Esempio n. 1
0
        HalfEdge EdgeSplit(HalfEdge edge, Vector3 vertex)
        {
            /*
              original:

                        edge
             *<======================
              ---------------------->*
                        twin

             split:

                newEdge		thisEdge
             *<=========*<===========
              --------->*----------->*
                thisTwin	newTwin

            */

            var thisEdge = edge;
            var thisTwinIndex = edge.TwinIndex;
            var thisTwin = Edges[thisTwinIndex];
            var thisEdgeIndex = thisTwin.TwinIndex;

            var newEdge = new HalfEdge();
            var newEdgeIndex = (short)Edges.Count;

            var newTwin = new HalfEdge();
            var newTwinIndex = (short)(newEdgeIndex + 1);
            var vertexIndex = (short)Vertices.Count;

            newEdge.PolygonIndex = thisEdge.PolygonIndex;
            newTwin.PolygonIndex = thisTwin.PolygonIndex;

            newEdge.VertexIndex = thisEdge.VertexIndex;
            thisEdge.VertexIndex = vertexIndex;

            newTwin.VertexIndex = thisTwin.VertexIndex;
            thisTwin.VertexIndex = vertexIndex;

            newEdge.NextIndex = thisEdge.NextIndex;
            thisEdge.NextIndex = newEdgeIndex;

            newTwin.NextIndex = thisTwin.NextIndex;
            thisTwin.NextIndex = newTwinIndex;

            newEdge.TwinIndex = thisTwinIndex;
            thisTwin.TwinIndex = newEdgeIndex;

            thisEdge.TwinIndex = newTwinIndex;
            newTwin.TwinIndex = thisEdgeIndex;

            Edges.Add(newEdge);
            Edges.Add(newTwin);
            Vertices.Add(vertex);
            return newEdge;
        }
Esempio n. 2
0
            public EdgeIntersection(HalfEdge edge, short planeIndexA, short planeIndexB)
            {
                PlaneIndices[0] = planeIndexA;
                PlaneIndices[1] = planeIndexB;

                Edge = edge;
            }
Esempio n. 3
0
        public static CSGMesh Combine(Vector3 offset, IDictionary<CSGNode, CSGMesh> brushMeshes)
        {
            var planeLookup = new Dictionary<Plane, short>();
            var vertexLookup = new Dictionary<Vector3, short>();

            var planes = new List<Plane>();
            var polygons = new List<Polygon>();
            var edges = new List<HalfEdge>();
            var vertices = new List<Vector3>();

            var bounds = new AABB();

            bounds.Clear();
            int edgeIndex = 0;
            int polygonIndex = 0;
            foreach (var item in brushMeshes)
            {
                var node = item.Key;
                var translation = Vector3.Subtract(node.Translation, offset);
                var mesh = item.Value;
                foreach (var edge in mesh.Edges)
                {
                    short vertexIndex;
                    var vertex = Vector3.Add(mesh.Vertices[edge.VertexIndex], translation);
                    if (!vertexLookup.TryGetValue(vertex, out vertexIndex))
                    {
                        vertexIndex = (short)vertices.Count;
                        vertices.Add(vertex);
                        vertexLookup.Add(vertex, vertexIndex);
                    }

                    var newEdge = new HalfEdge();
                    newEdge.VertexIndex = vertexIndex;
                    newEdge.NextIndex = (short)(edge.NextIndex + edgeIndex);
                    newEdge.TwinIndex = (short)(edge.TwinIndex + edgeIndex);
                    newEdge.PolygonIndex = (short)(edge.PolygonIndex + polygonIndex);

                    edges.Add(newEdge);
                }

                foreach (var polygon in mesh.Polygons)
                {
                    if (polygon.FirstIndex == -1)
                        continue;
                    short planeIndex;
                    var plane = mesh.Planes[polygon.PlaneIndex];
                    if (!planeLookup.TryGetValue(plane, out planeIndex))
                    {
                        planeIndex = (short)planes.Count;
                        planes.Add(plane);
                        planeLookup.Add(plane, planeIndex);
                    }

                    var newPolygon = new Polygon();
                    newPolygon.PlaneIndex = planeIndex;
                    newPolygon.FirstIndex = (short)(polygon.FirstIndex + edgeIndex);
                    newPolygon.Category = polygon.Category;
                    newPolygon.Visible = polygon.Visible;
                    newPolygon.Bounds.Set(polygon.Bounds, translation);

                    polygons.Add(newPolygon);

                    if (newPolygon.Visible)
                    {
                        var first = edges[newPolygon.FirstIndex];
                        var iterator = first;
                        do
                        {
                            bounds.Add(vertices[iterator.VertexIndex]);
                            iterator = edges[iterator.NextIndex];
                        } while (iterator != first);
                    }
                }
                edgeIndex = edges.Count;
                polygonIndex = polygons.Count;
            }
            return new CSGMesh(planes.ToArray(), polygons, edges, vertices, bounds);
        }
Esempio n. 4
0
        // Note: This method is not optimized! Code is simplified for clarity!
        //          for example: Plane.Distance / Plane.OnSide should be inlined manually and shouldn't use enums, but floating point values directly!
        public PolygonSplitResult PolygonSplit(Plane cuttingPlane, Vector3 translation, ref Polygon inputPolygon, out Polygon outsidePolygon)
        {
            HalfEdge prev		= Edges[inputPolygon.FirstIndex];
            HalfEdge current	= Edges[prev.NextIndex];
            HalfEdge next		= Edges[current.NextIndex];
            HalfEdge last		= next;
            HalfEdge enterEdge	= null;
            HalfEdge exitEdge	= null;

            var prevVertex			= Vertices[prev.VertexIndex];
            var prevDistance		= cuttingPlane.Distance(prevVertex);		// distance to previous vertex
            var prevSide			= Plane.OnSide(prevDistance);				// side of plane of previous vertex

            var currentVertex		= Vertices[current.VertexIndex];
            var currentDistance		= cuttingPlane.Distance(currentVertex);		// distance to current vertex
            var currentSide			= Plane.OnSide(currentDistance);			// side of plane of current vertex

            do
            {
                var nextVertex		= Vertices[next.VertexIndex];
                var nextDistance	= cuttingPlane.Distance(nextVertex);		// distance to next vertex
                var nextSide		= Plane.OnSide(nextDistance);				// side of plane of next vertex

                if (prevSide != currentSide)							// check if edge crossed the plane ...
                {
                    if (currentSide != PlaneSideResult.Intersects)		// prev:inside/outside - current:inside/outside - next:??
                    {
                        if (prevSide != PlaneSideResult.Intersects)		// prev:inside/outside - current:outside        - next:??
                        {
                            // Calculate intersection of edge with plane split the edge into two, inserting the new vertex
                            var newVertex	= Plane.Intersection(prevVertex, currentVertex, prevDistance, currentDistance);
                            var newEdge		= EdgeSplit(current, newVertex);

                            if (prevSide == PlaneSideResult.Inside)		// prev:inside         - current:outside        - next:??
                            {
                                //edge01 exits:
                                //
                                //      outside
                                //         1
                                //         *
                                // ......./........ intersect
                                //       /
                                //      0
                                //      inside

                                exitEdge		= current;
                            } else
                            if (prevSide == PlaneSideResult.Outside)		// prev:outside - current:inside - next:??
                            {
                                //edge01 enters:
                                //
                                //      outside
                                //      0
                                //       \
                                // .......\........ intersect
                                //         *
                                //         1
                                //      inside

                                enterEdge		= current;
                            }

                            prevDistance	= 0;
                            prev			= Edges[prev.NextIndex];
                            prevSide		= PlaneSideResult.Intersects;

                            if (exitEdge != null &&
                                enterEdge != null)
                                break;

                            current			= Edges[prev.NextIndex];
                            currentVertex	= Vertices[current.VertexIndex];

                            next			= Edges[current.NextIndex];
                            nextVertex		= Vertices[next.VertexIndex];
                        }
                    } else												// prev:??                - current:intersects - next:??
                    {
                        if (prevSide == PlaneSideResult.Intersects ||	// prev:intersects        - current:intersects - next:??
                            nextSide == PlaneSideResult.Intersects ||	// prev:??                - current:intersects - next:intersects
                            prevSide == nextSide)						// prev:inside/outde      - current:intersects - next:inside/outde
                        {
                            if (prevSide == PlaneSideResult.Inside ||	// prev:inside            - current:intersects - next:intersects/inside
                                nextSide == PlaneSideResult.Inside)		// prev:intersects/inside - current:intersects - next:inside
                            {
                                //      outside
                                // 0       1
                                // --------*....... intersect
                                //          \
                                //           2
                                //       inside
                                //
                                //      outside
                                //         1      2
                                // ........*------- intersect
                                //        /
                                //       0
                                //      inside
                                //
                                //     outside
                                //        1
                                //........*....... intersect
                                //       / \
                                //      0   2
                                //      inside
                                //

                                prevSide = PlaneSideResult.Inside;
                                enterEdge = exitEdge = null;
                                break;
                            } else
                            if (prevSide == PlaneSideResult.Outside ||		// prev:outside            - current:intersects - next:intersects/outside
                                nextSide == PlaneSideResult.Outside)		// prev:intersects/outside - current:intersects - next:outside
                            {
                                //     outside
                                //          2
                                //         /
                                //..------*....... intersect
                                //  0     1
                                //     inside
                                //
                                //     outside
                                //      0
                                //       \
                                //........*------- intersect
                                //        1      2
                                //     inside
                                //
                                //     outside
                                //      0   2
                                //       \ /
                                //........*....... intersect
                                //        1
                                //     inside
                                //

                                prevSide = PlaneSideResult.Outside;
                                enterEdge = exitEdge = null;
                                break;
                            }
                        } else											// prev:inside/outside - current:intersects - next:inside/outside
                        {
                            if (prevSide == PlaneSideResult.Inside)		// prev:inside         - current:intersects - next:outside
                            {
                                //find exit edge:
                                //
                                //      outside
                                //           2
                                //        1 /
                                // ........*....... intersect
                                //        /
                                //       0
                                //       inside

                                exitEdge = current;
                                if (enterEdge != null)
                                    break;
                            } else										// prev:outside        - current:intersects - next:inside
                            {
                                //find enter edge:
                                //
                                //      outside
                                //       0
                                //        \ 1
                                // ........*....... intersect
                                //          \
                                //           2
                                //       inside

                                enterEdge = current;
                                if (exitEdge != null)
                                    break;
                            }
                        }
                    }
                }

                prev	= current;
                current = next;
                next	= Edges[next.NextIndex];

                prevDistance	= currentDistance;
                currentDistance = nextDistance;
                prevSide		= currentSide;
                currentSide		= nextSide;
                prevVertex		= currentVertex;
                currentVertex	= nextVertex;
            } while (next != last);

            // We should never have only one edge crossing the plane ..
            //Debug.Assert((enterEdge == null) == (exitEdge == null));

            // Check if we have an edge that exits and an edge that enters the plane and split the polygon into two if we do
            if (enterEdge != null && exitEdge != null)
            {
                //enter   .
                //        .
                //  =====>*----->
                //        .
                //
                //outside . inside
                //        .
                //  <-----*<=====
                //        .
                //        .  exit

                outsidePolygon = new Polygon();
                var outsidePolygonIndex = (short)this.Polygons.Count;
                this.Polygons.Add(outsidePolygon);

                var outsideEdge			= new HalfEdge();
                var outsideEdgeIndex	= (short)Edges.Count;

                var insideEdge			= new HalfEdge();
                var insideEdgeIndex		= (short)(outsideEdgeIndex + 1);

                outsideEdge.TwinIndex		= insideEdgeIndex;
                insideEdge.TwinIndex		= outsideEdgeIndex;

                //insideEdge.PolygonIndex	= inputPolygonIndex;// index does not change
                outsideEdge.PolygonIndex	= outsidePolygonIndex;

                outsideEdge.VertexIndex		= exitEdge.VertexIndex;
                insideEdge.VertexIndex		= enterEdge.VertexIndex;

                outsideEdge.NextIndex		= exitEdge.NextIndex;
                insideEdge.NextIndex		= enterEdge.NextIndex;

                exitEdge.NextIndex			= insideEdgeIndex;
                enterEdge.NextIndex			= outsideEdgeIndex;

                outsidePolygon.FirstIndex	= outsideEdgeIndex;
                inputPolygon.FirstIndex		= insideEdgeIndex;

                outsidePolygon.Visible		= inputPolygon.Visible;
                outsidePolygon.Category		= inputPolygon.Category;
                outsidePolygon.PlaneIndex	= inputPolygon.PlaneIndex;

                Edges.Add(outsideEdge);
                Edges.Add(insideEdge);

                // calculate the bounds of the polygons
                outsidePolygon.Bounds.Clear();
                var first = Edges[outsidePolygon.FirstIndex];
                var iterator = first;
                do
                {
                    outsidePolygon.Bounds.Add(Vertices[iterator.VertexIndex]);
                    iterator.PolygonIndex = outsidePolygonIndex;
                    iterator = Edges[iterator.NextIndex];
                } while (iterator != first);

                inputPolygon.Bounds.Clear();
                first = Edges[inputPolygon.FirstIndex];
                iterator = first;
                do
                {
                    inputPolygon.Bounds.Add(Vertices[iterator.VertexIndex]);
                    iterator = Edges[iterator.NextIndex];
                } while (iterator != first);

                return PolygonSplitResult.Split;
            } else
            {
                outsidePolygon = null;
                switch (prevSide)
                {
                    case PlaneSideResult.Inside:	return PolygonSplitResult.CompletelyInside;
                    case PlaneSideResult.Outside:	return PolygonSplitResult.CompletelyOutside;
                    default:
                    case PlaneSideResult.Intersects:
                    {
                        var polygonPlane = Planes[inputPolygon.PlaneIndex];
                        var result = Vector3.DotProduct(polygonPlane.Normal, cuttingPlane.Normal);
                        if (result > 0)
                            return PolygonSplitResult.PlaneAligned;
                        else
                            return PolygonSplitResult.PlaneOppositeAligned;
                    }
                }
            }
        }
Esempio n. 5
0
        public CSGMesh Clone()
        {
            var newPlanes = new Plane[Planes.Length];
            for (int i = 0; i < Planes.Length; i++)
            {
                var plane = Planes[i];
                newPlanes[i] = new Plane(plane.A, plane.B, plane.C, plane.D);
            }
            var newPolygons = new List<Polygon>(Polygons.Count);
            foreach (var polygon in Polygons)
            {
                var newPolygon = new Polygon();
                newPolygon.FirstIndex = polygon.FirstIndex;
                newPolygon.Visible = polygon.Visible;
                newPolygon.Category = polygon.Category;
                newPolygon.PlaneIndex = polygon.PlaneIndex;
                newPolygon.Bounds.Set(polygon.Bounds);

                newPolygons.Add(newPolygon);
            }

            var newEdges = new List<HalfEdge>(Edges.Count);
            foreach (var edge in Edges)
            {
                var newEdge = new HalfEdge();
                newEdge.NextIndex = edge.NextIndex;
                newEdge.PolygonIndex = edge.PolygonIndex;
                newEdge.TwinIndex = edge.TwinIndex;
                newEdge.VertexIndex = edge.VertexIndex;
                newEdges.Add(newEdge);
            }

            var newVertices = new List<Vector3>(Vertices.Count);
            foreach (var vertex in Vertices)
            {
                var newVertex = new Vector3(vertex.X, vertex.Y, vertex.Z);
                newVertices.Add(newVertex);
            }

            var newBounds = new AABB(Bounds);
            var newMesh = new CSGMesh(
                newPlanes,
                newPolygons,
                newEdges,
                newVertices,
                newBounds);

            return newMesh;
        }
Esempio n. 6
0
        public static CSGMesh CreateFromPlanes(Plane[] brushPlanes)
        {
            var planes = new Plane[brushPlanes.Length];
            for (int i = 0; i < brushPlanes.Length; i++)
            {
                var plane = brushPlanes[i];
                planes[i] = new Plane(plane.A, plane.B, plane.C, plane.D);
            }

            var pointIntersections = new List<PointIntersection>(planes.Length * planes.Length);
            var intersectingPlanes = new List<short>();
            var vertices = new List<Vector3>();
            var edges = new List<HalfEdge>();

            // Find all point intersections where 3 (or more planes) intersect
            for (short planeIndex1 = 0; planeIndex1 < planes.Length - 2; planeIndex1++)
            {
                var plane1 = planes[planeIndex1];
                for (short planeIndex2 = (short)(planeIndex1 + 1); planeIndex2 < planes.Length - 1; planeIndex2++)
                {
                    var plane2 = planes[planeIndex2];
                    for (short planeIndex3 = (short)(planeIndex2 + 1); planeIndex3 < planes.Length; planeIndex3++)
                    {
                        var plane3 = planes[planeIndex3];

                        // Calculate the intersection
                        var vertex = Plane.Intersection(plane1, plane2, plane3);

                        // Check if the intersection is valid
                        if (float.IsNaN(vertex.X) || float.IsNaN(vertex.Y) || float.IsNaN(vertex.Z) ||
                            float.IsInfinity(vertex.X) || float.IsInfinity(vertex.Y) || float.IsInfinity(vertex.Z))
                            continue;

                        intersectingPlanes.Clear();
                        intersectingPlanes.Add(planeIndex1);
                        intersectingPlanes.Add(planeIndex2);
                        intersectingPlanes.Add(planeIndex3);

                        for (short planeIndex4 = 0; planeIndex4 < planes.Length; planeIndex4++)
                        {
                            if (planeIndex4 == planeIndex1 ||
                                planeIndex4 == planeIndex2 ||
                                planeIndex4 == planeIndex3)
                                continue;

                            var plane4 = planes[planeIndex4];
                            var side = plane4.OnSide(vertex);
                            if (side == PlaneSideResult.Intersects)
                            {
                                if (planeIndex4 < planeIndex3)
                                    // Already found this vertex
                                    goto SkipIntersection;

                                // We've found another plane which goes trough our found intersection point
                                intersectingPlanes.Add(planeIndex4);
                            }
                            else
                                if (side == PlaneSideResult.Outside)
                                    // Intersection is outside of brush
                                    goto SkipIntersection;
                        }

                        var vertexIndex = (short)vertices.Count;
                        vertices.Add(vertex);

                        // Add intersection point to our list
                        pointIntersections.Add(new PointIntersection(vertexIndex, intersectingPlanes));

                    SkipIntersection:
                        ;
                    }
                }
            }

            var foundPlanes = new short[2];
            // Find all our intersection edges which are formed by a pair of planes
            // (this could probably be done inside the previous loop)
            for (int i = 0; i < pointIntersections.Count; i++)
            {
                var pointIntersectionA = pointIntersections[i];
                for (int j = i + 1; j < pointIntersections.Count; j++)
                {
                    var pointIntersectionB = pointIntersections[j];
                    var planesIndicesA = pointIntersectionA.PlaneIndices;
                    var planesIndicesB = pointIntersectionB.PlaneIndices;

                    short foundPlaneIndex = 0;
                    foreach (var currentPlaneIndex in planesIndicesA)
                    {
                        if (!planesIndicesB.Contains(currentPlaneIndex))
                            continue;

                        foundPlanes[foundPlaneIndex] = currentPlaneIndex;
                        foundPlaneIndex++;

                        if (foundPlaneIndex == 2)
                            break;
                    }

                    // If foundPlaneIndex is 0 or 1 then either this combination does not exist,
                    // or only goes trough one point
                    if (foundPlaneIndex < 2)
                        continue;

                    // Create our found intersection edge
                    var halfEdgeA = new HalfEdge();
                    var halfEdgeAIndex = (short)edges.Count;
                    edges.Add(halfEdgeA);

                    var halfEdgeB = new HalfEdge();
                    var halfEdgeBIndex = (short)edges.Count;
                    edges.Add(halfEdgeB);

                    halfEdgeA.TwinIndex = halfEdgeBIndex;
                    halfEdgeB.TwinIndex = halfEdgeAIndex;

                    halfEdgeA.VertexIndex = pointIntersectionA.VertexIndex;
                    halfEdgeB.VertexIndex = pointIntersectionB.VertexIndex;

                    // Add it to our points
                    pointIntersectionA.Edges.Add(new EdgeIntersection(
                                                        halfEdgeA,
                                                        foundPlanes[0],
                                                        foundPlanes[1]));
                    pointIntersectionB.Edges.Add(new EdgeIntersection(
                                                        halfEdgeB,
                                                        foundPlanes[0],
                                                        foundPlanes[1]));
                }
            }

            var polygons = new List<Polygon>();
            for (short i = 0; i < (short)planes.Length; i++)
            {
                var polygon = new Polygon();
                polygon.PlaneIndex = i;
                polygons.Add(polygon);
            }

            var bounds = new AABB();
            var direction = new Vector3();
            for (int i = pointIntersections.Count - 1; i >= 0; i--)
            {
                var pointIntersection = pointIntersections[i];
                var pointEdges = pointIntersection.Edges;

                // Make sure that we have at least 2 edges ...
                // This may happen when a plane only intersects at a single edge.
                if (pointEdges.Count <= 2)
                {
                    pointIntersections.RemoveAt(i);
                    continue;
                }

                var vertexIndex = pointIntersection.VertexIndex;
                var vertex = vertices[vertexIndex];

                for (int j = 0; j < pointEdges.Count - 1; j++)
                {
                    var edge1 = pointEdges[j];
                    for (int k = j + 1; k < pointEdges.Count; k++)
                    {
                        var edge2 = pointEdges[k];

                        int planeIndex1 = -1;
                        int planeIndex2 = -1;

                        // Determine if and which of our 2 planes are identical
                        if (edge1.PlaneIndices[0] == edge2.PlaneIndices[0]) { planeIndex1 = 0; planeIndex2 = 0; }
                        else
                            if (edge1.PlaneIndices[0] == edge2.PlaneIndices[1]) { planeIndex1 = 0; planeIndex2 = 1; }
                            else
                                if (edge1.PlaneIndices[1] == edge2.PlaneIndices[0]) { planeIndex1 = 1; planeIndex2 = 0; }
                                else
                                    if (edge1.PlaneIndices[1] == edge2.PlaneIndices[1]) { planeIndex1 = 1; planeIndex2 = 1; }
                                    else
                                        continue;

                        HalfEdge ingoing;
                        HalfEdge outgoing;
                        short outgoingIndex;

                        var shared_plane = planes[edge1.PlaneIndices[planeIndex1]];
                        var edge1_plane = planes[edge1.PlaneIndices[1 - planeIndex1]];
                        var edge2_plane = planes[edge2.PlaneIndices[1 - planeIndex2]];

                        direction = Vector3.CrossProduct(shared_plane.Normal, edge1_plane.Normal);

                        // Determine the orientation of our two edges to determine
                        // which edge is in-going, and which one is out-going
                        if (Vector3.DotProduct(direction, edge2_plane.Normal) < 0)
                        {
                            ingoing = edge2.Edge;
                            outgoingIndex = edge1.Edge.TwinIndex;
                            outgoing = edges[outgoingIndex];
                        }
                        else
                        {
                            ingoing = edge1.Edge;
                            outgoingIndex = edge2.Edge.TwinIndex;
                            outgoing = edges[outgoingIndex];
                        }

                        // Link the out-going half-edge to the in-going half-edge
                        ingoing.NextIndex = outgoingIndex;

                        // Add reference to polygon to half-edge, and make sure our
                        // polygon has a reference to a half-edge
                        // Since a half-edge, in this case, serves as a circular
                        // linked list this just works.
                        var polygonIndex = edge1.PlaneIndices[planeIndex1];

                        ingoing.PolygonIndex = polygonIndex;
                        outgoing.PolygonIndex = polygonIndex;

                        var polygon = polygons[polygonIndex];
                        polygon.FirstIndex = outgoingIndex;
                        polygon.Bounds.Add(vertex);
                    }
                }

                // Add the intersection point to the area of our bounding box
                bounds.Add(vertex);
            }

            return new CSGMesh(planes, polygons, edges, vertices, bounds);
        }
        public static bool GenerateControlMeshFromVertices(ShapePolygon shape2DPolygon,
                                                           Matrix4x4 localToWorld,
                                                           Vector3 direction,
                                                           float height,
                                                           TexGen capTexgen,
                                                           bool?smooth,
                                                           bool singleSurfaceEnds,                                                                                 //Plane buildPlane,
                                                           out ControlMesh controlMesh,
                                                           out Shape shape)
        {
            if (shape2DPolygon == null)
            {
                controlMesh = null;
                shape       = null;
                return(false);
            }

            var vertices = shape2DPolygon.Vertices;

            if (vertices.Length < 3)
            {
                controlMesh = null;
                shape       = null;
                return(false);
            }
            if (height == 0.0f)
            {
                controlMesh = null;
                shape       = null;
                return(false);
            }

            Vector3 from;
            Vector3 to;

            if (height > 0)
            {
                @from = direction * height;                // buildPlane.normal * height;
                to    = MathConstants.zeroVector3;
            }
            else
            {
                @from = MathConstants.zeroVector3;
                to    = direction * height;               //buildPlane.normal * height;
            }

            var count           = vertices.Length;
            var doubleCount     = (count * 2);
            var extraPoints     = 0;
            var extraEdges      = 0;
            var endsPolygons    = 2;
            var startEdgeOffset = doubleCount;

            if (!singleSurfaceEnds)
            {
                extraPoints      = 2;
                extraEdges       = (4 * count);
                endsPolygons     = doubleCount;
                startEdgeOffset += extraEdges;
            }


            var dstPoints   = new Vector3 [doubleCount + extraPoints];
            var dstEdges    = new HalfEdge[(count * 6) + extraEdges];
            var dstPolygons = new Polygon [count + endsPolygons];

            var center1 = MathConstants.zeroVector3;
            var center2 = MathConstants.zeroVector3;


            for (int i = 0; i < count; i++)
            {
                var point1 = vertices[i];
                var point2 = vertices[(count + i - 1) % count];

                point1 += @from;
                point2 += to;

                // swap y/z to solve texgen issues
                dstPoints[i].x = point1.x;
                dstPoints[i].y = point1.y;
                dstPoints[i].z = point1.z;

                center1 += dstPoints[i];

                dstEdges [i].VertexIndex = (short)i;
                dstEdges [i].HardEdge    = true;

                // swap y/z to solve texgen issues
                dstPoints[i + count].x = point2.x;
                dstPoints[i + count].y = point2.y;
                dstPoints[i + count].z = point2.z;
                center2 += dstPoints[i + count];

                dstEdges [i + count].VertexIndex = (short)(i + count);
                dstEdges [i + count].HardEdge    = true;
            }

            if (!singleSurfaceEnds)
            {
                dstPoints[doubleCount]     = center1 / count;
                dstPoints[doubleCount + 1] = center2 / count;

                int   edge_offset   = doubleCount;
                short polygon_index = (short)count;

                // 'top'
                for (int i = 0, j = count - 1; i < count; j = i, i++)
                {
                    var jm = (j) % count;
                    var im = (i) % count;

                    var edgeOut0 = edge_offset + (jm * 2) + 1;
                    var edgeIn0  = edge_offset + (im * 2) + 0;
                    var edgeOut1 = edge_offset + (im * 2) + 1;

                    dstEdges[edgeIn0].VertexIndex = (short)(doubleCount);
                    dstEdges[edgeIn0].HardEdge    = true;
                    dstEdges[edgeIn0].TwinIndex   = edgeOut1;

                    dstEdges[edgeOut1].VertexIndex = (short)im;
                    dstEdges[edgeOut1].HardEdge    = true;
                    dstEdges[edgeOut1].TwinIndex   = edgeIn0;

                    dstEdges[im].PolygonIndex       = polygon_index;
                    dstEdges[edgeIn0].PolygonIndex  = polygon_index;
                    dstEdges[edgeOut0].PolygonIndex = polygon_index;

                    dstPolygons[polygon_index] = new Polygon(new int[] { im, edgeIn0, edgeOut0 }, polygon_index);
                    polygon_index++;
                }

                edge_offset = doubleCount * 2;
                // 'bottom'
                for (int i = 0, j = count - 1; j >= 0; i = j, j--)
                {
                    var jm = (count + count - j) % count;
                    var im = (count + count - i) % count;

                    var edgeOut0 = edge_offset + (jm * 2) + 1;
                    var edgeIn0  = edge_offset + (im * 2) + 0;
                    var edgeOut1 = edge_offset + (im * 2) + 1;

                    dstEdges[edgeIn0].VertexIndex = (short)(doubleCount + 1);
                    dstEdges[edgeIn0].HardEdge    = true;
                    dstEdges[edgeIn0].TwinIndex   = edgeOut1;

                    dstEdges[edgeOut1].VertexIndex = (short)(im + count);
                    dstEdges[edgeOut1].HardEdge    = true;
                    dstEdges[edgeOut1].TwinIndex   = edgeIn0;

                    dstEdges[im + count].PolygonIndex = polygon_index;
                    dstEdges[edgeIn0].PolygonIndex    = polygon_index;
                    dstEdges[edgeOut0].PolygonIndex   = polygon_index;

                    dstPolygons[polygon_index] = new Polygon(new int[] { im + count, edgeIn0, edgeOut0 }, polygon_index);
                    polygon_index++;
                }
            }
            else
            {
                var polygon0Edges = new int[count];
                var polygon1Edges = new int[count];
                for (var i = 0; i < count; i++)
                {
                    dstEdges [i].PolygonIndex         = (short)(count + 0);
                    dstEdges [i + count].PolygonIndex = (short)(count + 1);
                    polygon0Edges[i] = i;
                    polygon1Edges[count - (i + 1)] = i + count;
                }
                dstPolygons[count + 0] = new Polygon(polygon0Edges, count + 0);
                dstPolygons[count + 1] = new Polygon(polygon1Edges, count + 1);
            }


            for (int v0 = count - 1, v1 = 0; v1 < count; v0 = v1, v1++)
            {
                var polygonIndex = (short)(v1);

                var nextOffset = startEdgeOffset + (((v1 + 1) % count) * 4);
                var currOffset = startEdgeOffset + (((v1)) * 4);
                var prevOffset = startEdgeOffset + (((v1 + count - 1) % count) * 4);

                var nextTwin = nextOffset + 1;
                var prevTwin = prevOffset + 3;

                dstEdges[v1].TwinIndex         = currOffset + 0;
                dstEdges[v1 + count].TwinIndex = currOffset + 2;

                dstEdges[currOffset + 0].PolygonIndex = polygonIndex;
                dstEdges[currOffset + 1].PolygonIndex = polygonIndex;
                dstEdges[currOffset + 2].PolygonIndex = polygonIndex;
                dstEdges[currOffset + 3].PolygonIndex = polygonIndex;

                dstEdges[currOffset + 0].TwinIndex = (v1);
                dstEdges[currOffset + 1].TwinIndex = prevTwin;
                dstEdges[currOffset + 2].TwinIndex = (v1 + count);
                dstEdges[currOffset + 3].TwinIndex = nextTwin;

                dstEdges[currOffset + 0].VertexIndex = (short)(v0);
                dstEdges[currOffset + 1].VertexIndex = (short)(v1 + count);
                dstEdges[currOffset + 2].VertexIndex = (short)(((v1 + 1) % count) + count);
                dstEdges[currOffset + 3].VertexIndex = (short)(v1);

                dstEdges[currOffset + 0].HardEdge = true;
                dstEdges[currOffset + 1].HardEdge = true;
                dstEdges[currOffset + 2].HardEdge = true;
                dstEdges[currOffset + 3].HardEdge = true;

                dstPolygons[polygonIndex] = new Polygon(new [] { currOffset + 0,
                                                                 currOffset + 1,
                                                                 currOffset + 2,
                                                                 currOffset + 3 }, polygonIndex);
            }

            for (int i = 0; i < dstPoints.Length; i++)
            {
                dstPoints[i] = localToWorld.MultiplyPoint(dstPoints[i]);
            }

            controlMesh = new ControlMesh
            {
                Vertices = dstPoints,
                Edges    = dstEdges,
                Polygons = dstPolygons
            };
            controlMesh.SetDirty();

            shape = new Shape(dstPolygons.Length);


            var smoothinggroup = (smooth.HasValue && smooth.Value) ? SurfaceUtility.FindUnusedSmoothingGroupIndex() : 0;


            var containedMaterialCount = 0;

            if (shape2DPolygon.EdgeTexgens != null /* &&
                                                    * shape2DPolygon.edgeTexgenFlags != null*/)
            {
                containedMaterialCount = shape2DPolygon.EdgeTexgens.Length;
            }

            if (capTexgen.RenderMaterial == null)
            {
                capTexgen.RenderMaterial = CSGSettings.DefaultMaterial;
            }

            for (var i = 0; i < dstPolygons.Length; i++)
            {
                if (i < containedMaterialCount)
                {
                    //shape.TexGenFlags[i] = shape2DPolygon.edgeTexgenFlags[i];
                    shape.TexGens    [i]             = shape2DPolygon.EdgeTexgens[i];
                    shape.Surfaces   [i].TexGenIndex = i;
                }
                else
                {
                    shape.TexGens[i] = capTexgen;
                    //shape.TexGenFlags[i]			= TexGenFlags.None;
                    shape.Surfaces[i].TexGenIndex = i;
                }
                if (smooth.HasValue)
                {
                    if (i < count)
                    {
                        shape.TexGens[i].SmoothingGroup = smoothinggroup;
                    }
                    else
                    {
                        shape.TexGens[i].SmoothingGroup = 0;
                    }
                }
            }

            for (var s = 0; s < dstPolygons.Length; s++)
            {
                var normal = shape.Surfaces[s].Plane.normal;
                shape.Surfaces[s].Plane = GeometryUtility.CalcPolygonPlane(controlMesh, (short)s);
                Vector3 tangent, binormal;
                GeometryUtility.CalculateTangents(normal, out tangent, out binormal);
                //var tangent		= Vector3.Cross(GeometryUtility.CalculateTangent(normal), normal).normalized;
                //var binormal	= Vector3.Cross(normal, tangent);
                shape.Surfaces[s].Tangent     = tangent;
                shape.Surfaces[s].BiNormal    = binormal;
                shape.Surfaces[s].TexGenIndex = s;
            }

            controlMesh.IsValid = ControlMeshUtility.Validate(controlMesh, shape);
            if (controlMesh.IsValid)
            {
                return(true);
            }

            controlMesh = null;
            shape       = null;
            return(false);
        }