution[1];
 	unsigned int  k = l / n01;
 	unsigned int  temp = l % n01;
 	unsigned int j = temp / m_resolution[0];
 	unsigned int i = temp % m_resolution[0];
 	btMultiIndex mi;
 	mi.ijk[0] = i;
 	mi.ijk[1] = j;
 	mi.ijk[2] = k;
 	return mi;
 }
 btAlignedBox3d
 btMiniSDF::subdomain(unsigned int l) const
 {
 	btAssert(m_isValid);
 	return subdomain(singleToMultiIndex(l));
 }
 btShapeMatrix
 btMiniSDF::shape_function_(btVector3 const& xi, btShapeGradients* gradient) const
 {
 	btAssert(m_isValid);
 	btShapeMatrix res;
 	btScalar x = xi[0];
 	btScalar y = xi[1];
 	btScalar z = xi[2];
 	btScalar  x2 = x*x;
 	btScalar  y2 = y*y;
 	btScalar  z2 = z*z;
 	btScalar  _1mx = 1.0 - x;
 	btScalar  _1my = 1.0 - y;
 	btScalar  _1mz = 1.0 - z;
 	btScalar  _1px = 1.0 + x;
 	btScalar  _1py = 1.0 + y;
 	btScalar  _1pz = 1.0 + z;
 	btScalar  _1m3x = 1.0 - 3.0 * x;
 	btScalar  _1m3y = 1.0 - 3.0 * y;
 	btScalar  _1m3z = 1.0 - 3.0 * z;
 	btScalar  _1p3x = 1.0 + 3.0 * x;
 	btScalar  _1p3y = 1.0 + 3.0 * y;
 	btScalar  _1p3z = 1.0 + 3.0 * z;
 	btScalar  _1mxt1my = _1mx * _1my;
 	btScalar  _1mxt1py = _1mx * _1py;
 	btScalar  _1pxt1my = _1px * _1my;
 	btScalar  _1pxt1py = _1px * _1py;
 	btScalar  _1mxt1mz = _1mx * _1mz;
 	btScalar  _1mxt1pz = _1mx * _1pz;
 	btScalar  _1pxt1mz = _1px * _1mz;
 	btScalar  _1pxt1pz = _1px * _1pz;
 	btScalar  _1myt1mz = _1my * _1mz;
 	btScalar  _1myt1pz = _1my * _1pz;
 	btScalar  _1pyt1mz = _1py * _1mz;
 	btScalar  _1pyt1pz = _1py * _1pz;
 	btScalar  _1mx2 = 1.0 - x2;
 	btScalar  _1my2 = 1.0 - y2;
 	btScalar  _1mz2 = 1.0 - z2;
 	// Corner nodes.
 	btScalar  fac = 1.0 / 64.0 * (9.0 * (x2 + y2 + z2) - 19.0);
 	res[0] = fac * _1mxt1my * _1mz;
 	res[1] = fac * _1pxt1my * _1mz;
 	res[2] = fac * _1mxt1py * _1mz;
 	res[3] = fac * _1pxt1py * _1mz;
 	res[4] = fac * _1mxt1my * _1pz;
 	res[5] = fac * _1pxt1my * _1pz;
 	res[6] = fac * _1mxt1py * _1pz;
 	res[7] = fac * _1pxt1py * _1pz;
 	// Edge nodes.
 	fac = 9.0 / 64.0 * _1mx2;
 	btScalar  fact1m3x = fac * _1m3x;
 	btScalar  fact1p3x = fac * _1p3x;
 	res[ 8] = fact1m3x * _1myt1mz;
 	res[ 9] = fact1p3x * _1myt1mz;
 	res[10] = fact1m3x * _1myt1pz;
 	res[11] = fact1p3x * _1myt1pz;
 	res[12] = fact1m3x * _1pyt1mz;
 	res[13] = fact1p3x * _1pyt1mz;
 	res[14] = fact1m3x * _1pyt1pz;
 	res[15] = fact1p3x * _1pyt1pz;
 	fac = 9.0 / 64.0 * _1my2;
 	btScalar  fact1m3y = fac * _1m3y;
 	btScalar  fact1p3y = fac * _1p3y;
 	res[16] = fact1m3y * _1mxt1mz;
 	res[17] = fact1p3y * _1mxt1mz;
 	res[18] = fact1m3y * _1pxt1mz;
 	res[19] = fact1p3y * _1pxt1mz;
 	res[20] = fact1m3y * _1mxt1pz;
 	res[21] = fact1p3y * _1mxt1pz;
 	res[22] = fact1m3y * _1pxt1pz;
 	res[23] = fact1p3y * _1pxt1pz;
 	fac = 9.0 / 64.0 * _1mz2;
 	btScalar  fact1m3z = fac * _1m3z;
 	btScalar  fact1p3z = fac * _1p3z;
 	res[24] = fact1m3z * _1mxt1my;
 	res[25] = fact1p3z * _1mxt1my;
 	res[26] = fact1m3z * _1mxt1py;
 	res[27] = fact1p3z * _1mxt1py;
 	res[28] = fact1m3z * _1pxt1my;
 	res[29] = fact1p3z * _1pxt1my;
 	res[30] = fact1m3z * _1pxt1py;
 	res[31] = fact1p3z * _1pxt1py;
 	if (gradient)
 	{
 		btShapeGradients& dN = *gradient;
 		btScalar _9t3x2py2pz2m19 = 9.0 * (3.0 * x2 + y2 + z2) - 19.0;
 		btScalar _9tx2p3y2pz2m19 = 9.0 * (x2 + 3.0 * y2 + z2) - 19.0;
 		btScalar _9tx2py2p3z2m19 = 9.0 * (x2 + y2 + 3.0 * z2) - 19.0;
 		btScalar _18x = 18.0 * x;
 		btScalar _18y = 18.0 * y;
 		btScalar _18z = 18.0 * z;
 		btScalar _3m9x2 = 3.0 - 9.0 * x2;
 		btScalar _3m9y2 = 3.0 - 9.0 * y2;
 		btScalar _3m9z2 = 3.0 - 9.0 * z2;
 		btScalar _2x = 2.0 * x;
 		btScalar _2y = 2.0 * y;
 		btScalar _2z = 2.0 * z;
 		btScalar _18xm9t3x2py2pz2m19 = _18x - _9t3x2py2pz2m19;
 		btScalar _18xp9t3x2py2pz2m19 = _18x + _9t3x2py2pz2m19;
 		btScalar _18ym9tx2p3y2pz2m19 = _18y - _9tx2p3y2pz2m19;
 		btScalar _18yp9tx2p3y2pz2m19 = _18y + _9tx2p3y2pz2m19;
 		btScalar _18zm9tx2py2p3z2m19 = _18z - _9tx2py2p3z2m19;
 		btScalar _18zp9tx2py2p3z2m19 = _18z + _9tx2py2p3z2m19;
 		dN(0,0) =_18xm9t3x2py2pz2m19 * _1myt1mz;
 		dN(0,1) =_1mxt1mz * _18ym9tx2p3y2pz2m19;
 		dN(0,2) =_1mxt1my * _18zm9tx2py2p3z2m19;
 		dN(1,0) =_18xp9t3x2py2pz2m19 * _1myt1mz;
 		dN(1,1) =_1pxt1mz * _18ym9tx2p3y2pz2m19;
 		dN(1,2) =_1pxt1my * _18zm9tx2py2p3z2m19;
 		dN(2,0) =_18xm9t3x2py2pz2m19 * _1pyt1mz;
 		dN(2,1) =_1mxt1mz * _18yp9tx2p3y2pz2m19;
 		dN(2,2) =_1mxt1py * _18zm9tx2py2p3z2m19;
 		dN(3,0) =_18xp9t3x2py2pz2m19 * _1pyt1mz;
 		dN(3,1) =_1pxt1mz * _18yp9tx2p3y2pz2m19;
 		dN(3,2) =_1pxt1py * _18zm9tx2py2p3z2m19;
 		dN(4,0) =_18xm9t3x2py2pz2m19 * _1myt1pz;
 		dN(4,1) =_1mxt1pz * _18ym9tx2p3y2pz2m19;
 		dN(4,2) =_1mxt1my * _18zp9tx2py2p3z2m19;
 		dN(5,0) =_18xp9t3x2py2pz2m19 * _1myt1pz;
 		dN(5,1) =_1pxt1pz * _18ym9tx2p3y2pz2m19;
 		dN(5,2) =_1pxt1my * _18zp9tx2py2p3z2m19;
 		dN(6,0) =_18xm9t3x2py2pz2m19 * _1pyt1pz;
 		dN(6,1) =_1mxt1pz * _18yp9tx2p3y2pz2m19;
 		dN(6,2) =_1mxt1py * _18zp9tx2py2p3z2m19;
 		dN(7,0) =_18xp9t3x2py2pz2m19 * _1pyt1pz;
 		dN(7,1) =_1pxt1pz * _18yp9tx2p3y2pz2m19;
 		dN(7,2) =_1pxt1py * _18zp9tx2py2p3z2m19;
 		dN.topRowsDivide(8, 64.0);
 		btScalar _m3m9x2m2x = -_3m9x2 - _2x;
 		btScalar _p3m9x2m2x =  _3m9x2 - _2x;
 		btScalar _1mx2t1m3x = _1mx2 * _1m3x;
 		btScalar _1mx2t1p3x = _1mx2 * _1p3x;
 		dN( 8,0) =    _m3m9x2m2x * _1myt1mz,
 		dN( 8,1) =   -_1mx2t1m3x * _1mz,
 		dN( 8,2) =   -_1mx2t1m3x * _1my;
 		dN( 9,0) =    _p3m9x2m2x * _1myt1mz,
 		dN( 9,1) =   -_1mx2t1p3x * _1mz,
 		dN( 9,2) =   -_1mx2t1p3x * _1my;
 		dN(10,0) =    _m3m9x2m2x * _1myt1pz,
 		dN(10,1) =   -_1mx2t1m3x * _1pz,
 		dN(10,2) =   _1mx2t1m3x * _1my;
 		dN(11,0) =    _p3m9x2m2x * _1myt1pz,
 		dN(11,1) =   -_1mx2t1p3x * _1pz,
 		dN(11,2) =   _1mx2t1p3x * _1my;
 		dN(12,0) =    _m3m9x2m2x * _1pyt1mz,
 		dN(12,1) =   _1mx2t1m3x * _1mz,
 		dN(12,2) =   -_1mx2t1m3x * _1py;
 		dN(13,0) =    _p3m9x2m2x * _1pyt1mz,
 		dN(13,1) =   _1mx2t1p3x * _1mz,
 		dN(13,2) =   -_1mx2t1p3x * _1py;
 		dN(14,0) =    _m3m9x2m2x * _1pyt1pz,
 		dN(14,1) =   _1mx2t1m3x * _1pz,
 		dN(14,2) =   _1mx2t1m3x * _1py;
 		dN(15,0) =    _p3m9x2m2x * _1pyt1pz,
 		dN(15,1) =   _1mx2t1p3x * _1pz,
 		dN(15,2) =   _1mx2t1p3x * _1py;
 		btScalar _m3m9y2m2y = -_3m9y2 - _2y;
 		btScalar _p3m9y2m2y =  _3m9y2 - _2y;
 		btScalar _1my2t1m3y = _1my2 * _1m3y;
 		btScalar _1my2t1p3y = _1my2 * _1p3y;
 		dN(16,0) =    -_1my2t1m3y * _1mz,
 		dN(16,1) =   _m3m9y2m2y * _1mxt1mz,
 		dN(16,2) =   -_1my2t1m3y * _1mx;
 		dN(17,0) =    -_1my2t1p3y * _1mz,
 		dN(17,1) =   _p3m9y2m2y * _1mxt1mz,
 		dN(17,2) =   -_1my2t1p3y * _1mx;
 		dN(18,0) =    _1my2t1m3y * _1mz,
 		dN(18,1) =   _m3m9y2m2y * _1pxt1mz,
 		dN(18,2) =   -_1my2t1m3y * _1px;
 		dN(19,0) =    _1my2t1p3y * _1mz,
 		dN(19,1) =   _p3m9y2m2y * _1pxt1mz,
 		dN(19,2) =   -_1my2t1p3y * _1px;
 		dN(20,0) =    -_1my2t1m3y * _1pz,
 		dN(20,1) =   _m3m9y2m2y * _1mxt1pz,
 		dN(20,2) =   _1my2t1m3y * _1mx;
 		dN(21,0) =    -_1my2t1p3y * _1pz,
 		dN(21,1) =   _p3m9y2m2y * _1mxt1pz,
 		dN(21,2) =   _1my2t1p3y * _1mx;
 		dN(22,0) =    _1my2t1m3y * _1pz,
 		dN(22,1) =   _m3m9y2m2y * _1pxt1pz,
 		dN(22,2) =   _1my2t1m3y * _1px;
 		dN(23,0) =    _1my2t1p3y * _1pz,
 		dN(23,1) =   _p3m9y2m2y * _1pxt1pz,
 		dN(23,2) =   _1my2t1p3y * _1px;
 		btScalar _m3m9z2m2z = -_3m9z2 - _2z;
 		btScalar _p3m9z2m2z =  _3m9z2 - _2z;
 		btScalar _1mz2t1m3z = _1mz2 * _1m3z;
 		btScalar _1mz2t1p3z = _1mz2 * _1p3z;
 		dN(24,0) =    -_1mz2t1m3z * _1my,
 		dN(24,1) =  -_1mz2t1m3z * _1mx,
 		dN(24,2) =   _m3m9z2m2z * _1mxt1my;
 		dN(25,0) =    -_1mz2t1p3z * _1my,
 		dN(25,1) =   -_1mz2t1p3z * _1mx,
 		dN(25,2) =   _p3m9z2m2z * _1mxt1my;
 		dN(26,0) =    -_1mz2t1m3z * _1py,
 		dN(26,1) =   _1mz2t1m3z * _1mx,
 		dN(26,2) =   _m3m9z2m2z * _1mxt1py;
 		dN(27,0) =    -_1mz2t1p3z * _1py,
 		dN(27,1) =   _1mz2t1p3z * _1mx,
 		dN(27,2) =   _p3m9z2m2z * _1mxt1py;
 		dN(28,0) =    _1mz2t1m3z * _1my,
 		dN(28,1) =   -_1mz2t1m3z * _1px,
 		dN(28,2) =   _m3m9z2m2z * _1pxt1my;
 		dN(29,0) =    _1mz2t1p3z * _1my,
 		dN(29,1) =   -_1mz2t1p3z * _1px,
 		dN(29,2) =   _p3m9z2m2z * _1pxt1my;
 		dN(30,0) =    _1mz2t1m3z * _1py,
 		dN(30,1) =   _1mz2t1m3z * _1px,
 		dN(30,2) =   _m3m9z2m2z * _1pxt1py;
 		dN(31,0) =    _1mz2t1p3z * _1py,
 		dN(31,1) =   _1mz2t1p3z * _1px,
 		dN(31,2) =   _p3m9z2m2z * _1pxt1py;
 		dN.bottomRowsMul(32u - 8u, 9.0 / 64.0);
 	}
 	return res;
 }
 bool btMiniSDF::interpolate(unsigned int field_id, double& dist, btVector3 const& x,
 	btVector3* gradient) const
 {
 	btAssert(m_isValid);
 	if (!m_isValid)
 		return false;
 	if (!m_domain.contains(x))
 		return false;
 	btVector3 tmpmi = ((x - m_domain.min())*(m_inv_cell_size));//.cast<unsigned int>().eval();
 	unsigned int mi[3] = {(unsigned int )tmpmi[0],(unsigned int )tmpmi[1],(unsigned int )tmpmi[2]};
 	if (mi[0] >= m_resolution[0])
 		mi[0] = m_resolution[0]-1;
 	if (mi[1] >= m_resolution[1])
 		mi[1] = m_resolution[1]-1;
 	if (mi[2] >= m_resolution[2])
 		mi[2] = m_resolution[2]-1;
 	btMultiIndex mui; 
 	mui.ijk[0] = mi[0];
 	mui.ijk[1] = mi[1];
 	mui.ijk[2] = mi[2];
 	int i = multiToSingleIndex(mui);
 	unsigned int i_ = m_cell_map[field_id][i];
 	if (i_ == UINT_MAX)
 		return false;
 	btAlignedBox3d sd = subdomain(i);
 	i = i_;
 	btVector3 d = sd.m_max-sd.m_min;//.diagonal().eval();
 	btVector3 denom = (sd.max() - sd.min());
 	btVector3 c0 = btVector3(2.0,2.0,2.0)/denom;
 	btVector3 c1 = (sd.max() + sd.min())/denom;
 	btVector3 xi = (c0*x - c1);
 	btCell32 const& cell = m_cells[field_id][i];
 	if (!gradient)
 	{
 		//auto phi = m_coefficients[field_id][i].dot(shape_function_(xi, nullptr));
 		double phi = 0.0;
 		btShapeMatrix N = shape_function_(xi, nullptr);
 		for (unsigned int j = 0u; j < 32u; ++j)
 		{
 			unsigned int v = cell.m_cells[j];
 			double c = m_nodes[field_id][v];
 			if (c == DBL_MAX)
 			{
 				return false;;
 			}
 			phi += c * N[j];
 		}
 		dist = phi;
 		return true;
 	}
 	btShapeGradients dN;
 	btShapeMatrix N = shape_function_(xi, &dN);
 	double phi = 0.0;
 	gradient->setZero();
 	for (unsigned int j = 0u; j < 32u; ++j)
 	{
 		unsigned int v = cell.m_cells[j];
 		double c = m_nodes[field_id][v];
 		if (c == DBL_MAX)
 		{
 			gradient->setZero();
 			return false;
 		}
 		phi += c * N[j];
 		(*gradient)[0] += c * dN(j, 0);
 		(*gradient)[1] += c * dN(j, 1);
 		(*gradient)[2] += c * dN(j, 2);
 	}
 	(*gradient) *= c0;
 	dist = phi;
 	return true;
 }
--- a/src/BulletCollision/CollisionShapes/btMiniSDF.h
+++ b/src/BulletCollision/CollisionShapes/btMiniSDF.h
@@ -0,0 +1,134 @@
 #ifndef MINISDF_H
 #define MINISDF_H
 #include "LinearMath/btVector3.h"
 #include "LinearMath/btAabbUtil2.h"
 #include "Linearmath/btAlignedObjectArray.h"
 struct btMultiIndex
 {
 	unsigned int ijk[3];
 };
 struct btAlignedBox3d
 {
 	btVector3 m_min;
 	btVector3 m_max;
 	const btVector3& min() const
 	{
 		return m_min;
 	}
 	const btVector3& max() const
 	{
 		return m_max;
 	}
 	bool contains(const btVector3& x) const
 	{
 		return TestPointAgainstAabb2(m_min, m_max, x);
 	}
 	btAlignedBox3d(const btVector3& mn, const btVector3& mx)
 		:m_min(mn),
 		m_max(mx)
 	{
 	}
 	btAlignedBox3d()
 	{
 	}
 };
 struct btShapeMatrix
 {
 	double m_vec[32];
 	inline double&       operator[](int i)
 	{
 		return m_vec[i];
 	}
 	inline const double&       operator[](int i) const
 	{
 		return m_vec[i];
 	}
 };
 struct btShapeGradients
 {
 	btVector3	m_vec[32];
 	void topRowsDivide(int row, double denom)
 	{
 		for (int i=0;i<row;i++)
 		{
 			m_vec[i] /= denom;
 		}
 	}
 	void bottomRowsMul(int row, double val)
 	{
 		for (int i=32-row;i<32;i++)
 		{
 			m_vec[i] *= val;
 		}
 	}
 	inline double&       operator()(int i, int j)
 	{
 		return m_vec[i][j];
 	}
 };
 struct btCell32
 {
 	unsigned int m_cells[32];
 };
 struct btMiniSDF
 {
 	btAlignedBox3d m_domain;
 	unsigned int m_resolution[3];
 	btVector3 m_cell_size;
 	btVector3 m_inv_cell_size;
 	std::size_t m_n_cells;
 	std::size_t m_n_fields;
 	bool m_isValid;
 	btAlignedObjectArray<btAlignedObjectArray<double> > m_nodes;
 	btAlignedObjectArray<btAlignedObjectArray<btCell32 > > m_cells;
 	btAlignedObjectArray<btAlignedObjectArray<unsigned int> > m_cell_map;
 	btMiniSDF()
 	:m_isValid(false)
 	{
 	}
 	bool load(const char* data, int size);
 	bool isValid() const
 	{
 		return m_isValid;
 	}
 	unsigned int multiToSingleIndex(btMultiIndex const & ijk) const;
 	btAlignedBox3d subdomain(btMultiIndex const& ijk) const;
 	btMultiIndex singleToMultiIndex(unsigned int l) const;
 	btAlignedBox3d subdomain(unsigned int l) const;
 	btShapeMatrix
 	shape_function_(btVector3 const& xi, btShapeGradients* gradient = 0) const;
 	bool interpolate(unsigned int field_id, double& dist, btVector3 const& x, btVector3* gradient) const;
 };
 #endif //MINISDF_H
--- a/src/BulletCollision/CollisionShapes/btSdfCollisionShape.cpp
+++ b/src/BulletCollision/CollisionShapes/btSdfCollisionShape.cpp
@@ -0,0 +1,99 @@
 #include "btSdfCollisionShape.h"
 #include "btMiniSDF.h"
 #include "LinearMath/btAabbUtil2.h"
 struct btSdfCollisionShapeInternalData
 {
 	btVector3 m_localScaling;
 	btScalar m_margin;
 	btMiniSDF m_sdf;
 	btSdfCollisionShapeInternalData()
 		:m_localScaling(1,1,1),
 		m_margin(0)
 	{
 	}
 };
 bool btSdfCollisionShape::initializeSDF(const char* sdfData, int sizeInBytes)
 {
 	bool valid = m_data->m_sdf.load(sdfData, sizeInBytes);
 	return valid;
 }
 btSdfCollisionShape::btSdfCollisionShape()
 {
 	m_shapeType = SDF_SHAPE_PROXYTYPE;
 	m_data = new btSdfCollisionShapeInternalData();
 	//"E:/develop/bullet3/data/toys/ground_hole64_64_8.cdf");//ground_cube.cdf");
 	/*unsigned int field_id=0;
 	Eigen::Vector3d x (1,10,1);
 	Eigen::Vector3d gradient;
 	double dist = m_data->m_sdf.interpolate(field_id, x, &gradient);
 	printf("dist=%g\n", dist);
 	*/
 }
 btSdfCollisionShape::~btSdfCollisionShape()
 {
 	delete m_data;
 }
 void btSdfCollisionShape::getAabb(const btTransform& t,btVector3& aabbMin,btVector3& aabbMax) const
 {
 	btAssert(m_data->m_sdf.isValid());
 	btVector3 localAabbMin = m_data->m_sdf.m_domain.m_min;
 	btVector3 localAabbMax = m_data->m_sdf.m_domain.m_max;
 	btScalar margin(0);
 	btTransformAabb(localAabbMin,localAabbMax,margin,t,aabbMin,aabbMax);
 }
 void	btSdfCollisionShape::setLocalScaling(const btVector3& scaling)
 {
 	m_data->m_localScaling = scaling;
 }
 const btVector3& btSdfCollisionShape::getLocalScaling() const
 {
 	return m_data->m_localScaling;
 }
 void	btSdfCollisionShape::calculateLocalInertia(btScalar mass,btVector3& inertia) const
 {
 	inertia.setValue(0,0,0);
 }
 const char*	btSdfCollisionShape::getName()const
 {
 	return "btSdfCollisionShape";
 }
 void	btSdfCollisionShape::setMargin(btScalar margin)
 {
 	m_data->m_margin = margin;
 }
 btScalar	btSdfCollisionShape::getMargin() const
 {
 	return m_data->m_margin;
 }
 void	btSdfCollisionShape::processAllTriangles(btTriangleCallback* callback,const btVector3& aabbMin,const btVector3& aabbMax) const
 {
 	//not yet
 }
 bool btSdfCollisionShape::queryPoint(const btVector3& ptInSDF, btScalar& distOut, btVector3& normal)
 {
 	int field = 0;
 	btVector3 grad;
 	double dist;
 	bool hasResult = m_data->m_sdf.interpolate(field,dist, ptInSDF,&grad);
 	if (hasResult)
 	{
 		normal.setValue(grad[0],grad[1],grad[2]);
 		distOut= dist;
 	}
 	return hasResult;
 }
--- a/src/BulletCollision/CollisionShapes/btSdfCollisionShape.h
+++ b/src/BulletCollision/CollisionShapes/btSdfCollisionShape.h
@@ -0,0 +1,30 @@
 #ifndef BT_SDF_COLLISION_SHAPE_H
 #define BT_SDF_COLLISION_SHAPE_H
 #include "btConcaveShape.h"
 class btSdfCollisionShape : public btConcaveShape
 {
 	struct btSdfCollisionShapeInternalData* m_data;
 public:
 	btSdfCollisionShape();
 	virtual ~btSdfCollisionShape();
 	bool initializeSDF(const char* sdfData, int sizeInBytes);
 	virtual void getAabb(const btTransform& t,btVector3& aabbMin,btVector3& aabbMax) const;
 	virtual void	setLocalScaling(const btVector3& scaling);
 	virtual const btVector3& getLocalScaling() const;
 	virtual void	calculateLocalInertia(btScalar mass,btVector3& inertia) const;
 	virtual const char*	getName()const;
 	virtual void	setMargin(btScalar margin);
 	virtual btScalar	getMargin() const;
 	virtual void	processAllTriangles(btTriangleCallback* callback,const btVector3& aabbMin,const btVector3& aabbMax) const;
 	bool queryPoint(const btVector3& ptInSDF, btScalar& distOut, btVector3& normal);
 };
 #endif //BT_SDF_COLLISION_SHAPE_H