public static RenderGeometry CreateCubeStarGeometry(float size, float extrusion = 1, float cutTop = 0)
    {
        float extrusionScale = Mathf.Sqrt(2f) / 2;

        return(CreateCubeGeometryInternal(
                   size * Vector3.one, dim => SurfaceComponentGeometries.CreateExtrudedPolygonCapGeometry(1, extrusion * extrusionScale, 4, 1, cutTop, dim, RenderGeometry.FaceType.Polygonal, true)));
    }
Пример #2
0
    public static SurfaceComponentGeometry CreateDiamondCenterOctaSplitSquareGeometry(
        float sizeX, float sizeZ, int segmentX, int segmentZ, float diamondRatio = 0.6f, int surfaceGroup = 0, RenderGeometry.FaceType faceType = RenderGeometry.FaceType.Polygonal)
    {
        SurfaceComponentGeometry planeGeometry = SurfaceComponentGeometries.CreatePlaneGeometry(sizeX, sizeZ, segmentX, segmentZ);
        List <Vertex>            corners       = planeGeometry.corners;

        var structure    = new StructureGeometry(planeGeometry);
        var edgesToMerge = new List <Halfedge>();

        structure.faces.ForEach(f => {
            var component = CreateSingleDiamondCenterOctaSplitSquareGeometry(1, 1, diamondRatio, surfaceGroup, faceType);
            edgesToMerge.AddRange(component.boundaries.SelectMany(b => b).Select(e => e.opposite));
            structure.SetFaceComponent(f, component, true);
        });
        var geometry = new SurfaceComponentGeometry(structure.Build());

        foreach (Halfedge edge in edgesToMerge)
        {
            if (edge.index >= 0 && !edge.opposite.isBoundary)
            {
                geometry.MergeFaces(edge);
            }
        }
        geometry.DefineBoundaries(corners.Select(structure.GetBuiltVertex).ToArray());

        return(geometry);
    }
    public static RenderGeometry CreateDodecahedronStarGeometry(float size, float extrusion, float cutTop)
    {
        int   currentGroup   = 0;
        float extrusionScale = Mathf.Sqrt(3) * (Mathf.Sqrt(5) + 1) / 4;

        return(CreateDodecahedronGeometryInternal(
                   size, () => SurfaceComponentGeometries.CreateExtrudedPolygonCapGeometry(1, extrusion * extrusionScale, 5, 1, cutTop, currentGroup++, RenderGeometry.FaceType.Polygonal, true)));
    }
    public static RenderGeometry CreateSphereGeometry(float radius, int segmentP, int segmentH, bool smoothH, bool smoothV, float cutTop = 0, float cutBottom = 0)
    {
        if (cutTop + cutBottom > 1)
        {
            return(new RenderGeometry());
        }

        RenderGeometry.FaceType  faceType = GetFaceType(smoothH, smoothV);
        StructureGeometry        structure = new StructureGeometry();
        SurfaceComponentGeometry upperPart, lowerPart, middlePart;

        if (cutTop != 0)
        {
            upperPart = SurfaceComponentGeometries.CreateRegularPolygonGeometry(radius * Mathf.Sqrt(4 * cutTop * (1 - cutTop)), segmentP, 2);
            upperPart.ApplyOffset(radius * (1 - 2 * cutTop) * Vector3.up);
        }
        else
        {
            float angle = cutBottom != 0 ? Mathf.Acos(-1 + cutBottom * 2) : Mathf.PI * (segmentH / 2) / segmentH;
            upperPart = SurfaceComponentGeometries.CreateSphereCapGeometry(radius, segmentP, cutBottom != 0 ? segmentH : segmentH / 2, 2 * angle, 0, 1, faceType);
        }
        if (cutBottom != 0)
        {
            lowerPart = SurfaceComponentGeometries.CreateRegularPolygonGeometry(radius * Mathf.Sqrt(4 * cutBottom * (1 - cutBottom)), segmentP, 2);
            lowerPart.ApplyOffset(radius * (1 - 2 * cutBottom) * Vector3.up);
            lowerPart.ApplyRotation(Quaternion.AngleAxis(180, Vector3.right));
        }
        else
        {
            float angle = cutTop != 0 ? Mathf.Acos(-1 + cutTop * 2) : Mathf.PI * ((segmentH + 1) / 2) / segmentH;
            lowerPart = SurfaceComponentGeometries.CreateSphereCapGeometry(radius, segmentP, cutTop != 0 ? segmentH : (segmentH + 1) / 2, 2 * angle, 0, 1, faceType);
            lowerPart.ApplyRotation(Quaternion.AngleAxis(180, Vector3.right));
        }
        if (cutTop != 0 && cutBottom != 0)
        {
            float angle1 = Mathf.Acos(1 - cutTop * 2);
            float angle2 = Mathf.Acos(-1 + cutBottom * 2);
            middlePart = SurfaceComponentGeometries.CreateSphereSideGeometry(radius, angle1, angle2, segmentP, segmentH, 0, 1, faceType);

            Vertex cornerUp   = structure.CreateVertex();
            Vertex cornerDown = structure.CreateVertex();
            structure.CreateFace(middlePart, false, cornerUp, cornerUp, cornerDown, cornerDown);
            structure.CreateFace(upperPart, false, cornerUp);
            structure.CreateFace(lowerPart, false, cornerDown);
        }
        else
        {
            Vertex corner = structure.CreateVertex();
            structure.CreateFace(upperPart, false, corner);
            structure.CreateFace(lowerPart, false, corner);
        }
        return(structure.Build());
    }
Пример #5
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    public static SurfaceComponentGeometry CreateSplitTriangleGeometry(
        float sizeBase, float sizeHeight, float offsetTop, int segment, int surfaceGroup = 0, RenderGeometry.FaceType faceType = RenderGeometry.FaceType.Polygonal)
    {
        SurfaceComponentGeometry triangleGeometry = SurfaceComponentGeometries.CreateTriangleGeometry(sizeBase, sizeHeight, offsetTop, segment, false);
        List <Vertex>            corners          = triangleGeometry.corners;

        var structure = new StructureGeometry(triangleGeometry);

        structure.faces.ForEach(f => structure.SetFaceComponent(f, CreateSingleSplitTriangleGeometry(1, 1, 0, surfaceGroup, faceType), true));
        var geometry = new SurfaceComponentGeometry(structure.Build());

        geometry.DefineBoundaries(corners.Select(structure.GetBuiltVertex).ToArray());

        return(geometry);
    }
Пример #6
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    public static SurfaceComponentGeometry CreateDiamondCenterCrossSplitSquareGeometry(
        float sizeX, float sizeZ, int segmentX, int segmentZ, float diamondRatio = 0.6f, int surfaceGroup = 0, RenderGeometry.FaceType faceType = RenderGeometry.FaceType.Polygonal)
    {
        SurfaceComponentGeometry planeGeometry = SurfaceComponentGeometries.CreatePlaneGeometry(sizeX, sizeZ, segmentX, segmentZ);
        List <Vertex>            corners       = planeGeometry.corners;

        var structure = new StructureGeometry(planeGeometry);

        structure.faces.ForEach(f => structure.SetFaceComponent(f, CreateSingleDiamondCenterCrossSplitSquareGeometry(1, 1, diamondRatio, surfaceGroup, faceType), true));
        var geometry = new SurfaceComponentGeometry(structure.Build());

        geometry.DefineBoundaries(corners.Select(structure.GetBuiltVertex).ToArray());

        return(geometry);
    }
Пример #7
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    public static SurfaceComponentGeometry CreateTrianglesCombinedRegularPolygonGeometry(float radius, int segmentP, Func <SurfaceComponentGeometry> triangleSurfaceComponentProvider)
    {
        SurfaceComponentGeometry polygonGeometry = SurfaceComponentGeometries.CreateFanCapGeometry(radius, segmentP, 1);

        polygonGeometry.SplitBoundaries();
        List <Vertex> corners = polygonGeometry.corners;

        var structure = new StructureGeometry(polygonGeometry);

        structure.faces.ForEach(f => structure.SetFaceComponent(f, triangleSurfaceComponentProvider(), true));
        var geometry = new SurfaceComponentGeometry(structure.Build());

        geometry.DefineBoundaries(corners.Select(structure.GetBuiltVertex).ToArray());

        return(geometry);
    }
    public static RenderGeometry CreateConeGeometry(float radius, float height, int segmentP, int segmentH, bool smoothH, bool smoothV, float cutTop = 0, float cutAngle = 0)
    {
        if (cutTop == 0)
        {
            StructureGeometry       structure = new StructureGeometry();
            RenderGeometry.FaceType faceType  = GetFaceType(smoothH, smoothV);

            SurfaceComponentGeometry coneCap = SurfaceComponentGeometries.CreateConeCapGeometry(radius, height, segmentP, segmentH, cutAngle, 1, faceType);
            if (cutAngle == 0)
            {
                SurfaceComponentGeometry bottom = SurfaceComponentGeometries.CreateRegularPolygonGeometry(radius, segmentP, 2);
                bottom.ApplyRotation(Quaternion.AngleAxis(180, Vector3.right));

                Vertex corner = structure.CreateVertex();
                structure.CreateFace(coneCap, false, corner);
                structure.CreateFace(bottom, false, corner);
            }
            else
            {
                SurfaceComponentGeometry bottom = SurfaceComponentGeometries.CreateFanCapGeometry(radius, segmentP, 1, cutAngle, 2);
                SurfaceComponentGeometry wall1  = SurfaceComponentGeometries.CreateTriangleGeometry(1, 1, 0, segmentH, true, 3);
                SurfaceComponentGeometry wall2  = SurfaceComponentGeometries.CreateTriangleGeometry(1, 1, 0, segmentH, true, 4);

                Vertex cornerUp    = structure.CreateVertex(new Vector3(0, height, 0));
                Vertex cornerDownC = structure.CreateVertex(Vector3.zero);
                Vertex cornerDown1 = structure.CreateVertex(new Vector3(radius * Mathf.Cos(cutAngle), 0, -radius * Mathf.Sin(cutAngle)));
                Vertex cornerDown2 = structure.CreateVertex(new Vector3(radius, 0, 0));

                structure.CreateFace(coneCap, true, cornerDown1, cornerDown2, cornerUp);
                structure.CreateFace(bottom, true, cornerDown2, cornerDown1, cornerDownC);
                structure.CreateFace(wall1, true, cornerDown1, cornerUp, cornerDownC);
                structure.CreateFace(wall2, true, cornerDownC, cornerUp, cornerDown2);
            }
            return(structure.Build());
        }
        else
        {
            RenderGeometry geometry = CreateCylinderGeometry(radius, height, segmentP, segmentH, smoothH, smoothV, cutAngle);
            geometry.ApplyOffset(Vector3.up * (height / 2));

            float     shrinkCoeff = (1 - cutTop) / height;
            SpaceWarp warp        = new SpaceWarp($"x*(1-y*{shrinkCoeff})", "y", $"z*(1-y*{shrinkCoeff})");
            geometry.ApplySpaceWarp(warp);
            return(geometry);
        }
    }
Пример #9
0
    public static SurfaceComponentGeometry CreatePantagonSquareGeometry(
        float sizeX, float sizeZ, int segmentX, int segmentZ, float pantagonRatio = 0.3f, int surfaceGroup = 0, RenderGeometry.FaceType faceType = RenderGeometry.FaceType.Polygonal)
    {
        SurfaceComponentGeometry planeGeometry = SurfaceComponentGeometries.CreatePlaneGeometry(sizeX, sizeZ, segmentX * 2, segmentZ * 2, surfaceGroup, faceType);
        var originalVertexList = new List <Vertex>(planeGeometry.vertices);

        Vertex corner(int x, int z) => originalVertexList[x * (segmentZ * 2 + 1) + z];

        float deltaX = sizeX / (segmentX * 2) * pantagonRatio;
        float deltaZ = sizeZ / (segmentZ * 2) * pantagonRatio;

        for (int x = 1; x < segmentX * 2; x++)
        {
            for (int z = 1; z < segmentZ * 2; z++)
            {
                if (x % 2 == 0 && z % 2 == 1)
                {
                    corner(x, z).p += deltaX * ((x + z) % 4 == 3 ? Vector3.left : Vector3.right);
                }
                else if (x % 2 == 1 && z % 2 == 0)
                {
                    corner(x, z).p += deltaZ * ((x + z) % 4 == 3 ? Vector3.forward : Vector3.back);
                }
            }
        }
        for (int x = 0; x < segmentX; x++)
        {
            for (int z = 0; z < segmentZ; z++)
            {
                if ((x + z) % 2 == 0)
                {
                    planeGeometry.MergeFaces(planeGeometry.FindHalfedge(corner(x * 2 + 1, z * 2 + 1), corner(x * 2 + 1, z * 2)));
                    planeGeometry.MergeFaces(planeGeometry.FindHalfedge(corner(x * 2 + 1, z * 2 + 1), corner(x * 2 + 1, z * 2 + 2)));
                }
                else
                {
                    planeGeometry.MergeFaces(planeGeometry.FindHalfedge(corner(x * 2 + 1, z * 2 + 1), corner(x * 2, z * 2 + 1)));
                    planeGeometry.MergeFaces(planeGeometry.FindHalfedge(corner(x * 2 + 1, z * 2 + 1), corner(x * 2 + 2, z * 2 + 1)));
                }
            }
        }
        return(planeGeometry);
    }
    public static RenderGeometry CreateSpringGeometry(float ringRadius, float barRadius, float heightPerCycle, int segmentPerCycle, int segmentBar, bool smoothH, bool smoothV, float angle = 0, float deltaAngle = 0)
    {
        StructureGeometry structure = new StructureGeometry();

        RenderGeometry.FaceType faceType = GetFaceType(smoothH, smoothV);
        float heightPerRad = heightPerCycle / (2 * Mathf.PI);
        float slope        = heightPerRad / ringRadius;
        float scaleH       = Mathf.Sqrt(1 + slope * slope);
        int   segmentRing  = Mathf.CeilToInt(segmentPerCycle * angle / (2 * Mathf.PI) - 1e-6f);

        SurfaceComponentGeometry face = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, segmentBar, segmentRing, 1, faceType);

        var warp = new SpaceWarp(
            $" a1=(z+0.5)*{angle}",
            $" a2={deltaAngle}-x*(2*PI)",
            $" r={ringRadius}+{barRadius}*cos(a2)",
            $" X=r*cos(a1)",
            $" Y={scaleH}*{barRadius}*sin(a2)+a1*{heightPerRad}",
            $" Z=r*sin(a1)"
            );

        face.ApplySpaceWarp(warp);

        SurfaceComponentGeometry cap1 = SurfaceComponentGeometries.CreateRegularPolygonGeometry(barRadius, segmentBar, 2);
        SurfaceComponentGeometry cap2 = SurfaceComponentGeometries.CreateRegularPolygonGeometry(barRadius, segmentBar, 2);

        cap1.ApplyLinearTransform(
            Matrix4x4.Translate(Vector3.right * ringRadius) *
            Matrix4x4.Scale(new Vector3(1, scaleH, 1)) *
            Matrix4x4.Rotate(Quaternion.LookRotation(Vector3.down, Vector3.back) * Quaternion.AngleAxis(-deltaAngle * Mathf.Rad2Deg, Vector3.up)));
        cap2.ApplyLinearTransform(
            Matrix4x4.Translate(new Vector3(ringRadius * Mathf.Cos(angle), heightPerRad * angle, ringRadius * Mathf.Sin(angle))) *
            Matrix4x4.Scale(new Vector3(1, scaleH, 1)) *
            Matrix4x4.Rotate(Quaternion.LookRotation(Vector3.up, Quaternion.AngleAxis(angle * Mathf.Rad2Deg, Vector3.down) * Vector3.forward) * Quaternion.AngleAxis(deltaAngle * Mathf.Rad2Deg, Vector3.up)));

        Vertex corner1 = structure.CreateVertex();
        Vertex corner2 = structure.CreateVertex();

        structure.CreateFace(face, false, corner1, corner2, corner2, corner1);
        structure.CreateFace(cap1, false, corner1);
        structure.CreateFace(cap2, false, corner2);
        return(structure.Build());
    }
Пример #11
0
    public static SurfaceComponentGeometry CreateXSplitSquareGeometry(
        float sizeX, float sizeZ, int segmentX, int segmentZ, float spikeHeight = 0, int surfaceGroup = 0, RenderGeometry.FaceType faceType = RenderGeometry.FaceType.Polygonal)
    {
        var           planeGeometry = SurfaceComponentGeometries.CreatePlaneGeometry(sizeX, sizeZ, segmentX, segmentZ);
        List <Vertex> corners       = planeGeometry.corners;

        var structure  = new StructureGeometry(planeGeometry);
        var coneHeight = spikeHeight / (sizeZ / segmentZ) * Mathf.Sqrt(2);

        structure.faces.ForEach(f => {
            var component = SurfaceComponentGeometries.CreateConeCapGeometry(1, coneHeight, 4, 1, 0, surfaceGroup, faceType);
            component.SplitBoundaries();
            structure.SetFaceComponent(f, component, true);
        });
        var geometry = new SurfaceComponentGeometry(structure.Build());

        geometry.DefineBoundaries(corners.Select(structure.GetBuiltVertex).ToArray());

        return(geometry);
    }
    public static RenderGeometry CreateTorusGeometry(float ringRadius, float barRadius, int segmentRing, int segmentBar, bool smoothH, bool smoothV, float cutAngle = 0, float deltaAngle = 0)
    {
        StructureGeometry structure = new StructureGeometry();

        RenderGeometry.FaceType faceType = GetFaceType(smoothH, smoothV);

        SurfaceComponentGeometry face = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, segmentBar, segmentRing, 1, faceType);

        var warp = new SpaceWarp(
            $" a1=(z+0.5)*(2*PI-{cutAngle})",
            $" a2={deltaAngle}-x*(2*PI)",
            $" r={ringRadius}+{barRadius}*cos(a2)",
            $" X=r*cos(a1)",
            $" Y={barRadius}*sin(a2)",
            $" Z=r*sin(a1)"
            );

        face.ApplySpaceWarp(warp);

        if (cutAngle == 0)
        {
            Vertex corner = structure.CreateVertex();
            structure.CreateFace(face, false, corner, corner, corner, corner);
        }
        else
        {
            SurfaceComponentGeometry cap1 = SurfaceComponentGeometries.CreateRegularPolygonGeometry(barRadius, segmentBar, 2);
            SurfaceComponentGeometry cap2 = SurfaceComponentGeometries.CreateRegularPolygonGeometry(barRadius, segmentBar, 2);
            cap1.ApplyRotation(Quaternion.LookRotation(Vector3.down, Vector3.back) * Quaternion.AngleAxis(-deltaAngle, Vector3.up));
            cap1.ApplyOffset(Vector3.right * ringRadius);
            cap2.ApplyRotation(Quaternion.LookRotation(Vector3.up, Quaternion.AngleAxis(cutAngle * Mathf.Rad2Deg, Vector3.up) * Vector3.forward) * Quaternion.AngleAxis(deltaAngle * Mathf.Rad2Deg, Vector3.up));
            cap2.ApplyOffset(new Vector3(ringRadius * Mathf.Cos(cutAngle), 0, -ringRadius * Mathf.Sin(cutAngle)));

            Vertex corner1 = structure.CreateVertex();
            Vertex corner2 = structure.CreateVertex();
            structure.CreateFace(face, false, corner1, corner2, corner2, corner1);
            structure.CreateFace(cap1, false, corner1);
            structure.CreateFace(cap2, false, corner2);
        }
        return(structure.Build());
    }
    public static RenderGeometry CreateCapsuleGeometry(float radius, float height, int segmentP, int segmentH1, int segmentH2, bool smoothH, bool smoothV)
    {
        StructureGeometry structure = new StructureGeometry();

        RenderGeometry.FaceType faceType = GetFaceType(smoothH, smoothV);

        SurfaceComponentGeometry side = SurfaceComponentGeometries.CreateCylinderSideGeometry(radius, height, segmentP, segmentH1, faceType: faceType);

        SurfaceComponentGeometry upperCap = SurfaceComponentGeometries.CreateSphereCapGeometry(radius, segmentP, segmentH2, faceType: faceType);
        SurfaceComponentGeometry lowerCap = SurfaceComponentGeometries.CreateSphereCapGeometry(radius, segmentP, segmentH2, faceType: faceType);

        lowerCap.ApplyRotation(Quaternion.AngleAxis(180, Vector3.right));

        Vertex cornerUp   = structure.CreateVertex(new Vector3(radius, height / 2, 0));
        Vertex cornerDown = structure.CreateVertex(new Vector3(radius, -height / 2, 0));

        structure.CreateFace(side, false, cornerUp, cornerUp, cornerDown, cornerDown);
        structure.CreateFace(upperCap, true, cornerUp);
        structure.CreateFace(lowerCap, true, cornerDown);
        return(structure.Build());
    }
Пример #14
0
    private static void CreateStraightPlatformPart(
        StructureGeometry structure,
        Vertex cornerTopLeft1, Vertex cornerTopLeft2, Vertex cornerTopRight1, Vertex cornerTopRight2,
        Vertex cornerBottomLeft1, Vertex cornerBottomLeft2, Vertex cornerBottomRight1, Vertex cornerBottomRight2,
        bool addLeftSide, bool addRightSide, int segmentLength, RenderGeometry.FaceType sideFaceType)
    {
        SurfaceComponentGeometry topFace    = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, segmentLength, 0, sideFaceType);
        SurfaceComponentGeometry bottomFace = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, segmentLength, 1, sideFaceType);

        if (cornerTopLeft1 == cornerBottomLeft1)
        {
            // Copy vertices since it is a flat face.
            Vertex cornerLeft1  = structure.CreateVertex(cornerBottomLeft1.p);
            Vertex cornerLeft2  = structure.CreateVertex(cornerBottomLeft2.p);
            Vertex cornerRight1 = structure.CreateVertex(cornerBottomRight1.p);
            Vertex cornerRight2 = structure.CreateVertex(cornerBottomRight2.p);
            structure.CreateFace(topFace, true, cornerLeft1, cornerLeft2, cornerRight2, cornerRight1);
            structure.CreateFace(bottomFace, true, cornerRight1, cornerRight2, cornerLeft2, cornerLeft1);
        }
        else
        {
            SurfaceComponentGeometry backFace  = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, 1, 4, RenderGeometry.FaceType.Polygonal);
            SurfaceComponentGeometry frontFace = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, 1, 5, RenderGeometry.FaceType.Polygonal);
            structure.CreateFace(topFace, true, cornerTopLeft1, cornerTopLeft2, cornerTopRight2, cornerTopRight1);
            structure.CreateFace(bottomFace, true, cornerBottomRight1, cornerBottomRight2, cornerBottomLeft2, cornerBottomLeft1);
            structure.CreateFace(backFace, true, cornerBottomLeft1, cornerTopLeft1, cornerTopRight1, cornerBottomRight1);
            structure.CreateFace(frontFace, true, cornerBottomRight2, cornerTopRight2, cornerTopLeft2, cornerBottomLeft2);

            if (addLeftSide)
            {
                SurfaceComponentGeometry leftFace = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, segmentLength, 2, sideFaceType);
                structure.CreateFace(leftFace, true, cornerBottomLeft1, cornerBottomLeft2, cornerTopLeft2, cornerTopLeft1);
            }
            if (addRightSide)
            {
                SurfaceComponentGeometry rightFace = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, segmentLength, 3, sideFaceType);
                structure.CreateFace(rightFace, true, cornerTopRight1, cornerTopRight2, cornerBottomRight2, cornerBottomRight1);
            }
        }
    }
Пример #15
0
    public static SurfaceComponentGeometry CreateAlternatingDiagonalSplitSquareGeometry(
        float sizeX, float sizeZ, int segmentX, int segmentZ, int surfaceGroup = 0, RenderGeometry.FaceType faceType = RenderGeometry.FaceType.Polygonal)
    {
        var geometry = SurfaceComponentGeometries.CreatePlaneGeometry(sizeX, sizeZ, segmentX, segmentZ, surfaceGroup, faceType);

        foreach (Face face in new List <Face>(geometry.faces))
        {
            List <Halfedge> edges     = face.edges;
            Vector3         facePoint = edges[0].prev.vertex.p;
            int             x         = Mathf.RoundToInt((facePoint.x - sizeX / 2) / (sizeX / segmentX));
            int             z         = Mathf.RoundToInt((facePoint.z - sizeZ / 2) / (sizeZ / segmentZ));
            if ((x + z) % 2 == 0)
            {
                geometry.SplitFace(edges[0].vertex, edges[2].vertex);
            }
            else
            {
                geometry.SplitFace(edges[1].vertex, edges[3].vertex);
            }
        }
        return(geometry);
    }
Пример #16
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    public static SurfaceComponentGeometry CreateWallTiledTriangleGeometry(float sizeBase, float sizeHeight, float offsetTop, int segment, int surfaceGroup = 0, RenderGeometry.FaceType faceType = RenderGeometry.FaceType.Polygonal)
    {
        SurfaceComponentGeometry triangleGeometry = SurfaceComponentGeometries.CreateTriangleGeometry(sizeBase, sizeHeight, offsetTop, segment, true);
        List <Vertex>            corners          = triangleGeometry.corners;

        var      newVertices = new Dictionary <Vector2, Vertex>();
        Halfedge currentEdge = triangleGeometry.FindHalfedge(corners[2], corners[0]);
        Vector3  delta       = -currentEdge.vector / segment / 2;

        for (int i = 0; i < segment; i++)
        {
            Halfedge nextEdge  = currentEdge.next.next.opposite;
            Vector3  leftPoint = currentEdge.vertex.p;
            for (int j = 1; j < (segment - i) * 2; j++)
            {
                if (i == 0 && j % 2 == 1)
                {
                    continue;
                }
                Vertex newVertex = triangleGeometry.SplitEdge(currentEdge);
                newVertex.p            = leftPoint + j * delta;
                newVertices[Key(i, j)] = newVertex;
            }
            currentEdge = nextEdge;
        }

        for (int i = 0; i < segment - 1; i++)
        {
            for (int j = 1; j < segment - i; j++)
            {
                triangleGeometry.SplitFace(newVertices[Key(i, j * 2)], newVertices[Key(i + 1, j * 2 - 1)]);
            }
        }

        triangleGeometry.DefineBoundaries(corners.ToArray());
        return(triangleGeometry);
    }
    public static RenderGeometry CreateIcosahedronGeometry(float size, int segment)
    {
        int currentGroup = 0;

        return(CreateIcosahedronGeometryInternal(size, () => SurfaceComponentGeometries.CreateTriangleGeometry(1, 1, 0, segment, false, currentGroup++)));
    }
 public static RenderGeometry CreateCubeGeometry(Vector3 size, int[] segments)
 {
     return(CreateCubeGeometryInternal(size, dim => SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, segments[(dim + 2) % 3], segments[(dim + 1) % 3], dim)));
 }
    public static RenderGeometry CreateDodecahedronGeometry(float size)
    {
        int currentGroup = 0;

        return(CreateDodecahedronGeometryInternal(size, () => SurfaceComponentGeometries.CreateRegularPolygonGeometry(1, 5, currentGroup++, splitBoundary: true)));
    }
Пример #20
0
    private static void CreateStraightRampPart(
        StructureGeometry structure, bool isLeftRamp,
        Vertex cornerTopLeft1, Vertex cornerTopLeft2, Vertex cornerTopRight1, Vertex cornerTopRight2,
        Vertex cornerBottomLeft1, Vertex cornerBottomLeft2, Vertex cornerBottomRight1, Vertex cornerBottomRight2,
        bool addLeftSide, bool addRightSide, int segmentWidth, int segmentLength, float curvature, RenderGeometry.FaceType rampFaceType, RenderGeometry.FaceType sideFaceType)
    {
        bool hasBase = (cornerTopLeft1 != cornerBottomLeft1) && (cornerTopRight1 != cornerBottomRight1);

        SurfaceComponentGeometry rampFace = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, segmentWidth, segmentLength, 0, rampFaceType);
        SurfaceComponentGeometry rampBottom = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, segmentLength, 1, sideFaceType);
        SurfaceComponentGeometry rampLeftSide = null, rampRightSide = null;

        if (addLeftSide && (cornerTopLeft1 != cornerBottomLeft1))
        {
            rampLeftSide = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, segmentLength, 2, sideFaceType);
        }
        if (addRightSide && (cornerTopRight1 != cornerBottomRight1))
        {
            rampRightSide = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, segmentLength, 3, sideFaceType);
        }

        if (curvature != 0)
        {
            float angle = -curvature * Mathf.PI / 2;
            rampFace.ApplySpaceWarp(new SpaceWarp($"sin(x*{angle})/{angle}", $"(1-cos(x*{angle}))/{angle}", "z"));
        }
        // Fit to a 45 degree ramp, then scale.
        rampFace.ApplyLinearTransform(
            Matrix4x4.Translate(cornerTopLeft1.p) *
            Matrix4x4.Scale(VectorUtil.Abs(cornerTopRight2.p - cornerTopLeft1.p)) *
            MatrixUtil.PointToPointTransform(
                rampFace.corners[0].p, rampFace.corners[3].p, rampFace.corners[1].p,
                Vector3.zero, new Vector3(1, isLeftRamp ? 1 : -1, 0), Vector3.forward));

        structure.CreateFace(rampFace, false, cornerTopLeft1, cornerTopLeft2, cornerTopRight2, cornerTopRight1);
        structure.CreateFace(rampBottom, true, cornerBottomRight1, cornerBottomRight2, cornerBottomLeft2, cornerBottomLeft1);
        if (rampLeftSide != null)
        {
            structure.CreateFace(rampLeftSide, true, cornerBottomLeft1, cornerBottomLeft2, cornerTopLeft2, cornerTopLeft1);
        }
        if (rampRightSide != null)
        {
            structure.CreateFace(rampRightSide, true, cornerTopRight1, cornerTopRight2, cornerBottomRight2, cornerBottomRight1);
        }

        var backVertices = new List <Vector3>();

        backVertices.Add(isLeftRamp ? cornerBottomRight1.p : cornerBottomLeft1.p);
        if (isLeftRamp && hasBase)
        {
            backVertices.Add(cornerBottomLeft1.p);
        }
        backVertices.Add(rampFace.boundaries[3].Last().prev.vertex.p);
        backVertices.AddRange(rampFace.boundaries[3].Select(e => e.vertex.p).Reverse());
        if (!isLeftRamp && hasBase)
        {
            backVertices.Add(cornerBottomRight1.p);
        }
        var movedBackVertices = backVertices.Select(p => p + (cornerTopLeft2.p - cornerTopLeft1.p));
        var frontVertices = movedBackVertices.Take(1).Concat(movedBackVertices.Reverse().Take(backVertices.Count - 1)).ToList();

        SurfaceComponentGeometry backFace  = SurfaceComponentGeometries.CreateStarConvexPolygonGeometry(backVertices, 4, RenderGeometry.FaceType.Smooth);
        SurfaceComponentGeometry frontFace = SurfaceComponentGeometries.CreateStarConvexPolygonGeometry(frontVertices, 5, RenderGeometry.FaceType.Smooth);

        if (hasBase)
        {
            if (isLeftRamp)
            {
                backFace.CombineBoundaries(1, 1, segmentWidth, 1);
                frontFace.CombineBoundaries(1, segmentWidth, 1, 1);
                structure.CreateFace(backFace, false, cornerBottomRight1, cornerBottomLeft1, cornerTopLeft1, cornerTopRight1);
                structure.CreateFace(frontFace, false, cornerBottomRight2, cornerTopRight2, cornerTopLeft2, cornerBottomLeft2);
            }
            else
            {
                backFace.CombineBoundaries(1, segmentWidth, 1, 1);
                frontFace.CombineBoundaries(1, 1, segmentWidth, 1);
                structure.CreateFace(backFace, false, cornerBottomLeft1, cornerTopLeft1, cornerTopRight1, cornerBottomRight1);
                structure.CreateFace(frontFace, false, cornerBottomLeft2, cornerBottomRight2, cornerTopRight2, cornerTopLeft2);
            }
        }
        else
        {
            backFace.CombineBoundaries(1, segmentWidth, 1);
            frontFace.CombineBoundaries(1, segmentWidth, 1);
            structure.CreateFace(backFace, false, isLeftRamp ? cornerBottomRight1 : cornerBottomLeft1, cornerTopLeft1, cornerTopRight1);
            structure.CreateFace(frontFace, false, isLeftRamp ? cornerBottomRight2 : cornerBottomLeft2, cornerTopRight2, cornerTopLeft2);
        }
    }
    public static RenderGeometry CreateCylinderGeometry(float radius, float height, int segmentP, int segmentH, bool smoothH, bool smoothV, float cutAngle = 0, float hollowRatio = 0)
    {
        StructureGeometry structure = new StructureGeometry();

        RenderGeometry.FaceType faceType = GetFaceType(smoothH, smoothV);
        float hollowRadius = hollowRatio * radius;

        SurfaceComponentGeometry side      = SurfaceComponentGeometries.CreateCylinderSideGeometry(radius, height, segmentP, segmentH, cutAngle, false, 1, faceType);
        SurfaceComponentGeometry sideInner = null;

        if (hollowRatio > 0)
        {
            sideInner = SurfaceComponentGeometries.CreateCylinderSideGeometry(hollowRadius, height, segmentP, segmentH, cutAngle, true, 1, faceType);
        }
        SurfaceComponentGeometry upperCap, lowerCap;

        if (hollowRatio > 0)
        {
            upperCap = SurfaceComponentGeometries.CreateRingCapGeometry(radius, hollowRadius, segmentP, 1, cutAngle, 2);
            lowerCap = SurfaceComponentGeometries.CreateRingCapGeometry(radius, hollowRadius, segmentP, 1, cutAngle, 2);
        }
        else if (cutAngle == 0)
        {
            upperCap = SurfaceComponentGeometries.CreateRegularPolygonGeometry(radius, segmentP, 2);
            lowerCap = SurfaceComponentGeometries.CreateRegularPolygonGeometry(radius, segmentP, 2);
        }
        else
        {
            upperCap = SurfaceComponentGeometries.CreateFanCapGeometry(radius, segmentP, 1, cutAngle, 2);
            lowerCap = SurfaceComponentGeometries.CreateFanCapGeometry(radius, segmentP, 1, cutAngle, 2);
        }
        lowerCap.ApplyRotation(Quaternion.AngleAxis(cutAngle * Mathf.Rad2Deg, Vector3.up) * Quaternion.AngleAxis(180, Vector3.right));

        if (cutAngle == 0)
        {
            Vertex cornerUp   = structure.CreateVertex(new Vector3(radius, height / 2, 0));
            Vertex cornerDown = structure.CreateVertex(new Vector3(radius, -height / 2, 0));
            if (hollowRatio == 0)
            {
                structure.CreateFace(side, false, cornerUp, cornerUp, cornerDown, cornerDown);
                structure.CreateFace(upperCap, true, cornerUp);
                structure.CreateFace(lowerCap, true, cornerDown);
            }
            else
            {
                Vertex cornerUpInner   = structure.CreateVertex(new Vector3(hollowRadius, height / 2, 0));
                Vertex cornerDownInner = structure.CreateVertex(new Vector3(hollowRadius, -height / 2, 0));
                structure.CreateFace(side, false, cornerUp, cornerUp, cornerDown, cornerDown);
                structure.CreateFace(sideInner, false, cornerDownInner, cornerDownInner, cornerUpInner, cornerUpInner);
                structure.CreateFace(upperCap, true, cornerUpInner, cornerUpInner, cornerUp, cornerUp);
                structure.CreateFace(lowerCap, true, cornerDownInner, cornerDownInner, cornerDown, cornerDown);
            }
        }
        else
        {
            SurfaceComponentGeometry wall1 = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, segmentH, 3);
            SurfaceComponentGeometry wall2 = SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, 1, segmentH, 4);

            Vertex cornerUp1   = structure.CreateVertex(new Vector3(radius * Mathf.Cos(cutAngle), height / 2, -radius * Mathf.Sin(cutAngle)));
            Vertex cornerUp2   = structure.CreateVertex(new Vector3(radius, height / 2, 0));
            Vertex cornerDown1 = structure.CreateVertex(new Vector3(radius * Mathf.Cos(cutAngle), -height / 2, -radius * Mathf.Sin(cutAngle)));
            Vertex cornerDown2 = structure.CreateVertex(new Vector3(radius, -height / 2, 0));
            if (hollowRatio == 0)
            {
                Vertex cornerUpC   = structure.CreateVertex(new Vector3(0, height / 2, 0));
                Vertex cornerDownC = structure.CreateVertex(new Vector3(0, -height / 2, 0));
                structure.CreateFace(side, false, cornerUp2, cornerUp1, cornerDown1, cornerDown2);
                structure.CreateFace(upperCap, true, cornerUp1, cornerUp2, cornerUpC);
                structure.CreateFace(lowerCap, true, cornerDown2, cornerDown1, cornerDownC);
                structure.CreateFace(wall1, true, cornerUpC, cornerDownC, cornerDown1, cornerUp1);
                structure.CreateFace(wall2, true, cornerDownC, cornerUpC, cornerUp2, cornerDown2);
            }
            else
            {
                Vertex cornerUp1Inner   = structure.CreateVertex(new Vector3(hollowRadius * Mathf.Cos(cutAngle), height / 2, -hollowRadius * Mathf.Sin(cutAngle)));
                Vertex cornerUp2Inner   = structure.CreateVertex(new Vector3(hollowRadius, height / 2, 0));
                Vertex cornerDown1Inner = structure.CreateVertex(new Vector3(hollowRadius * Mathf.Cos(cutAngle), -height / 2, -hollowRadius * Mathf.Sin(cutAngle)));
                Vertex cornerDown2Inner = structure.CreateVertex(new Vector3(hollowRadius, -height / 2, 0));
                structure.CreateFace(side, false, cornerUp2, cornerUp1, cornerDown1, cornerDown2);
                structure.CreateFace(sideInner, false, cornerDown2Inner, cornerDown1Inner, cornerUp1Inner, cornerUp2Inner);
                structure.CreateFace(upperCap, true, cornerUp2Inner, cornerUp1Inner, cornerUp1, cornerUp2);
                structure.CreateFace(lowerCap, true, cornerDown1Inner, cornerDown2Inner, cornerDown2, cornerDown1);
                structure.CreateFace(wall1, true, cornerUp1Inner, cornerDown1Inner, cornerDown1, cornerUp1);
                structure.CreateFace(wall2, true, cornerDown2Inner, cornerUp2Inner, cornerUp2, cornerDown2);
            }
        }
        return(structure.Build());
    }
Пример #22
0
    public void UpdateMesh()
    {
        if (meshSaved)
        {
            return;
        }

        RenderGeometry g = null;

        if (type == HyperPrimitiveType.Plane)
        {
            g = SurfaceComponentGeometries.CreatePlaneGeometry(sizeX, sizeZ, segmentX, segmentZ);
        }
        else if (type == HyperPrimitiveType.Triangle)
        {
            g = SurfaceComponentGeometries.CreateTriangleGeometry(sizeX, sizeZ, offset, segmentX);
        }
        else if (type == HyperPrimitiveType.Polygon)
        {
            g = SurfaceComponentGeometries.CreateRegularPolygonGeometry(sizeR, segmentP);
        }
        else if (type == HyperPrimitiveType.PolygonFan)
        {
            g = SurfaceComponentGeometries.CreateFanCapGeometry(sizeR, segmentP, segmentY, Rad(cutAngle));
        }
        else if (type == HyperPrimitiveType.Sphere)
        {
            g = CircularGeometries.CreateSphereGeometry(sizeR, segmentP, segmentP2, smoothH, smoothV, cutTop, cutBottom);
        }
        else if (type == HyperPrimitiveType.Cylinder)
        {
            g = CircularGeometries.CreateCylinderGeometry(sizeR, sizeY, segmentP, segmentY, smoothH, smoothV, Rad(cutAngle), hollowRatio);
        }
        else if (type == HyperPrimitiveType.Capsule)
        {
            g = CircularGeometries.CreateCapsuleGeometry(sizeR, sizeY, segmentP, segmentY, segmentP2, smoothH, smoothV);
        }
        else if (type == HyperPrimitiveType.Cone)
        {
            g = CircularGeometries.CreateConeGeometry(sizeR, sizeY, segmentP, segmentP2, smoothH, smoothV, cutTop, Rad(cutAngle));
        }
        else if (type == HyperPrimitiveType.Torus)
        {
            g = CircularGeometries.CreateTorusGeometry(sizeR, sizeR2, segmentP, segmentP2, smoothH, smoothV, Rad(cutAngle), Rad(angleOffset));
        }
        else if (type == HyperPrimitiveType.Spring)
        {
            g = CircularGeometries.CreateSpringGeometry(sizeR, sizeR2, sizeY, segmentP, segmentP2, smoothH, smoothV, Rad(angle), Rad(angleOffset));
        }
        else if (type == HyperPrimitiveType.Cube)
        {
            g = PolyhedronGeometries.CreateCubeGeometry(new Vector3(sizeX, sizeY, sizeZ), new int[] { segmentX, segmentY, segmentZ });
        }
        else if (type == HyperPrimitiveType.CubeStar)
        {
            g = PolyhedronGeometries.CreateCubeStarGeometry(sizeX, extrusion, cutTop);
        }
        else if (type == HyperPrimitiveType.CubeFrame)
        {
            g = PolyhedronGeometries.CreateCubeFrameGeometry(sizeX, ratio);
        }
        else if (type == HyperPrimitiveType.BuildingBlock)
        {
            g = PolyhedronGeometries.CreateBuildingBlockGeometry(new Vector3(sizeX, sizeY, sizeZ), new bool[, , ] {
                { { xyz, xyZ }, { xYz, xYZ } }, { { Xyz, XyZ }, { XYz, XYZ } }
            });
        }
        else if (type == HyperPrimitiveType.Tetrahedron)
        {
            g = PolyhedronGeometries.CreateTetrahedronGeometry(sizeX, segmentX);
        }
        else if (type == HyperPrimitiveType.TetrahedronStar)
        {
            g = PolyhedronGeometries.CreateTetrahedronStarGeometry(sizeX, extrusion, cutTop);
        }
        else if (type == HyperPrimitiveType.Octahedron)
        {
            g = PolyhedronGeometries.CreateOctahedronGeometry(sizeX, segmentX);
        }
        else if (type == HyperPrimitiveType.OctahedronStar)
        {
            g = PolyhedronGeometries.CreateOctahedronStarGeometry(sizeX, extrusion, cutTop);
        }
        else if (type == HyperPrimitiveType.Dodecahedron)
        {
            g = PolyhedronGeometries.CreateDodecahedronGeometry(sizeX);
        }
        else if (type == HyperPrimitiveType.DodecahedronStar)
        {
            g = PolyhedronGeometries.CreateDodecahedronStarGeometry(sizeX, extrusion, cutTop);
        }
        else if (type == HyperPrimitiveType.Icosahedron)
        {
            g = PolyhedronGeometries.CreateIcosahedronGeometry(sizeX, segmentX);
        }
        else if (type == HyperPrimitiveType.IcosahedronStar)
        {
            g = PolyhedronGeometries.CreateIcosahedronStarGeometry(sizeX, extrusion, cutTop);
        }
        else if (type == HyperPrimitiveType.TrunctedTetrahedron)
        {
            g = PolyhedronGeometries.CreateTetrahedronToTetrahedronTransitionGeometry(sizeX, ratio, cutEdge);
        }
        else if (type == HyperPrimitiveType.TrunctedCubeOctahedron)
        {
            g = PolyhedronGeometries.CreateCubeToOctahedronTransitionGeometry(sizeX, ratio, cutEdge);
        }
        else if (type == HyperPrimitiveType.TrunctedIcosahedronDodecahedron)
        {
            g = PolyhedronGeometries.CreateIcosahedronToDodecahedronTransitionGeometry(sizeX, ratio, cutEdge);
        }
        else if (type == HyperPrimitiveType.Ramp)
        {
            g = RampGeometries.CreateStraightRampGeometry(sizeX, sizeY, sizeZ, segmentX, segmentZ, smoothX, smoothZ, rampType, curvature, extraSizeY, extraSizeX, extraSizeX2);
        }
        else if (type == HyperPrimitiveType.Test)
        {
            g = SpecialSurfaceComponentGeometries.CreateSplitTriangleGeometry(1, 1, 0, 3);
        }
        else
        {
            g = new RenderGeometry();
        }

        foreach (HyperModifier modifier in GetComponents <HyperModifier>())
        {
            modifier.Apply(g);
        }

        GetComponent <MeshFilter>().sharedMesh = g.ToMesh(surfaceFacing, globalSurfaceType);
        currentGeometry = g;
    }
Пример #23
0
        public void SetUpLevel(string levelCode, int size, float minePercentage)
        {
            RenderGeometry geometry;
            var            goldenNumber = (Mathf.Sqrt(5) + 1) / 2;

            switch (levelCode)
            {
            case "1-1":
                geometry = PolyhedronGeometries.CreateCubeGeometry(Vector3.one * TILE_SIZE_SQUARE * size, new[] { size, size, size });
                break;

            case "1-2":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateCubeGeometry(Vector3.one * TILE_SIZE_SQUARE * size * 2, new[] { 1, 1, 1 }),
                    f => SpecialSurfaceComponentGeometries.CreateDiamondCenterCrossSplitSquareGeometry(1, 1, size, size));
                break;

            case "1-3":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateCubeGeometry(Vector3.one * TILE_SIZE_SQUARE * size * 2, new[] { 1, 1, 1 }),
                    f => SpecialSurfaceComponentGeometries.CreateDiamondCenterOctaSplitSquareGeometry(1, 1, size, size));
                break;

            case "1-4":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateCubeGeometry(Vector3.one * TILE_SIZE_SQUARE * size * 1.5f, new[] { 1, 1, 1 }),
                    f => SpecialSurfaceComponentGeometries.CreatePantagonSquareGeometry(1, 1, size, size, 0.4f));
                break;

            case "1-5":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateCubeGeometry(Vector3.one * TILE_SIZE_SQUARE * size * 1.2f, new[] { 1, 1, 1 }),
                    f => SpecialSurfaceComponentGeometries.CreateAlternatingDiagonalSplitSquareGeometry(1, 1, size, size));
                break;

            case "1-6":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateCubeGeometry(Vector3.one * TILE_SIZE_SQUARE * size * 1.5f, new[] { 1, 1, 1 }),
                    f => SpecialSurfaceComponentGeometries.CreateXSplitSquareGeometry(1, 1, size, size, 0.2f / size));
                break;

            case "2-1":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateCubeStarGeometry(TILE_SIZE_SQUARE * size, 2, 1),
                    f => SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, size, size));
                break;

            case "3-1":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateCubeFrameGeometry(TILE_SIZE_SQUARE * (size + 2), 1 - ((size + 2) / 3 * 2) / (float)(size + 2)),
                    f => SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, Mathf.RoundToInt(f.edge.prev.length / TILE_SIZE_SQUARE), Mathf.RoundToInt(f.edge.length / TILE_SIZE_SQUARE)));
                break;

            case "4-1":
                geometry = PolyhedronGeometries.CreateTetrahedronGeometry(TILE_SIZE_TRIANGLE * size / Mathf.Sqrt(2), size);
                break;

            case "4-2":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateTetrahedronGeometry(TILE_SIZE_TRIANGLE * size * Mathf.Sqrt(2), 1),
                    f => SpecialSurfaceComponentGeometries.CreateSplitTriangleGeometry(1, 1, 0, size));
                break;

            case "4-3":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateOctahedronStarGeometry(TILE_SIZE_TRIANGLE * size * Mathf.Sqrt(2), 2, 0),
                    f => SurfaceComponentGeometries.CreateTriangleGeometry(1, 1, 0, size));
                break;

            case "4-4":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateOctahedronStarGeometry(TILE_SIZE_TRIANGLE * size * 2 * Mathf.Sqrt(2), 2, 0),
                    f => SpecialSurfaceComponentGeometries.CreateSplitTriangleGeometry(1, 1, 0, size));
                break;

            case "5-1":
                geometry = PolyhedronGeometries.CreateOctahedronGeometry(TILE_SIZE_TRIANGLE * size * Mathf.Sqrt(2), size);
                break;

            case "5-2":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateCuboctahedronGeometry(TILE_SIZE_SQUARE_TRIANGLE * size * Mathf.Sqrt(2), 0.5f),
                    f => f.edges.Count == 4
                        ? SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, size, size)
                        : SurfaceComponentGeometries.CreateTriangleGeometry(1, 1, 0, size));
                break;

            case "5-3":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateRhombicuboctahedronGeometry(TILE_SIZE_SQUARE_TRIANGLE * size * (1 + Mathf.Sqrt(2)), Mathf.Sqrt(2) / (1 + Mathf.Sqrt(2))),
                    f => f.edges.Count == 4
                        ? SurfaceComponentGeometries.CreatePlaneGeometry(1, 1, size, size)
                        : SurfaceComponentGeometries.CreateTriangleGeometry(1, 1, 0, size));
                break;

            case "6-1":
                geometry = PolyhedronGeometries.CreateIcosahedronGeometry(TILE_SIZE_TRIANGLE * size * goldenNumber, size);
                break;

            case "6-2":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateDodecahedronGeometry(TILE_SIZE_TRIANGLE * size * goldenNumber * goldenNumber),
                    f => SpecialSurfaceComponentGeometries.CreateTrianglesCombinedRegularPolygonGeometry(1, 5, () => SpecialSurfaceComponentGeometries.CreateWallTiledTriangleGeometry(1, 1, 0, size).ShiftBoundaries(1)));
                break;

            case "6-3":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateIcosidodecahedronGeometry(TILE_SIZE_TRIANGLE * size * goldenNumber * 2),
                    f => f.edges.Count == 5
                         ? SpecialSurfaceComponentGeometries.CreateTrianglesCombinedRegularPolygonGeometry(1, 5, () => SpecialSurfaceComponentGeometries.CreateWallTiledTriangleGeometry(1, 1, 0, size).ShiftBoundaries(1))
                         : SurfaceComponentGeometries.CreateTriangleGeometry(1, 1, 0, size));
                break;

            case "6-4":
                geometry = ReplaceAllFace(
                    PolyhedronGeometries.CreateTrunctedIcosahedronGeometry(TILE_SIZE_TRIANGLE * size * goldenNumber * goldenNumber * 2, 2 / 3f),
                    f => f.edges.Count == 5
                         ? SpecialSurfaceComponentGeometries.CreateTrianglesCombinedRegularPolygonGeometry(1, 5, () => SpecialSurfaceComponentGeometries.CreateWallTiledTriangleGeometry(1, 1, 0, size).ShiftBoundaries(1))
                         : SpecialSurfaceComponentGeometries.CreateTrianglesCombinedRegularPolygonGeometry(1, 6, () => SurfaceComponentGeometries.CreateTriangleGeometry(1, 1, 0, size)));
                break;

            case "7-1":
                geometry = CircularGeometries.CreateTorusGeometry(TILE_SIZE_SQUARE * (3 + size) * 0.4f, TILE_SIZE_SQUARE * (3 + size) * 0.16f, (3 + size) * 2, 3 + size, false, false);
                break;

            case "9-9":
                geometry = SpecialSurfaceComponentGeometries.CreateTrianglesCombinedRegularPolygonGeometry(TILE_SIZE_SQUARE * size, 5, () => SpecialSurfaceComponentGeometries.CreateWallTiledTriangleGeometry(1, 1, 0, size).ShiftBoundaries(1));
                break;

            default:
                return;
            }

            MineFieldControl.instance.InitField(geometry, Mathf.RoundToInt(geometry.faces.Count * minePercentage));
        }