protected override bool ConfigureTriangle(int i, out TriangleIndices indices)
        {
            MeshBoundingBoxTreeData data = mesh.Shape.TriangleMesh.Data;
            int triangleIndex            = overlappedTriangles.Elements[i];

            data.GetTriangle(triangleIndex, out localTriangleShape.vA, out localTriangleShape.vB, out localTriangleShape.vC);
            AffineTransform transform;

            AffineTransform.CreateFromRigidTransform(ref mesh.worldTransform, out transform);
            AffineTransform.Transform(ref localTriangleShape.vA, ref transform, out localTriangleShape.vA);
            AffineTransform.Transform(ref localTriangleShape.vB, ref transform, out localTriangleShape.vB);
            AffineTransform.Transform(ref localTriangleShape.vC, ref transform, out localTriangleShape.vC);
            //In instanced meshes, the bounding box we found in local space could collect more triangles than strictly necessary.
            //By doing a second pass, we should be able to prune out quite a few of them.
            BoundingBox triangleAABB;

            Toolbox.GetTriangleBoundingBox(ref localTriangleShape.vA, ref localTriangleShape.vB, ref localTriangleShape.vC, out triangleAABB);
            bool toReturn;

            triangleAABB.Intersects(ref convex.boundingBox, out toReturn);
            if (!toReturn)
            {
                indices = new TriangleIndices();
                return(false);
            }

            TriangleSidedness sidedness;

            switch (mesh.Shape.solidity)
            {
            case MobileMeshSolidity.Clockwise:
                sidedness = TriangleSidedness.Clockwise;
                break;

            case MobileMeshSolidity.Counterclockwise:
                sidedness = TriangleSidedness.Counterclockwise;
                break;

            case MobileMeshSolidity.DoubleSided:
                sidedness = TriangleSidedness.DoubleSided;
                break;

            default:
                sidedness = mesh.Shape.solidSidedness;
                break;
            }
            localTriangleShape.sidedness       = sidedness;
            localTriangleShape.collisionMargin = 0;
            indices = new TriangleIndices()
            {
                A = data.uindices[triangleIndex],
                B = data.uindices[triangleIndex + 1],
                C = data.uindices[triangleIndex + 2]
            };
            return(true);
        }
Example #2
0
        /// <summary>
        /// Precomputes the transform to bring triangles from their native local space to the local space of the convex.
        /// </summary>
        /// <param name="convexInverseWorldTransform">Inverse of the world transform of the convex shape.</param>
        /// <param name="fromMeshLocalToConvexLocal">Transform to apply to native local triangles to bring them into the local space of the convex.</param>
        protected override void PrecomputeTriangleTransform(ref AffineTransform convexInverseWorldTransform, out AffineTransform fromMeshLocalToConvexLocal)
        {
            //MobileMeshes only have TransformableMeshData sources.
            var data = ((TransformableMeshData)mesh.Shape.TriangleMesh.Data);
            //The mobile mesh has a shape-based transform followed by the rigid body transform.
            AffineTransform mobileMeshWorldTransform;

            AffineTransform.CreateFromRigidTransform(ref mesh.worldTransform, out mobileMeshWorldTransform);
            AffineTransform combinedMobileMeshWorldTransform;

            AffineTransform.Multiply(ref data.worldTransform, ref mobileMeshWorldTransform, out combinedMobileMeshWorldTransform);
            AffineTransform.Multiply(ref combinedMobileMeshWorldTransform, ref convexInverseWorldTransform, out fromMeshLocalToConvexLocal);
        }
        protected override void UpdateContainedPairs(float dt)
        {
            var             overlappedElements = CommonResources.GetIntList();
            BoundingBox     localBoundingBox;
            AffineTransform meshTransform;

            AffineTransform.CreateFromRigidTransform(ref mesh.worldTransform, out meshTransform);

            System.Numerics.Vector3 sweep;
            Vector3Ex.Subtract(ref mobileMesh.entity.linearVelocity, ref mesh.entity.linearVelocity, out sweep);
            Vector3Ex.Multiply(ref sweep, dt, out sweep);
            mobileMesh.Shape.GetSweptLocalBoundingBox(ref mobileMesh.worldTransform, ref meshTransform, ref sweep, out localBoundingBox);
            mesh.Shape.TriangleMesh.Tree.GetOverlaps(localBoundingBox, overlappedElements);
            for (int i = 0; i < overlappedElements.Count; i++)
            {
                TryToAdd(overlappedElements.Elements[i]);
            }

            CommonResources.GiveBack(overlappedElements);
        }
Example #4
0
        ///<summary>
        /// Updates the manifold.
        ///</summary>
        ///<param name="dt">Timestep duration.</param>
        public override void Update(float dt)
        {
            //First, refresh all existing contacts.  This is an incremental manifold.
            var transform = MeshTransform;

            ContactRefresher.ContactRefresh(contacts, supplementData, ref convex.worldTransform, ref transform, contactIndicesToRemove);

            RemoveQueuedContacts();


            CleanUpOverlappingTriangles();
            //Get all the overlapped triangle indices.
            //Note that the collection of triangles is left up to the child implementation.
            //We're basically treating the child class like an indexable collection.
            //A little gross to have it organized this way instead of an explicit collection to separate the logic up. Would be nice to improve someday!
            int triangleCount = FindOverlappingTriangles(dt);

            //Just use 32 elements for all the lists and sets in this system.
            const int    bufferPoolSizePower = 5;
            BoundarySets boundarySets;

            if (UseImprovedBoundaryHandling)
            {
                boundarySets = new BoundarySets(bufferPoolSizePower);
            }
            else
            {
                boundarySets = new BoundarySets();
            }

            var candidatesToAdd = new QuickList <ContactData>(BufferPools <ContactData> .Thread, bufferPoolSizePower);

            //A single triangle shape will be reused for all operations. It's pulled from a thread local pool to avoid holding a TriangleShape around for every single contact manifold or pair tester.
            var localTriangleShape = PhysicsThreadResources.GetTriangle();

            //Precompute the transform to take triangles from their native local space to the convex's local space.
            RigidTransform inverseConvexWorldTransform;

            RigidTransform.Invert(ref convex.worldTransform, out inverseConvexWorldTransform);
            AffineTransform convexInverseWorldTransform;

            AffineTransform.CreateFromRigidTransform(ref inverseConvexWorldTransform, out convexInverseWorldTransform);
            AffineTransform fromMeshLocalToConvexLocal;

            PrecomputeTriangleTransform(ref convexInverseWorldTransform, out fromMeshLocalToConvexLocal);

            //Grab the convex's local space bounding box up front. This will be used for a secondary pruning step.
            BoundingBox convexLocalBoundingBox;

            convex.Shape.GetBoundingBox(ref Toolbox.RigidIdentity, out convexLocalBoundingBox);

            Matrix3x3 orientation;

            Matrix3x3.CreateFromQuaternion(ref convex.worldTransform.Orientation, out orientation);
            var guaranteedContacts = 0;

            for (int i = 0; i < triangleCount; i++)
            {
                //Initialize the local triangle.
                TriangleIndices indices;
                if (ConfigureLocalTriangle(i, localTriangleShape, out indices))
                {
                    //Put the triangle into the local space of the convex.
                    AffineTransform.Transform(ref localTriangleShape.vA, ref fromMeshLocalToConvexLocal, out localTriangleShape.vA);
                    AffineTransform.Transform(ref localTriangleShape.vB, ref fromMeshLocalToConvexLocal, out localTriangleShape.vB);
                    AffineTransform.Transform(ref localTriangleShape.vC, ref fromMeshLocalToConvexLocal, out localTriangleShape.vC);

                    //Do one last AABB test between the convex and triangle in the convex's local space.
                    //This can prune out a lot of triangles when dealing with larger objects, and it's pretty cheap to do.
                    BoundingBox triangleBoundingBox;
                    Toolbox.GetTriangleBoundingBox(ref localTriangleShape.vA, ref localTriangleShape.vB, ref localTriangleShape.vC, out triangleBoundingBox);

                    bool intersecting;
                    triangleBoundingBox.Intersects(ref convexLocalBoundingBox, out intersecting);
                    if (!intersecting)
                    {
                        continue;
                    }

                    //Find a pairtester for the triangle.
                    TrianglePairTester pairTester;
                    if (!activePairTesters.TryGetValue(indices, out pairTester))
                    {
                        pairTester = GetTester();
                        pairTester.Initialize(convex.Shape);
                        activePairTesters.Add(indices, pairTester);
                    }
                    pairTester.Updated = true;


                    //Now, generate a contact between the two shapes.
                    TinyStructList <ContactData> contactList;
                    if (pairTester.GenerateContactCandidates(localTriangleShape, out contactList))
                    {
                        for (int j = 0; j < contactList.Count; j++)
                        {
                            ContactData contact;
                            contactList.Get(j, out contact);


                            if (UseImprovedBoundaryHandling)
                            {
                                if (AnalyzeCandidate(ref indices, localTriangleShape, pairTester, ref contact, ref boundarySets))
                                {
                                    //This is let through if there's a face contact. Face contacts cannot be blocked.
                                    guaranteedContacts++;
                                    AddLocalContact(ref contact, ref orientation, ref candidatesToAdd);
                                }
                            }
                            else
                            {
                                AddLocalContact(ref contact, ref orientation, ref candidatesToAdd);
                            }
                        }
                    }

                    //Get the voronoi region from the contact candidate generation.  Possibly just recalculate, since most of the systems don't calculate it.
                    //Depending on which voronoi region it is in (Switch on enumeration), identify the indices composing that region.  For face contacts, don't bother- just add it if unique.
                    //For AB, AC, or BC, add an Edge to the blockedEdgeRegions set with the corresponding indices.
                    //For A, B, or C, add the index of the vertex to the blockedVertexRegions set.
                    //If the edge/vertex is already present in the set, then DO NOT add the contact.
                    //When adding a contact, add ALL other voronoi regions to the blocked sets.
                }
            }



            if (UseImprovedBoundaryHandling)
            {
                //If there were no face contacts that absolutely must be included, we may get into a very rare situation
                //where absolutely no contacts get created.  For example, a sphere falling directly on top of a vertex in a flat terrain.
                //It will generally get locked out of usage by belonging only to restricted regions (numerical issues make it visible by both edges and vertices).
                //In some cases, the contacts will be ignored instead of corrected (e.g. spheres).
                //To prevent objects from just falling through the ground in such a situation, force-correct the contacts regardless of the pair tester's desires.
                //Sure, it might not be necessary under normal circumstances, but it's a better option than having no contacts.
                //TODO: There is another option: Changing restricted regions so that a vertex only restricts the other two vertices and the far edge,
                //and an edge only restricts the far vertex and other two edges.  This introduces an occasional bump though...

                //It's possible, in very specific instances, for an object to wedge itself between two adjacent triangles.
                //For this state to continue beyond a brief instant generally requires the object be orientation locked and slender.
                //However, some characters fit this description, so it can't be ignored!

                //Conceptually, this issue can occur at either a vertex junction or a shared edge (usually on extremely flat surfaces only).
                //However, an object stuck between multiple triangles is not in a stable state.  In the edge case, the object gets shoved to one side
                //as one contact 'wins' the solver war.  That's not enough to escape, unfortunately.
                //The vertex case, on the other hand, is degenerate and decays into an edge case rapidly thanks to this lack of stability.
                //So, we don't have to explicitly handle the somewhat more annoying and computationally expensive vertex unstucking case, because the edge case handles both! :)

                //This isn't a completely free operation, but it's guarded behind pretty rare conditions.
                //Essentially, we will check to see if there's just edge contacts fighting against each other.
                //If they are, then we will correct any stuck-contributing normals to the triangle normal.
                if (boundarySets.VertexContacts.Count == 0 && guaranteedContacts == 0 && boundarySets.EdgeContacts.Count > 1)
                {
                    //There are only edge contacts, check to see if:
                    //all normals are coplanar, and
                    //at least one normal faces against the other normals (meaning it's probably stuck, as opposed to just colliding on a corner).

                    bool allNormalsInSamePlane   = true;
                    bool atLeastOneNormalAgainst = false;

                    var firstNormal = boundarySets.EdgeContacts.Elements[0].ContactData.Normal;
                    boundarySets.EdgeContacts.Elements[0].CorrectedNormal.Normalize();
                    float dot;
                    Vector3Ex.Dot(ref firstNormal, ref boundarySets.EdgeContacts.Elements[0].CorrectedNormal, out dot);
                    if (Math.Abs(dot) > .01f)
                    {
                        //Go ahead and test the first contact separately, since we're using its contact normal to determine coplanarity.
                        allNormalsInSamePlane = false;
                    }
                    else
                    {
                        //TODO: Note that we're only checking the new edge contacts, not the existing contacts.
                        //It's possible that some existing contacts could interfere and cause issues, but for the sake of simplicity and due to rarity
                        //we'll ignore that possibility for now.
                        for (int i = 1; i < boundarySets.EdgeContacts.Count; i++)
                        {
                            Vector3Ex.Dot(ref boundarySets.EdgeContacts.Elements[i].ContactData.Normal, ref firstNormal, out dot);
                            if (dot < 0)
                            {
                                atLeastOneNormalAgainst = true;
                            }
                            //Check to see if the normal is outside the plane.
                            Vector3Ex.Dot(ref boundarySets.EdgeContacts.Elements[i].ContactData.Normal, ref boundarySets.EdgeContacts.Elements[0].CorrectedNormal, out dot);

                            if (Math.Abs(dot) > .01f)
                            {
                                //We are not stuck!
                                allNormalsInSamePlane = false;
                                break;
                            }
                        }
                    }

                    if (allNormalsInSamePlane && atLeastOneNormalAgainst)
                    {
                        //Uh oh! all the normals are parallel... The object is probably in a weird situation.
                        //Let's correct the normals!

                        //Already normalized the first contact above.
                        //We don't need to perform the perpendicularity test here- we did that before! We know it's perpendicular already.
                        boundarySets.EdgeContacts.Elements[0].ContactData.Normal = boundarySets.EdgeContacts.Elements[0].CorrectedNormal;
                        boundarySets.EdgeContacts.Elements[0].ShouldCorrect      = true;

                        for (int i = 1; i < boundarySets.EdgeContacts.Count; i++)
                        {
                            //Must normalize the corrected normal before using it.
                            boundarySets.EdgeContacts.Elements[i].CorrectedNormal.Normalize();
                            Vector3Ex.Dot(ref boundarySets.EdgeContacts.Elements[i].CorrectedNormal, ref boundarySets.EdgeContacts.Elements[i].ContactData.Normal, out dot);
                            if (dot < .01)
                            {
                                //Only bother doing the correction if the normal appears to be pointing nearly horizontally- implying that it's a contributor to the stuckness!
                                //If it's blocked, the next section will use the corrected normal- if it's not blocked, the next section will use the direct normal.
                                //Make them the same thing :)
                                boundarySets.EdgeContacts.Elements[i].ContactData.Normal = boundarySets.EdgeContacts.Elements[i].CorrectedNormal;
                                boundarySets.EdgeContacts.Elements[i].ShouldCorrect      = true;
                                //Note that the penetration depth is NOT corrected.  The contact's depth no longer represents the true depth.
                                //However, we only need to have some penetration depth to get the object to escape the rut.
                                //Furthermore, the depth computed from the horizontal opposing contacts is known to be less than the depth in the perpendicular direction.
                                //If the current depth was NOT less than the true depth along the corrected normal, then the collision detection system
                                //would have picked a different depth, as it finds a reasonable approximation of the minimum penetration!
                                //As a consequence, this contact will not be active beyond the object's destuckification, because its contact depth will be negative (or very close to it).
                            }
                        }
                    }
                }



                for (int i = 0; i < boundarySets.EdgeContacts.Count; i++)
                {
                    //Only correct if it's allowed AND it's blocked.
                    //If it's not blocked, the contact being created is necessary!
                    //The normal generated by the triangle-convex tester is already known not to
                    //violate the triangle sidedness.
                    if (!boundarySets.BlockedEdgeRegions.Contains(boundarySets.EdgeContacts.Elements[i].Edge))
                    {
                        //If it's not blocked, use the contact as-is without correcting it.
                        AddLocalContact(ref boundarySets.EdgeContacts.Elements[i].ContactData, ref orientation, ref candidatesToAdd);
                    }
                    else if (boundarySets.EdgeContacts.Elements[i].ShouldCorrect || guaranteedContacts == 0)
                    {
                        //If it is blocked, we can still make use of the contact.  But first, we need to change the contact normal to ensure that
                        //it will not interfere (and cause a bump or something).
                        float dot;
                        boundarySets.EdgeContacts.Elements[i].CorrectedNormal.Normalize();
                        Vector3Ex.Dot(ref boundarySets.EdgeContacts.Elements[i].CorrectedNormal, ref boundarySets.EdgeContacts.Elements[i].ContactData.Normal, out dot);
                        boundarySets.EdgeContacts.Elements[i].ContactData.Normal            = boundarySets.EdgeContacts.Elements[i].CorrectedNormal;
                        boundarySets.EdgeContacts.Elements[i].ContactData.PenetrationDepth *= MathHelper.Max(0, dot); //Never cause a negative penetration depth.
                        AddLocalContact(ref boundarySets.EdgeContacts.Elements[i].ContactData, ref orientation, ref candidatesToAdd);
                    }
                    //If it's blocked AND it doesn't allow correction, ignore its existence.
                }



                for (int i = 0; i < boundarySets.VertexContacts.Count; i++)
                {
                    if (!boundarySets.BlockedVertexRegions.Contains(boundarySets.VertexContacts.Elements[i].Vertex))
                    {
                        //If it's not blocked, use the contact as-is without correcting it.
                        AddLocalContact(ref boundarySets.VertexContacts.Elements[i].ContactData, ref orientation, ref candidatesToAdd);
                    }
                    else if (boundarySets.VertexContacts.Elements[i].ShouldCorrect || guaranteedContacts == 0)
                    {
                        //If it is blocked, we can still make use of the contact.  But first, we need to change the contact normal to ensure that
                        //it will not interfere (and cause a bump or something).
                        float dot;
                        boundarySets.VertexContacts.Elements[i].CorrectedNormal.Normalize();
                        Vector3Ex.Dot(ref boundarySets.VertexContacts.Elements[i].CorrectedNormal, ref boundarySets.VertexContacts.Elements[i].ContactData.Normal, out dot);
                        boundarySets.VertexContacts.Elements[i].ContactData.Normal            = boundarySets.VertexContacts.Elements[i].CorrectedNormal;
                        boundarySets.VertexContacts.Elements[i].ContactData.PenetrationDepth *= MathHelper.Max(0, dot); //Never cause a negative penetration depth.
                        AddLocalContact(ref boundarySets.VertexContacts.Elements[i].ContactData, ref orientation, ref candidatesToAdd);
                    }
                    //If it's blocked AND it doesn't allow correction, ignore its existence.
                }


                boundarySets.Dispose();
            }



            //Remove stale pair testers.
            for (int i = activePairTesters.Count - 1; i >= 0; --i)
            {
                var tester = activePairTesters.Values[i];
                if (!tester.Updated)
                {
                    tester.CleanUp();
                    GiveBackTester(tester);
                    activePairTesters.FastRemove(activePairTesters.Keys[i]);
                }
                else
                {
                    tester.Updated = false;
                }
            }

            //Some child types will want to do some extra post processing on the manifold.
            ProcessCandidates(ref candidatesToAdd);


            //Check if adding the new contacts would overflow the manifold.
            if (contacts.Count + candidatesToAdd.Count > 4)
            {
                //Adding all the contacts would overflow the manifold.  Reduce to the best subset.
                var reducedCandidates = new QuickList <ContactData>(BufferPools <ContactData> .Thread, bufferPoolSizePower);
                ContactReducer.ReduceContacts(contacts, ref candidatesToAdd, contactIndicesToRemove, ref reducedCandidates);
                RemoveQueuedContacts();
                for (int i = reducedCandidates.Count - 1; i >= 0; i--)
                {
                    Add(ref reducedCandidates.Elements[i]);
                    reducedCandidates.RemoveAt(i);
                }
                reducedCandidates.Dispose();
            }
            else if (candidatesToAdd.Count > 0)
            {
                //Won't overflow the manifold, so just toss it in PROVIDED that it isn't too close to something else.
                for (int i = 0; i < candidatesToAdd.Count; i++)
                {
                    Add(ref candidatesToAdd.Elements[i]);
                }
            }


            PhysicsThreadResources.GiveBack(localTriangleShape);
            candidatesToAdd.Dispose();
        }