Exemplo n.º 1
0
Bounds3 Bounds3::ToManaged(PxBounds3 bounds)
{
	PxVec3 center = bounds.getCenter();
	PxVec3 extents = bounds.getExtents();

	return Bounds3(MathUtil::PxVec3ToVector3(center - extents), MathUtil::PxVec3ToVector3(center + extents));
}
void Sc::ParticleSystemSim::visualizeInteractions(Cm::RenderOutput& out)
{
	out << PxU32(PxDebugColor::eARGB_GREEN) << Cm::RenderOutput::LINES;
	for(PxU32 i=0; i < mParticlePacketShapes.size(); i++)
	{
		ParticlePacketShape* particleShape = mParticlePacketShapes[i];

		ParticleElementRbElementInteraction** interactions = particleShape->getInteractions();
		PxU32 nbInteractions = particleShape->getInteractionsCount();

		while(nbInteractions--)
		{
			ParticleElementRbElementInteraction* interaction = *interactions++;

			PX_ASSERT(interaction->getType() == InteractionType::ePARTICLE_BODY);

			const PxBounds3 bounds = particleShape->getBounds();

			PX_ALIGN(16, PxTransform absPos);
			interaction->getRbShape().getAbsPoseAligned(&absPos);

			out << bounds.getCenter() << absPos.p;
		}
	}
}
void testBoundsMesh(	
	const Gu::InternalTriangleMeshData& meshData,
	const PxTransform& world2Shape,
	const PxTransform& s2w,
	const Cm::FastVertex2ShapeScaling& meshScaling,
	bool idtScaleMesh,
	const PxBounds3& worldBounds,
	PxcContactCellMeshCallback& callback)
{
	// Find colliding triangles.
	// Setup an OBB for the fluid particle cell (in local space of shape)
	// assuming uniform scaling in most cases, using the pose as box rotation
	// if scaling is non-uniform, the bounding box is conservative

	PxBounds3 boundsInMesh;
	PX_ASSERT(!worldBounds.isEmpty());
	boundsInMesh = PxBounds3::transformFast(world2Shape, worldBounds);

	Gu::Box vertexSpaceOBB(boundsInMesh.getCenter(), boundsInMesh.getExtents(), PxMat33(PxIdentity));

	if(!idtScaleMesh)
		meshScaling.transformQueryBounds(vertexSpaceOBB.center, vertexSpaceOBB.extents);

	// Set collider flags (has to be done each time again!)
	Gu::RTreeMidphaseData hmd;
	meshData.mCollisionModel.getRTreeMidphaseData(hmd);	
	MPT_SET_CONTEXT("flui", s2w, meshScaling); PX_UNUSED(s2w);
	Gu::MeshRayCollider::collideOBB(vertexSpaceOBB, true, hmd, callback);
}
Exemplo n.º 4
0
PxBounds3 NpCloth::getWorldBounds(float inflation) const
{
	NP_READ_CHECK(NpActor::getOwnerScene(*this));

	const PxBounds3 bounds = mCloth.getWorldBounds();
	PX_ASSERT(bounds.isValid());

	// PT: unfortunately we can't just scale the min/max vectors, we need to go through center/extents.
	const PxVec3 center = bounds.getCenter();
	const PxVec3 inflatedExtents = bounds.getExtents() * inflation;
	return PxBounds3::centerExtents(center, inflatedExtents);
}
Exemplo n.º 5
0
void NpSpatialIndex::overlap(const PxBounds3& aabb, 
							 PxSpatialOverlapCallback& callback) const
{
	PX_SIMD_GUARD;
	PX_CHECK_AND_RETURN(aabb.isValid(),			"PxSpatialIndex::overlap: aabb is not valid.");

	flushUpdates();
	OverlapCallback cb(callback);
	PxBoxGeometry boxGeom(aabb.getExtents());
	PxTransform xf(aabb.getCenter());
	Sq::ShapeData shapeData(boxGeom, xf, 0.0f); // temporary rvalue not compatible with PX_NOCOPY 
	mPruner->overlap(shapeData, cb);
}
Exemplo n.º 6
0
PxBounds3 NpArticulation::getWorldBounds(float inflation) const
{
	NP_READ_CHECK(getOwnerScene());
	PxBounds3 bounds = PxBounds3::empty();

	for(PxU32 i=0; i < mArticulationLinks.size(); i++)
	{
		bounds.include(mArticulationLinks[i]->getWorldBounds());
	}
	PX_ASSERT(bounds.isValid());

	// PT: unfortunately we can't just scale the min/max vectors, we need to go through center/extents.
	const PxVec3 center = bounds.getCenter();
	const PxVec3 inflatedExtents = bounds.getExtents() * inflation;
	return PxBounds3::centerExtents(center, inflatedExtents);
}
static void tessellateTriangle(PxU32& nbNewTris, const PxTriangle& tr, PxU32 index, TriArray& worldTriangles, IntArray& triIndicesArray, const PxBounds3& cullingBox, const CCTParams& params, PxU16& nbTessellation)
{
	TessParams tp;
	tp.nbNewTris			= 0;
	tp.index				= index;
	tp.worldTriangles		= &worldTriangles;
	tp.triIndicesArray		= &triIndicesArray;
	tp.cullingBoxCenter		= cullingBox.getCenter();
	tp.cullingBoxExtents	= cullingBox.getExtents();
	tp.maxEdgeLength2		= params.mMaxEdgeLength2;
	tp.nbTessellation		= 0;
	tessellateTriangle(&tp, tr.verts[0], tr.verts[1], tr.verts[2]);

	nbNewTris += tp.nbNewTris;
	nbTessellation += tp.nbTessellation;
//	nbTessellation += PxU16(tp.nbNewTris);
}
Exemplo n.º 8
0
void NpSpatialIndex::sweep(const PxBounds3& aabb, 
						   const PxVec3& unitDir, 
						   PxReal maxDist, 
						   PxSpatialLocationCallback& callback) const
{
	PX_SIMD_GUARD;

	PX_CHECK_AND_RETURN(aabb.isValid(),									"PxSpatialIndex::sweep: aabb is not valid.");
	PX_CHECK_AND_RETURN(unitDir.isFinite() && unitDir.isNormalized(),	"PxSpatialIndex::sweep: unitDir is not valid.");
	PX_CHECK_AND_RETURN(maxDist > 0.0f,									"PxSpatialIndex::sweep: distance must be positive");

	flushUpdates();
	LocationCallback cb(callback);
	PxBoxGeometry boxGeom(aabb.getExtents());
	PxTransform xf(aabb.getCenter());
	Sq::ShapeData shapeData(boxGeom, xf, 0.0f); // temporary rvalue not compatible with PX_NOCOPY 
	mPruner->sweep(shapeData, unitDir, maxDist, cb);
}
Exemplo n.º 9
0
static PX_FORCE_INLINE bool planesAABBOverlap(const PxBounds3& a, const PxPlane* p, PxU32& out_clip_mask, PxU32 in_clip_mask)
	{
		//------------------------------------------------------------------------
		// Convert the AABB from (minimum,maximum) form into (center,half-diagonal).
		// Note that we could get rid of these six subtractions and three
		// multiplications if the AABB was originally expressed in (center,
		// half-diagonal) form.
		//------------------------------------------------------------------------

		PxVec3 m = a.getCenter();		// get center of AABB ((minimum+maximum)*0.5f)
		PxVec3 d = a.maximum;	d-=m;	// get positive half-diagonal (maximum - center)

		//------------------------------------------------------------------------
		// Evaluate through all active frustum planes. We determine the relation 
		// between the AABB and a plane by using the concept of "near" and "far"
		// vertices originally described by Zhang (and later by Moeller). Our
		// variant here uses 3 fabs ops, 6 muls, 7 adds and two floating point
		// comparisons per plane. The routine early-exits if the AABB is found
		// to be outside any of the planes. The loop also constructs a new output
		// clip mask. Most FPUs have a native single-cycle fabsf() operation.
		//------------------------------------------------------------------------

		PxU32 Mask				= 1;			// current mask index (1,2,4,8,..)
		PxU32 TmpOutClipMask	= 0;			// initialize output clip mask into empty. 

		while(Mask<=in_clip_mask)				// keep looping while we have active planes left...
		{
			if(in_clip_mask & Mask)				// if clip plane is active, process it..
			{               
				const float NP = d.x*PxAbs(p->n.x) + d.y*PxAbs(p->n.y) + d.z*PxAbs(p->n.z);
				const float MP = m.x*p->n.x + m.y*p->n.y + m.z*p->n.z + p->d;

				if(NP < MP)						// near vertex behind the clip plane... 
					return false;				// .. so there is no intersection..
				if((-NP) < MP)					// near and far vertices on different sides of plane..
					TmpOutClipMask |= Mask;		// .. so update the clip mask...
			}
			Mask+=Mask;							// mk = (1<<plane)
			p++;								// advance to next plane
		}

		out_clip_mask = TmpOutClipMask;			// copy output value (temp used to resolve aliasing!)
		return true;							// indicate that AABB intersects frustum
	}
Exemplo n.º 10
0
void Sc::ParticleSystemSim::visualizeInteractions(Cm::RenderOutput& out)
{
	out << PxU32(PxDebugColor::eARGB_GREEN) << Cm::RenderOutput::LINES;
	for(PxU32 i=0; i < mParticlePacketShapes.size(); i++)
	{
		ParticlePacketShape* particleShape = mParticlePacketShapes[i];

		Cm::Range<ParticleElementRbElementInteraction*const> interactions = particleShape->getPacketShapeInteractions();
		for (; !interactions.empty(); interactions.popFront())
		{
			ParticleElementRbElementInteraction*const interaction = interactions.front();

			PX_ASSERT(interaction->getType() == PX_INTERACTION_TYPE_PARTICLE_BODY);

			PxBounds3 bounds = particleShape->getBounds();
			out << bounds.getCenter() << interaction->getRbShape().getAbsPose().p;
		}
	}
}
Exemplo n.º 11
0
void Sc::ParticleSystemSim::visualizeSpatialGrid(Cm::RenderOutput& out)
{
	PxReal packetSize = getCore().getGridSize();

	for (PxU32 i = 0; i < mParticlePacketShapes.size(); i++)
	{
		ParticlePacketShape* particleShape = mParticlePacketShapes[i];

		PxBounds3 bounds = particleShape->getBounds();
		PxVec3 centerGridSpace = bounds.getCenter() / packetSize;		
		
		for (PxU32 d = 0; d < 3; d++)
			bounds.minimum[d] = Ps::floor(centerGridSpace[d]) * packetSize;
		for (PxU32 d = 0; d < 3; d++)
			bounds.maximum[d] = Ps::ceil(centerGridSpace[d]) * packetSize;

		out << PxU32(PxDebugColor::eARGB_BLUE) << Cm::DebugBox(bounds);
	}
}
Exemplo n.º 12
0
void obj_DroppedItem::UpdateObjectPositionAfterCreation()
{
	if(!PhysicsObject)
		return;

	PxActor* actor = PhysicsObject->getPhysicsActor();
	if(!actor)
		return;

	PxBounds3 pxBbox = actor->getWorldBounds();
	PxVec3 pxCenter = pxBbox.getCenter();

	// place object on the ground, to prevent excessive bouncing
	{
		PxRaycastHit hit;
		PxSceneQueryFilterData filter(PxFilterData(COLLIDABLE_STATIC_MASK, 0, 0, 0), PxSceneQueryFilterFlag::eSTATIC);
		if(g_pPhysicsWorld->raycastSingle(PxVec3(pxCenter.x, pxCenter.y, pxCenter.z), PxVec3(0, -1, 0), 50.0f, PxSceneQueryFlag::eIMPACT, hit, filter))
		{
			SetPosition(r3dPoint3D(hit.impact.x, hit.impact.y+0.1f, hit.impact.z));
		}
	}
}
void FDestructibleMeshEditorViewportClient::Draw( const FSceneView* View,FPrimitiveDrawInterface* PDI )
{
	FEditorViewportClient::Draw(View, PDI);

#if WITH_APEX
	const bool DrawChunkMarker = true;

	UDestructibleComponent* Comp = PreviewDestructibleComp.Get();
	
	if (Comp)
	{
		if (Comp->DestructibleMesh != NULL && Comp->DestructibleMesh->FractureSettings != NULL)
		{
			if (Comp->DestructibleMesh->ApexDestructibleAsset != NULL)
			{
				NxDestructibleAsset* Asset = Comp->DestructibleMesh->ApexDestructibleAsset;
				const NxRenderMeshAsset* RenderMesh = Asset->getRenderMeshAsset();

				for (uint32 i=0; i < Asset->getChunkCount(); ++i)
				{
					int32 PartIdx = Asset->getPartIndex(i);
					int32 BoneIdx = i+1;

					if ( SelectedChunkIndices.Contains(i) )
					{
						PxBounds3 PBounds = RenderMesh->getBounds(PartIdx);

						FVector Center = P2UVector(PBounds.getCenter()) + Comp->GetBoneLocation(Comp->GetBoneName(BoneIdx));
						FVector Extent = P2UVector(PBounds.getExtents());

						FBox Bounds(Center - Extent, Center + Extent);
						DrawWireBox(PDI, Bounds, FColor::Blue, SDPG_World);
					}
				}
			}
		}
	}
#endif // WITH_APEX
}
static void outputMeshToStream(	PxShape* meshShape, const PxRigidActor* actor, const PxTransform& meshPose, IntArray& geomStream, TriArray& worldTriangles, IntArray& triIndicesArray,
								const PxExtendedVec3& origin, const PxBounds3& tmpBounds, const CCTParams& params, Cm::RenderBuffer* renderBuffer, PxU16& nbTessellation)
{
	PX_ASSERT(meshShape->getGeometryType() == PxGeometryType::eTRIANGLEMESH);
	// Do AABB-mesh query

	PxTriangleMeshGeometry triGeom;
	meshShape->getTriangleMeshGeometry(triGeom);

	const PxBoxGeometry boxGeom(tmpBounds.getExtents());
	const PxTransform boxPose(tmpBounds.getCenter(), PxQuat(PxIdentity));

	// Collide AABB against current mesh
	PxMeshOverlapUtil overlapUtil;
	const PxU32 nbTouchedTris = overlapUtil.findOverlap(boxGeom, boxPose, triGeom, meshPose);

	const PxVec3 offset(float(-origin.x), float(-origin.y), float(-origin.z));

	TouchedMesh* touchedMesh			= (TouchedMesh*)reserve(geomStream, sizeof(TouchedMesh)/sizeof(PxU32));
	touchedMesh->mType					= TouchedGeomType::eMESH;
	touchedMesh->mTGUserData			= meshShape;
	touchedMesh->mActor					= actor;
	touchedMesh->mOffset				= origin;
	touchedMesh->mNbTris				= nbTouchedTris;
	touchedMesh->mIndexWorldTriangles	= worldTriangles.size();

	const PxU32* PX_RESTRICT indices = overlapUtil.getResults();

	if(params.mSlopeLimit!=0.0f)
	{
		if(!params.mTessellation)
		{
			// Loop through touched triangles
			PxU32 nbCreatedTris = 0;
			for(PxU32 i=0; i < nbTouchedTris; i++)
			{
				const PxU32 triangleIndex = indices[i];

				// Compute triangle in world space, add to array
				PxTriangle currentTriangle;
				PxMeshQuery::getTriangle(triGeom, meshPose, triangleIndex, currentTriangle);
				currentTriangle.verts[0] += offset;
				currentTriangle.verts[1] += offset;
				currentTriangle.verts[2] += offset;

				const PxU32 nbNewTris = createInvisibleWalls(params, currentTriangle, worldTriangles, triIndicesArray);
				nbCreatedTris += nbNewTris;
				if(!nbNewTris)
				{
					worldTriangles.pushBack(currentTriangle);

					triIndicesArray.pushBack(triangleIndex);
					nbCreatedTris++;
				}
			}
			touchedMesh->mNbTris = nbCreatedTris;
		}
		else
		{
			const PxBounds3 cullingBox = PxBounds3::centerExtents(boxPose.p + offset, boxGeom.halfExtents);

			// Loop through touched triangles
			PxU32 nbCreatedTris = 0;
			for(PxU32 i=0; i < nbTouchedTris; i++)
			{
				const PxU32 triangleIndex = indices[i];

				// Compute triangle in world space, add to array
				PxTriangle currentTriangle;
				PxMeshQuery::getTriangle(triGeom, meshPose, triangleIndex, currentTriangle);
				currentTriangle.verts[0] += offset;
				currentTriangle.verts[1] += offset;
				currentTriangle.verts[2] += offset;

				PxU32 nbNewTris = createInvisibleWalls(params, currentTriangle, worldTriangles, triIndicesArray);
				nbCreatedTris += nbNewTris;
				if(!nbNewTris)
				{
/*					worldTriangles.pushBack(currentTriangle);
					triIndicesArray.pushBack(triangleIndex);
					nbCreatedTris++;*/

					tessellateTriangle(nbNewTris, currentTriangle, triangleIndex, worldTriangles, triIndicesArray, cullingBox, params, nbTessellation);
					nbCreatedTris += nbNewTris;
//					printf("Tesselate: %d new tris\n", nbNewTris);
				}
			}
			touchedMesh->mNbTris = nbCreatedTris;
		}
	}
	else
	{
		if(!params.mTessellation)
		{
			// Reserve memory for incoming triangles
			PxTriangle* TouchedTriangles = reserve(worldTriangles, nbTouchedTris);

			// Loop through touched triangles
			for(PxU32 i=0; i < nbTouchedTris; i++)
			{
				const PxU32 triangleIndex = indices[i];

				// Compute triangle in world space, add to array
				PxTriangle& currentTriangle = *TouchedTriangles++;
				PxMeshQuery::getTriangle(triGeom, meshPose, triangleIndex, currentTriangle);
				currentTriangle.verts[0] += offset;
				currentTriangle.verts[1] += offset;
				currentTriangle.verts[2] += offset;

				triIndicesArray.pushBack(triangleIndex);
			}
		}
		else
		{
			const PxBounds3 cullingBox = PxBounds3::centerExtents(boxPose.p + offset, boxGeom.halfExtents);

			PxU32 nbCreatedTris = 0;
			for(PxU32 i=0; i < nbTouchedTris; i++)
			{
				const PxU32 triangleIndex = indices[i];

				// Compute triangle in world space, add to array
				PxTriangle currentTriangle;
				PxMeshQuery::getTriangle(triGeom, meshPose, triangleIndex, currentTriangle);

				currentTriangle.verts[0] += offset;
				currentTriangle.verts[1] += offset;
				currentTriangle.verts[2] += offset;

				PxU32 nbNewTris = 0;
				tessellateTriangle(nbNewTris, currentTriangle, triangleIndex, worldTriangles, triIndicesArray, cullingBox, params, nbTessellation);
//				printf("Tesselate: %d new tris\n", nbNewTris);
				nbCreatedTris += nbNewTris;
			}
			touchedMesh->mNbTris = nbCreatedTris;
		}
	}

	if(gVisualizeTouchedTris)
		visualizeTouchedTriangles(touchedMesh->mNbTris, touchedMesh->mIndexWorldTriangles, &worldTriangles[0], renderBuffer, offset, params.mUpDirection);
}
static void outputConvexToStream(PxShape* convexShape, const PxRigidActor* actor, const PxTransform& absPose_, IntArray& geomStream, TriArray& worldTriangles, IntArray& triIndicesArray,
								 const PxExtendedVec3& origin, const PxBounds3& tmpBounds, const CCTParams& params, Cm::RenderBuffer* renderBuffer, PxU16& nbTessellation)
{
	PX_ASSERT(convexShape->getGeometryType() == PxGeometryType::eCONVEXMESH);
	PxConvexMeshGeometry cg;
	convexShape->getConvexMeshGeometry(cg);
	PX_ASSERT(cg.convexMesh);

	// Do AABB-mesh query

	PxU32* TF;

	// Collide AABB against current mesh
	// The overlap function doesn't exist for convexes so let's just dump all tris
	PxConvexMesh& cm = *cg.convexMesh;

	// PT: convex triangles are not exposed anymore so we need to access convex polygons & triangulate them

	// PT: TODO: this is copied from "DrawObjects", move this to a shared place. Actually a helper directly in PxConvexMesh would be useful.
	PxU32 Nb = 0;
	{
		const PxU32 nbPolys = cm.getNbPolygons();
		const PxU8* polygons = cm.getIndexBuffer();

		for(PxU32 i=0;i<nbPolys;i++)
		{
			PxHullPolygon data;
			cm.getPolygonData(i, data);
			Nb += data.mNbVerts - 2;
		}

		// PT: revisit this code. We don't use the polygon offset?
		TF = (PxU32*)PxAlloca(sizeof(PxU32)*Nb*3);
		PxU32* t = TF;
		for(PxU32 i=0;i<nbPolys;i++)
		{
			PxHullPolygon data;
			cm.getPolygonData(i, data);

			const PxU32 nbV = data.mNbVerts;

			const PxU32 nbTris = nbV - 2;
			const PxU8 vref0 = *polygons;
			for(PxU32 j=0;j<nbTris;j++)
			{
				const PxU32 vref1 = polygons[(j+1)%nbV];
				const PxU32 vref2 = polygons[(j+2)%nbV];
				*t++ = vref0;
				*t++ = vref1;
				*t++ = vref2;
			}
			polygons += nbV;
		}
	}

	// PT: you can't use PxTransform with a non-uniform scaling
	const PxMat33 rot = PxMat33(absPose_.q) * cg.scale.toMat33();
	const PxMat44 absPose(rot, absPose_.p);

	const PxVec3 p = absPose.getPosition();
	const PxVec3 MeshOffset(float(p.x - origin.x), float(p.y - origin.y), float(p.z - origin.z));	// LOSS OF ACCURACY

	const PxVec3 offset(float(-origin.x), float(-origin.y), float(-origin.z));

	TouchedMesh* touchedMesh			= (TouchedMesh*)reserve(geomStream, sizeof(TouchedMesh)/sizeof(PxU32));
	touchedMesh->mType					= TouchedGeomType::eMESH;
	touchedMesh->mTGUserData			= convexShape;
	touchedMesh->mActor					= actor;
	touchedMesh->mOffset				= origin;
	touchedMesh->mIndexWorldTriangles	= worldTriangles.size();

	const PxVec3* verts = cm.getVertices();
	// Loop through touched triangles
	if(params.mTessellation)
	{
		const PxBoxGeometry boxGeom(tmpBounds.getExtents());
		const PxBounds3 cullingBox = PxBounds3::centerExtents(tmpBounds.getCenter() + offset, boxGeom.halfExtents);

		PxU32 nbCreatedTris = 0;
		while(Nb--)
		{
			// Compute triangle in world space, add to array
			PxTriangle currentTriangle;

			const PxU32 vref0 = *TF++;
			const PxU32 vref1 = *TF++;
			const PxU32 vref2 = *TF++;

			currentTriangle.verts[0] = MeshOffset + absPose.rotate(verts[vref0]);
			currentTriangle.verts[1] = MeshOffset + absPose.rotate(verts[vref1]);
			currentTriangle.verts[2] = MeshOffset + absPose.rotate(verts[vref2]);

			PxU32 nbNewTris = 0;
			tessellateTriangle(nbNewTris, currentTriangle, PX_INVALID_U32, worldTriangles, triIndicesArray, cullingBox, params, nbTessellation);
			nbCreatedTris += nbNewTris;
		}
		touchedMesh->mNbTris = nbCreatedTris;
	}
	else
	{
		// Reserve memory for incoming triangles
		PxTriangle* TouchedTriangles = reserve(worldTriangles, Nb);

		touchedMesh->mNbTris = Nb;
		while(Nb--)
		{
			// Compute triangle in world space, add to array
			PxTriangle& currentTriangle = *TouchedTriangles++;

			const PxU32 vref0 = *TF++;
			const PxU32 vref1 = *TF++;
			const PxU32 vref2 = *TF++;

			currentTriangle.verts[0] = MeshOffset + absPose.rotate(verts[vref0]);
			currentTriangle.verts[1] = MeshOffset + absPose.rotate(verts[vref1]);
			currentTriangle.verts[2] = MeshOffset + absPose.rotate(verts[vref2]);

			triIndicesArray.pushBack(PX_INVALID_U32);
		}
	}
	if(gVisualizeTouchedTris)
		visualizeTouchedTriangles(touchedMesh->mNbTris, touchedMesh->mIndexWorldTriangles, &worldTriangles[0], renderBuffer, offset, params.mUpDirection);
}
void Cct::findTouchedGeometry(
	const InternalCBData_FindTouchedGeom* userData,
	const PxExtendedBounds3& worldBounds,		// ### we should also accept other volumes

	TriArray& worldTriangles,
	IntArray& triIndicesArray,
	IntArray& geomStream,

	const CCTFilter& filter,
	const CCTParams& params)
{
	PX_ASSERT(userData);
	
	const PxInternalCBData_FindTouchedGeom* internalData = static_cast<const PxInternalCBData_FindTouchedGeom*>(userData);
	PxScene* scene = internalData->scene;
	Cm::RenderBuffer* renderBuffer = internalData->renderBuffer;

	PxExtendedVec3 Origin;	// Will be TouchedGeom::mOffset
	getCenter(worldBounds, Origin);

	// Find touched *boxes* i.e. touched objects' AABBs in the world
	// We collide against dynamic shapes too, to get back dynamic boxes/etc
	// TODO: add active groups in interface!
	PxSceneQueryFilterFlags sqFilterFlags;
	if(filter.mStaticShapes)	sqFilterFlags |= PxSceneQueryFilterFlag::eSTATIC;
	if(filter.mDynamicShapes)	sqFilterFlags |= PxSceneQueryFilterFlag::eDYNAMIC;
	if(filter.mFilterCallback)
	{
		if(filter.mPreFilter)
			sqFilterFlags |= PxSceneQueryFilterFlag::ePREFILTER;
		if(filter.mPostFilter)
			sqFilterFlags |= PxSceneQueryFilterFlag::ePOSTFILTER;
	}

	// ### this one is dangerous
	const PxBounds3 tmpBounds(toVec3(worldBounds.minimum), toVec3(worldBounds.maximum));	// LOSS OF ACCURACY

	// PT: unfortunate conversion forced by the PxGeometry API
	PxVec3 center = tmpBounds.getCenter(), extents = tmpBounds.getExtents();

	PxShape* hits[100];
	PxU32 size = 100;

	const PxSceneQueryFilterData sceneQueryFilterData = filter.mFilterData ? PxSceneQueryFilterData(*filter.mFilterData, sqFilterFlags) : PxSceneQueryFilterData(sqFilterFlags);

	PxI32 numberHits = scene->overlapMultiple(PxBoxGeometry(extents), PxTransform(center), hits, size, sceneQueryFilterData, filter.mFilterCallback);
	
	for(PxI32 i = 0; i < numberHits; i++)
	{
		PxShape* shape = hits[i];
		if(shape == NULL)
			continue;

		// Filtering

		// Discard all CCT shapes, i.e. kinematic actors we created ourselves. We don't need to collide with them since they're surrounded
		// by the real CCT volume - and collisions with those are handled elsewhere. We use the userData field for filtering because that's
		// really our only valid option (filtering groups are already used by clients and we don't have control over them, clients might
		// create other kinematic actors that we may want to keep here, etc, etc)
		if(internalData->cctShapeHashSet->contains(shape))
			continue;

		// Ubi (EA) : Discarding Triggers :
		if(shape->getFlags() & PxShapeFlag::eTRIGGER_SHAPE)
			continue;

		// PT: here you might want to disable kinematic objects.

		// Output shape to stream
		const PxTransform globalPose = getShapeGlobalPose(*shape);

		const PxGeometryType::Enum type = shape->getGeometryType();	// ### VIRTUAL!
		if(type==PxGeometryType::eSPHERE)				outputSphereToStream(shape, globalPose, geomStream, Origin);
		else	if(type==PxGeometryType::eCAPSULE)		outputCapsuleToStream(shape, globalPose, geomStream, Origin);
		else	if(type==PxGeometryType::eBOX)			outputBoxToStream(shape, globalPose, geomStream, worldTriangles, triIndicesArray, Origin, tmpBounds, params, renderBuffer);
		else	if(type==PxGeometryType::eTRIANGLEMESH)	outputMeshToStream(shape, globalPose, geomStream, worldTriangles, triIndicesArray, Origin, tmpBounds, params, renderBuffer);
		else	if(type==PxGeometryType::eHEIGHTFIELD)	outputHeightFieldToStream(shape, globalPose, geomStream, worldTriangles, triIndicesArray, Origin, tmpBounds, params, renderBuffer);
		else	if(type==PxGeometryType::eCONVEXMESH)	outputConvexToStream(shape, globalPose, geomStream, worldTriangles, triIndicesArray, Origin, tmpBounds);
		else	if(type==PxGeometryType::ePLANE)		outputPlaneToStream(shape, globalPose, geomStream, worldTriangles, triIndicesArray, Origin, tmpBounds, params, renderBuffer);
	}
}
static void outputHeightFieldToStream(	PxShape* hfShape, const PxTransform& heightfieldPose, IntArray& geomStream, TriArray& worldTriangles, IntArray& triIndicesArray,
										const PxExtendedVec3& origin, const PxBounds3& tmpBounds, const CCTParams& params, Cm::RenderBuffer* renderBuffer)
{
	PX_ASSERT(hfShape->getGeometryType() == PxGeometryType::eHEIGHTFIELD);
	// Do AABB-mesh query

	PxHeightFieldGeometry hfGeom;
	hfShape->getHeightFieldGeometry(hfGeom);

	PxBoxGeometry boxGeom(tmpBounds.getExtents());
	PxTransform boxPose;
	boxPose.p = tmpBounds.getCenter();
	boxPose.q = PxQuat::createIdentity();

	// Collide AABB against current heightfield
	PxFindOverlapTriangleMeshUtil overlapUtil;
	const PxU32 nbTouchedTris = overlapUtil.findOverlap(boxGeom, boxPose, hfGeom, heightfieldPose);

	const PxVec3 offset(float(-origin.x), float(-origin.y), float(-origin.z));

	TouchedMesh* touchedMesh			= (TouchedMesh*)reserve(geomStream, sizeof(TouchedMesh)/sizeof(PxU32));
	touchedMesh->mType					= TouchedGeomType::eMESH; // ptchernev: seems to work
	touchedMesh->mUserData				= hfShape;
	touchedMesh->mOffset				= origin;
	touchedMesh->mNbTris				= nbTouchedTris;
	touchedMesh->mIndexWorldTriangles	= worldTriangles.size();

	const PxU32* PX_RESTRICT indices = overlapUtil.getResults();

	if(params.mSlopeLimit!=0.0f)
	{
		// Reserve memory for incoming triangles
//		PxTriangle* TouchedTriangles = reserve(worldTriangles, nbTouchedTris);

		// Loop through touched triangles
		PxU32 nbCreatedTris = 0;
		for(PxU32 i=0; i < nbTouchedTris; i++)
		{
			const PxU32 triangleIndex = indices[i];

			// Compute triangle in world space, add to array
			PxTriangle currentTriangle;
			PxMeshQuery::getTriangle(hfGeom, heightfieldPose, triangleIndex, currentTriangle);
			currentTriangle.verts[0] += offset;
			currentTriangle.verts[1] += offset;
			currentTriangle.verts[2] += offset;

			const PxU32 nbNewTris = createInvisibleWalls(params, currentTriangle, worldTriangles, triIndicesArray);
			nbCreatedTris += nbNewTris;
			if(!nbNewTris)
			{
				worldTriangles.pushBack(currentTriangle);

				triIndicesArray.pushBack(triangleIndex);
				nbCreatedTris++;
			}
		}
		touchedMesh->mNbTris = nbCreatedTris;
	}
	else
	{
		// Reserve memory for incoming triangles
		PxTriangle* TouchedTriangles = reserve(worldTriangles, nbTouchedTris);

		// Loop through touched triangles
		for(PxU32 i=0; i < nbTouchedTris; i++)
		{
			const PxU32 triangleIndex = indices[i];

			// Compute triangle in world space, add to array
			PxTriangle& currentTriangle = *TouchedTriangles++;
			PxMeshQuery::getTriangle(hfGeom, heightfieldPose, triangleIndex, currentTriangle);
			currentTriangle.verts[0] += offset;
			currentTriangle.verts[1] += offset;
			currentTriangle.verts[2] += offset;

			triIndicesArray.pushBack(triangleIndex);
		}
	}

	if(gVisualizeTouchedTris)
		visualizeTouchedTriangles(touchedMesh->mNbTris, touchedMesh->mIndexWorldTriangles, &worldTriangles[0], renderBuffer, offset, params.mUpDirection);
}
static void outputBoxToStream(	PxShape* boxShape, const PxRigidActor* actor, const PxTransform& globalPose, IntArray& geomStream, TriArray& worldTriangles, IntArray& triIndicesArray,
								const PxExtendedVec3& origin, const PxBounds3& tmpBounds, const CCTParams& params, PxU16& nbTessellation)
{
	PX_ASSERT(boxShape->getGeometryType() == PxGeometryType::eBOX);
	PxBoxGeometry bg;
	boxShape->getBoxGeometry(bg);

	//8 verts in local space.
	const PxF32 dx = bg.halfExtents.x;
	const PxF32 dy = bg.halfExtents.y;
	const PxF32 dz = bg.halfExtents.z;
	PxVec3 boxVerts[8]=
	{
		PxVec3(-dx,-dy,-dz),
		PxVec3(+dx,-dy,-dz),
		PxVec3(+dx,+dy,-dz),
		PxVec3(-dx,+dy,-dz),
		PxVec3(-dx,-dy,+dz),
		PxVec3(+dx,-dy,+dz),
		PxVec3(+dx,+dy,+dz),
		PxVec3(-dx,+dy,+dz)
	};
	//Transform verts into world space.
	const PxVec3 pxOrigin = toVec3(origin);
	for(PxU32 i = 0; i < 8; i++)
	{
		boxVerts[i] = globalPose.transform(boxVerts[i]) - pxOrigin;
	}

	//Index of triangles.
	const PxU32 boxTris[12][3]=
	{
		{0,2,1},
		{2,0,3},	//0,1,2,3

		{3,6,2},
		{6,3,7},	//3,2,6,7
		
		{7,5,6},
		{5,7,4},	//7,6,5,4

		{4,1,5},
		{1,4,0},	//4,5,1,0

		{0,7,3},
		{7,0,4},	//0,3,7,4

		{2,5,1},
		{5,2,6}		//2,1,5,6
	};

	TouchedMesh* touchedMesh			= (TouchedMesh*)reserve(geomStream, sizeof(TouchedMesh)/sizeof(PxU32));
	touchedMesh->mType					= TouchedGeomType::eMESH;
	touchedMesh->mTGUserData			= boxShape;
	touchedMesh->mActor					= actor;
	touchedMesh->mOffset				= origin;
	touchedMesh->mIndexWorldTriangles	= worldTriangles.size();

	if(params.mTessellation)
	{
		const PxBoxGeometry boxGeom(tmpBounds.getExtents());
		const PxVec3 offset(float(-origin.x), float(-origin.y), float(-origin.z));
		const PxBounds3 cullingBox = PxBounds3::centerExtents(tmpBounds.getCenter() + offset, boxGeom.halfExtents);

		PxU32 nbCreatedTris = 0;
		for(PxU32 i=0; i<12; i++)
		{
			// Compute triangle in world space, add to array
			const PxTriangle currentTriangle(boxVerts[boxTris[i][0]], boxVerts[boxTris[i][1]], boxVerts[boxTris[i][2]]);

			PxU32 nbNewTris = 0;
			tessellateTriangle(nbNewTris, currentTriangle, PX_INVALID_U32, worldTriangles, triIndicesArray, cullingBox, params, nbTessellation);
			nbCreatedTris += nbNewTris;
		}
		touchedMesh->mNbTris = nbCreatedTris;
	}
	else
	{
		touchedMesh->mNbTris = 12;

		// Reserve memory for incoming triangles
		PxTriangle* TouchedTriangles = reserve(worldTriangles, 12);

		for(PxU32 i=0; i<12; i++)
		{
			PxTriangle& currentTriangle = TouchedTriangles[i];
			currentTriangle.verts[0] = boxVerts[boxTris[i][0]];
			currentTriangle.verts[1] = boxVerts[boxTris[i][1]];
			currentTriangle.verts[2] = boxVerts[boxTris[i][2]];

			triIndicesArray.pushBack(PX_INVALID_U32);
		}
	}
}
void FDestructibleMeshEditorViewportClient::ProcessClick( class FSceneView& View, class HHitProxy* HitProxy, FKey Key, EInputEvent Event, uint32 HitX, uint32 HitY )
{
#if WITH_APEX
	bool bKeepSelection = Viewport->KeyState(EKeys::LeftControl) || Viewport->KeyState(EKeys::RightControl);
	bool bSelectionChanged = false;

	if (Key == EKeys::LeftMouseButton && Event == EInputEvent::IE_Released)
	{
		UDestructibleComponent* Comp = PreviewDestructibleComp.Get();
		NxDestructibleAsset* Asset = Comp->DestructibleMesh->ApexDestructibleAsset;
		const NxRenderMeshAsset* RenderMesh = Asset->getRenderMeshAsset();

		FVector2D ScreenPos(HitX, HitY);
		FVector ClickOrigin, ViewDir;
		View.DeprojectFVector2D(ScreenPos, ClickOrigin, ViewDir);

		float NearestHitDistance = FLT_MAX;
		int32 ClickedChunk = -1;

		for (uint32 i=0; i < Asset->getChunkCount(); ++i)
		{
			int32 PartIdx = Asset->getPartIndex(i);
			int32 BoneIdx = i+1;
			
			if (!Comp->IsBoneHidden(BoneIdx))
			{
				PxBounds3 PBounds = RenderMesh->getBounds(PartIdx);

				FVector Center = P2UVector(PBounds.getCenter()) + Comp->GetBoneLocation(Comp->GetBoneName(BoneIdx));
				FVector Extent = P2UVector(PBounds.getExtents());

				FBox Bounds(Center - Extent, Center + Extent);

				FVector HitLoc, HitNorm;
				float HitTime;
				
				if (FMath::LineExtentBoxIntersection(Bounds, ClickOrigin, ClickOrigin + ViewDir * 1000.0f, FVector(0,0,0), HitLoc, HitNorm, HitTime))
				{
					float dist = (HitLoc - ClickOrigin).SizeSquared();

					if (dist < NearestHitDistance)
					{
						NearestHitDistance = dist;
						ClickedChunk = i;
					}
				}
			}
		}

		if (ClickedChunk >= 0)
		{
			int32 Idx = SelectedChunkIndices.Find(ClickedChunk);
		
			if (Idx < 0)
			{
				if (!bKeepSelection) { SelectedChunkIndices.Empty(); }

				SelectedChunkIndices.Add(ClickedChunk);
				bSelectionChanged = true;
			}
			else
			{
				SelectedChunkIndices.RemoveAt(Idx);
				bSelectionChanged = true;
			}
		}
		else if (!bKeepSelection)
		{
			SelectedChunkIndices.Empty();
 			bSelectionChanged = true;
		}
	}

	if (bSelectionChanged)
	{
		UpdateChunkSelection(SelectedChunkIndices);
	}
#endif // WITH_APEX
}
Exemplo n.º 20
0
	//////////////////////////////////////////////////////////////////////////
	// checks if points form a valid AABB cube, if not construct a default CUBE
	static bool checkPointsAABBValidity(PxU32 numPoints, const PxVec3* points, PxU32 stride , float distanceEpsilon,
		float resizeValue, PxVec3& center, PxVec3& scale, PxU32& vcount, PxVec3* vertices, bool fCheck = false)
	{
		const char* vtx = reinterpret_cast<const char *> (points);
		PxBounds3 bounds;
		bounds.setEmpty();

		// get the bounding box		
		for (PxU32 i = 0; i < numPoints; i++)
		{
			const PxVec3& p = *reinterpret_cast<const PxVec3 *> (vtx);
			vtx += stride;

			bounds.include(p);
		}

		PxVec3 dim = bounds.getDimensions();
		center = bounds.getCenter();

		// special case, the AABB is very thin or user provided us with only input 2 points
		// we construct an AABB cube and return it
		if ( dim.x < distanceEpsilon || dim.y < distanceEpsilon || dim.z < distanceEpsilon || numPoints < 3 )
		{
			float len = FLT_MAX;

			// pick the shortest size bigger than the distance epsilon
			if ( dim.x > distanceEpsilon && dim.x < len ) 
				len = dim.x;
			if ( dim.y > distanceEpsilon && dim.y < len ) 
				len = dim.y;
			if ( dim.z > distanceEpsilon && dim.z < len ) 
				len = dim.z;

			// if the AABB is small in all dimensions, resize it
			if ( len == FLT_MAX )
			{
				dim = PxVec3(resizeValue);
			}
			// if one edge is small, set to 1/5th the shortest non-zero edge.
			else
			{
				if ( dim.x < distanceEpsilon )
					dim.x = len * 0.05f;
				else
					dim.x *= 0.5f;
				if ( dim.y < distanceEpsilon )
					dim.y = len * 0.05f;
				else
					dim.y *= 0.5f;
				if ( dim.z < distanceEpsilon ) 
					dim.z = len * 0.05f;
				else
					dim.z *= 0.5f;
			}

			// construct the AABB
			const PxVec3 extPos = center + dim;
			const PxVec3 extNeg = center - dim;

			if(fCheck)
				vcount = 0;

			vertices[vcount++] = extNeg;			
			vertices[vcount++] = PxVec3(extPos.x,extNeg.y,extNeg.z);
			vertices[vcount++] = PxVec3(extPos.x,extPos.y,extNeg.z);			
			vertices[vcount++] = PxVec3(extNeg.x,extPos.y,extNeg.z);			
			vertices[vcount++] = PxVec3(extNeg.x,extNeg.y,extPos.z);			
			vertices[vcount++] = PxVec3(extPos.x,extNeg.y,extPos.z);			
			vertices[vcount++] = extPos;			
			vertices[vcount++] = PxVec3(extNeg.x,extPos.y,extPos.z);			
			return true; // return cube
		}
		else
		{
			scale = dim;
		}
		return false;
	}