Beispiel #1
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="da">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess da)
        {
            // SET ALL INPUT PARAMETERS
            var curves    = da.FetchList <Curve>("Polylines");
            var dist      = da.Fetch <double>("Distance");
            var pln       = da.Fetch <Plane>("Plane");
            var tolerance = da.Fetch <double>("Tolerance");
            var openType  = da.FetchList <int>("OpenFillet").Cast <Polyline3D.OpenFilletType>().ToList();

            if (openType.Count == 0)
            {
                openType = new List <Polyline3D.OpenFilletType> {
                    Polyline3D.OpenFilletType.Square
                };
            }
            var miter      = da.Fetch <double>("Miter");
            var closedType = da.FetchList <int>("ClosedFillet").Cast <Polyline3D.ClosedFilletType>().ToList();
            var polylines  = Polyline3D.ConvertCurvesToPolyline(curves).ToList();

            if (curves.Count == 0)
            {
                return;
            }

            if (pln.Equals(default))
Beispiel #2
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            // SET ALL INPUT PARAMETERS
            List <Curve> A = DA.FetchList <Curve>("A");
            List <Curve> B = DA.FetchList <Curve>("B");

            try {
                ClipType type      = (ClipType)DA.Fetch <int>("BooleanType");
                Plane    pln       = DA.Fetch <Plane>("Plane");
                double   tolerance = DA.Fetch <double>("Tolerance");

                // Convert the curves to polylines
                // This is a crude way of doing this.
                // Should we add some parameters for this perhaps?
                IEnumerable <Polyline> APl = Polyline3D.ConvertCurvesToPolyline(A);
                IEnumerable <Polyline> BPl = Polyline3D.ConvertCurvesToPolyline(B);

                // If we don't have a plane, let's try to create a plane from the first curve.
                if (pln.Equals(default(Plane)) || !pln.IsValid)
                {
                    pln = APl.First().FitPlane();
                }

                List <Polyline> result = new List <Polyline>();

                // do the boolean operation
                result = Polyline3D.Boolean(type, APl, BPl, pln, tolerance, EvenOdd);

                // OUTPUT LOGIC
                DA.SetDataList("Result", result);
            } catch (Exception e) {
                this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, e.Message + ": " + e.StackTrace.ToString());
            }
        }
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            MeshProps meshProps0 = DA.Fetch <MeshProps>("MeshProp0");

            NGonsCore.Nexorades.Nexors nexors0 = DA.Fetch <NGonsCore.Nexorades.Nexors>("Nexors0");

            MeshProps meshProps1 = DA.Fetch <MeshProps>("MeshProp1");

            NGonsCore.Nexorades.Nexors nexors1 = DA.Fetch <NGonsCore.Nexorades.Nexors>("Nexors1");

            try
            {
                DA.SetDataTree(0, nexors0.Beams2(meshProps0));
                DA.SetDataTree(1, nexors0.Panels(meshProps0));
                nexors0.RoundBeams(meshProps0, 0.06);
                DA.SetDataTree(2, nexors0.GetNexorPipesBreps());
                DA.SetDataTree(3, nexors0.Cuts());
                DA.SetDataTree(4, nexors0.GetCNC_Cuts());


                DA.SetDataTree(5, nexors1.Beams2(meshProps1));
                DA.SetDataTree(6, nexors1.Panels(meshProps1));
                nexors1.RoundBeams(meshProps1, 0.06);
                DA.SetDataTree(7, nexors1.GetNexorPipesBreps());
                DA.SetDataTree(8, nexors1.Cuts());
                DA.SetDataTree(9, nexors1.GetCNC_Cuts());

                DA.SetDataTree(10, nexors0.GetDowels(0.03, 10));
                DA.SetDataTree(11, nexors1.GetDowels(0.03, 10));
            }
            catch (Exception e)
            {
                Rhino.RhinoApp.WriteLine(e.ToString());
            }
        }
Beispiel #4
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            double?from  = DA.Fetch <double?>("From");
            double?to    = DA.Fetch <double?>("To");
            int    steps = DA.Fetch <int>("Steps");

            InputSelector inputSelector = new InputSelector(steps, from, to);

            DA.SetData(0, inputSelector);
        }
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="da">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess da)
        {
            // SET ALL INPUT PARAMETERS
            if (!Polyline3D.ConvertCurveToPolyline(da.Fetch <Curve>("Polyline"), out var plA))
            {
                AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Unable to convert to polyline from curve");
                return;
            }
            var pt        = da.Fetch <Point3d>("Point");
            var pln       = da.Fetch <Plane>("Plane");
            var tolerance = da.Fetch <double>("Tolerance");

            if (pln.Equals(default))
Beispiel #6
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            // SET ALL INPUT PARAMETERS
            List <Curve> curves    = DA.FetchList <Curve>("Polylines");
            double       dist      = DA.Fetch <double>("Distance");
            Plane        pln       = DA.Fetch <Plane>("Plane");
            double       tolerance = DA.Fetch <double>("Tolerance");
            List <Polyline3D.OpenFilletType> openType = DA.FetchList <int>("OpenFillet").Cast <Polyline3D.OpenFilletType>().ToList();

            if (openType == null || openType.Count == 0)
            {
                openType = new List <Polyline3D.OpenFilletType> {
                    Polyline3D.OpenFilletType.Square
                };
            }
            double miter = DA.Fetch <double> ("Miter");

            List <Polyline3D.ClosedFilletType> closedType = DA.FetchList <int>("ClosedFillet").Cast <Polyline3D.ClosedFilletType>().ToList();

            IEnumerable <Polyline> polylines = Polyline3D.ConvertCurvesToPolyline(curves);

            if (pln.Equals(default(Plane)))
            {
                pln = polylines.First().FitPlane();
            }

            // set default fillet type.
            if (closedType == null || closedType.Count == 0)
            {
                closedType = new List <Polyline3D.ClosedFilletType> {
                    Polyline3D.ClosedFilletType.Square
                };
            }

            if (curves.Count == 0)
            {
                return;
            }

            List <List <Polyline> > outside;
            List <List <Polyline> > holes;

            Polyline3D.Offset(polylines, openType, closedType, pln, tolerance, new List <double> {
                dist
            }, miter, 0.25, out outside, out holes);


            // OUTPUT LOGIC
            DA.SetDataList("Contour", outside.First());
            DA.SetDataList("Holes", holes.First());
        }
Beispiel #7
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            var bb = DA.Fetch <Rectangle3d>("BoundingBox");
            var x  = DA.Fetch <double>("SizeX");
            var y  = DA.Fetch <double>("SizeY");

            var vg = new PixelGrid2D(bb, new Point2d(x, y));

            if (!vg.IsValid)
            {
                AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Result was an invalid grid");
            }

            DA.SetData(0, new GH_PixelGrid((PixelGrid2D)vg.Clone()));
        }
        protected override void SolveInstance(IGH_DataAccess DA) {

            Curve curve = DA.Fetch<Curve>("Poly");
            double t = DA.Fetch<double>("Chamfer");

            Polyline polyline;
            if (curve.TryGetPolyline(out polyline)) {

                DA.SetData(0, PolylineUtil.Chamfer(polyline, t));
            }




        }
Beispiel #9
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            Mesh M = DA.Fetch <Mesh>("M");
            int  n = 2;

            DA.GetData(1, ref n);

            bool ef = true;

            DA.GetData(2, ref ef);
            try
            {
                if (ef)
                {
                    Grasshopper.DataTree <int> Colors       = Algo.Graph._GraphColorHalfEdges(M, n);
                    List <Polyline>            EdgeOutlines = M._EFPolylinesAll();

                    DA.SetDataList(0, EdgeOutlines);
                    DA.SetDataTree(1, Colors);
                }
                else
                {
                    Grasshopper.DataTree <int> Colors = Algo.Graph._GraphColorFaces(M, n);


                    DA.SetDataList(0, M.GetPolylines());
                    DA.SetDataTree(1, Colors);
                }
            }
            catch (Exception e)
            {
                Rhino.RhinoApp.WriteLine(e.ToString());
            }
        }
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            MeshProps meshProps = DA.Fetch <MeshProps>("MeshProp");
            //GH_Structure<GH_Number> D = DA.FetchTree<GH_Number>("Dist");
            List <double> D = DA.FetchList <double>("Dist");

            try
            {
                double     firstDist = (D.Count > 0) ? D[0] : 0.01;
                double[][] DArray    = new double[][] { new double[1] {
                                                            D[0]
                                                        } };


                if (D.Count > 0)
                {
                    DArray = new double[meshProps.FEFlatten.Length][];
                    for (int i = 0; i < meshProps.FEFlatten.Length; i++)
                    {
                        DArray[i] = new double[meshProps.FEFlatten[i].Length];
                    }

                    for (int i = 0; i < meshProps._FlattenFE.Count; i++)
                    {
                        DArray[meshProps._FlattenFE[i][0]][meshProps._FlattenFE[i][1]] = D[i % D.Count];
                    }
                }


                //Compute translation
                //Create Nexors
                NGonsCore.Nexorades.Nexors nexors = new NGonsCore.Nexorades.Nexors();
                for (int i = 0; i < meshProps.M._countF(); i++)
                {
                    for (int j = 0; j < meshProps.M._countE(i); j++)
                    {
                        nexors.Add(meshProps.EFLines[i][j], i, j);
                        nexors[i, j].translation = DArray[i][j];
                    }
                }



                Line[][] translatedLines = meshProps.NexorTranslateLines(ref nexors, DArray);



                //Output
                DA.SetDataTree(0, nexors.GetNexorLines());
                DA.SetDataTree(1, nexors.GetNexorEccentricities());
                DA.SetData(2, nexors);
                DA.SetData(3, meshProps);
                DA.SetDataTree(4, nexors.GetNexorLines(-1));
            }
            catch (Exception e)
            {
                Rhino.RhinoApp.WriteLine(e.ToString());
            }
        }
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            // SET ALL INPUT PARAMETERS
            Polyline plA = default(Polyline);

            if (!Polyline3D.ConvertCurveToPolyline(DA.Fetch <Curve>("A"), out plA))
            {
                this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Unable to convert to polyline from curve");
                return;
            }
            Polyline plB = default(Polyline);

            if (!Polyline3D.ConvertCurveToPolyline(DA.Fetch <Curve>("B"), out plB))
            {
                this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Unable to convert to polyline from curve");
                return;
            }

            Plane  pln       = DA.Fetch <Plane>("Plane");
            double tolerance = DA.Fetch <double>("Tolerance");

            if (pln.Equals(default(Plane)))
            {
                pln = plA.FitPlane();
            }

            Point3d ptCenter = new Box(pln, plB).Center;

            List <Polyline> outCurves          = new List <Polyline>();
            List <Polyline> outDisplacedCurves = new List <Polyline>();

            foreach (List <IntPoint> path in ClipperLib.Clipper.MinkowskiSum(plA.ToPath2D(pln, tolerance), plB.ToPath2D(pln, tolerance), true))
            {
                Polyline plSum = path.ToPolyline(pln, tolerance, true);
                //Polyline plDisplacedSum = new Polyline(plSum);
                //plDisplacedSum.Transform(Transform.Translation(-new Vector3d(ptCenter)));
                outCurves.Add(plSum);
                //outDisplacedCurves.Add(plDisplacedSum);
            }



            // OUTPUT LOGIC
            DA.SetDataList("Sum", outCurves);
            DA.SetDataList("DisplacedSum", outCurves);
        }
Beispiel #12
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            /*
             * todo: select mesh box or simple box
             */
            var pg         = DA.Fetch <PixelGrid2D> (0);
            var trueColor  = DA.Fetch <Color>(1);
            var falseColor = DA.Fetch <Color>(2);

            if (pg == null || !pg.IsValid)
            {
                AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "The (input) voxelgrid was invalid");
                return;
            }
            var m = pg.GenerateMesh(trueColor, falseColor);

            DA.SetData(0, new GH_Mesh(m));
        }
Beispiel #13
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            Surface      m0     = DA.Fetch <Surface>("Srf0");
            Surface      m1     = DA.Fetch <Surface>("Srf1");
            List <Curve> curves = DA.FetchList <Curve>("Curves");

            List <Polyline> polylines = new List <Polyline>();

            foreach (Curve c in curves)
            {
                Polyline polyline;
                if (c.TryGetPolyline(out polyline))
                {
                    polylines.Add(polyline);
                }
            }


            DA.SetDataList(0, polylines.MappedFromSurfaceToSurface(m0, m1));
        }
Beispiel #14
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="da">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess da)
        {
            // SET ALL INPUT PARAMETERS
            var curvesA = da.FetchList <Curve>("A");
            var curvesB = da.FetchList <Curve>("B");

            try
            {
                var type      = (ClipType)da.Fetch <int>("BooleanType");
                var pln       = da.Fetch <Plane>("Plane");
                var tolerance = da.Fetch <double>("Tolerance");

                // Convert the curves to polylines
                // This is a crude way of doing this.
                // Should we add some parameters for this perhaps?
                var polylinesA = Polyline3D.ConvertCurvesToPolyline(curvesA).ToList();
                var polylinesB = Polyline3D.ConvertCurvesToPolyline(curvesB).ToList();

                // If we don't have a plane, let's try to create a plane from the first curve.
                if (pln.Equals(default) || !pln.IsValid)
Beispiel #15
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            Mesh         m0     = DA.Fetch <Mesh>("Mesh0");
            Mesh         m1     = DA.Fetch <Mesh>("Mesh1");
            List <Curve> curves = DA.FetchList <Curve>("Curves");

            List <Polyline> polylines = new List <Polyline>();

            foreach (Curve c in curves)
            {
                Polyline polyline;
                if (c.TryGetPolyline(out polyline))
                {
                    polylines.Add(polyline);
                }
            }


            DA.SetDataList(0, polylines.MappedFromMeshToMesh(m0, m1));
        }
Beispiel #16
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            Mesh m = new Mesh();

            DA.GetData(0, ref m);

            double dist = DA.Fetch <double>("Offset");
            bool   flip = DA.Fetch <bool>("Flip");

            if (dist != 0)
            {
                m = m.FaceFaceOffset(dist);
                //Rhino.RhinoDoc.ActiveDoc.Objects.AddMesh(m);
            }

            Mesh M = NGonsCore.MeshCreate.MeshFromPolylines(m.GetFacePolylinesArray(), 0.01);

            if (flip)
            {
                M.Flip(true, true, true);
            }
            DA.SetData(4, M);

            try
            {
                MeshProps mp = M._Planes();



                DA.SetData(0, mp);
                DA.SetDataTree(1, GrasshopperUtil.IE(mp.fPl, -1));
                DA.SetDataTree(2, GrasshopperUtil.IE2(mp.fePl));
                // DA.SetDataTree(3, GrasshopperUtil.IE2(mp.fePl90));
                DA.SetDataTree(3, GrasshopperUtil.IE(mp.ePl));
                //DA.SetDataTree(5, GrasshopperUtil.IE(mp.ePl90));
            }
            catch (Exception e)
            {
                Rhino.RhinoApp.WriteLine(e.ToString());
            }
        }
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            // SET ALL INPUT PARAMETERS
            Polyline plA = default(Polyline);

            if (!Polyline3D.ConvertCurveToPolyline(DA.Fetch <Curve>("Polyline"), out plA))
            {
                this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Unable to convert to polyline from curve");
                return;
            }
            Point3d pt        = DA.Fetch <Point3d>("Point");
            Plane   pln       = DA.Fetch <Plane>("Plane");
            double  tolerance = DA.Fetch <double>("Tolerance");

            if (pln.Equals(default(Plane)))
            {
                pln = plA.FitPlane();
            }

            DA.SetData("Inside", plA.IsInside(pt, pln, tolerance));
        }
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            //1 divide the brep by the Z components of the grid (get Z values on plane of the grid
            //2 intersect the grid for reach Z value -> planar surface the results
            //3 check for each pixel if it is closer than the
            var geometry = DA.FetchList <IGH_GeometricGoo>(0);
            var pg       = DA.Fetch <PixelGrid2D>(1);

            pg = (PixelGrid2D)pg.Clone();

            if (pg == null || !pg.IsValid)
            {
                AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "The (input) voxelgrid was invalid");
                return;
            }


            var geometryIndex = new Dictionary <int, IGH_GeometricGoo>();

            for (int i = 0, count = geometry.Count; i < count; i++)
            {
                geometryIndex.Add(i, geometry[i]);
            }

            var ptList    = GeometryHelper.TryCastGeometry <Point3d>(geometryIndex, false);
            var curveList = GeometryHelper.TryCastGeometry <Curve>(geometryIndex, false);

            foreach (var pt in ptList.Values)
            {
                AddPoint3d(pg, pt);
            }

            foreach (var c in curveList.Values)
            {
                AddCurve(pg, c);
            }

            DA.SetData(0, new GH_PixelGrid((PixelGrid2D)pg.Clone()));
        }
Beispiel #19
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="da">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess da)
        {
            var pg = da.Fetch <PixelGrid2D>(0);


            var values   = new List <bool>();
            var location = new List <Point3d>();

            if (pg == null || !pg.IsValid)
            {
                AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "The (input) voxelgrid was invalid");
                return;
            }

            for (var i = 0; i < pg.SizeUV.SelfProduct(); i++)
            {
                values.Add(pg.ValueAt(i));
                location.Add(pg.PointAt(i));
            }
            da.SetDataList(0, values);
            da.SetDataList(1, location);
            da.SetData(2, pg.BBox);
        }
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            #region updateInputs
            //if (!cap && this.Params.Input.Count ==7)
            //{
            //    this.Params.Input[5].RemoveAllSources();
            //    this.Params.UnregisterInputParameter(this.Params.Input[5]);
            //    this.Params.Input[6].RemoveAllSources();
            //    this.Params.UnregisterInputParameter(this.Params.Input[6]);

            //    Params.OnParametersChanged();
            //}
            //if (cap && this.Params.Input.Count == 5)
            //{
            //    this.Params.RegisterInputParam(new Param_Colour
            //    {
            //        Name = "MinColor",
            //        NickName = "MinColor",
            //        Description = "MinColor",
            //        Access = GH_ParamAccess.item,
            //        Optional = true
            //    });
            //    this.Params.RegisterInputParam(new Param_Colour
            //    {
            //        Name = "MaxColor",
            //        NickName = "MaxColor",
            //        Description = "MinColor",
            //        Access = GH_ParamAccess.item,
            //        Optional = true
            //    });

            //    Params.OnParametersChanged();
            //}

            #endregion updateInputs

            //bool caps = DA.Fetch<bool>("Cap");
            var maxColor   = DA.Fetch <Color>(inputSelecterMax);
            var minColor   = DA.Fetch <Color>(inputSelectorMin);
            var allResults = DA.FetchTree <GH_Number>("Results");
            var grids      = DA.FetchList <Grid>("Grids");
            var range      = DA.Fetch <string>("Range");
            var inStepSize = DA.Fetch <int>("StepSize");
            var inSteps    = DA.Fetch <int>("Steps");

            if (allResults.Branches.Count != grids.Count)
            {
                throw new Exception("Grid count doesnt match results");
            }

            if (!caps)
            {
                this.Params.Input[inputSelectorMin].NickName = "-";
                this.Params.Input[inputSelectorMin].Name     = "-";
                this.Params.Input[inputSelecterMax].NickName = "-";
                this.Params.Input[inputSelecterMax].Name     = "-";
            }
            else
            {
                this.Params.Input[inputSelectorMin].NickName = "MinColor";
                this.Params.Input[inputSelectorMin].Name     = "MinColor";
                this.Params.Input[inputSelecterMax].NickName = "MaxColor";
                this.Params.Input[inputSelecterMax].Name     = "MaxColor";
            }

            var domain = Misc.AutoDomain(range, allResults);
            //Rhino.RhinoApp.WriteLine($"{range}  ->  {domain[0]} to {domain[1]}");

            GH_GradientControl gc;
            try
            {
                gc = (GH_GradientControl)Params.Input[inputGradient].Sources[0].Attributes.GetTopLevel.DocObject;
            }
            catch (System.ArgumentOutOfRangeException)
            {
                this.AddRuntimeMessage(GH_RuntimeMessageLevel.Remark, "Remember to add a gradient component in grasshopper!");
                gc = null;
            }

            GradientParser gp = new GradientParser(gc)
            {
                Cap      = caps,
                AboveMax = maxColor,
                BelowMin = minColor,
                Min      = domain[0],
                Max      = domain[1],
                Reverse  = Params.Input[inputGradient].Reverse
            };


            //Rhino.RhinoApp.WriteLine($"Probing {domain[0]} to the value of {gp.GetColors(new List<double> { domain[0] })[0]}");
            //Rhino.RhinoApp.WriteLine($"Probing {domain[1]} to the value of {gp.GetColors(new List<double> { domain[1] })[0]}");

            #region coloredMesh
            var outMeshes = new List <Mesh>();



            for (int i = 0; i < grids.Count; i++)
            {
                //AddRuntimeMessage(GH_RuntimeMessageLevel.Remark, $"Mesh vertices: {grids[i].SimMesh.Vertices.Count}, colors = {gp.GetColors(allResults.Branches[i].Select(p => p.Value).ToArray()).Length} f");


                outMeshes.Add(grids[i].GetColoredMesh(gp.GetColors(allResults.Branches[i].Select(p => p.Value).ToArray())));

                Mesh      m      = grids[i].SimMesh;
                Point3d[] points = grids[i].SimPoints.ToArray();
                outMeshes[outMeshes.Count - 1].Translate(0, 0, Units.ConvertFromMeter(0.001));
            }


            DA.SetDataList(0, outMeshes);

            #endregion coloredMesh



            #region layeredMesh

            if (grids[0].UseCenters == true)
            {
                return;
            }

            //Outputs
            GH_Structure <GH_Mesh>  layeredMeshes = new GH_Structure <GH_Mesh>();
            List <GH_Mesh>          tempMeshes    = new List <GH_Mesh>();
            List <GH_Plane>         outPlanes     = new List <GH_Plane>();
            GH_Structure <GH_Curve> outCurves     = new GH_Structure <GH_Curve>();

            const double SCALAR = 1; // don't change.
            const float  OFFSET = 0.0001f;

            double allMin = double.MaxValue;
            double allMax = -double.MaxValue;

            for (int i = 0; i < allResults.Branches.Count; i++)
            {
                //System.Collections.IList results = allResults.get_Branch(i);

                for (int j = 0; j < allResults[i].Count; j++)
                {
                    double result = allResults[i][j].Value;
                    if (result < allMin)
                    {
                        allMin = result;
                    }
                    if (result > allMax)
                    {
                        allMax = result;
                    }
                }
            }

            stepSize = inStepSize;
            double roundToNearest = 1;
            if (inStepSize == 0) // auto
            {
                //double digits = Math.Round(Math.Log10((domain[1] - domain[0]))) + 1;
                //double multiplier = Math.Pow(10, digits);
                //stepSize = Math.Log10((domain[1] - domain[0]));
                //if (allMax > 1000)
                //    stepSize = 100;
                //else if (allMax > 100)
                //    stepSize = 10;
                //else if (allMax > 10)
                //    stepSize = 1;
                //else
                //    stepSize = 0.1;
                stepSize = Misc.AutoStep(domain, out roundToNearest); // <-- TODO: We can set each slice in exactly the "round to nearest" number.
            }
            else if (inStepSize < 0)                                  // fragment
            {
                stepSize = 1 / Math.Abs(inStepSize);
            }

            steps = Convert.ToInt32((domain[1] - domain[0]) / stepSize);


            for (int g = 0; g < grids.Count; g++)
            {
                //GH_Structure<GH_Curve> curves = new GH_Structure<GH_Curve>();
                Grid grid      = grids[g];
                Mesh meshToCut = grids[g].SimMesh.DuplicateMesh();
                //Mesh meshToCut = grids[g].SimMesh;

                List <double> results = ((List <GH_Number>)allResults.get_Branch(g)).Select(r => r.Value).ToList();

                if (grids[g].UseCenters == true)
                {
                    results = RTreeSolver.FindClosestWeightedValues(grids[g], results, true).ToList();
                    // ADD CONVERSION TODO:
                }



                //Rhino.RhinoApp.WriteLine($"min = {allMin}, max = {allMax}, steps = {steps}, stepsize = {stepSize}");

                if (steps <= 1 || steps > 100)
                {
                    AddRuntimeMessage(GH_RuntimeMessageLevel.Error, $"too {(steps < 4 ? "few" : "many")} steps (should be between 1 to 100)");
                    AddRuntimeMessage(GH_RuntimeMessageLevel.Error, $"min = {allMin}, max = {allMax}, steps = {steps}, stepsize = {stepSize}");
                    continue;
                }

                if (allMax == allMin)
                {
                    AddRuntimeMessage(GH_RuntimeMessageLevel.Error, $"max==min");
                    continue;
                }
                meshToCut.Normals.ComputeNormals();

                Plane cuttingPlane = new Plane(meshToCut.Vertices[0], meshToCut.FaceNormals[0]);

                //var planeOut = new Plane(plane);

                var planeBottom = new Plane(cuttingPlane);

                //List<int> belongsToWhichLayer = new List<int>();

                Vector3f normal = (Vector3f)(cuttingPlane.ZAxis);
                //AddRuntimeMessage(GH_RuntimeMessageLevel.Error, $"normal  x = {normal.X}, Y = {normal.Y}, Z = {normal.Z}");

                planeBottom.Transform(Transform.Translation(-cuttingPlane.ZAxis));

                //Moving the bottom down
                meshToCut.Translate(-normal * OFFSET);

                //Moving the vertices up
                for (int i = 0; i < results.Count; i++)
                {
                    meshToCut.Vertices[i] += (normal) * (float)SCALAR * (OFFSET + (float)results[i]);
                }

                Mesh topMesh = meshToCut.DuplicateMesh();

                tempMeshes.Add(new GH_Mesh(topMesh));

                Mesh edgeMesh = new Mesh();

                List <Point3d> ptOut = new List <Point3d>();
                Polyline[]     edges = meshToCut.GetNakedEdges();

                double totalLength = 0;

                for (int i = 0; i < edges.Length; i++)
                {
                    totalLength += edges[i].Length;
                }

                Polyline[] edgesProjected = new Polyline[edges.Length];

                Transform p = Transform.PlanarProjection(planeBottom);

                for (int i = 0; i < edges.Length; i++)
                {
                    for (int j = 0; j < edges[i].SegmentCount; j++)
                    {
                        Mesh      msh = new Mesh();
                        Point3d[] pts = new Point3d[4];

                        int id = (j == edges[i].SegmentCount - 1) ? 0 : j + 1;

                        pts[0] = new Point3d(edges[i].X[j], edges[i].Y[j], edges[i].Z[j]);
                        pts[1] = new Point3d(edges[i].X[id], edges[i].Y[id], edges[i].Z[id]);
                        pts[2] = new Point3d(pts[1]);
                        pts[3] = new Point3d(pts[0]);
                        pts[2].Transform(p);
                        pts[3].Transform(p);

                        msh.Vertices.AddVertices(pts);
                        var fc = new MeshFace(3, 2, 1, 0);
                        ptOut.AddRange(pts);
                        msh.Faces.AddFace(fc);

                        edgeMesh.Append(msh);
                    }
                }

                meshToCut.Append(edgeMesh);
                meshToCut.Weld(Math.PI);

                tempMeshes.Add(new GH_Mesh(meshToCut));

                //Transform t = Transform.Translation(new Vector3d(0, 0, inStepSize * SCALAR));

                Vector3f v = normal * (float)(stepSize.RoundTo(roundToNearest) * SCALAR);

                Transform t = Transform.Translation(v);

                //AddRuntimeMessage(GH_RuntimeMessageLevel.Error, $"Vector v = {v.X}, {v.Y}, {v.Z},   instep = ");

                Mesh meshPerArea     = new Mesh();
                MeshingParameters mp = new MeshingParameters(0);


                //double resultValue = inputMin;
                //stepSize = (inputMax - inputMin) / (float)steps;



                double currentValue = domain[0];
                int    cuttingCount = -1;

                while (currentValue <= domain[1])
                {
                    cuttingCount++;

                    if (cuttingCount == 0)
                    {
                        currentValue = domain[0];
                    }


                    if (cuttingCount == 1)
                    {
                        cuttingPlane.Translate(new Vector3d(0, 0, domain[0].RoundTo(roundToNearest)));
                        //currentValue = domain[0];
                    }

                    if (cuttingCount > 0)
                    {
                        currentValue += stepSize;
                    }



                    if (cuttingCount > 80)
                    {
                        AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "ERROR CUT THE CUTTINGCOUNT");
                        break;
                    }

                    //Rhino.RhinoApp.WriteLine($"CurrentValue = {currentValue}, cuttingCount = {cuttingCount}");


                    //var resultValue = (double)cuttingCount / steps * (allMax - allMin) + allMin;


                    //resultValue = (double)cuttingCount / steps * (domain[1] - domain[0]) + domain[0];
                    //resultValue = (double)cuttingCount / steps * (domain[1] - domain[0]) + domain[0];

                    //var resultValue = currentValue; // new

                    //Rhino.RhinoApp.WriteLine($"Cutting {cuttingCount}, {resultValue}, {currentValue}, {allMin} - {allMax}");
                    //if (resultValue < domain[0])
                    //    continue;
                    //if (resultValue > domain[1])
                    //    break;



                    Polyline[] pl = Rhino.Geometry.Intersect.Intersection.MeshPlane(meshToCut, cuttingPlane);
                    outPlanes.Add(new GH_Plane(cuttingPlane));

                    if (pl == null)
                    {
                        break;
                    }



                    Color col = gp.GetColors(new List <double>()
                    {
                        cuttingCount == 0 ? double.MinValue : currentValue.RoundTo(roundToNearest)
                    })[0];
                    //Rhino.RhinoApp.WriteLine($"Probing value {currentValue} to {col}");

                    //Mesh meshPerCut = new Mesh();

                    GH_Path path = new GH_Path(g, cuttingCount);

                    if (pl.Length > 0)
                    {
                        List <Curve> curves = new List <Curve>();
                        for (int j = 0; j < pl.Length; j++)
                        {
                            Curve curve = new PolylineCurve(pl[j]);

                            if (cuttingCount <= 0)
                            {
                                curve.Translate(normal * (float)(domain[0] - stepSize));
                            }


                            curve.Translate(-normal * (float)(currentValue * 0.95 - stepSize)); // was 0.95 nice

                            //curve.Translate(-normal * (float)allMin + normal * (float)(cuttingCount * Units.ConvertFromMeter(0.01)));



                            curves.Add(curve);                           // to create brep later

                            outCurves.Append(new GH_Curve(curve), path); // for output
                        }

                        Brep[] breps2 = Brep.CreatePlanarBreps(curves, Units.ConvertFromMeter(0.001));
                        for (int j = 0; j < breps2.Length; j++)
                        {
                            Mesh[] mesh2 = Mesh.CreateFromBrep(breps2[j], mp);

                            for (int k = 0; k < mesh2.Length; k++)
                            {
                                mesh2[k].VertexColors.CreateMonotoneMesh(col);

                                //meshPerCut.Append(mesh2[k]);

                                layeredMeshes.Append(new GH_Mesh(mesh2[k]), path);
                            }
                        }
                    }

                    //meshPerCut.VertexColors.CreateMonotoneMesh(col);



                    if (cuttingCount > 0)
                    {
                        cuttingPlane.Transform(t);
                    }
                }

                //layeredMeshes.Append(new GH_Mesh(meshPerArea), new GH_Path(g, );
            }



            //for (int j = 0; j < pl.Length; j++)
            //{
            //    Curve curve = pl[j].ToNurbsCurve();
            //    GH_Path path = new GH_Path(g, cuttingCount);

            //    outCurves.Append(new GH_Curve(curve), path);


            //    Brep[] breps = Brep.CreatePlanarBreps(curve, Units.ConvertFromMeter(0.001));

            //    if (breps == null)
            //        continue;

            //    Brep brep = breps[0];

            //    var area = AreaMassProperties.Compute(brep);
            //    if (area.Area > maxSize)
            //    {
            //        maxSize = area.Area;
            //        outerIndex = j;
            //    }
            //}

            //boundaryEdge = pl[outerIndex];


            //for (int j = 0; j < pl.Length; j++)
            //{
            //    if (j != outerIndex)
            //        holes.Add(pl[j].ToNurbsCurve());
            //}

            //Mesh mesh = null;
            //if (boundaryEdge.IsClosed)
            //{
            //    mesh = Mesh.CreatePatch(boundaryEdge, Math.PI / 2.0, null, holes, null, null, false, 0);

            //}
            //else
            //{

            //    AddRuntimeMessage(GH_RuntimeMessageLevel.Remark, $"Curve is not closed");
            //}



            //outPlanes.Add(new GH_Plane(new Plane(cuttingPlane)));



            //int curvesCount = pl.Length;
            //int[] pointsRanges = new int[curvesCount];
            //Point3d[][] pts = new Point3d[curvesCount][];

            //for (int j = 0; j < pl.Length; j++)
            //{
            //    //Mesh mesh = GreenScenario.MeshUtil.CreateMeshWithHoles(pl);
            //    //Mesh mesh = Mesh.CreateFromTessellation(points, pl, Plane.WorldXY, false);
            //    //var mesh = Mesh.CreateFromClosedPolyline(pl[j]);


            //    if (mesh == null)
            //        continue;

            //    //outCurves.Append(new GH_Curve(pl[j].ToNurbsCurve()));

            //    //List<Color> colorList = new List<Color>();

            //    ////for (int i = 0; i < mesh.Faces.Count; i++)
            //    ////{
            //    ////    colorList.Add(col);
            //    ////    colorList.Add(col);
            //    ////    colorList.Add(col);
            //    ////    if (mesh.Faces[i].IsQuad)
            //    ////        colorList.Add(col);
            //    ////}

            //    //for (int i = 0; i < mesh.Vertices.Count; i++)
            //    //{
            //    //    colorList.Add(col);
            //    //}



            //    ////mesh.VertexColors.SetColors(colorList.ToArray());
            //    //AddRuntimeMessage(GH_RuntimeMessageLevel.Remark, $"Vertices = {mesh.Vertices.Count}, colors = {mesh.VertexColors.Count}");

            //    //    mesh.VertexColors.CreateMonotoneMesh(col);
            //    //mesh.Translate(-normal * inStepSize * (float)SCALAR * cuttingCount * 0.90f);

            //    //   meshPerArea.Append(mesh);


            //    // we don't have more heights to cut off.
            //    //if (brep == null)
            //    //    continue;


            //    //for (int i = 0; i < brep.Length; i++)
            //    //{

            //    //    belongsToWhichLayer.Add(count);

            //    //}
            //    //pts.Add(polylinecrv.PointAtStart);


            //}



            // By now curves are moved to different elevations.
            //crvs = crvs;



            //Rhino.RhinoApp.WriteLine("adding a mesh");



            //oNumbers = outNumbers;



            //B = breps;
            //meshOut = mesh;


            Message = $"Cap = {(this.caps ? "on" : "off")} | Steps = {steps} | Step = {stepSize:0.0}";

            DA.SetDataTree(1, layeredMeshes);
            DA.SetDataTree(2, outCurves);
            DA.SetDataList("Planes", outPlanes);
            DA.SetDataList("TempMeshes", tempMeshes);

            #endregion layeredMesh
        }
Beispiel #21
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            Mesh           m     = DA.Fetch <Mesh>("Mesh");
            List <Point3d> p     = DA.FetchList <Point3d>("Points");
            int            n     = DA.Fetch <int>("Smooth");
            int            prune = DA.Fetch <int>("Prune");

            if (m != null)
            {
                DataTree <Line>    dt;
                DataTree <Point3d> naked;
                var c = NGonsCore.MeshSkeleton.GetCurves(m, p, out dt, out naked);



                //Smooth
                foreach (Polyline curve in c)
                {
                    Point3d start = new Point3d(curve[0]);

                    for (int i = 0; i < n; i++)
                    {
                        curve.Smooth(0.1);

                        if (curve[0].DistanceToSquared(curve.Last()) < 0.001)
                        {
                            curve[0] = start;
                            curve[curve.Count - 1] = start;
                        }
                    }
                }


                //Prune


                List <Polyline> c_ = new List <Polyline>();
                foreach (Polyline cc in c)
                {
                    c_.Add(new Polyline(cc));
                }



                for (int y = 0; y < prune; y++)
                {
                    List <Line> lines = new List <Line>();

                    foreach (Polyline cc in c_)
                    {
                        lines.Add(new Line(cc.First(), cc.Last()));
                    }

                    List <Polyline> curves = new List <Polyline>();

                    Tuple <Point3d[], List <string>, List <int>, List <int>, List <int>, DataTree <int> > data = NGonsCore.Graphs.LineGraph.GetGraphData(lines);
                    for (int i = 0; i < data.Item3.Count; i++)
                    {
                        if (data.Item6.Branch(data.Item3[i]).Count != 1 && data.Item6.Branch(data.Item4[i]).Count != 1)
                        {
                            curves.Add(new Polyline(c_[i]));
                        }
                    }
                    c_ = curves;
                }
                //A = curves;

                DA.SetDataList(0, c_);
                DA.SetDataTree(1, dt);
                DA.SetDataTree(2, naked);

                List <Point3d> ptAll = new List <Point3d>();
                ptAll.AddRange(naked.AllData());

                foreach (var cc in c_)
                {
                    ptAll.Add(cc[0]);
                    ptAll.Add(cc[cc.Count - 1]);
                }

                foreach (var cc in dt.AllData())
                {
                    ptAll.Add(cc.From);
                    ptAll.Add(cc.To);
                }
                DA.SetDataList(3, ptAll);
            }
        }
Beispiel #22
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            try {
                ////////////////////////////////////////////////////////////////////
                //Inputs Grasshopper
                Mesh M = DA.Fetch <Mesh>("Mesh");
                DataTree <Polyline> PanelOutlines = DA.FetchTree <GH_Curve>("Panels").ToPolylineDT();

                //Create joints
                DataTree <Vector3d> order = DA.FetchTree <GH_Vector>("InsertionVec").ToVectorDT();


                ////////////////////////////////////////////////////////////////////
                //      Insertion vectors

                //DataTree<Vector3d> EV = M.insertionVectors(Center, EVec);

                bool Center = DA.Fetch <bool>("Center");
                if (order.DataCount == 0)
                {
                    order = M.insertionVectorsJoints(Center, null);//joints
                }
                DataTree <Vector3d> EV = order;
                ////////////////////////////////////////////////////////////////////

                List <Point3d> twoJoints        = DA.FetchList <Point3d>("TwoJoints");
                List <Line>    extendedJoints   = DA.FetchList <Line>("ExtendedJoints");
                List <Line>    deeperCutsJoints = DA.FetchList <Line>("DeeperCutsJoints");

                List <JointsVDAInputs> joints = GetJoints(order, M, twoJoints, extendedJoints, deeperCutsJoints);

                if (order.DataCount != 0)
                {
                    order = M.insertionVectorsJoints(Center, joints);//joints
                }
                bool Finger = DA.Fetch <bool>("Finger");
                DataTree <Polyline> CChamfer = new DataTree <Polyline>();
                int           iterations     = DA.Fetch <int>("Iterations");
                List <int>    sequence       = DA.FetchList <int>("Sequence");
                List <double> textSize       = DA.FetchList <double>("TextScale");


                if (textSize.Count != 8)
                {
                    textSize = new List <double> {
                        30, 12, 15, 0.5, 0.6, 0, 1, 5
                    }
                }
                ;

                DataTree <Panel> PanelGroups = DA.FetchTree <GH_Curve>("Panels").ToPanelsDT();
                DataTree <Panel> JointGroups = new DataTree <Panel>();

                ////////////////////////////////////////////////////////////////////


                ////////////////////////////////////////////////////////////////////

                int[][]                 tv      = M.GetNGonsTopoBoundaries();
                int[][]                 fe      = M.GetNGonFacesEdges(tv);
                HashSet <int>           e       = M.GetAllNGonEdges(tv);
                Dictionary <int, int[]> efDict  = M.GetFE(e, false);
                Point3d[]               centers = M.GetNGonCenters();

                Vector3d[] fn = M.GetNgonNormals();
                //int[][] ef = M.GetNgonsConnectedToNGonsEdges(e, true);
                ////////////////////////////////////////////////////////////////////


                DataTree <Polyline> diagonalConnections = new DataTree <Polyline>();
                //DataTree<Polyline> recJoints = new DataTree<Polyline>();

                //Iterate insertion edges
                Dictionary <int, int> meshEdgeDict = new Dictionary <int, int>();
                for (int i = 0; i < EV.BranchCount; i++)  // EV.BranchCount


                {
                    int meshEdge = EV.Path(i).Indices[0];//mesh edge is used as dataTree branch

                    meshEdgeDict.Add(meshEdge, i);

                    if (efDict[meshEdge].Length != 2)
                    {
                        continue;
                    }
                    int f0 = efDict[meshEdge][0];
                    int f1 = efDict[meshEdge][1];

                    //Divide line into points and create a planes on these point, following insertion direction and average face normal
                    // Point3d[] pts = M.TopologyEdges.EdgeLine(meshEdge).InterpolateLine(divisions, false);
                    Point3d[] pts = M.TopologyEdges.EdgeLine(meshEdge).InterpolateLine(joints[i].divisions, false);

                    Vector3d avNormal = fn[f0] + fn[f1];
                    //Vector3d jointVector = Vector3d.CrossProduct(M.TopologyEdges.EdgeLine(meshEdge).Direction, avNormal);
                    //EV.Branch(EV.Path(i))[0] = jointVector;

                    for (int j = 0; j < pts.Length; j++)
                    {
                        //(new Line(pts[j], pts[j]+ avNormal*40)).Bake();
                        //JointGroups.Add(new Panel(new Plane(pts[j], EV.Branch(EV.Path(i))[0].UnitVector(), M.GetMeshEdgePerpDir(meshEdge))), EV.Path(i));
                        Plane plane = new Plane(pts[j], avNormal, EV.Branch(EV.Path(i))[0].UnitVector());
                        // Plane plane = new Plane(pts[j],EV.Branch(EV.Path(i))[0].UnitVector(), M.GetMeshEdgePerpDir(meshEdge));

                        plane = plane.Switch("YX");
                        JointGroups.Add(new Panel(plane), EV.Path(i));
                        //plane.Bake(40);
                    }


                    //Construct joint outlines from planes
                    //Iterate number of joints per edge
                    for (int j = 0; j < pts.Length; j++)
                    {
                        JointGroups.Branch(EV.Path(i))[j].planeOffset0 = JointGroups.Branch(EV.Path(i))[j].plane.MovePlanebyAxis(joints[i].thickness * 0.5);  //offset planes

                        JointGroups.Branch(EV.Path(i))[j].planeOffset1 = JointGroups.Branch(EV.Path(i))[j].plane.MovePlanebyAxis(-joints[i].thickness * 0.5); //offset planes
                        JointGroups.Branch(EV.Path(i))[j].planeRot     = new Plane(pts[j], Vector3d.CrossProduct(EV.Branch(EV.Path(i))[0].UnitVector(), M.GetMeshEdgePerpDir(meshEdge)), M.GetMeshEdgePerpDir(meshEdge));
                        int[] ngons     = M.GetEdgeNgons(meshEdge);
                        Plane tempPlane = JointGroups.Branch(EV.Path(i))[j].planeRot.MovePlanebyAxis(joints[i].length);
                        int   sign      = tempPlane.Origin.DistanceToSquared(centers[ngons[0]]) < tempPlane.Origin.DistanceToSquared(centers[ngons[1]]) ? 1 : -1;

                        JointGroups.Branch(EV.Path(i))[j].planeRotOffset0 = JointGroups.Branch(EV.Path(i))[j].planeRot.MovePlanebyAxis(joints[i].length * sign);  //offset planes
                        JointGroups.Branch(EV.Path(i))[j].planeRotOffset1 = JointGroups.Branch(EV.Path(i))[j].planeRot.MovePlanebyAxis(-joints[i].length * sign); //offset plane
                        JointGroups.Branch(EV.Path(i))[j].planeEdge       = new Plane(pts[j], M.TopologyEdges.EdgeLine(meshEdge).Direction, M.GetMeshEdgePerpDir(meshEdge));

                        List <Plane> planesF0 = new List <Plane>();
                        List <Plane> planesF1 = new List <Plane>();
                        for (int k = 0; k < PanelGroups.Branch(f0).Count; k++)
                        {
                            planesF0.Add(PanelGroups.Branch(f0)[k].plane);
                        }
                        for (int k = 0; k < PanelGroups.Branch(f1).Count; k++)
                        {
                            planesF1.Add(PanelGroups.Branch(f1)[k].plane);
                        }



                        JointGroups.Branch(EV.Path(i))[j].planeF0 = PlaneUtil.AveragePlaneOrigin(planesF0);
                        JointGroups.Branch(EV.Path(i))[j].planeF1 = PlaneUtil.AveragePlaneOrigin(planesF1);

                        //JointGroups.Branch(EV.Path(i))[j].planeF0.MovePlanebyAxis(joints[i].height).Bake(40);
                        //JointGroups.Branch(EV.Path(i))[j].planeF1.MovePlanebyAxis(joints[i].height).Bake(40);

                        List <Plane> jointPlaneLoop = new List <Plane> {
                            JointGroups.Branch(EV.Path(i))[j].planeRotOffset0,
                            JointGroups.Branch(EV.Path(i))[j].planeF0.MovePlanebyAxis(joints[i].height),
                            JointGroups.Branch(EV.Path(i))[j].planeEdge,
                            JointGroups.Branch(EV.Path(i))[j].planeF1.MovePlanebyAxis(joints[i].height),                                   //3
                            JointGroups.Branch(EV.Path(i))[j].planeRotOffset1,
                            JointGroups.Branch(EV.Path(i))[j].planeF1.MovePlanebyAxis(-joints[i].height),                                  //5
                            JointGroups.Branch(EV.Path(i))[j].planeEdge,
                            JointGroups.Branch(EV.Path(i))[j].planeF0.MovePlanebyAxis(-joints[i].height),
                        };

                        //Rhino.RhinoDoc.ActiveDoc.Objects.AddRectangle(new Rectangle3d(JointGroups.Branch(EV.Path(i))[j].planeF1, new Interval(-20, 20), new Interval(-20, 20)));
                        //Rhino.RhinoDoc.ActiveDoc.Objects.AddRectangle(new Rectangle3d(JointGroups.Branch(EV.Path(i))[j].planeF1, new Interval(-20, 20), new Interval(-20, 20)));

                        JointGroups.Branch(EV.Path(i))[j].contourNoJoints[0] = PolylineUtil.PolylineFromPlanes(JointGroups.Branch(EV.Path(i))[j].planeOffset0, jointPlaneLoop);
                        JointGroups.Branch(EV.Path(i))[j].contourNoJoints[1] = PolylineUtil.PolylineFromPlanes(JointGroups.Branch(EV.Path(i))[j].planeOffset1, jointPlaneLoop);
                        JointGroups.Branch(EV.Path(i))[j].contour[0]         = new Polyline(JointGroups.Branch(EV.Path(i))[j].contourNoJoints[0]);
                        JointGroups.Branch(EV.Path(i))[j].contour[1]         = new Polyline(JointGroups.Branch(EV.Path(i))[j].contourNoJoints[1]);
                        //JointGroups.Branch(EV.Path(i))[j].contour[0].Bake();
                    }


                    //Construct Cuts
                    //Iterate number of joints per edge
                    for (int j = 0; j < pts.Length; j++)
                    {
                        int localMeshEdgeF0 = Array.IndexOf(fe[f0], meshEdge);
                        int localMeshEdgeF1 = Array.IndexOf(fe[f1], meshEdge);



                        //Iterate number of panels and create cuts
                        for (int k = 0; k < PanelGroups.Branch(f0).Count; k++)
                        {
                            Panel jointPanel = JointGroups.Branch(EV.Path(i))[j];
                            //Rhino.RhinoApp.WriteLine(jointPanel.contourNoJoints[0].Count.ToString());

                            jointPanel.id = f0.ToString() + "-" + f1.ToString();

                            if (pts.Length > 1)
                            {
                                jointPanel.id += "-" + j.ToString();
                            }

                            PanelGroups.Branch(f0)[k].CreateCut(localMeshEdgeF0, JointGroups.Branch(EV.Path(i))[j].planeOffset0, JointGroups.Branch(EV.Path(i))[j].planeOffset1, joints[i].length, ref jointPanel, false);//, ref neiPanel, ref jointPanel);
                            //PanelGroups.Branch(f1)[k].CreateCut(localMeshEdgeF1, JointGroups.Branch(EV.Path(i))[j].planeOffset0, JointGroups.Branch(EV.Path(i))[j].planeOffset1, joints[i].length, ref jointPanel, false);//, ref neiPanel, ref jointPanel);

                            JointGroups.Branch(EV.Path(i))[j] = jointPanel;
                        }


                        //Iterate number of panels and create cuts
                        for (int k = 0; k < PanelGroups.Branch(f1).Count; k++)
                        {
                            Panel jointPanel = JointGroups.Branch(EV.Path(i))[j];

                            jointPanel.id = f0.ToString() + "-" + f1.ToString();

                            if (pts.Length > 1)
                            {
                                jointPanel.id += "-" + j.ToString();
                            }

                            //PanelGroups.Branch(f0)[k].CreateCut(localMeshEdgeF0, JointGroups.Branch(EV.Path(i))[j].planeOffset0, JointGroups.Branch(EV.Path(i))[j].planeOffset1, joints[i].length, ref jointPanel, false);//, ref neiPanel, ref jointPanel);
                            PanelGroups.Branch(f1)[k].CreateCut(localMeshEdgeF1, JointGroups.Branch(EV.Path(i))[j].planeOffset0, JointGroups.Branch(EV.Path(i))[j].planeOffset1, joints[i].length, ref jointPanel, false);//, ref neiPanel, ref jointPanel);

                            JointGroups.Branch(EV.Path(i))[j] = jointPanel;
                        }
                    }
                }


                for (int i = 0; i < JointGroups.BranchCount; i++)
                {
                    for (int j = 0; j < JointGroups.Branch(i).Count; j++)
                    {
                        if (joints[i].custom == 0)
                        {
                            if (joints[i].custom > 0)
                            {
                                JointGroups.Branch(i)[j].ChangeJoint(joints[i].custom, 0, joints[i].cutExtend, joints[i].addExtend);
                            }
                            else if (joints[i].custom < 0)
                            {
                                JointGroups.Branch(i)[j].ChangeJoint(joints[i].custom, 1, joints[i].cutExtend, joints[i].addExtend);
                            }
                        }
                    }
                }



                ////////////////////////Output
                var dtPlates       = new DataTree <Polyline>();
                var dtJoints       = new DataTree <Polyline>();
                var dtPlatesMid    = new DataTree <Polyline>();
                var dtJointsMid    = new DataTree <Polyline>();
                var dtPlatesPlanes = new DataTree <Plane>();
                var dtJointsPlanes = new DataTree <Plane>();
                var dtPlatesTxt    = new DataTree <Curve>();
                var dtJointsTxt    = new DataTree <Curve>();

                var dtPlatesLast       = new DataTree <Polyline>();
                var dtJointsLast       = new DataTree <Polyline>();
                var dtPlatesMidLast    = new DataTree <Polyline>();
                var dtJointsMidLast    = new DataTree <Polyline>();
                var dtPlatesPlanesLast = new DataTree <Plane>();
                var dtJointsPlanesLast = new DataTree <Plane>();
                var dtPlatesTxtLast    = new DataTree <Curve>();
                var dtJointsTxtLast    = new DataTree <Curve>();

                HashSet <int> jointSequenceTemp = new HashSet <int>();
                HashSet <int> jointSequence     = new HashSet <int>();

                HashSet <int> jointSequenceLast = new HashSet <int>();
                int           last = Math.Min(iterations, PanelGroups.BranchCount);
                int           prev = Math.Max(0, last - (int)textSize[6]);



                for (int i = 0; i < last; i++)  //Math.Min(iterations, sequence.Count) PanelGroups.BranchCount

                {
                    for (int j = 0; j < fe[i].Length; j++)
                    {
                        bool seq = jointSequenceTemp.Add(fe[i][j]);

                        if (i >= prev)
                        {
                            if (seq)
                            {
                                jointSequenceLast.Add(fe[i][j]);
                            }
                            else
                            {
                                jointSequence.Add(fe[i][j]);
                            }
                        }
                        else
                        {
                            jointSequence.Add(fe[i][j]);
                        }
                    }

                    for (int j = 0; j < PanelGroups.Branch(i).Count; j++)
                    {
                        if (i >= prev)
                        {
                            dtPlatesLast.Add(PanelGroups.Branch(i)[j].contour[0], new GH_Path(i, j));
                            dtPlatesLast.Add(PanelGroups.Branch(i)[j].contour[1], new GH_Path(i, j));
                            dtPlatesMidLast.Add(PanelGroups.Branch(i)[j].MidContour(), new GH_Path(i, j));
                        }
                        else
                        {
                            dtPlates.Add(PanelGroups.Branch(i)[j].contour[0], new GH_Path(i, j));
                            dtPlates.Add(PanelGroups.Branch(i)[j].contour[1], new GH_Path(i, j));
                            dtPlatesMid.Add(PanelGroups.Branch(i)[j].MidContour(), new GH_Path(i, j));
                        }



                        Plane textPlane = PanelGroups.Branch(i)[j].planeOffset0;
                        textPlane.Flip();

                        if (j > 0)
                        {
                            textPlane = PanelGroups.Branch(i)[j].planeOffset1;
                        }



                        if (i >= prev)
                        {
                            dtPlatesPlanesLast.Add(textPlane, new GH_Path(i, j));
                        }
                        else
                        {
                            dtPlatesPlanes.Add(textPlane, new GH_Path(i, j));
                        }


                        string text   = i.ToString() + "-" + j.ToString();
                        var    txtCrv = Typewriter.Regular.Write(text, textPlane, textSize[0]);


                        if (i >= prev)
                        {
                            dtPlatesTxtLast.AddRange(txtCrv, new GH_Path(i, j));
                        }
                        else
                        {
                            dtPlatesTxt.AddRange(txtCrv, new GH_Path(i, j));
                        }


                        var a = PanelGroups.Branch(i)[j];

                        Line[] segments = PanelGroups.Branch(i)[j].contourNoJoints[Math.Min(1, j)].GetSegments();


                        int counter = 0;
                        foreach (Line l in segments)
                        {
                            int meshEdge = fe[i][counter];

                            int neiF = M.GetOppositeNgon(meshEdge, i);


                            //Adjacent face plane
                            Point3d  origin = l.PointAt(textSize[3]);
                            Vector3d xaxis  = l.Direction;
                            Vector3d yaxis  = l.Direction;
                            origin.Transform(Rhino.Geometry.Transform.Scale(textPlane.Origin, textSize[4]));
                            yaxis.Rotate(Math.PI * 0.5, textPlane.ZAxis);
                            Plane ePlane = new Plane(origin, xaxis, yaxis);

                            var txtCrvF = Typewriter.Regular.Write(neiF.ToString(), ePlane, textSize[2]);


                            if (i >= prev)
                            {
                                dtPlatesTxtLast.AddRange(txtCrvF, new GH_Path(i, j));
                            }
                            else
                            {
                                dtPlatesTxt.AddRange(txtCrvF, new GH_Path(i, j));
                            }



                            //Mesh edge direction
                            Line meshEdgeLine = M.TopologyEdges.EdgeLine(meshEdge);
                            meshEdgeLine.Transform(Rhino.Geometry.Transform.Scale(meshEdgeLine.PointAt(0.5), textSize[4]));
                            meshEdgeLine.Transform(Rhino.Geometry.Transform.Scale(textPlane.Origin, textSize[4]));
                            //meshEdgeLine.Extend(-textSize[4], -textSize[4]);


                            Plane e0Plane = new Plane(ePlane.ClosestPoint(meshEdgeLine.From), xaxis, yaxis);
                            Plane e1Plane = new Plane(ePlane.ClosestPoint(meshEdgeLine.To), xaxis, yaxis);

                            var txtCrvF0 = Typewriter.Regular.Write("I", e0Plane, textSize[2]);


                            if (i >= prev)
                            {
                                dtPlatesTxtLast.AddRange(txtCrvF0, new GH_Path(i, j));
                            }
                            else
                            {
                                dtPlatesTxt.AddRange(txtCrvF0, new GH_Path(i, j));
                            }

                            var txtCrvF1 = Typewriter.Regular.Write("II", e1Plane, textSize[2]);


                            if (i >= prev)
                            {
                                dtPlatesTxtLast.AddRange(txtCrvF1, new GH_Path(i, j));
                            }
                            else
                            {
                                dtPlatesTxt.AddRange(txtCrvF1, new GH_Path(i, j));
                            }


                            counter++;
                            //
                        }
                    }
                }

                DataTree <Vector3d> insertionVectors = new DataTree <Vector3d>();


                foreach (int meshEdge in jointSequence)
                {
                    if (!meshEdgeDict.ContainsKey(meshEdge))
                    {
                        continue;
                    }
                    int i = meshEdgeDict[meshEdge];



                    for (int j = 0; j < JointGroups.Branch(i).Count; j++)
                    {
                        GH_Path path = new GH_Path(meshEdge, j);

                        insertionVectors.Add(JointGroups.Branch(i)[j].planeOffset0.XAxis, path);


                        dtJoints.Add(JointGroups.Branch(i)[j].contour[0], path);
                        dtJoints.Add(JointGroups.Branch(i)[j].contour[1], path);
                        dtJointsMid.Add(JointGroups.Branch(i)[j].MidContour(), path);
                        dtJointsPlanes.Add(JointGroups.Branch(i)[j].planeOffset0, path);

                        Plane planet = new Plane(JointGroups.Branch(i)[j].planeOffset0.Origin + JointGroups.Branch(i)[j].planeOffset0.YAxis * textSize[5], JointGroups.Branch(i)[j].planeOffset0.XAxis, JointGroups.Branch(i)[j].planeOffset0.YAxis);



                        string text   = JointGroups.Branch(i)[j].id;
                        var    txtCrv = Typewriter.Regular.Write(text, planet, textSize[1]);
                        dtJointsTxt.AddRange(txtCrv, path);
                    }
                }



                foreach (int meshEdge in jointSequenceLast)
                {
                    if (!meshEdgeDict.ContainsKey(meshEdge))
                    {
                        continue;
                    }
                    int i = meshEdgeDict[meshEdge];



                    for (int j = 0; j < JointGroups.Branch(i).Count; j++)
                    {
                        dtJointsLast.Add(JointGroups.Branch(i)[j].contour[0], new GH_Path(meshEdge, j));
                        dtJointsLast.Add(JointGroups.Branch(i)[j].contour[1], new GH_Path(meshEdge, j));
                        dtJointsMidLast.Add(JointGroups.Branch(i)[j].MidContour(), new GH_Path(meshEdge, j));

                        dtJointsPlanesLast.Add(JointGroups.Branch(i)[j].planeOffset0, new GH_Path(meshEdge, j));

                        Plane planet = new Plane(JointGroups.Branch(i)[j].planeOffset0.Origin + JointGroups.Branch(i)[j].planeOffset0.YAxis * textSize[5], JointGroups.Branch(i)[j].planeOffset0.XAxis, JointGroups.Branch(i)[j].planeOffset0.YAxis);


                        string text   = JointGroups.Branch(i)[j].id;
                        var    txtCrv = Typewriter.Regular.Write(text, planet, textSize[1]);
                        dtJointsTxtLast.AddRange(txtCrv, new GH_Path(meshEdge, j));
                    }
                }


                DA.SetDataTree(0, dtPlates);
                DA.SetDataTree(1, dtJoints);

                DA.SetDataTree(2, dtPlatesMid);
                DA.SetDataTree(3, dtJointsMid);

                DA.SetDataTree(4, dtPlatesPlanes);
                DA.SetDataTree(5, dtJointsPlanes);

                DA.SetDataTree(6, dtPlatesTxt);
                DA.SetDataTree(7, dtJointsTxt);



                DA.SetDataTree(8, dtPlatesLast);
                DA.SetDataTree(9, dtJointsLast);

                DA.SetDataTree(10, dtPlatesMidLast);
                DA.SetDataTree(11, dtJointsMidLast);

                DA.SetDataTree(12, dtPlatesPlanesLast);
                DA.SetDataTree(13, dtJointsPlanesLast);

                DA.SetDataTree(14, dtPlatesTxtLast);
                DA.SetDataTree(15, dtJointsTxtLast);
            } catch (Exception e) {
                Rhino.RhinoApp.WriteLine(e.ToString());
            }
        }
Beispiel #23
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            // SET ALL INPUT PARAMETERS
              List<Curve> curves = DA.FetchList<Curve>("Polylines");
              double dist = DA.Fetch<double>("Distance");
              Plane pln = DA.Fetch<Plane>("Plane");
              double tolerance = DA.Fetch<double>("Tolerance");
              List<Polyline3D.OpenFilletType> openType = DA.FetchList<int>("OpenFillet").Cast<Polyline3D.OpenFilletType>().ToList();
              if (openType == null || openType.Count == 0) {
            openType = new List<Polyline3D.OpenFilletType> { Polyline3D.OpenFilletType.Square };
              }
              double miter = DA.Fetch<double> ("Miter");

              List<Polyline3D.ClosedFilletType> closedType = DA.FetchList<int>("ClosedFillet").Cast<Polyline3D.ClosedFilletType>().ToList();

              IEnumerable<Polyline> polylines = Polyline3D.ConvertCurvesToPolyline(curves);

              if (pln.Equals(default(Plane)))
              {
            pln = polylines.First().FitPlane();
              }

              // set default fillet type.
              if (closedType == null || closedType.Count == 0) {
            closedType = new List<Polyline3D.ClosedFilletType> { Polyline3D.ClosedFilletType.Square };
              }

              if (curves.Count == 0) {
            return;
              }

              List<List<Polyline>> outside;
              List<List<Polyline>> holes;
              Polyline3D.Offset(polylines, openType, closedType, pln, tolerance, new List<double> { dist }, miter, 0.25, out outside, out holes);

              // OUTPUT LOGIC
              DA.SetDataList("Contour", outside.First());
              DA.SetDataList("Holes", holes.First());
        }
Beispiel #24
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            var gridSize   = Units.ConvertFromMeter(DA.Fetch <double>("GridSize [m]"));
            var edgeOffset = Units.ConvertFromMeter(DA.Fetch <double>("Edge Offset [m]"));

            var offset     = Units.ConvertFromMeter(DA.Fetch <double>("Vertical Offset [m]"));
            var useCenters = DA.Fetch <bool>("IsoCurves");
            var geometries = DA.FetchList <IGH_GeometricGoo>("Geometry");
            var goLarge    = DA.Fetch <bool>("GoLarge");

            DataTree <Point3d> centers = new DataTree <Point3d>();
            List <Grid>        myGrids = new List <Grid>();
            List <Mesh>        meshes  = new List <Mesh>();

            //List<Mesh> inMeshes = new List<Mesh>();
            List <Brep>  inBreps = new List <Brep>();
            List <Curve> inCrvs  = new List <Curve>();

            //string msg = "";
            useCenters = !useCenters;

            for (int i = 0; i < geometries.Count; i++)
            {
                if (geometries[i] == null)
                {
                    continue;
                }

                IGH_GeometricGoo shape = geometries[i].DuplicateGeometry();

                shape.Transform(Transform.Translation(0, 0, offset));

                if (shape is Mesh || shape is GH_Mesh)
                {
                    //inMeshes.Add(GH_Convert.ToGeometryBase(shape) as Mesh);
                    myGrids.Add(new Grid(GH_Convert.ToGeometryBase(shape) as Mesh, useCenters: useCenters));
                }
                else if (shape is Brep || shape is GH_Brep)
                {
                    //myGrids.Add(new Grid(GH_Convert.ToGeometryBase(shape) as Brep, gridSize, useCenters: useCenters));
                    inBreps.Add(GH_Convert.ToGeometryBase(shape) as Brep);
                }
                else if (shape is Curve || shape is GH_Curve)
                {
                    //myGrids.Add(new Grid(GH_Convert.ToGeometryBase(shape) as Curve, gridSize, useCenters: useCenters));
                    inCrvs.Add(GH_Convert.ToGeometryBase(shape) as Curve);
                }
                else
                {
                    myGrids.Add(null);
                    meshes.Add(null);
                    AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "error on an input grid");
                }
            }

            List <Brep> breps = InputGeometries.CurvesToOffsetBreps(inCrvs, edgeOffset) ?? new List <Brep>();

            breps.AddRange(InputGeometries.BrepsToOffsetBreps(inBreps, edgeOffset));


            for (int i = 0; i < breps.Count; i++)
            {
                myGrids.Add(new Grid(breps[i], gridSize, useCenters: useCenters, goLarge));
            }

            for (int i = 0; i < myGrids.Count; i++)
            {
                meshes.Add(myGrids[i].SimMesh);
                GH_Path p = new GH_Path(i);
                centers.AddRange(myGrids[i].SimPoints, p);
            }


            DA.SetDataList(0, myGrids);
            DA.SetDataList(1, meshes);
            DA.SetDataTree(2, centers);
            //DA.SetData(3, msg);
        }
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            // SET ALL INPUT PARAMETERS
              Polyline plA = default(Polyline);
              if (!Polyline3D.ConvertCurveToPolyline(DA.Fetch<Curve>("A"), out plA))
              {
            this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Unable to convert to polyline from curve");
            return;
              }
              Polyline plB = default(Polyline);
              if (!Polyline3D.ConvertCurveToPolyline(DA.Fetch<Curve>("B"), out plB)) {
            this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Unable to convert to polyline from curve");
            return;
              }

              Plane pln = DA.Fetch<Plane>("Plane");
              double tolerance = DA.Fetch<double>("Tolerance");
              if (pln.Equals(default(Plane)))
              {
            pln = plA.FitPlane();
              }

              Point3d ptCenter = new Box(pln, plB).Center;

              List<Polyline> outCurves = new List<Polyline>();
              List<Polyline> outDisplacedCurves = new List<Polyline>();
              foreach (List<IntPoint> path in ClipperLib.Clipper.MinkowskiSum(plA.ToPath2D(pln, tolerance), plB.ToPath2D(pln, tolerance), true)) {
            Polyline plSum = path.ToPolyline(pln, tolerance, true);
            //Polyline plDisplacedSum = new Polyline(plSum);
            //plDisplacedSum.Transform(Transform.Translation(-new Vector3d(ptCenter)));
            outCurves.Add(plSum);
            //outDisplacedCurves.Add(plDisplacedSum);
              }

              // OUTPUT LOGIC
              DA.SetDataList("Sum", outCurves);
              DA.SetDataList("DisplacedSum", outCurves);
        }
Beispiel #26
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            Mesh       mesh = DA.Fetch <Mesh>("Mesh");
            string     v    = DA.Fetch <string>("Start");
            List <int> o    = DA.FetchList <int>("Sequence");

            v = Math.Min(Convert.ToInt32(v), mesh.Ngons.Count - 1).ToString();


            var        ve    = NGonsCore.Graphs.UndirectedGraphBfsRhino.MeshBFS(mesh, v);
            List <int> order = ve.Item1[0];

            DA.SetDataTree(0, NGonsCore.GrasshopperUtil.IE2(ve.Item1));
            DA.SetDataTree(1, NGonsCore.GrasshopperUtil.IE3(ve.Item2));



            if (mesh.Ngons.Count == o.Count)
            {
                order = o;
            }



            int S = mesh.Ngons.Count;//stop
            //Insertion vectors
            DataTree <int> N = SequenceNeighbours(mesh, order, S);

            //FN = N;
            //O_ = O;
            //Edge Vectors
            int[][]                 tv     = mesh.GetNGonsTopoBoundaries();
            int[][]                 fe     = mesh.GetNGonFacesEdges(tv);
            HashSet <int>           e      = mesh.GetAllNGonEdges(tv);
            Dictionary <int, int[]> efDict = mesh.GetFE(e, false);

            Polyline[] outlines = mesh.GetPolylines();



            //Dictionary<int, Vector3d> edgeVectors = new Dictionary<int, Vector3d> ();
            DataTree <Vector3d> edgeVectors = new DataTree <Vector3d>();


            for (int i = 0; (i < S && i < mesh.Ngons.Count); i++)
            {
                /////////////
                // Properties
                /////////////
                //Current path and face
                GH_Path p = new GH_Path(i);
                int     f = order[i];//O[i];
                if (!N.PathExists(p))
                {
                    continue;                                        //If no connectio nskip
                }
                HashSet <int> fadj = new HashSet <int>(N.Branch(p)); //adjacency list


                /////////////
                // Solution
                /////////////
                //Iterate mesh edges
                //Get connected faces
                //Check if they are in adjacency list
                //The order thoses ids

                List <int> NotOrderedEdges = new List <int>();
                for (int j = 0; j < fe[f].Length; j++)
                {
                    int[] facePair = efDict[fe[f][j]];//get face pair
                    if (facePair.Length == 1)
                    {
                        continue;                      //if naked skip
                    }
                    if (fadj.Contains(facePair[0]) || fadj.Contains(facePair[1]))
                    {
                        NotOrderedEdges.Add(j);                                                          //if edge face are in fadj
                    }
                }

                List <int> orderedEdges = SortIntegers(NotOrderedEdges, fe[f].Length);


                //Collect lines for Insertion Vector
                List <Line> el = new List <Line>();
                //Line[] lines = outlines[f].GetSegments();
                foreach (int j in orderedEdges)
                {
                    el.Add(outlines[f].SegmentAt(j));//el.Add(M.TopologyEdges.EdgeLine(fe[f][j]));
                }

                //Create Insertion Vector
                Vector3d vec = NGonsCore.VectorUtil.BisectorVector(el, outlines[f].AverageNormal(), false);

                foreach (int j in orderedEdges)
                {
                    //edgeVectors.Add(fe[f][j],vec);
                    edgeVectors.Add(vec, new GH_Path(fe[f][j]));
                }


                //A = el;
                //B = vec;
                //C = outlines[f].AverageNormal();
            }

            //EV = edgeVectors;
            DA.SetDataTree(2, edgeVectors);
            //Get current face edges
            //Take edge only connected in current set
        }
Beispiel #27
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            try {
                ////////////////////////////////////////////////////////////////////
                //Inputs Grasshopper
                Mesh M = DA.Fetch <Mesh>("Mesh");
                DataTree <Polyline> PanelOutlines = DA.FetchTree <GH_Curve>("Panels").ToPolylineDT();
                DataTree <Vector3d> EVec          = DA.FetchTree <GH_Vector>("EdgeVectors").ToDT();
                int    D      = DA.Fetch <int>("JointDiv");
                double L      = DA.Fetch <double>("JointLen");
                double H      = DA.Fetch <double>("JointHei");
                double W      = DA.Fetch <double>("JointThi");
                bool   Center = DA.Fetch <bool>("Center");
                bool   Finger = DA.Fetch <bool>("Finger");
                double Custom = DA.Fetch <double>("Custom");
                DataTree <Polyline> CChamfer = new DataTree <Polyline>();
                int           iterations     = DA.Fetch <int>("Iterations");
                List <int>    sequence       = DA.FetchList <int>("Sequence");
                List <double> textSize       = DA.FetchList <double>("TextScale");

                if (textSize.Count < 6)
                {
                    textSize = new List <double> {
                        20, 10, 10, 0.5, 0.75, 10
                    }
                }
                ;

                DataTree <Panel> PanelGroups = DA.FetchTree <GH_Curve>("Panels").ToPanelsDT();
                DataTree <Panel> JointGroups = new DataTree <Panel>();
                ////////////////////////////////////////////////////////////////////


                ////////////////////////////////////////////////////////////////////
                //Inputs Local
                int    divisions   = Math.Max(1, D);
                double jointLength = L;//Math.Max(0.1, L);
                double height      = Math.Max(0.1, H);
                double width       = Math.Max(0.1, W);

                int[][]                 tv      = M.GetNGonsTopoBoundaries();
                int[][]                 fe      = M.GetNGonFacesEdges(tv);
                HashSet <int>           e       = M.GetAllNGonEdges(tv);
                Dictionary <int, int[]> efDict  = M.GetFE(e, false);
                Point3d[]               centers = M.GetNGonCenters();
                ////////////////////////////////////////////////////////////////////

                ////////////////////////////////////////////////////////////////////
                //      Insertion vectors
                DataTree <Vector3d> EV = M.insertionVectors(Center, EVec);
                ////////////////////////////////////////////////////////////////////

                DataTree <Polyline> diagonalConnections = new DataTree <Polyline>();
                //DataTree<Polyline> recJoints = new DataTree<Polyline>();

                //Iterate insertion edges
                Dictionary <int, int> meshEdgeDict = new Dictionary <int, int>();
                for (int i = 0; i < EV.BranchCount; i++)  // EV.BranchCount


                {
                    int meshEdge = EV.Path(i).Indices[0];//mesh edge is used as dataTree branch

                    meshEdgeDict.Add(meshEdge, i);

                    if (efDict[meshEdge].Length != 2)
                    {
                        continue;
                    }
                    int f0 = efDict[meshEdge][0];
                    int f1 = efDict[meshEdge][1];

                    //Divide line into points and create a planes on these point, following insertion direction and average face normal
                    Point3d[] pts = M.TopologyEdges.EdgeLine(meshEdge).InterpolateLine(divisions, false);

                    for (int j = 0; j < pts.Length; j++)
                    {
                        JointGroups.Add(new Panel(new Plane(pts[j], EV.Branch(EV.Path(i))[0].UnitVector(), M.GetMeshEdgePerpDir(meshEdge))), EV.Path(i));
                    }


                    //Construct joint outlines from planes
                    //Iterate number of joints per edge
                    for (int j = 0; j < pts.Length; j++)
                    {
                        JointGroups.Branch(EV.Path(i))[j].planeOffset0    = JointGroups.Branch(EV.Path(i))[j].plane.MovePlanebyAxis(W * 0.5);         //offset planes
                        JointGroups.Branch(EV.Path(i))[j].planeOffset1    = JointGroups.Branch(EV.Path(i))[j].plane.MovePlanebyAxis(-W * 0.5);        //offset planes
                        JointGroups.Branch(EV.Path(i))[j].planeRot        = new Plane(pts[j], Vector3d.CrossProduct(EV.Branch(EV.Path(i))[0].UnitVector(), M.GetMeshEdgePerpDir(meshEdge)), M.GetMeshEdgePerpDir(meshEdge));
                        JointGroups.Branch(EV.Path(i))[j].planeRotOffset0 = JointGroups.Branch(EV.Path(i))[j].planeRot.MovePlanebyAxis(jointLength);  //offset planes
                        JointGroups.Branch(EV.Path(i))[j].planeRotOffset1 = JointGroups.Branch(EV.Path(i))[j].planeRot.MovePlanebyAxis(-jointLength); //offset plane
                        JointGroups.Branch(EV.Path(i))[j].planeEdge       = new Plane(pts[j], M.TopologyEdges.EdgeLine(meshEdge).Direction, M.GetMeshEdgePerpDir(meshEdge));

                        List <Plane> planesF0 = new List <Plane>();
                        List <Plane> planesF1 = new List <Plane>();
                        for (int k = 0; k < PanelGroups.Branch(f0).Count; k++)
                        {
                            planesF0.Add(PanelGroups.Branch(f0)[k].plane);
                            planesF1.Add(PanelGroups.Branch(f1)[k].plane);
                        }



                        JointGroups.Branch(EV.Path(i))[j].planeF0 = PlaneUtil.AveragePlaneOrigin(planesF0);
                        JointGroups.Branch(EV.Path(i))[j].planeF1 = PlaneUtil.AveragePlaneOrigin(planesF1);

                        List <Plane> jointPlaneLoop = new List <Plane> {
                            JointGroups.Branch(EV.Path(i))[j].planeRotOffset0,
                            JointGroups.Branch(EV.Path(i))[j].planeF0.MovePlanebyAxis(height),
                            JointGroups.Branch(EV.Path(i))[j].planeEdge,
                            JointGroups.Branch(EV.Path(i))[j].planeF1.MovePlanebyAxis(height),  //3
                            JointGroups.Branch(EV.Path(i))[j].planeRotOffset1,
                            JointGroups.Branch(EV.Path(i))[j].planeF1.MovePlanebyAxis(-height), //5
                            JointGroups.Branch(EV.Path(i))[j].planeEdge,
                            JointGroups.Branch(EV.Path(i))[j].planeF0.MovePlanebyAxis(-height),
                        };

                        //Rhino.RhinoDoc.ActiveDoc.Objects.AddRectangle(new Rectangle3d(JointGroups.Branch(EV.Path(i))[j].planeF1, new Interval(-20, 20), new Interval(-20, 20)));
                        //Rhino.RhinoDoc.ActiveDoc.Objects.AddRectangle(new Rectangle3d(JointGroups.Branch(EV.Path(i))[j].planeF1, new Interval(-20, 20), new Interval(-20, 20)));

                        JointGroups.Branch(EV.Path(i))[j].contourNoJoints[0] = PolylineUtil.PolylineFromPlanes(JointGroups.Branch(EV.Path(i))[j].planeOffset0, jointPlaneLoop);
                        JointGroups.Branch(EV.Path(i))[j].contourNoJoints[1] = PolylineUtil.PolylineFromPlanes(JointGroups.Branch(EV.Path(i))[j].planeOffset1, jointPlaneLoop);
                        JointGroups.Branch(EV.Path(i))[j].contour[0]         = new Polyline(JointGroups.Branch(EV.Path(i))[j].contourNoJoints[0]);
                        JointGroups.Branch(EV.Path(i))[j].contour[1]         = new Polyline(JointGroups.Branch(EV.Path(i))[j].contourNoJoints[1]);
                    }


                    //Construct Cuts
                    //Iterate number of joints per edge
                    for (int j = 0; j < pts.Length; j++)
                    {
                        int localMeshEdgeF0 = Array.IndexOf(fe[f0], meshEdge);
                        int localMeshEdgeF1 = Array.IndexOf(fe[f1], meshEdge);



                        //Iterate number of panels and create cuts
                        for (int k = 0; k < PanelGroups.Branch(f0).Count; k++)
                        {
                            Panel jointPanel = JointGroups.Branch(EV.Path(i))[j];

                            jointPanel.id = f0.ToString() + "-" + f1.ToString();

                            //if(f0==f1)
                            //  Rhino.RhinoApp.WriteLine(jointPanel.id);

                            if (pts.Length > 1)
                            {
                                jointPanel.id += "-" + j.ToString();
                            }

                            bool flag = f0 == 165 && f1 == 166;
                            PanelGroups.Branch(f0)[k].CreateCut(localMeshEdgeF0, JointGroups.Branch(EV.Path(i))[j].planeOffset0, JointGroups.Branch(EV.Path(i))[j].planeOffset1, jointLength, ref jointPanel, flag); //, ref neiPanel, ref jointPanel);
                            PanelGroups.Branch(f1)[k].CreateCut(localMeshEdgeF1, JointGroups.Branch(EV.Path(i))[j].planeOffset0, JointGroups.Branch(EV.Path(i))[j].planeOffset1, jointLength, ref jointPanel, flag); //, ref neiPanel, ref jointPanel);

                            JointGroups.Branch(EV.Path(i))[j] = jointPanel;
                        }
                    }
                }


                for (int i = 0; i < JointGroups.BranchCount; i++)
                {
                    for (int j = 0; j < JointGroups.Branch(i).Count; j++)
                    {
                        if (Custom > 0)
                        {
                            JointGroups.Branch(i)[j].ChangeJoint(Custom, 0);
                        }
                        else if (Custom < 0)
                        {
                            JointGroups.Branch(i)[j].ChangeJoint(Custom, 1, textSize[7]);
                        }
                    }
                }



                ////////////////////////Output
                var dtPlates       = new DataTree <Polyline>();
                var dtJoints       = new DataTree <Polyline>();
                var dtPlatesMid    = new DataTree <Polyline>();
                var dtJointsMid    = new DataTree <Polyline>();
                var dtPlatesPlanes = new DataTree <Plane>();
                var dtJointsPlanes = new DataTree <Plane>();
                var dtPlatesTxt    = new DataTree <Curve>();
                var dtJointsTxt    = new DataTree <Curve>();

                var dtPlatesLast       = new DataTree <Polyline>();
                var dtJointsLast       = new DataTree <Polyline>();
                var dtPlatesMidLast    = new DataTree <Polyline>();
                var dtJointsMidLast    = new DataTree <Polyline>();
                var dtPlatesPlanesLast = new DataTree <Plane>();
                var dtJointsPlanesLast = new DataTree <Plane>();
                var dtPlatesTxtLast    = new DataTree <Curve>();
                var dtJointsTxtLast    = new DataTree <Curve>();

                HashSet <int> jointSequence = new HashSet <int>();

                HashSet <int> jointSequenceLast = new HashSet <int>();
                int           last = Math.Min(iterations, PanelGroups.BranchCount);
                int           prev = Math.Max(0, last - (int)textSize[6]);


                for (int i = 0; i < last; i++)  //Math.Min(iterations, sequence.Count) PanelGroups.BranchCount

                {
                    for (int j = 0; j < fe[i].Length; j++)
                    {
                        bool seq = jointSequence.Add(fe[i][j]);

                        if (i >= prev)
                        {
                            if (seq)
                            {
                                jointSequenceLast.Add(fe[i][j]);
                            }
                        }
                    }

                    for (int j = 0; j < PanelGroups.Branch(i).Count; j++)
                    {
                        dtPlates.Add(PanelGroups.Branch(i)[j].contour[0], new GH_Path(i, j));
                        dtPlates.Add(PanelGroups.Branch(i)[j].contour[1], new GH_Path(i, j));
                        dtPlatesMid.Add(PanelGroups.Branch(i)[j].MidContour(), new GH_Path(i, j));

                        if (i >= prev)
                        {
                            dtPlatesLast.Add(PanelGroups.Branch(i)[j].contour[0], new GH_Path(i, j));
                            dtPlatesLast.Add(PanelGroups.Branch(i)[j].contour[1], new GH_Path(i, j));
                            dtPlatesMidLast.Add(PanelGroups.Branch(i)[j].MidContour(), new GH_Path(i, j));
                        }



                        Plane textPlane = PanelGroups.Branch(i)[j].planeOffset0;
                        textPlane.Flip();

                        if (j == 1)
                        {
                            textPlane = PanelGroups.Branch(i)[j].planeOffset1;
                        }



                        dtPlatesPlanes.Add(textPlane, new GH_Path(i, j));

                        if (i >= prev)
                        {
                            dtPlatesPlanesLast.Add(textPlane, new GH_Path(i, j));
                        }


                        string text   = i.ToString() + "-" + j.ToString();
                        var    txtCrv = Typewriter.Regular.Write(text, textPlane, textSize[0]);
                        dtPlatesTxt.AddRange(txtCrv, new GH_Path(i, j));

                        if (i >= prev)
                        {
                            dtPlatesTxtLast.AddRange(txtCrv, new GH_Path(i, j));
                        }


                        //for(int k = 0; k < PanelGroups.Branch(i)[j].contourNoJoints.Length; k++) {


                        Line[] segments = PanelGroups.Branch(i)[j].contourNoJoints[j].GetSegments();

                        int counter = 0;
                        foreach (Line l in segments)
                        {
                            int meshEdge = fe[i][counter];

                            int neiF = M.GetOppositeNgon(meshEdge, i);


                            //Adjacent face plane
                            Point3d  origin = l.PointAt(textSize[3]);
                            Vector3d xaxis  = l.Direction;
                            Vector3d yaxis  = l.Direction;
                            origin.Transform(Transform.Scale(textPlane.Origin, textSize[4]));
                            yaxis.Rotate(Math.PI * 0.5, textPlane.ZAxis);
                            Plane ePlane = new Plane(origin, xaxis, yaxis);

                            var txtCrvF = Typewriter.Regular.Write(neiF.ToString(), ePlane, textSize[2]);
                            dtPlatesTxt.AddRange(txtCrvF, new GH_Path(i, j));

                            if (i >= prev)
                            {
                                dtPlatesTxtLast.AddRange(txtCrvF, new GH_Path(i, j));
                            }



                            //Mesh edge direction
                            Line meshEdgeLine = M.TopologyEdges.EdgeLine(meshEdge);
                            meshEdgeLine.Transform(Transform.Scale(meshEdgeLine.PointAt(0.5), textSize[4]));
                            meshEdgeLine.Transform(Transform.Scale(textPlane.Origin, textSize[4]));
                            //meshEdgeLine.Extend(-textSize[4], -textSize[4]);


                            Plane e0Plane = new Plane(ePlane.ClosestPoint(meshEdgeLine.From), xaxis, yaxis);
                            Plane e1Plane = new Plane(ePlane.ClosestPoint(meshEdgeLine.To), xaxis, yaxis);

                            var txtCrvF0 = Typewriter.Regular.Write("I", e0Plane, textSize[2]);
                            dtPlatesTxt.AddRange(txtCrvF0, new GH_Path(i, j));

                            if (i >= prev)
                            {
                                dtPlatesTxtLast.AddRange(txtCrvF0, new GH_Path(i, j));
                            }

                            var txtCrvF1 = Typewriter.Regular.Write("II", e1Plane, textSize[2]);
                            dtPlatesTxt.AddRange(txtCrvF1, new GH_Path(i, j));

                            if (i >= prev)
                            {
                                dtPlatesTxtLast.AddRange(txtCrvF1, new GH_Path(i, j));
                            }


                            counter++;
                            //
                        }
                    }
                }

                foreach (int meshEdge in jointSequence)
                {
                    //for (int i = 0; i < Math.Min(iterations, sequence.Count); i++) {//JointGroups.BranchCount
                    if (!meshEdgeDict.ContainsKey(meshEdge))
                    {
                        continue;
                    }
                    int i = meshEdgeDict[meshEdge];

                    for (int j = 0; j < JointGroups.Branch(i).Count; j++)
                    {
                        dtJoints.Add(JointGroups.Branch(i)[j].contour[0], new GH_Path(meshEdge, j));
                        dtJoints.Add(JointGroups.Branch(i)[j].contour[1], new GH_Path(meshEdge, j));
                        dtJointsMid.Add(JointGroups.Branch(i)[j].MidContour(), new GH_Path(i, j));

                        dtJointsPlanes.Add(JointGroups.Branch(i)[j].planeOffset0, new GH_Path(meshEdge, j));

                        Plane planet = new Plane(JointGroups.Branch(i)[j].planeOffset0.Origin + JointGroups.Branch(i)[j].planeOffset0.YAxis * textSize[5], JointGroups.Branch(i)[j].planeOffset0.XAxis, JointGroups.Branch(i)[j].planeOffset0.YAxis);


                        string text   = JointGroups.Branch(i)[j].id;
                        var    txtCrv = Typewriter.Regular.Write(text, planet, textSize[1]);
                        dtJointsTxt.AddRange(txtCrv, new GH_Path(meshEdge, j));
                    }
                }

                foreach (int meshEdge in jointSequenceLast)
                {
                    //for (int i = 0; i < Math.Min(iterations, sequence.Count); i++) {//JointGroups.BranchCount
                    if (!meshEdgeDict.ContainsKey(meshEdge))
                    {
                        continue;
                    }
                    int i = meshEdgeDict[meshEdge];

                    for (int j = 0; j < JointGroups.Branch(i).Count; j++)
                    {
                        dtJointsLast.Add(JointGroups.Branch(i)[j].contour[0], new GH_Path(meshEdge, j));
                        dtJointsLast.Add(JointGroups.Branch(i)[j].contour[1], new GH_Path(meshEdge, j));
                        dtJointsMidLast.Add(JointGroups.Branch(i)[j].MidContour(), new GH_Path(i, j));

                        dtJointsPlanesLast.Add(JointGroups.Branch(i)[j].planeOffset0, new GH_Path(meshEdge, j));

                        Plane planet = new Plane(JointGroups.Branch(i)[j].planeOffset0.Origin + JointGroups.Branch(i)[j].planeOffset0.YAxis * textSize[5], JointGroups.Branch(i)[j].planeOffset0.XAxis, JointGroups.Branch(i)[j].planeOffset0.YAxis);


                        string text   = JointGroups.Branch(i)[j].id;
                        var    txtCrv = Typewriter.Regular.Write(text, planet, textSize[1]);
                        dtJointsTxtLast.AddRange(txtCrv, new GH_Path(meshEdge, j));
                    }
                }


                DA.SetDataTree(0, dtPlates);
                DA.SetDataTree(1, dtJoints);

                DA.SetDataTree(2, dtPlatesMid);
                DA.SetDataTree(3, dtJointsMid);

                DA.SetDataTree(4, dtPlatesPlanes);
                DA.SetDataTree(5, dtJointsPlanes);

                DA.SetDataTree(6, dtPlatesTxt);
                DA.SetDataTree(7, dtJointsTxt);



                DA.SetDataTree(8, dtPlatesLast);
                DA.SetDataTree(9, dtJointsLast);

                DA.SetDataTree(10, dtPlatesMidLast);
                DA.SetDataTree(11, dtJointsMidLast);

                DA.SetDataTree(12, dtPlatesPlanesLast);
                DA.SetDataTree(13, dtJointsPlanesLast);

                DA.SetDataTree(14, dtPlatesTxtLast);
                DA.SetDataTree(15, dtJointsTxtLast);
            } catch (Exception e) {
                Rhino.RhinoApp.WriteLine(e.ToString());
            }
        }
Beispiel #28
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            Mesh   M = DA.Fetch <Mesh>("Mesh");
            double A = DA.Fetch <double>("Angle");
            double S = DA.Fetch <double>("Scale");
            bool   N = DA.Fetch <bool>("NormalType");

            int[][]       tv    = M.GetNGonsTopoBoundaries();
            HashSet <int> ehash = M.GetAllNGonEdges(tv);

            int[]   e      = ehash.ToArray();
            int[][] ef     = M.GetNgonsConnectedToNGonsEdges(ehash, false);
            Plane[] planes = M.GetNgonPlanes();


            Dictionary <int, int> eDict = new Dictionary <int, int>();

            int[][] fe = M.GetNGonFacesEdges(tv);

            int i = 0;

            foreach (int meshedge in ehash)
            {
                eDict.Add(meshedge, i++);
            }

            int[][] fe_  = new int[fe.Length][];
            int[][] fe_0 = new int[fe.Length][];

            for (i = 0; i < fe.Length; i++)
            {
                fe_[i]  = new int[fe[i].Length];
                fe_0[i] = new int[fe[i].Length];

                for (int j = 0; j < fe[i].Length; j++)
                {
                    fe_[i][j] = eDict[fe[i][j]];
                }

                for (int j = 0; j < fe[i].Length; j++)
                {
                    fe_0[i][j] = eDict[fe[i][(j + 1) % fe[i].Length]];
                }
            }



            List <Vector3d> vecs = new List <Vector3d>();

            i = 0;
            foreach (int n in e)
            {
                int[] edgeFaces = ef[i];

                Vector3d vec = Vector3d.Zero;

                if (N)
                {
                    for (int j = 0; j < edgeFaces.Length; j++)
                    {
                        vec += planes[edgeFaces[j]].ZAxis;
                    }
                    vec         /= edgeFaces.Length;
                    base.Message = "Average";
                }
                else
                {
                    int[] triangleFaces = M.TopologyEdges.GetConnectedFaces(n);

                    for (int j = 0; j < triangleFaces.Length; j++)
                    {
                        vec += M.FaceNormals[triangleFaces[j]];
                    }
                    vec         /= triangleFaces.Length;
                    base.Message = "Face";
                }

                /*
                 * //l.Transform(Transform.Rotation())
                 * Rhino.IndexPair ip = M.TopologyEdges.GetTopologyVertices(n);
                 * int v0 = M.TopologyVertices.MeshVertexIndices(ip.I)[0];
                 * int v1 = M.TopologyVertices.MeshVertexIndices(ip.J)[0];
                 * Vector3d vec = new Vector3d(
                 * (M.Normals[v0].X + M.Normals[v1].X) * 0.5,
                 * (M.Normals[v0].Y + M.Normals[v1].Y) * 0.5,
                 * (M.Normals[v0].Z + M.Normals[v1].Z) * 0.5
                 * );
                 */

                vecs.Add(vec);
                i++;
            }

            Line[] lines = M.GetAllNGonEdgesLines(ehash);
            //List<Line> ln = new List<Line>();

            for (int j = 0; j < lines.Length; j++)
            {
                //Line l = lines[j];
                lines[j].Transform(Rhino.Geometry.Transform.Scale(lines[j].PointAt(0.5), S));
                lines[j].Transform(Rhino.Geometry.Transform.Rotation(A, vecs[j], lines[j].PointAt(0.5)));
            }


            DA.SetDataList(0, lines);
            DA.SetDataTree(1, NGonsCore.GrasshopperUtil.IE2(fe_));
            DA.SetDataTree(2, NGonsCore.GrasshopperUtil.IE2(fe_0));
            DA.SetDataList(3, vecs);
        }
Beispiel #29
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            Mesh        mesh          = DA.Fetch <Mesh>("Mesh");
            string      v             = DA.Fetch <string>("Start");
            List <int>  o             = DA.FetchList <int>("Sequence");
            Curve       sequenceCrv   = DA.Fetch <Curve>("SequenceCrv");
            List <Line> customVectors = DA.FetchList <Line>("CustomVectors");
            double      angleTol      = DA.Fetch <double>("Angle");



            v = Math.Min(Convert.ToInt32(v), mesh.Ngons.Count - 1).ToString();



            if (mesh.Ngons.Count == o.Count)
            {
                mesh         = mesh.ReoderMeshNgons(o);
                base.Message = "Sequence";
            }
            else if (sequenceCrv != null)
            {
                if (sequenceCrv.IsValid)
                {
                    mesh = mesh.ReoderMeshNgons(sequenceCrv);
                    List <int> order = Enumerable.Range(0, mesh.Ngons.Count).ToList();
                    base.Message = "Sequence Curve";
                }
            }
            else
            {
                var        ve    = NGonsCore.Graphs.UndirectedGraphBfsRhino.MeshBFS(mesh, v);
                List <int> order = ve.Item1[0];
                mesh         = mesh.ReoderMeshNgons(ve.Item1[0]);
                base.Message = "BFS";
                DA.SetDataTree(0, GrasshopperUtil.IE2(ve.Item1));
                DA.SetDataTree(1, GrasshopperUtil.IE3(ve.Item2));
            }

            DA.SetData(4, mesh);


            List <int> order_ = Enumerable.Range(0, mesh.Ngons.Count).ToList();

            DataTree <int> vertices_ = new DataTree <int>(order_);
            DataTree <int> edges_    = new DataTree <int>();

            for (int i = 0; i < order_.Count - 1; i++)
            {
                edges_.Add(order_[i], new GH_Path(i));
                edges_.Add(order_[i] + 1, new GH_Path(i));
            }


            int S = mesh.Ngons.Count;//stop
            //Insertion vectors
            DataTree <int> N = SequenceNeighbours(mesh, order_, S);

            //FN = N;
            //O_ = O;
            //Edge Vectors
            int[][]                 tv     = mesh.GetNGonsTopoBoundaries();
            int[][]                 fe     = mesh.GetNGonFacesEdges(tv);
            HashSet <int>           e      = mesh.GetAllNGonEdges(tv);
            Dictionary <int, int[]> efDict = mesh.GetFE(e, false);

            Polyline[] outlines = mesh.GetPolylines();



            //Dictionary<int, Vector3d> edgeVectors = new Dictionary<int, Vector3d> ();
            DataTree <Vector3d> edgeVectors = new DataTree <Vector3d>();
            List <Vector3d>     faceVectors = new List <Vector3d>();
            Dictionary <int, List <GH_Path> > faceEdgeID = new Dictionary <int, List <GH_Path> >();


            for (int i = 0; (i < S && i < mesh.Ngons.Count); i++)
            {
                /////////////
                // Properties
                /////////////
                //Current path and face
                GH_Path p = new GH_Path(i);
                int     f = order_[i];//O[i];
                if (!N.PathExists(p))
                {
                    continue;                                        //If no connectio nskip
                }
                HashSet <int> fadj = new HashSet <int>(N.Branch(p)); //adjacency list


                /////////////
                // Solution
                /////////////
                //Iterate mesh edges
                //Get connected faces
                //Check if they are in adjacency list
                //The order thoses ids

                List <int> NotOrderedEdges = new List <int>();
                for (int j = 0; j < fe[f].Length; j++)
                {
                    int[] facePair = efDict[fe[f][j]];//get face pair
                    if (facePair.Length == 1)
                    {
                        continue;                      //if naked skip
                    }
                    if (fadj.Contains(facePair[0]) || fadj.Contains(facePair[1]))
                    {
                        NotOrderedEdges.Add(j);                                                          //if edge face are in fadj
                    }
                }

                List <int> orderedEdges = SortIntegers(NotOrderedEdges, fe[f].Length);


                //Collect lines for Insertion Vector
                List <Line> el = new List <Line>();
                //Line[] lines = outlines[f].GetSegments();
                foreach (int j in orderedEdges)
                {
                    el.Add(outlines[f].SegmentAt(j));//el.Add(M.TopologyEdges.EdgeLine(fe[f][j]));
                }

                //Create Insertion Vector
                Vector3d vec = NGonsCore.VectorUtil.BisectorVector(el, outlines[f].AverageNormal(), false);
                faceVectors.Add(vec);


                List <GH_Path> paths = new List <GH_Path>();
                foreach (int j in orderedEdges)
                {
                    //edgeVectors.Add(fe[f][j],vec);
                    edgeVectors.Add(vec, new GH_Path(fe[f][j]));
                    paths.Add(new GH_Path(fe[f][j]));
                }

                faceEdgeID.Add(i, paths);
                //Rhino.RhinoApp.WriteLine(i.ToString() + " " + paths.Count.ToString());

                //A = el;
                //B = vec;
                //C = outlines[f].AverageNormal();
            }

            DataTree <Vector3d> EV    = mesh.insertionVectors(true);
            DataTree <Line>     edges = new DataTree <Line>();
            PointCloud          cloud = new PointCloud();

            //Check angles if vectors are not parallel to mesh edge
            foreach (GH_Path p in EV.Paths)
            {
                Line  line      = mesh.TopologyEdges.EdgeLine(p.Indices[0]);
                Plane edgePlane = new Plane(line.PointAt(0.5), mesh.GetMeshEdgePerpDir(p.Indices[0]));

                cloud.Add(line.PointAt(0.5), new Vector3d(p.Indices[0], 0, 0));

                double angledifference = Math.Abs(Vector3d.VectorAngle(line.Direction, edgeVectors.Branch(p)[0], edgePlane) % Math.PI);

                //Rhino.RhinoApp.WriteLine(angledifference.ToString());
                if (angledifference < angleTol || angledifference > (Math.PI - angleTol))
                {
                    edges.Add(new Line(line.PointAt(0.5), line.PointAt(0.5) + line.Direction.UnitVector() * line.Length * 0.25), p);
                    edges.Add(new Line(line.PointAt(0.5), line.PointAt(0.5) + edgeVectors.Branch(p)[0].UnitVector() * line.Length * 0.25), p);
                    edgeVectors.Branch(p)[0] = -EV.Branch(p)[0];
                }
                else
                {
                }
            }


            //Change insertion vectors
            if (customVectors.Count > 0)
            {
                for (int i = 0; i < customVectors.Count; i++)
                {
                    int edgeID = cloud.ClosestPoint(customVectors[i].From);
                    edgeVectors.Branch(new GH_Path((int)cloud[edgeID].Normal.X))[0] = customVectors[i].Direction;
                }
            }

            //Rhino.RhinoApp.WriteLine (faceEdgeID.Count.ToString());

            List <Vector3d> NGonsVectors = new List <Vector3d>()
            {
                Vector3d.ZAxis
            };

            for (int i = 1; i < faceEdgeID.Count; i++)
            {
                Vector3d vec = Vector3d.Zero;
                for (int j = 0; j < faceEdgeID[i].Count; j++)
                {
                    vec += edgeVectors.Branch(faceEdgeID[i][j])[0];
                }
                vec.Unitize();
                NGonsVectors.Add(vec);
            }

            DA.SetDataList(5, NGonsVectors);

            //EV = edgeVectors;
            DA.SetDataTree(2, edgeVectors);
            DA.SetDataTree(3, edges);
            //Get current face edges
            //Take edge only connected in current set
        }
Beispiel #30
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            List <Mesh> m_     = DA.FetchList <Mesh>("Mesh");
            double      radius = DA.Fetch <double>("Radius");

            Mesh[] m  = new Mesh[m_.Count];
            Mesh   mj = new Mesh();

            for (int i = 0; i < m_.Count; i++)
            {
                m[i] = m_[i].DuplicateMesh();
                mj.Append(m_[i]);
            }



            if (radius == -2)
            {
                for (int i = 0; i < m_.Count; i++)
                {
                    if (m[i].SolidOrientation() == -1)
                    {
                        m[i].Flip(true, true, true);
                    }
                    m[i].Unweld(0, true);

                    mj.Append(m[i]);
                }

                DA.SetDataList(0, m);

                this.PreparePreview(mj, DA.Iteration);
            }
            if (radius == -3)
            {
                for (int i = 0; i < m_.Count; i++)
                {
                    if (m[i].SolidOrientation() == -1)
                    {
                        m[i].Flip(true, true, true);
                    }
                    m[i] = m[i].WeldUsingRTree(0.001, foo);
                    m[i].Unweld(0, true);
                    m[i].UnifyNormals();

                    mj.Append(m[i]);
                }
                DA.SetDataList(0, m);


                this.PreparePreview(mj, DA.Iteration);
            }


            //m.WeldUsingRTree(radius);
            else if (radius > 0)
            {
                //Rhino.RhinoApp.WriteLine("hi");

                mj = mj.WeldUsingRTree(radius, foo);


                mj.Compact();
                mj.Vertices.CombineIdentical(true, true);
                mj.Vertices.CullUnused();

                if (mj.Ngons.Count > 0)
                {
                    mj.UnifyNormalsNGons();
                }
                else
                {
                    mj.UnifyNormals();
                }


                mj.Weld(3.14159265358979);
                mj.FaceNormals.ComputeFaceNormals();
                mj.Normals.ComputeNormals();



                if (mj.SolidOrientation() == -1)
                {
                    mj.Flip(true, true, true);
                }

                this.PreparePreview(mj, DA.Iteration);



                DA.SetDataList(0, new Mesh[] { mj });

                //m.WeldFull(radius);
            }

            //DA.SetData(0, m);
        }
Beispiel #31
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            Mesh    M  = DA.Fetch <Mesh>("Mesh");
            double  A  = DA.Fetch <double>("Angle");
            double  S  = DA.Fetch <double>("Scale");
            bool    N  = DA.Fetch <bool>("NormalType");
            double  D  = DA.Fetch <double>("Height");
            double  O  = DA.Fetch <double>("Offset");
            double  W1 = DA.Fetch <double>("W1");
            double  W2 = DA.Fetch <double>("W2");
            double  T  = DA.Fetch <double>("Thickness");
            Surface RS = DA.Fetch <Surface>("RoofSurface");

            List <Curve>    JointMale   = DA.FetchList <Curve>("JointMale");
            List <Curve>    JointFemale = DA.FetchList <Curve>("JointFemale");
            JointReciprocal jm          = new JointReciprocal(JointMale);
            JointReciprocal jf          = new JointReciprocal(JointFemale);

            int[][]       tv    = M.GetNGonsTopoBoundaries();
            HashSet <int> ehash = M.GetAllNGonEdges(tv);

            int[]   e      = ehash.ToArray();
            int[][] ef     = M.GetNgonsConnectedToNGonsEdges(ehash, false);
            Plane[] planes = M.GetNgonPlanes();



            Dictionary <int, int> eDict = new Dictionary <int, int>();

            int[][] fe = M.GetNGonFacesEdges(tv);

            int i = 0;

            foreach (int meshedge in ehash)
            {
                eDict.Add(meshedge, i++);
            }

            int[][] fe_  = new int[fe.Length][];
            int[][] fe_0 = new int[fe.Length][];


            for (i = 0; i < fe.Length; i++)
            {
                fe_[i]  = new int[fe[i].Length];
                fe_0[i] = new int[fe[i].Length];

                for (int j = 0; j < fe[i].Length; j++)
                {
                    fe_[i][j] = eDict[fe[i][MathUtil.Wrap((j - 1), fe[i].Length)]];
                }

                for (int j = 0; j < fe[i].Length; j++)
                {
                    fe_0[i][j] = eDict[fe[i][MathUtil.Wrap((j + 0), fe[i].Length)]];
                }
            }



            List <Vector3d> vecs = new List <Vector3d>();

            i = 0;
            foreach (int n in e)
            {
                int[] edgeFaces = ef[i];

                Vector3d vec = Vector3d.Zero;

                if (N)
                {
                    for (int j = 0; j < edgeFaces.Length; j++)
                    {
                        vec += planes[edgeFaces[j]].ZAxis;
                    }
                    vec         /= edgeFaces.Length;
                    base.Message = "Average";
                }
                else
                {
                    int[] triangleFaces = M.TopologyEdges.GetConnectedFaces(n);

                    for (int j = 0; j < triangleFaces.Length; j++)
                    {
                        vec += M.FaceNormals[triangleFaces[j]];
                    }
                    vec         /= triangleFaces.Length;
                    base.Message = "Face";
                }


                vecs.Add(vec);
                i++;
            }

            Line[] lines = M.GetAllNGonEdgesLines(ehash);
            //List<Line> ln = new List<Line>();

            for (int j = 0; j < lines.Length; j++)
            {
                //Line l = lines[j];
                lines[j].Transform(Rhino.Geometry.Transform.Scale(lines[j].PointAt(0.5), S));
                lines[j].Transform(Rhino.Geometry.Transform.Rotation(A, vecs[j], lines[j].PointAt(0.5)));
            }


            //2nd part extend

            Plane[] linePlanes = new Plane[lines.Length];
            for (i = 0; i < lines.Length; i++)
            {
                linePlanes[i] = new Plane(lines[i].PointAt(0.5), lines[i].Direction, vecs[i]);
            }



            Plane[][] endPlanes  = new Plane[0][];
            Line[]    cutLines   = new Line[0];
            int[][]   neighbours = new int[0][];

            DA.SetDataList(1, GetLines(lines, linePlanes, fe_, out endPlanes, out neighbours, out cutLines, D));
            DA.SetDataList(2, GetLines(lines, linePlanes, fe_, out endPlanes, out neighbours, out cutLines, -D));
            DA.SetDataList(0, GetLines(lines, linePlanes, fe_, out endPlanes, out neighbours, out cutLines));
            DA.SetDataList(3, linePlanes);
            DA.SetDataTree(4, NGonsCore.GrasshopperUtil.IE2(endPlanes));

            DA.SetDataTree(5, NGonsCore.GrasshopperUtil.IE2(fe_));
            DA.SetDataTree(6, NGonsCore.GrasshopperUtil.IE2(FaceOutlines(M, planes, linePlanes, fe_, fe, O, T, cutLines, eDict, RS)));
            DA.SetDataList(7, cutLines);
            //DA.SetDataTree(2, NGonsCore.GrasshopperUtil.IE2(fe_0));
            //DA.SetDataList(3, vecs);

            //Get Support Structure
            Plane[]      ep0 = null;
            Plane[]      ep1 = null;
            Plane[]      lp2 = null;
            Plane[]      lp3 = null;
            Polyline[][] supportStructure = GetSupportStructure(M, W1, W2, planes, linePlanes, endPlanes, fe_0, fe, RS, eDict, ref ep0, ref ep1, ref lp2, ref lp3);
            DA.SetDataTree(8, NGonsCore.GrasshopperUtil.IE2(supportStructure));
            DA.SetDataList(9, ep0);
            DA.SetDataList(10, ep1);
            DA.SetDataList(11, lp2);
            DA.SetDataList(12, lp3);

            //DA.SetDataTree(11, NGonsCore.GrasshopperUtil.IE2(neighbours));


            //Orient joints
            var elements = new ElementReciprocal[e.Length];

            for (i = 0; i < e.Length; i++)
            {
                elements[i]               = new ElementReciprocal(supportStructure[i]);
                elements[i]._joints       = new JointReciprocal[] { jm.OrientCopy(Plane.WorldXY, ep0[i]), jm.OrientCopy(Plane.WorldXY, ep1[i]) };
                elements[i]._jointsFemale = new JointReciprocal[] { jf.OrientCopy(Plane.WorldXY, ep0[i]), jf.OrientCopy(Plane.WorldXY, ep1[i]) };
            }


            //orient holes
            for (i = 0; i < neighbours.Length; i++)
            {
                for (int j = 0; j < neighbours[i].Length; j++)
                {
                    elements[neighbours[i][j]]._jointsNei.Add(elements[i]._jointsFemale[j]);
                }
            }

            DA.SetDataTree(13, NGonsCore.GrasshopperUtil.IE3(elements.GetJointsGeo()));
            //DA.SetDataTree(12, NGonsCore.GrasshopperUtil.IE2(jointsMortise));
        }
Beispiel #32
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            #region updateInputs
            //if (!cap && this.Params.Input.Count ==7)
            //{
            //    this.Params.Input[5].RemoveAllSources();
            //    this.Params.UnregisterInputParameter(this.Params.Input[5]);
            //    this.Params.Input[6].RemoveAllSources();
            //    this.Params.UnregisterInputParameter(this.Params.Input[6]);

            //    Params.OnParametersChanged();
            //}
            //if (cap && this.Params.Input.Count == 5)
            //{
            //    this.Params.RegisterInputParam(new Param_Colour
            //    {
            //        Name = "MinColor",
            //        NickName = "MinColor",
            //        Description = "MinColor",
            //        Access = GH_ParamAccess.item,
            //        Optional = true
            //    });
            //    this.Params.RegisterInputParam(new Param_Colour
            //    {
            //        Name = "MaxColor",
            //        NickName = "MaxColor",
            //        Description = "MinColor",
            //        Access = GH_ParamAccess.item,
            //        Optional = true
            //    });

            //    Params.OnParametersChanged();
            //}

            #endregion updateInputs

            //bool caps = DA.Fetch<bool>("Cap");
            Color?maxColor   = DA.Fetch <Color?>(i_inputSelecterMax);
            Color?minColor   = DA.Fetch <Color?>(i_inputSelectorMin);
            var   allResults = DA.FetchTree <GH_Number>("Results");
            var   grids      = DA.FetchList <Grid>("Grids");
            //var gradientRange = DA.Fetch<string>("GradientRange");
            //int maxCount = DA.Fetch<int>("MaxCount");
            int maxCount = 200;
            //var inStepSize = DA.Fetch<int>("StepSize");
            //var inSteps = DA.Fetch<int>("Steps");
            InputSelector inputSelector = DA.Fetch <InputSelector>("_Section Type");

            double globalMin = double.MaxValue;
            double globalMax = double.MinValue;

            for (int g = 0; g < grids.Count; g++)
            {
                globalMin = Math.Min(globalMin, ((List <GH_Number>)allResults.get_Branch(g)).Select(r => r.Value).Min());
                globalMax = Math.Max(globalMax, ((List <GH_Number>)allResults.get_Branch(g)).Select(r => r.Value).Max());
            }


            if (inputSelector == null)
            {
                inputSelector = new InputSelector(10, globalMin, globalMax);
            }



            if (allResults.Branches.Count != grids.Count)
            {
                throw new Exception("Grid count doesnt match results");
            }


            //var colorDomain = Misc.AutoDomain(gradientRange, allResults);
            //Rhino.RhinoApp.WriteLine($"{range}  ->  {domain[0]} to {domain[1]}");

            GH_GradientControl gc;
            try
            {
                gc = (GH_GradientControl)Params.Input[i_inputGradient].Sources[0].Attributes.GetTopLevel.DocObject;
            }
            catch (System.ArgumentOutOfRangeException)
            {
                this.AddRuntimeMessage(GH_RuntimeMessageLevel.Remark, "Remember to add a gradient component in grasshopper!");
                gc = null;
            }

            GradientParser gp = new GradientParser(gc)
            {
                //Cap = caps,
                AboveMax = maxColor == default(Color) ? null : maxColor,
                BelowMin = minColor == default(Color) ? null : minColor,
                //Min = domain[0],
                //Max = domain[1],
                Reverse = Params.Input[i_inputGradient].Reverse
            };



            IDictionary <string, Color> colorDescriptions = new Dictionary <string, Color>();
            IDictionary <string, int>   colorPaths        = new Dictionary <string, int>();



            #region coloredMesh
            var outMeshes = new List <Mesh>();



            for (int i = 0; i < grids.Count; i++)
            {
                //AddRuntimeMessage(GH_RuntimeMessageLevel.Remark, $"Mesh vertices: {grids[i].SimMesh.Vertices.Count}, colors = {gp.GetColors(allResults.Branches[i].Select(p => p.Value).ToArray()).Length} f");


                outMeshes.Add(grids[i].GetColoredMesh(gp.GetColors(allResults.Branches[i].Select(p => p.Value).ToArray())));

                Mesh      m      = grids[i].SimMesh;
                Point3d[] points = grids[i].SimPoints.ToArray();
                outMeshes[outMeshes.Count - 1].Translate(0, 0, Units.ConvertFromMeter(0.001));
            }


            DA.SetDataList(0, outMeshes);

            #endregion coloredMesh



            #region layeredMesh

            if (grids[0].UseCenters == true)
            {
                return;
            }

            //Outputs
            GH_Structure <GH_Mesh>  oLayeredMeshes = new GH_Structure <GH_Mesh>();
            List <GH_Mesh>          previewMeshes  = new List <GH_Mesh>();
            List <GH_Plane>         outPlanes      = new List <GH_Plane>();
            GH_Structure <GH_Curve> outCurves      = new GH_Structure <GH_Curve>();

            GH_Structure <GH_String> outValues = new GH_Structure <GH_String>();
            GH_Structure <GH_Colour> outColors = new GH_Structure <GH_Colour>();

            const double SCALAR = 1; // don't change.



            if (((GH_Structure <GH_Number>)gc.Params.Input[1].VolatileData)[0][0].Value == 1)
            {
                this.AddRuntimeMessage(GH_RuntimeMessageLevel.Remark, "The gradient connected has 1 as max. Is that on purpose? Check the inputs of your gradient component." +
                                       $"\nI suggest you set your max somewhere around {globalMax:0.0}");
            }


            for (int g = 0; g < grids.Count; g++)
            {
                //GH_Structure<GH_Curve> curves = new GH_Structure<GH_Curve>();
                Grid grid      = grids[g];
                Mesh inputMesh = grids[g].SimMesh.DuplicateMesh();
                //Mesh meshToCut = grids[g].SimMesh;

                List <double> results = ((List <GH_Number>)allResults.get_Branch(g)).Select(r => r.Value).ToList();

                if (grids[g].UseCenters == true)
                {
                    results = RTreeSolver.FindClosestWeightedValues(grids[g], results, true).ToList();
                    // ADD CONVERSION TODO:
                }

                inputMesh.Normals.ComputeNormals();

                Vector3f normal = inputMesh.FaceNormals[0];

                Plane basePlane = new Plane(inputMesh.Vertices[0], normal);

                Transform ProjectToBase = Transform.PlanarProjection(basePlane);

                Plane cuttingPlane = new Plane(basePlane);

                Mesh meshToCut = CreateMeshToBeCut(SCALAR, inputMesh, results, cuttingPlane);

                previewMeshes.Add(new GH_Mesh(inputMesh));

                MeshingParameters mp = new MeshingParameters(0);

                List <Mesh> layeredMeshesThisGrid = new List <Mesh>();


                double valueForSmallAreas = double.MinValue;

                double resultsMin = results.Min();

                foreach (var item in inputSelector)
                {
                    if (resultsMin >= item)
                    {
                        valueForSmallAreas = item;
                        break;
                    }
                }

                //Color col = gp.GetColors(new List<double>() { inputSelector.Min.Value })[0];
                Color col = gp.GetColors(new List <double>()
                {
                    gp.BelowMin.HasValue&& inputSelector.Min.Value <= gp.Min ? resultsMin > gp.Min ? valueForSmallAreas : double.MinValue :  inputSelector.Min.Value
                })[0];

                Polyline[] outlinePolylines = inputMesh.GetNakedEdges();

                PolylineCurve[] curvesFromOutline = new PolylineCurve[outlinePolylines.Length];

                for (int i = 0; i < outlinePolylines.Length; i++)
                {
                    curvesFromOutline[i] = new PolylineCurve(outlinePolylines[i]);
                    curvesFromOutline[i].Transform(ProjectToBase);
                }


                Mesh meshFromCurves = GetMeshFromCurves(curvesFromOutline, mp, in col);

                GH_Path startPath = new GH_Path(g, -1);
                oLayeredMeshes.Append(new GH_Mesh(meshFromCurves), startPath);


                string lessThanKey = gp.BelowMin.HasValue && inputSelector.Min.Value < gp.Min ? $"<{gp.Min:0.0}" : $"<{inputSelector.Min.Value:0.0}";
                if (!colorDescriptions.ContainsKey(lessThanKey) && inputSelector.First() < gp.Min)
                {
                    colorDescriptions.Add(lessThanKey, col);
                    colorPaths.Add(lessThanKey, -1);
                }

                ////outColors.Append(new GH_Colour(col), startPath);
                ////outValues.Append(new GH_Number(double.MinValue), startPath);

                //Mesh[] meshesFromCurves = GetMeshesFromCurves(curvesFromOutline, mp, in col);

                //oLayeredMeshes.AppendRange(meshesFromCurves.Select(m => new GH_Mesh(m)), new GH_Path(g, -1));



                int    cuttingCount  = 0;
                double previousValue = 0;

                foreach (double currentValue in inputSelector)
                {
                    if (cuttingCount > maxCount)
                    {
                        AddRuntimeMessage(GH_RuntimeMessageLevel.Error, $"Too many steps... I reached  {maxCount} and then stopped");
                        break;
                    }

                    if (gp.BelowMin.HasValue && currentValue < gp.Min)
                    {
                        continue;
                    }


                    if (currentValue > results.Max())
                    {
                        break;
                    }


                    // Create planes

                    Vector3f moveUpVector = normal * (float)((currentValue - previousValue) * SCALAR);

                    Transform t = Transform.Translation(moveUpVector);

                    GH_Path path = new GH_Path(g, cuttingCount);

                    cuttingPlane.Transform(t);

                    outPlanes.Add(new GH_Plane(cuttingPlane));



                    // Create boundary intersected curves

                    Curve[] intersectedCurves = GetIntersectedCurves(inputMesh, cuttingPlane);



                    if (intersectedCurves != null)
                    {
                        outCurves.AppendRange(intersectedCurves.Select(c => new GH_Curve(c.DuplicateCurve())), path);

                        foreach (var curve in intersectedCurves)
                        {
                            curve.Transform(ProjectToBase);
                        }


                        // Create meshes

                        col = gp.GetColors(new List <double>()
                        {
                            currentValue
                        })[0];



                        meshFromCurves = GetMeshFromCurves(intersectedCurves, mp, in col);

                        meshFromCurves.Transform(Transform.Translation(0, 0, (cuttingCount + 1) * Rhino.RhinoDoc.ActiveDoc.ModelAbsoluteTolerance * 12.0));



                        if (meshFromCurves != null)
                        {
                            //oLayeredMeshes.AppendRange(meshesFromCurves.Select(m => new GH_Mesh(m)), path);
                            oLayeredMeshes.Append(new GH_Mesh(meshFromCurves), path);
                            string key = currentValue >= gp.Max.Value ? $">{currentValue:0.0}" : $"{currentValue:0.0}";
                            if (!colorDescriptions.ContainsKey(key))
                            {
                                colorDescriptions.Add(key, col);
                                colorPaths.Add(key, cuttingCount);
                            }
                        }

                        if (currentValue >= gp.Max.Value)
                        {
                            break;
                        }
                    }



                    previousValue = currentValue;

                    cuttingCount++;
                }
            }

            foreach (KeyValuePair <string, Color> valuePair in colorDescriptions)
            {
                GH_Path path = new GH_Path(colorPaths[valuePair.Key]);


                outColors.Append(new GH_Colour(valuePair.Value), path);
                outValues.Append(new GH_String(valuePair.Key), path);
            }



            DA.SetDataTree(1, oLayeredMeshes);
            DA.SetDataTree(2, outCurves);
            DA.SetDataList("Planes", outPlanes);
            DA.SetDataList("TempMeshes", previewMeshes);
            DA.SetDataTree(6, outValues);
            DA.SetDataTree(5, outColors);

            #endregion layeredMesh
        }
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            // SET ALL INPUT PARAMETERS
              Polyline plA = default(Polyline);
              if (!Polyline3D.ConvertCurveToPolyline(DA.Fetch<Curve>("Polyline"), out plA)) {
            this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Unable to convert to polyline from curve");
            return;
              }
              Point3d pt = DA.Fetch<Point3d>("Point");
              Plane pln = DA.Fetch<Plane>("Plane");
              double tolerance = DA.Fetch<double>("Tolerance");

              if (pln.Equals(default(Plane)))
              {
            pln = plA.FitPlane();
              }

              DA.SetData("Inside", plA.IsInside(pt,pln, tolerance));
        }
Beispiel #34
0
        /// <summary>
        /// This is the method that actually does the work.
        /// </summary>
        /// <param name="DA">The DA object is used to retrieve from inputs and store in outputs.</param>
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            // SET ALL INPUT PARAMETERS
              List<Curve> A = DA.FetchList<Curve>("A");
              List<Curve> B = DA.FetchList<Curve>("B");
              try {
            ClipType type = (ClipType)DA.Fetch<int>("BooleanType");
            Plane pln = DA.Fetch<Plane>("Plane");
            double tolerance = DA.Fetch<double>("Tolerance");

            // Convert the curves to polylines
            // This is a crude way of doing this.
            // Should we add some parameters for this perhaps?
            IEnumerable<Polyline> APl = Polyline3D.ConvertCurvesToPolyline(A);
            IEnumerable<Polyline> BPl = Polyline3D.ConvertCurvesToPolyline(B);

            // If we don't have a plane, let's try to create a plane from the first curve.
            if (pln.Equals(default(Plane)) || !pln.IsValid) {
              pln = APl.First().FitPlane();
            }

            List<Polyline> result = new List<Polyline>();

            // do the boolean operation
            result = Polyline3D.Boolean(type, APl, BPl, pln, tolerance, EvenOdd);

            // OUTPUT LOGIC
            DA.SetDataList("Result", result);
              } catch (Exception e) {
            this.AddRuntimeMessage(GH_RuntimeMessageLevel.Error, e.Message + ": " + e.StackTrace.ToString());
              }
        }