コード例 #1
0
ファイル: ParkingLot.cs プロジェクト: Esrup/Antflow
        private static void closeIntersect(Curve innerBounderyCrv, PointCloud startPTsLeft, List <Parkingspace> finalParkingLinesLeft, Point3d crvEnd, out Curve lineOne, out CurveIntersections intersectionsOne)
        {
            int indexOne = startPTsLeft.ClosestPoint(crvEnd);

            lineOne = finalParkingLinesLeft[indexOne].Curves;

            Vector3d vectorone = lineOne.TangentAtEnd;

            vectorone.Rotate(RhinoMath.ToRadians(90), new Vector3d(0, 0, 1));
            Point3d movedPTone = lineOne.PointAtStart + vectorone;

            vectorone.Rotate(RhinoMath.ToRadians(180), new Vector3d(0, 0, 1));
            Point3d    movedPTTwo  = lineOne.PointAtStart + vectorone;
            PointCloud directionPT = new PointCloud();

            directionPT.Add(movedPTone);
            directionPT.Add(movedPTTwo);

            int indexdir = directionPT.ClosestPoint(crvEnd);

            if (indexdir == 0)
            {
                vectorone.Rotate(RhinoMath.ToRadians(180), new Vector3d(0, 0, 1));
            }
            vectorone        = Vector3d.Multiply(vectorone, 10);
            intersectionsOne = Intersection.CurveCurve(innerBounderyCrv, new Line(lineOne.PointAtEnd, vectorone).ToNurbsCurve(), 0.01, 0.01);
        }
コード例 #2
0
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            string      name     = String.Empty;
            Profile     profile  = null;
            List <Line> lines    = new List <Line>();
            double      angle    = 0.0;
            Material    material = null;
            int         type     = 0;

            DA.GetData(0, ref name);
            DA.GetData(1, ref profile);
            if (!DA.GetData(2, ref angle))
            {
                return;
            }
            if (_useDegrees)
            {
                angle = RhinoMath.ToRadians(angle);
            }
            DA.GetData(3, ref material);
            DA.GetData(4, ref type);
            DA.GetDataList(5, lines);

            ProfileToElements profileToElements = new ProfileToElements(name, profile, lines, angle, material, type);

            DA.SetData(0, profileToElements);
            DA.SetDataList(1, profileToElements.Breps);
        }
コード例 #3
0
ファイル: CurveSpacingGH.cs プロジェクト: paireks/T-Rex
        protected override void SolveInstance(IGH_DataAccess DA)
        {
            int        id         = 0;
            RebarShape rebarShape = null;
            int        count      = 0;
            Curve      curve      = null;
            double     angle      = 0.0;

            DA.GetData(0, ref id);
            DA.GetData(1, ref rebarShape);
            DA.GetData(2, ref curve);
            DA.GetData(3, ref count);
            if (!DA.GetData(4, ref angle))
            {
                return;
            }
            if (_useDegrees)
            {
                angle = RhinoMath.ToRadians(angle);
            }

            RebarGroup rebarGroup = new RebarGroup(id, new RebarSpacing(rebarShape, count, curve, angle));

            DA.SetData(0, rebarGroup);
            DA.SetDataList(1, rebarGroup.RebarGroupMesh);
            DA.SetDataList(2, rebarGroup.RebarGroupCurves);
        }
コード例 #4
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        public override void Draw()
        {
            // you need the up vector to determine the rotation axis
            //Vector3d up_vector = new Vector3d(0.0,0.0,1.0);
            // this is the same as Vector3d.ZAxis, which always returns new Vector(0.0,0.0,1.0)

            // rotate the earth sphere (radians,rotation_axis,rotation_origin)
            double base_speed = 0.1;

            earth.Rotate(RhinoMath.ToRadians(base_speed), Vector3d.ZAxis, origin);

            // add earth to document
            doc.Objects.AddSphere(earth);

            //moon speed ratio (orbit time = earth : 365.4 days, moon : 27.32days)
            double moon_speed = 365.4 / 27.32;

            // you can access to the spheres center by getting the .Center property.
            // rotation the moon sphere

            moon.Rotate(RhinoMath.ToRadians(base_speed * moon_speed), Vector3d.ZAxis, earth.Center);

            // add moon to document
            doc.Objects.AddSphere(moon);
        }
コード例 #5
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    /// <summary>
    /// This procedure contains the user code. Input parameters are provided as regular arguments,
    /// Output parameters as ref arguments. You don't have to assign output parameters,
    /// they will have a default value.
    /// </summary>
    private void RunScript(Brep brep, object void0, int fate, int mode, double rot, object void1, int divX, int divY, double stepZ, int inX, int inY, ref object DucatiumPanigaleumAmamusDumSpiramus, ref object Elapsed, ref object baseBoxWire, ref object baseGrid, ref object baseColumns, ref object xStruts, ref object yStruts)
    {
        if (brep == null || !brep.IsValid)
        {
            return;
        }

        System.Diagnostics.Stopwatch sw = new System.Diagnostics.Stopwatch();
        sw.Start();

        BrepFace baseFace = brep.Faces.Where(x => x.IsPlanar()).ToList()[0];
        Curve    bound    = baseFace.OuterLoop.To3dCurve();

        Plane  plane    = Plane.WorldXY;
        double rotPlane = RhinoMath.ToRadians(rot);

        plane.Rotate(rotPlane, plane.ZAxis);

        Box box = new Box(plane, bound);

        baseBoxWire = box.ToBrep().GetWireframe(-1);

        GetElements(box, divX, divY, baseFace, brep, stepZ, inX, inY);
        baseGrid    = grid;
        baseColumns = columns;
        xStruts     = xConn;
        yStruts     = yConn;

        sw.Stop();
        Elapsed = (string.Format("Elapsed: {0}ms", sw.Elapsed.TotalMilliseconds));
    }
コード例 #6
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        //Surfaceを回転させ積み上げていく
        public void MoveSrf(int num)//pile of brick
        {
            double ang = RhinoMath.ToRadians((angle / (num - 1)) * id);

            bool flag2 = srf.Rotate(ang, NormalVector(), Center());

            bool flag3 = srf.Rotate(ang, new Vector3d(0, 1, 0), Center());
        }
コード例 #7
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        public Hour(double newClockTime, double newAltitudeAngle, double newAzumithAngle)
        {
            clockTime     = newClockTime;
            altitudeAngle = RhinoMath.ToRadians(newAltitudeAngle);
            azumithAngle  = RhinoMath.ToRadians(newAzumithAngle);

            sunVector = CreateSunVector();
        }
コード例 #8
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        /// <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)
        {
            Guid    guid    = new Guid();
            Point3d loc     = new Point3d();
            Point3d tar     = new Point3d();
            double  ins     = 100;
            double  angle   = 90;
            double  hot     = 0.5;
            Color   diffuse = Color.Aqua;
            Color   spec    = Color.Aqua;

            DA.GetData("Guid", ref guid);
            DA.GetData("Location", ref loc);
            DA.GetData("Target", ref tar);
            DA.GetData("Intensity", ref ins);
            DA.GetData("Radius", ref angle);
            DA.GetData("HotSpot", ref hot);
            DA.GetData("DiffuseColor", ref diffuse);

            Rhino.DocObjects.LightObject spotObj = null;
            foreach (Rhino.DocObjects.LightObject obj in Rhino.RhinoDoc.ActiveDoc.Lights)
            {
                if (obj.Id == guid)
                {
                    spotObj = obj;
                    break;
                }
            }

            if (((Param_Number)Params.Input[4]).UseDegrees)
            {
                angle = RhinoMath.ToRadians(angle);
            }

            if (angle <= 0 || angle >= Math.PI / 2)
            {
                angle = Math.PI / 4;
                this.AddRuntimeMessage(GH_RuntimeMessageLevel.Warning, "Radius must be in 0-Pi/2.");
            }

            if (hot <= 0 || hot >= 1)
            {
                hot = 0.5;
                this.AddRuntimeMessage(GH_RuntimeMessageLevel.Warning, "HotSpot must be in 0-1.");
            }

            spotObj.LightGeometry.LightStyle       = LightStyle.WorldSpot;
            spotObj.LightGeometry.Location         = loc;
            spotObj.LightGeometry.Direction        = tar - loc;
            spotObj.LightGeometry.Intensity        = ins;
            spotObj.LightGeometry.SpotAngleRadians = angle;
            spotObj.LightGeometry.HotSpot          = hot;
            spotObj.LightGeometry.Diffuse          = diffuse;
            spotObj.LightGeometry.Specular         = spec;


            Rhino.RhinoDoc.ActiveDoc.Lights.Modify(guid, spotObj.LightGeometry);
        }
コード例 #9
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)
        {
            List <Line>     lines   = new List <Line>();
            List <Vector3d> vectors = new List <Vector3d>();
            double          angle   = 0;

            if (!DA.GetDataList(0, lines))
            {
                return;
            }
            if (!DA.GetDataList(1, vectors))
            {
                return;
            }
            if (!DA.GetData(2, ref angle))
            {
                return;
            }
            if (p.UseDegrees)
            {
                angle = RhinoMath.ToRadians(angle);
            }
            List <Line> goodline  = new List <Line>();
            List <Line> badline   = new List <Line>();
            List <int>  indexgood = new List <int>();
            List <int>  indexbad  = new List <int>();

            for (int i = 0; i < lines.Count; i++)
            {
                Line li = lines[i];
                for (int q = 0; q < vectors.Count; q++)
                {
                    double degree = Vector3d.VectorAngle(li.Direction, vectors[q]);
                    if (degree > Math.PI * 0.5)
                    {
                        degree = Math.PI - degree;
                    }
                    if (degree <= angle + 0.000000001)
                    {
                        goodline.Add(li);
                        indexgood.Add(i);
                        lines[i] = Line.Unset;
                        break;
                    }
                }
                if (lines[i] != Line.Unset)
                {
                    badline.Add(lines[i]);
                    indexbad.Add(i);
                }
            }
            DA.SetDataList(0, badline);
            DA.SetDataList(1, goodline);
            DA.SetDataList(2, indexbad);
            DA.SetDataList(3, indexgood);
        }
コード例 #10
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        //methods
        public void Rotate(RhinoDoc _doc)
        {
            // unit angle in one draw execution(frame). respectively for one year
            double delta_angle = RhinoMath.ToRadians(365.4 / rotation_days);

            // rotate the sphere
            obj.Rotate(delta_angle, Vector3d.ZAxis, rotation_origin);

            // add it to the document
            _doc.Objects.AddSphere(obj);
        }
コード例 #11
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        protected override void SolveInstance(IGH_DataAccess access)
        {
            Curve  curve = null;
            string edge  = null;
            string fill  = null;

            if (!access.GetData(0, ref curve))
            {
                return;
            }
            access.GetData(1, ref edge);
            access.GetData(2, ref fill);

            if (string.IsNullOrWhiteSpace(edge) && string.IsNullOrWhiteSpace(fill))
            {
                AddRuntimeMessage(GH_RuntimeMessageLevel.Warning, "Either an edge or a fill is required.");
                return;
            }

            Polyline polyline;

            if (!curve.TryGetPolyline(out polyline))
            {
                curve = curve.ToPolyline(0.1, RhinoMath.ToRadians(0.2), 0.01, 100);
                curve.TryGetPolyline(out polyline);
            }
            if (polyline == null)
            {
                AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Curve could not be converted to polyline.");
                return;
            }

            List <string> edges = new List <string>();
            List <string> fills = new List <string>();

            if (!string.IsNullOrWhiteSpace(edge))
            {
                edges.Add(edge);
            }
            if (!string.IsNullOrWhiteSpace(fill))
            {
                fills.Add(fill);
            }

            GdiShapeGoo goo = new GdiShapeGoo(polyline, edges, fills)
            {
                DrawFillsBeforeEdges = true
            };

            access.SetData(0, goo);
        }
コード例 #12
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        //methods
        public void Rotate()
        {
            // unit angle in one draw execution(frame). respectively for one year
            double delta_angle = RhinoMath.ToRadians(365.4 / rotation_days);

            // rotate the sphere
            //obj.Rotate(delta_angle,Vector3d.ZAxis,rotation_origin); // seems it has little delay...
            //TODO: position the obj coordinates not using Rotate(); function

            RhinoApp.WriteLine(Loop.frame_no.ToString());


            // add it to the document
            //_doc.Objects.AddSphere(obj); // made function to handle this
        }
コード例 #13
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    // <Custom additional code>
    Point3d adjustPlane(Curve axis, Plane plnToAdjust, Brep workEnvelope, double currentAngle, out double newAngle, out bool isValid)
    {
        double param;

        axis.ClosestPoint(plnToAdjust.Origin, out param);
        Point3d pt     = axis.PointAt(param);
        Circle  circle = new Circle(new Plane(pt, new Vector3d(axis.PointAtEnd - axis.PointAtStart)), pt, pt.DistanceTo(plnToAdjust.Origin));

        Curve[]   overlapCurves;
        Point3d[] intersectionPoints;
        Intersection.CurveBrep(circle.ToNurbsCurve(), workEnvelope, 0.01, out overlapCurves, out intersectionPoints);

        Vector3d vecA = new Vector3d(pt - plnToAdjust.Origin);
        Vector3d vecB = new Vector3d(pt - intersectionPoints[0]);

        newAngle = Vector3d.VectorAngle(vecA, vecB, new Plane(pt, new Vector3d(axis.PointAtEnd - axis.PointAtStart)));
        newAngle = RhinoMath.ToRadians(newAngle);
        newAngle = currentAngle + newAngle;

        double surfaceDeflector = (1000 / vecB.Z) * 300;

        vecB.Unitize();
        Vector3d vecFinal = vecB * surfaceDeflector;

        if (intersectionPoints.Length < 2)
        {
            isValid = false;
            return(new Point3d());
        }
        else
        {
            isValid = true;
            double  highestZ = 0;
            Point3d toReturn = new Point3d();
            foreach (Point3d tempPt in intersectionPoints)
            {
                double tempDist = tempPt.Z;
                if (tempDist > highestZ)
                {
                    highestZ = tempDist;
                    toReturn = tempPt;
                }
            }

            return(toReturn += vecFinal);
            //return intersectionPoints[1] += vecFinal;
        }
    }
コード例 #14
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        /// <summary>
        /// Called by Rhino when the user wants to run this command.
        /// </summary>
        protected override Result RunCommand(RhinoDoc doc, RunMode mode)
        {
            ReportSampleSharedXformTable("Before transform table operations:");

            var go = new GetObject();

            go.SetCommandPrompt("Select objects to add random transformations");
            go.SubObjectSelect = false;
            go.GetMultiple(1, 0);
            if (go.CommandResult() != Result.Success)
            {
                return(go.CommandResult());
            }

            foreach (var obj_ref in go.Objects())
            {
                var count      = Rnd.Next(50, 100);
                var transforms = new Transform[count];
                for (var i = 0; i < count; i++)
                {
                    var degrees = Rnd.Next(0, 360);
                    var radians = RhinoMath.ToRadians(degrees);
                    transforms[i] = Transform.Rotation(radians, Point3d.Origin);
                }

                if (SampleSharedXformTable.Contains(obj_ref.ObjectId))
                {
                    SampleSharedXformTable.Update(obj_ref.ObjectId, transforms);
                }
                else
                {
                    SampleSharedXformTable.Add(obj_ref.ObjectId, transforms);
                }
            }

            ReportSampleSharedXformTable("After transform table operations:");

            return(Result.Success);
        }
コード例 #15
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        /// <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)
        {
            Mesh   mesh  = new Mesh();
            double angle = Math.PI / 6;

            DA.GetData("Mesh", ref mesh);
            DA.GetData("AngleLimit", ref angle);

            if (((Param_Number)Params.Input[1]).UseDegrees)
            {
                angle = RhinoMath.ToRadians(angle);
            }

            mesh.FaceNormals.ComputeFaceNormals();

            List <Line> meshLine = new List <Line>();

            for (int i = 0; i <= mesh.TopologyEdges.Count; i++)
            {
                int[] faces = mesh.TopologyEdges.GetConnectedFaces(i);
                if (faces.Length == 2)
                {
                    Vector3d vec0 = mesh.FaceNormals[faces[0]];
                    Vector3d vec1 = mesh.FaceNormals[faces[1]];
                    if (Vector3d.VectorAngle(vec0, vec1) > angle)
                    {
                        meshLine.Add(mesh.TopologyEdges.EdgeLine(i));
                    }
                }
                else
                {
                    meshLine.Add(mesh.TopologyEdges.EdgeLine(i));
                }
            }

            DA.SetDataList("Edge", meshLine);
        }
コード例 #16
0
ファイル: Wirecutter.cs プロジェクト: 5chmidt/4AxisWirecutter
        /// <summary>
        /// Generate a list of curves that show the toolpath movement.
        /// </summary>
        /// <param name="onOrigin">If true generate the toolpaths at world Origin.</param>
        /// <param name="lineLength">The length of the cut line to be shown.</param>
        /// <returns>Line[] - array of lines showing the gcode positions.</returns>
        public Line[] ToolpathToCurves(bool onOrigin, double lineLength = 6)
        {
            List <Line> lines = new List <Line>();

            foreach (DataRow row in this.GCode.Rows)
            {
                double x     = (double)row["X"];
                double y     = (double)row["Y"];
                double z     = (double)row["Z"];
                double angle = (double)row["Q1="];

                Transform xform = Transform.Rotation(RhinoMath.ToRadians(angle), this.cutPlane.Normal, new Point3d(x, y, z));
                Point3d   pt0   = new Point3d(x, y, z) + (this.cutPlane.XAxis * lineLength);
                Point3d   pt1   = new Point3d(x, y, z) - (this.cutPlane.XAxis * lineLength);
                pt0.Transform(xform);
                pt1.Transform(xform);

                Line line = new Line(pt0, pt1);
                line.Transform(this.XformInverse);
                lines.Add(line);
            }

            return(lines.ToArray());
        }
コード例 #17
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)
        {
            List <Line> lines = new List <Line>();
            double      t1    = 0;
            double      t2    = 0;

            if (!DA.GetDataList(0, lines) || !DA.GetData(1, ref t1) || !DA.GetData(2, ref t2))
            {
                return;
            }
            if (p.UseDegrees)
            {
                t1 = RhinoMath.ToRadians(t1);
            }
            ////t1 角度公差  t2 两条相邻直线间的距离公差
            DataTree <Line> last      = new DataTree <Line>();
            DataTree <int>  lastIndex = new DataTree <int>();
            List <Line>     restLine  = new List <Line>();
            List <int>      restIndex = new List <int>();
            List <Line>     collects  = new List <Line>();
            List <int>      indexes   = new List <int>();
            Line            collect   = Line.Unset;
            int             count     = 0;

            for (int i = 0; i < lines.Count; i++)
            {
                if (lines[i] == Line.Unset)
                {
                    continue;
                }
                collects.Add(lines[i]);
                indexes.Add(i);
                int  mem  = i;
                bool flag = true;
                while (true)///找出满足ln1的线段 注意,这只是单方向
                {
                    Line    ln1      = collects[collects.Count - 1];
                    Point3d center1  = ln1.ToNurbsCurve().PointAtNormalizedLength(0.5); ///中点
                    double  distance = double.MaxValue;
                    for (int q = 0; q < lines.Count; q++)                               /////从剩余的选择满足条件的最近线段
                    {
                        if (lines[q] == Line.Unset || q == mem || q == i)
                        {
                            continue;
                        }
                        Line    ln2     = lines[q];
                        Point3d center2 = ln2.ToNurbsCurve().PointAtNormalizedLength(0.5);///中点
                        if (CoLine(ln1, ln2, t1, t2) && distance > center1.DistanceTo(center2))
                        {
                            collect  = ln2;
                            distance = center1.DistanceTo(center2);
                            mem      = q;
                        }
                    }
                    distance = double.MaxValue;
                    if (collect != Line.Unset)///说明上式选出了满足条件的线段
                    {
                        collects.Add(collect);
                        indexes.Add(mem);
                        lines[mem] = Line.Unset;
                        collect    = Line.Unset;
                        continue;
                    }
                    if (collects.Count > 1 && flag)/////第二次遍历
                    {
                        flag = false;
                        collects.Reverse();
                        indexes.Reverse();
                        continue;
                    }
                    break;////没有就退出
                }
                if (collects.Count > 1)
                {
                    last.AddRange(collects, new GH_Path(0, count));
                    lastIndex.AddRange(indexes, new GH_Path(0, count));
                    lines[i] = Line.Unset;
                    count++;
                }
                collects.Clear();
                indexes.Clear();
            }
            for (int i = 0; i < lines.Count; i++)////剩余线段
            {
                if (lines[i] == Line.Unset)
                {
                    continue;
                }
                restLine.Add(lines[i]);
                restIndex.Add(i);
            }
            DA.SetDataTree(0, last);
            DA.SetDataTree(2, lastIndex);
            DA.SetDataList(1, restLine);
            DA.SetDataList(3, restIndex);
        }
コード例 #18
0
    // <Custom additional code>
    List <Plane> CreateTravelPath(WindingClass wC, WindingClass nextWC, Curve curve, Curve axis, double VecAmp, bool isBackSyntax)
    {
        List <Plane> path = new List <Plane>();

        Point3d[] geoDiv;
        int       divisionCount = 30;

        curve.DivideByCount(divisionCount, true, out geoDiv);
        //curve.DivideByLength(50, true, out geoDiv);
        curve.Domain = new Interval(0, 1);
        Point3d midPoint = axis.PointAt(0.55);

        for (int i = 0; i < geoDiv.Length - 1; i++)
        {
            double u;
            double v;
            wC.srf.ClosestPoint(geoDiv[i], out u, out v);
            Plane rpln;
            wC.srf.FrameAt(u, v, out rpln);
            double param;
            axis.ClosestPoint(geoDiv[i], out param);


            // Offset plane from surface
            Vector3d V = rpln.ZAxis;
            V.Unitize();

            Vector3d vec = V * VecAmp;
            rpln.Origin -= vec;



            // If is back syntax add vector that attracts the planes towards the middle

            if (true)

            {
                Vector3d toMid    = nextWC.basePlane.Origin - midPoint;
                Vector3d toMidNoZ = new Vector3d(toMid.X, toMid.Y, 0);

                Vector3d toMidCurrent    = wC.basePlane.Origin - midPoint;
                Vector3d toMidNoZCurrent = new Vector3d(toMidCurrent.X, toMidCurrent.Y, 0);

                Vector3d localToMid    = rpln.Origin - midPoint;
                Vector3d localToMidNoZ = new Vector3d(localToMid.X, localToMid.Y, 0);

                if (toMidNoZ.Length >= 1900)
                {
                    if (toMidNoZCurrent.Length >= 1900 && wC.edgeIndex != nextWC.edgeIndex)
                    {
                        localToMidNoZ += Vector3d.ZAxis * -100;
                        rpln.Origin   -= localToMidNoZ * 0.15;
                    }
                    else if (wC.edgeIndex != nextWC.edgeIndex)
                    {
                        rpln.Origin -= localToMidNoZ * 0.05;
                    }
                }
                else
                {
                    //rpln.Origin -= toMidNoZ * 0.1;
                }
            }



            Plane xyPlane = Plane.WorldXY;
            xyPlane.Origin = rpln.Origin;
            double distance = wC.basePlane.Origin.DistanceTo(nextWC.basePlane.Origin);

            // Universal Adjustments
            xyPlane.Rotate(RhinoMath.ToRadians(-90), xyPlane.ZAxis, xyPlane.Origin);
            xyPlane.Rotate(RhinoMath.ToRadians(-180), xyPlane.YAxis, xyPlane.Origin);



            int extremetiesThreshold = 1500;
            if (nextWC.basePlane.Origin.Y > wC.basePlane.Origin.Y)
            {
                // Rotate plane so robot is pulling fiber, reduces friction
                xyPlane.Rotate(RhinoMath.ToRadians(-45), xyPlane.YAxis, xyPlane.Origin);

                // Reorient if winding at extreme ends of component
                if (xyPlane.Origin.Y > extremetiesThreshold)
                {
                    xyPlane.Rotate(RhinoMath.ToRadians(-35), xyPlane.ZAxis, xyPlane.Origin);
                    xyPlane.Rotate(RhinoMath.ToRadians(-25), xyPlane.XAxis, xyPlane.Origin);
                }
                else if (xyPlane.Origin.Y < -extremetiesThreshold)
                {
                    xyPlane.Rotate(RhinoMath.ToRadians(35), xyPlane.ZAxis, xyPlane.Origin);
                }
            }
            else
            {
                // Rotate plane so robot is pulling fiber, reduces friction
                xyPlane.Rotate(RhinoMath.ToRadians(45), xyPlane.YAxis, xyPlane.Origin);

                // Reorient if winding at extreme ends of component
                if (xyPlane.Origin.Y < -extremetiesThreshold)
                {
                    xyPlane.Rotate(RhinoMath.ToRadians(35), xyPlane.ZAxis, xyPlane.Origin);
                    xyPlane.Rotate(RhinoMath.ToRadians(-25), xyPlane.XAxis, xyPlane.Origin);
                }
                else if (xyPlane.Origin.Y > extremetiesThreshold)
                {
                    xyPlane.Rotate(RhinoMath.ToRadians(-35), xyPlane.ZAxis, xyPlane.Origin);
                }
            }


            // Remove first few and last few travel planes

            if (i < 0 || i > divisionCount - 0)
            {
            }
            else
            {
                path.Add(xyPlane);
            }
        }
        return(path);
    }
コード例 #19
0
        public static IGH_GeometricGoo BldgPartToRoof(BuildingPart bldgPart)
        {
            IGH_GeometricGoo roof = bldgPart.PartGoo;
            PolylineCurve    pL   = bldgPart.PartFootprint; ///Already at min height

            bldgPart.PartOsmGeo.Tags.TryGetValue("roof:shape", out string roofShape);

            bldgPart.PartOsmGeo.Tags.TryGetValue("height", out string heightString);
            double height = GetHeightDimensioned(heightString);

            bldgPart.PartOsmGeo.Tags.TryGetValue("min_height", out string minHeightString);
            double min_height = GetHeightDimensioned(minHeightString);

            bldgPart.PartOsmGeo.Tags.TryGetValue("roof:height", out string roofHeightString);
            double roofHeight = GetHeightDimensioned(roofHeightString);

            double facadeHeight = height - roofHeight;

            ///Make sure there's a minium facade height for SF Transamerica Pyramid case
            if (facadeHeight <= 0)
            {
                facadeHeight = 2 * DocumentTolerance();
            }

            bldgPart.PartOsmGeo.Tags.TryGetValue("roof:orientation", out string roofOrientationString);

            bldgPart.PartOsmGeo.Tags.TryGetValue("roof:direction", out string roofDirectionString);
            double   roofDirection       = System.Convert.ToDouble(roofDirectionString);
            Vector3d roofDirectionVector = Plane.WorldXY.YAxis;

            roofDirectionVector.Rotate(RhinoMath.ToRadians(-roofDirection), Plane.WorldXY.ZAxis);

            Line[]  edges    = pL.ToPolyline().GetSegments();
            Point3d centroid = AreaMassProperties.Compute(pL).Centroid;

            switch (roofShape)
            {
            case "pyramidal":
                centroid.Z = height;
                pL.TryGetPolyline(out Polyline pLPolyline);
                Line[]      pLLines         = pLPolyline.GetSegments();
                List <Brep> pyramidBrepList = Brep.CreatePlanarBreps(pL, DocumentTolerance()).ToList();

                if (!string.IsNullOrEmpty(roofHeightString))
                {
                    Plane facadeHeightPlane = Plane.WorldXY;
                    facadeHeightPlane.Translate(new Vector3d(0, 0, facadeHeight));
                    pLPolyline.Transform(Transform.PlanarProjection(facadeHeightPlane));

                    ///Creating individual faces seems to work better/cleaner than lofting curves
                    for (int i = 0; i < pLLines.Count(); i++)
                    {
                        Line bottomEdge = pLLines[i];
                        Line topEdge    = bottomEdge;
                        topEdge.Transform(Transform.PlanarProjection(facadeHeightPlane));
                        pyramidBrepList.Add(Brep.CreateFromCornerPoints(bottomEdge.PointAt(0), bottomEdge.PointAt(1), topEdge.PointAt(1), topEdge.PointAt(0), DocumentTolerance()));
                    }
                }

                foreach (Line edge in pLPolyline.GetSegments())
                {
                    pyramidBrepList.Add(Brep.CreateFromCornerPoints(edge.PointAt(0), centroid, edge.PointAt(1), DocumentTolerance()));
                }

                Brep[] pyramidBrep = Brep.CreateSolid(pyramidBrepList, DocumentTolerance());
                if (pyramidBrep[0].IsSolid)
                {
                    roof = GH_Convert.ToGeometricGoo(pyramidBrep[0]);
                }
                break;

            case "skillion":
                Line   frontEdge     = new Line();
                Line   backEdge      = new Line();
                double frontAngleMin = RhinoMath.ToRadians(90);
                double backAngleMin  = RhinoMath.ToRadians(90);

                foreach (Line edge in edges)
                {
                    Point3d  closestPt       = edge.ClosestPoint(centroid, true);
                    Vector3d perpVector      = closestPt - centroid;
                    double   angleDifference = Vector3d.VectorAngle(roofDirectionVector, perpVector);
                    if (angleDifference < frontAngleMin)
                    {
                        frontEdge     = edge;
                        frontAngleMin = angleDifference;
                    }
                    if (angleDifference > backAngleMin)
                    {
                        backEdge     = edge;
                        backAngleMin = angleDifference;
                    }
                }

                Point3d backEdgeFrom = backEdge.From;
                backEdgeFrom.Z = height;
                Point3d backEdgeTo = backEdge.To;
                backEdgeTo.Z = height;
                Point3d frontEdgeFrom = frontEdge.From;
                frontEdgeFrom.Z = facadeHeight;
                Point3d frontEdgeTo = frontEdge.To;
                frontEdgeTo.Z = facadeHeight;

                List <Point3d> basePtList = new List <Point3d> {
                    backEdge.From, backEdge.To, frontEdge.From, frontEdge.To, backEdge.From
                };
                Polyline       basePolyline = new Polyline(basePtList);
                List <Point3d> topPtList    = new List <Point3d> {
                    backEdgeFrom, backEdgeTo, frontEdgeFrom, frontEdgeTo, backEdgeFrom
                };
                Polyline topPolyline = new Polyline(topPtList);

                ///Creating individual faces seems to work better/cleaner than lofting curves
                List <Brep> skillionBreps = new List <Brep>();
                Line[]      baseLines     = basePolyline.GetSegments();
                Line[]      topLines      = topPolyline.GetSegments();
                for (int i = 0; i < baseLines.Count(); i++)
                {
                    Line bottomEdge = baseLines[i];
                    Line topEdge    = topLines[i];
                    skillionBreps.Add(Brep.CreateFromCornerPoints(bottomEdge.PointAt(0), bottomEdge.PointAt(1), topEdge.PointAt(1), topEdge.PointAt(0), DocumentTolerance()));
                }
                Brep baseSkillion = Brep.CreateFromCornerPoints(backEdge.From, backEdge.To, frontEdge.From, frontEdge.To, DocumentTolerance());
                Brep topSkillion  = Brep.CreateFromCornerPoints(backEdgeFrom, backEdgeTo, frontEdgeFrom, frontEdgeTo, DocumentTolerance());

                skillionBreps.Add(baseSkillion);
                skillionBreps.Add(topSkillion);
                Brep[] skillion = Brep.CreateSolid(skillionBreps, DocumentTolerance());
                if (skillion.Count() > 0)
                {
                    roof = GH_Convert.ToGeometricGoo(skillion[0]);
                }

                break;

            case "gabled":
                ///TODO: Look into getting oriented bbox using front edge as orientation plane,
                ///extrude gable roof profile from face of bbox, trim roof geo from footprint,
                ///loft between footprint and trimmed roof edges and join everything.

                ///Need to simply polylines with colinear segments. Angle tolerance based on Notre-Dame de Paris case
                //pL.Simplify(CurveSimplifyOptions.All, 0, RhinoMath.ToRadians(2)).TryGetPolyline(out Polyline pLSimplified);
                Polyline pLSimplified = pL.ToPolyline();
                pLSimplified.MergeColinearSegments(DocumentAngleTolerance() * 5, true);

                Line[] edgesSimplified = pLSimplified.GetSegments();
                if (edgesSimplified.Count() != 4)
                {
                    break;
                }
                Line        ridge            = new Line();
                Line        eaveOne          = new Line();
                Line        eaveTwo          = new Line();
                Polyline    topGablePolyline = new Polyline();
                List <Brep> gableBreps       = new List <Brep>();

                if ((edgesSimplified[0].Length > edgesSimplified[1].Length && roofOrientationString != "across") || ((edgesSimplified[0].Length < edgesSimplified[1].Length && roofOrientationString == "across")))
                {
                    ridge         = new Line(edgesSimplified[3].PointAt(0.5), edgesSimplified[1].PointAt(0.5));
                    ridge.FromZ   = height;
                    ridge.ToZ     = height;
                    eaveOne       = edgesSimplified[0];
                    eaveOne.FromZ = facadeHeight;
                    eaveOne.ToZ   = facadeHeight;
                    eaveTwo       = edgesSimplified[2];
                    eaveTwo.Flip();
                    eaveTwo.FromZ    = facadeHeight;
                    eaveTwo.ToZ      = facadeHeight;
                    topGablePolyline = new Polyline {
                        eaveOne.From, eaveOne.To, ridge.To, eaveTwo.To, eaveTwo.From, ridge.From, eaveOne.From
                    };

                    Brep[] gableRoof = Brep.CreateFromLoft(new List <Curve> {
                        eaveOne.ToNurbsCurve(), ridge.ToNurbsCurve(), eaveTwo.ToNurbsCurve()
                    }, Point3d.Unset, Point3d.Unset, LoftType.Straight, false);
                    gableRoof[0].Faces.SplitKinkyFaces();
                    gableBreps.Add(gableRoof[0]);
                }

                if ((edgesSimplified[0].Length > edgesSimplified[1].Length && roofOrientationString == "across") || (edgesSimplified[0].Length < edgesSimplified[1].Length && roofOrientationString != "across"))
                {
                    ridge         = new Line(edgesSimplified[0].PointAt(0.5), edgesSimplified[2].PointAt(0.5));
                    ridge.FromZ   = height;
                    ridge.ToZ     = height;
                    eaveOne       = edgesSimplified[1];
                    eaveOne.FromZ = facadeHeight;
                    eaveOne.ToZ   = facadeHeight;
                    eaveTwo       = edgesSimplified[3];
                    eaveTwo.Flip();
                    eaveTwo.FromZ    = facadeHeight;
                    eaveTwo.ToZ      = facadeHeight;
                    topGablePolyline = new Polyline {
                        eaveTwo.From, ridge.From, eaveOne.From, eaveOne.To, ridge.To, eaveTwo.To, eaveTwo.From
                    };

                    Brep[] gableRoof = Brep.CreateFromLoft(new List <Curve> {
                        eaveOne.ToNurbsCurve(), ridge.ToNurbsCurve(), eaveTwo.ToNurbsCurve()
                    }, Point3d.Unset, Point3d.Unset, LoftType.Straight, false);
                    gableRoof[0].Faces.SplitKinkyFaces();
                    gableBreps.Add(gableRoof[0]);
                }

                Brep[] gablewalls = Brep.CreateFromLoft(new List <Curve> {
                    pLSimplified.ToPolylineCurve(), topGablePolyline.ToPolylineCurve()
                }, Point3d.Unset, Point3d.Unset, LoftType.Straight, false);
                gablewalls[0].Faces.SplitKinkyFaces();
                gablewalls[0].MergeCoplanarFaces(DocumentTolerance());
                gableBreps.Add(gablewalls[0]);

                Brep baseGable = Brep.CreateFromCornerPoints(edgesSimplified[0].From, edgesSimplified[0].To, edgesSimplified[2].From, edgesSimplified[2].To, DocumentTolerance());
                gableBreps.Add(baseGable);
                Brep[] gable = Brep.JoinBreps(gableBreps, DocumentTolerance());

                if (gable[0].IsValid)
                {
                    roof = GH_Convert.ToGeometricGoo(gable[0]);
                }
                break;

            default:
                break;
            }

            return(roof);
        }
コード例 #20
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)
        {
            List <Point3d> points    = new List <Point3d>();
            Point3d        point0    = new Point3d();
            Point3d        point1    = new Point3d();
            double         tolerance = 0;

            if (!DA.GetDataList(0, points))
            {
                return;
            }
            if (!DA.GetData(1, ref point0))
            {
                return;
            }
            if (!DA.GetData(2, ref point1))
            {
                return;
            }
            if (!DA.GetData(3, ref tolerance))
            {
                return;
            }
            Vector3d vc2 = Point3d.Subtract(point1, point0);

            if (p.UseDegrees)
            {
                tolerance = RhinoMath.ToRadians(tolerance);
            }
            /////////////////////////////////////////////////////////
            List <int>     mems = new List <int>();
            List <Point3d> pty  = new List <Point3d>();
            bool           flag = true;///终止循环

            pty.Add(point0);
            pty.Add(point1);
            for (int i = 0; i < 2; i++)///用户输入点的序号
            {
                for (int j = 0; j < points.Count; j++)
                {
                    if (points[j] == pty[i])
                    {
                        mems.Add(j);
                        break;
                    }
                }
            }
            #region
            while (flag)////////////////////该循环每循环一次,则找出最近的满足条件的一个点直到找完为止
            {
                double  max   = double.MaxValue;
                Point3d getPt = Point3d.Unset;
                int     index = int.MaxValue;
                for (int i = 0; i < points.Count; i++)
                {
                    if (pty.Contains(points[i]))
                    {
                        continue;
                    }
                    Vector3d test  = Point3d.Subtract(points[i], pty[pty.Count - 1]);
                    double   angle = Vector3d.VectorAngle(test, vc2);
                    double   dist  = points[i].DistanceTo(pty[pty.Count - 1]);
                    if (angle <= tolerance && max > dist)
                    {
                        getPt = points[i];
                        max   = dist;
                        index = i;
                    }
                }
                if (getPt != Point3d.Unset)
                {
                    vc2 = Point3d.Subtract(getPt, pty[pty.Count - 1]);
                    pty.Add(getPt);
                    mems.Add(index);
                }
                else
                {
                    flag = false;
                }
            }
            #endregion ;
            DA.SetDataList(0, pty);
            DA.SetDataList(1, mems);
        }
コード例 #21
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)
        {
            List <Curve> curves = new List <Curve>();
            List <Curve> c      = new List <Curve>();
            double       angle  = 0;

            if (!DA.GetDataList(0, curves))
            {
                return;
            }
            if (!DA.GetDataList(1, c))
            {
                return;
            }
            if (!DA.GetData(2, ref angle))
            {
                return;
            }
            if (p.UseDegrees)
            {
                angle = RhinoMath.ToRadians(angle);
            }
            //////////////////////////////////////////////////////////
            List <Curve> collect   = new List <Curve>();
            List <int>   index     = new List <int>();
            bool         flag1     = false;
            bool         flag2     = false;
            Curve        c1        = null;
            List <Curve> same      = new List <Curve>();
            List <int>   sameindex = chongfu(curves, c, out same);////删除与指定曲线重合部分后的源曲线

            for (int k = 0; k < c.Count; k++)
            {
                c1 = c[k];
                while (true)
                {
                    for (int q = 0; q < curves.Count; q++)
                    {
                        flag1 = false;
                        Vector3d v1 = Point3d.Subtract(c1.PointAtEnd, c1.PointAtStart);
                        if (curves[q] == null)
                        {
                            continue;
                        }
                        Curve    c2 = curves[q];
                        Vector3d v2 = Point3d.Subtract(c2.PointAtEnd, c2.PointAtStart);
                        if (Rhino.Geometry.Intersect.Intersection.CurveCurve(c1, c2, 0, 0).Count == 1 && zhefan(c1, c2))///有一个交点
                        {
                            double ag = Vector3d.VectorAngle(v1, v2);
                            if (ag > Math.PI * 0.5)
                            {
                                ag = Math.PI - ag;
                            }
                            if (ag <= angle)////角度满足要求
                            {
                                index.Add(q);
                                collect.Add(curves[q]);
                                c1        = collect[collect.Count - 1];
                                curves[q] = null;
                                flag1     = true;
                                break;
                            }
                        }
                    }
                    if (flag1)////如果有满足情况的曲线,则继续执行上一步操作
                    {
                        continue;
                    }
                    //////////////////////////////////////////////////////////////////先判断第一个方向所有满足条件的线
                    //////////////////////////////////////////////////////////////////
                    if (!flag2)
                    {
                        c1    = c[k];
                        flag1 = false;
                        flag2 = true;
                        continue;
                    }
                    if (collect.Count == 0)/////如果没有匹配的曲线
                    {
                        flag2 = false;
                        flag1 = false;
                        break;
                    }
                    flag2 = false;
                    flag1 = false;
                    break;
                }
            }
            collect.AddRange(same);
            index.AddRange(sameindex);
            DA.SetDataList(0, collect);
            DA.SetDataList(1, index);
        }
コード例 #22
0
    // <Custom additional code>
    Plane AdjustAttackAngle(WindingClass wp)
    {
        Vector3d tangent = wp.edgeCurve.TangentAt(wp.edgeParam);

        Plane tempPln;

        wp.edgeCurve.FrameAt(wp.edgeParam, out tempPln);

        Vector3d perpVector = Vector3d.CrossProduct(tangent, tempPln.YAxis);

        Plane npln = new Plane(wp.basePlane.Origin, perpVector, tangent);


        if (wp.edgeIndex == 1)
        {
            npln.Rotate(RhinoMath.ToRadians(180), npln.ZAxis);
            if (wp.edgeParam > 0.5)
            {
                npln.Rotate(RhinoMath.ToRadians(-105), npln.YAxis);
                npln.Rotate(RhinoMath.ToRadians(-90), npln.ZAxis);
                npln.Rotate(RhinoMath.ToRadians(-70), npln.XAxis);
            }
            else
            {
                npln.Rotate(RhinoMath.ToRadians(-105), npln.YAxis);
                npln.Rotate(RhinoMath.ToRadians(-90), npln.ZAxis);
                npln.Rotate(RhinoMath.ToRadians(-70), npln.XAxis);
                npln.Rotate(RhinoMath.ToRadians(60), npln.ZAxis);
            }
        }

        else if (wp.edgeIndex == 3)
        {
            npln = new Plane(wp.basePlane);
            npln.Rotate(RhinoMath.ToRadians(180), npln.XAxis);

            npln.Rotate(wp.edgeParam > 0.5 ? RhinoMath.ToRadians(50) : RhinoMath.ToRadians(70), npln.ZAxis);
        }
        else if (wp.edgeIndex == 2)
        {
            npln.Rotate(RhinoMath.ToRadians(90), npln.ZAxis);
            npln.Rotate(RhinoMath.ToRadians(180), npln.YAxis);
            npln.Rotate(RhinoMath.ToRadians(-80), npln.XAxis);
            if (wp.edgeParam < 0.25)
            {
                npln.Rotate(RhinoMath.ToRadians(-60), npln.ZAxis);
            }
            else if (wp.edgeParam < 0.5)
            {
                npln.Rotate(RhinoMath.ToRadians(-25), npln.ZAxis);
            }
            else if (wp.edgeParam > 0.5)
            {
                npln.Rotate(RhinoMath.ToRadians(35), npln.ZAxis);
                //npln.Rotate(RhinoMath.ToRadians(15), npln.XAxis);
            }
            //npln.Rotate(wp.edgeParam > 0.5 ? RhinoMath.ToRadians(65) : RhinoMath.ToRadians(-15), npln.ZAxis);
        }
        else if (wp.edgeIndex == 0)
        {
            npln.Rotate(RhinoMath.ToRadians(90), npln.ZAxis);
            npln.Rotate(RhinoMath.ToRadians(-90), npln.XAxis);
            npln.Rotate(wp.edgeParam > 0.5 ? RhinoMath.ToRadians(-25) : RhinoMath.ToRadians(25), npln.ZAxis);
        }

        // Check for vertical pins and reorient
        List <int> verticalPinsIds = new List <int>()
        {
            2, 6, 10, 14, 18, 22, 26, 30, 34, 38
        };

        if (wp.edgeIndex == 0)
        {
            bool isInList = verticalPinsIds.IndexOf(wp.pinIndex) != -1;
            if (isInList)
            {
                //npln.Rotate(RhinoMath.ToRadians(-110), npln.XAxis);
                //npln.Rotate(RhinoMath.ToRadians(180), npln.ZAxis);
                //if (wp.edgeParam < 0.3)
                //{
                //    npln.Rotate(RhinoMath.ToRadians(-45), npln.ZAxis);
                //    npln.Rotate(RhinoMath.ToRadians(-40), npln.YAxis);


                //}
                //else if (wp.edgeParam > 0.7)
                //{
                //    npln.Rotate(RhinoMath.ToRadians(45), npln.ZAxis);
                //    npln.Rotate(RhinoMath.ToRadians(-25), npln.XAxis);
                //    npln.Rotate(RhinoMath.ToRadians(35), npln.YAxis);
                //    npln.Rotate(RhinoMath.ToRadians(45), npln.ZAxis);
                //}
                //else
                //{
                //    npln.Rotate(RhinoMath.ToRadians(45), npln.ZAxis);
                //    npln.Rotate(RhinoMath.ToRadians(90), npln.YAxis);
                //    //npln.Rotate(RhinoMath.ToRadians(30), npln.XAxis);
                //    npln.Rotate(RhinoMath.ToRadians(45), npln.ZAxis);
                //}
                wp.isVertical = true;
            }
        }
        else if (wp.edgeIndex == 2)
        {
            bool isInList = verticalPinsIds.IndexOf(wp.pinIndex) != -1;
            if (isInList)
            {
                //npln.Rotate(RhinoMath.ToRadians(270), npln.YAxis);
                //npln.Rotate(RhinoMath.ToRadians(-90), npln.ZAxis);
                //if (wp.edgeParam < 0.3)
                //{
                //    npln.Rotate(RhinoMath.ToRadians(90), npln.YAxis);
                //    npln.Rotate(RhinoMath.ToRadians(-20), npln.ZAxis);
                //    npln.Rotate(RhinoMath.ToRadians(-40), npln.XAxis);



                //}
                //else if (wp.edgeParam > 0.7)
                //{
                //    npln.Rotate(RhinoMath.ToRadians(40), npln.ZAxis);
                //    npln.Rotate(RhinoMath.ToRadians(25), npln.YAxis);
                //    npln.Rotate(RhinoMath.ToRadians(-25), npln.XAxis);



                //}
                //else
                //{
                //    npln.Rotate(RhinoMath.ToRadians(-70), npln.XAxis);
                //    npln.Rotate(RhinoMath.ToRadians(45), npln.ZAxis);


                //}
                wp.isVertical = true;
            }
        }

        return(npln);
    }
コード例 #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)
        {
            List <Curve> polylines  = new List <Curve>();
            double       tolerance1 = 0;
            double       tolerance2 = 0;

            if (!DA.GetDataList(0, polylines))
            {
                return;
            }
            if (!DA.GetData(1, ref tolerance1))
            {
                return;
            }
            if (!DA.GetData(2, ref tolerance2))
            {
                return;
            }
            if (p.UseDegrees)
            {
                tolerance2 = RhinoMath.ToRadians(tolerance2);
            }
            List <Polyline> x     = new List <Polyline>();
            List <string>   wrong = new List <string>();

            for (int i = 0; i < polylines.Count; i++)
            {
                Polyline pl = null;
                if (polylines[i].TryGetPolyline(out pl))
                {
                    x.Add(pl);
                }
                else
                {
                    string mm = "序号为" + i + "的曲线不是多段线";
                    wrong.Add(mm);
                }
            }
            double            t1     = tolerance1;
            double            t2     = tolerance2;
            DataTree <double> length = new DataTree <double>();
            DataTree <double> angle  = new DataTree <double>();
            int num = 0;

            for (int i = 0; i < x.Count; i++)
            {
                angle.AddRange(Angles(x[i]), new GH_Path(0, num));
                Line[] lines = x[i].GetSegments();
                for (int j = 0; j < lines.Length; j++)
                {
                    length.Add(lines[j].Length, new GH_Path(0, num));
                }
                num++;
            }
            /////////////////////////////////////////////////////////////////
            DataTree <Polyline> last  = new DataTree <Polyline>();
            DataTree <int>      index = new DataTree <int>();

            num = 0;
            for (int i = 0; i < x.Count; i++)
            {
                if (x[i] == null)
                {
                    continue;
                }
                last.Add(x[i], new GH_Path(0, DA.Iteration, num));
                index.Add(i, new GH_Path(0, DA.Iteration, num));
                for (int j = 0; j < x.Count; j++)
                {
                    if (x[j] == null || i == j || x[i].SegmentCount != x[j].SegmentCount)
                    {
                        continue;
                    }
                    if (Test(length.Branch(i), length.Branch(j), t1) && Test(angle.Branch(i), angle.Branch(j), t2))
                    {
                        last.Add(x[j], new GH_Path(0, DA.Iteration, num));
                        index.Add(j, new GH_Path(0, DA.Iteration, num));
                        x[j] = null;
                    }
                }
                x[i] = null;
                num++;
            }
            DA.SetDataTree(0, last);
            DA.SetDataTree(1, index);
            DA.SetDataList(2, wrong);
        }
コード例 #24
0
        protected override void PostDrawObjects(DrawEventArgs e)
        {
            var points = new[] { new Point3d(2, 2, 0), new Point3d(2, -6, 0), new Point3d(5, -6, 0), new Point3d(5, 2, 0) };

            e.Display.DrawPolygon(points, Color.Black, false);

            var fill   = Color.FromArgb(250, Color.White);
            var center = new Point3d(2, 2, 0);
            var off_x  = new Point3d(3, 2, 0);
            var off_y  = new Point3d(2, 3, 0);
            var radius = 3;

            e.Display.DrawPoint(center, PointStyle.RoundControlPoint, Color.Black, fill, radius, 1, 0, 0, true, true);

            var world_to_screen = e.Viewport.GetTransform(CoordinateSystem.World, CoordinateSystem.Screen);
            var center_screen   = center;

            center_screen.Transform(world_to_screen);
            var off_screen = off_x;

            off_screen.Transform(world_to_screen);
            var xaxis = new Vector3d(off_screen.X - center_screen.X, off_screen.Y - center_screen.Y, 0);
            var angle = Vector3d.VectorAngle(Vector3d.XAxis, xaxis);

            if (xaxis.Y > 0)
            {
                angle = -angle;
            }
            e.Display.DrawPoint(center, PointStyle.ArrowTail, Color.Black, fill, 6, 1, 3, (float)angle, true, true);
            e.Display.DrawPoint(center, PointStyle.ArrowTail, Color.Black, fill, 6, 1, 3, (float)(angle + RhinoMath.ToRadians(180)), true, true);

            off_screen = off_y;
            off_screen.Transform(world_to_screen);
            var yaxis = new Vector3d(off_screen.X - center_screen.X, off_screen.Y - center_screen.Y, 0);

            angle = Vector3d.VectorAngle(Vector3d.YAxis, yaxis);
            if (yaxis.X < 0)
            {
                angle = -angle;
            }
            e.Display.DrawPoint(center, PointStyle.ArrowTail, Color.Black, fill, 6, 1, 3, (float)(angle + RhinoMath.ToRadians(90)), true, true);
            e.Display.DrawPoint(center, PointStyle.ArrowTail, Color.Black, fill, 6, 1, 3, (float)(angle + RhinoMath.ToRadians(270)), true, true);

            center = new Point3d(5, -2, 0);
            e.Display.DrawPoint(center, PointStyle.RoundControlPoint, Color.Black, fill, radius, 1, 0, 0, true, true);
            center_screen = center;
            center_screen.Transform(world_to_screen);
            off_screen    = center;
            off_screen.X += 1;
            off_screen.Transform(world_to_screen);
            xaxis = new Vector3d(off_screen.X - center_screen.X, off_screen.Y - center_screen.Y, 0);
            angle = Vector3d.VectorAngle(Vector3d.XAxis, xaxis);
            if (xaxis.Y > 0)
            {
                angle = -angle;
            }
            e.Display.DrawPoint(center, PointStyle.ArrowTail, Color.Black, fill, 6, 1, 3, (float)angle, true, true);
            e.Display.DrawPoint(center, PointStyle.ArrowTail, Color.Black, fill, 6, 1, 3, (float)(angle + RhinoMath.ToRadians(180)), true, true);

            e.Display.DrawPoint(points[1], PointStyle.Pin, Color.Black, Color.PeachPuff, 15, 1, 5, 0, true, true);

            base.PostDrawObjects(e);
        }
コード例 #25
0
        public override bool Construct(bool append = false)
        {
            if (!append)
            {
                foreach (var part in Parts)
                {
                    part.Geometry.Clear();
                }
            }

            double added = ExtraLength;

            var obeam = (Over.Element as BeamElement).Beam;
            var ubeam = (Under.Element as BeamElement).Beam;

            var oPlane = obeam.GetPlane(Over.Parameter);
            var uPlane = ubeam.GetPlane(Under.Parameter);

            // Calculate offset for backcut angle
            double tan = Math.Tan(RhinoMath.ToRadians(Math.Max(1.0, TaperAngle)));
            double addedTan = added * tan;
            if (DepthOverride == 0.0) DepthOverride = obeam.Height;
            double TaperOffset = DepthOverride * 0.5 * tan;

            uPlane = UnifyPlanes(oPlane, uPlane);

            var xaxis = oPlane.ZAxis;
            var yaxis = uPlane.ZAxis;
            var zaxis = Vector3d.CrossProduct(xaxis, yaxis);
            zaxis.Unitize();

            // Create centre plane
            var plane = new Plane((oPlane.Origin + uPlane.Origin) / 2, zaxis);
            var planeProj = plane.ProjectAlongVector(zaxis);

            // Create side planes for Over
            var oPlanes = new Plane[2];
            oPlanes[0] = new Plane(oPlane.Origin - oPlane.XAxis * obeam.Width * 0.5,
              oPlane.ZAxis, oPlane.YAxis);
            oPlanes[1] = new Plane(oPlane.Origin + oPlane.XAxis * obeam.Width * 0.5,
              -oPlane.ZAxis, oPlane.YAxis);

            // Create side planes for Under
            var uPlanes = new Plane[2];
            uPlanes[0] = new Plane(uPlane.Origin - uPlane.XAxis * ubeam.Width * 0.5,
              uPlane.ZAxis, uPlane.YAxis);
            uPlanes[1] = new Plane(uPlane.Origin + uPlane.XAxis * ubeam.Width * 0.5,
              -uPlane.ZAxis, uPlane.YAxis);

            var corners = new Point3d[4];

            Rhino.Geometry.Intersect.Intersection.PlanePlanePlane(plane, oPlanes[0], uPlanes[0], out corners[0]);
            Rhino.Geometry.Intersect.Intersection.PlanePlanePlane(plane, oPlanes[0], uPlanes[1], out corners[1]);
            Rhino.Geometry.Intersect.Intersection.PlanePlanePlane(plane, oPlanes[1], uPlanes[1], out corners[2]);
            Rhino.Geometry.Intersect.Intersection.PlanePlanePlane(plane, oPlanes[1], uPlanes[0], out corners[3]);

            var offsetCorners = new Point3d[3];
            offsetCorners[0] = corners[0] - yaxis * TaperOffset;
            offsetCorners[1] = corners[1] - yaxis * TaperOffset - xaxis * TaperOffset;
            offsetCorners[2] = corners[2] - xaxis * TaperOffset;

            var topCorners = new Point3d[4];
            topCorners[0] = corners[0] - zaxis * (obeam.Height * 0.5 + added) + yaxis * addedTan;
            topCorners[1] = corners[1] - zaxis * (obeam.Height * 0.5 + added) + yaxis * addedTan + xaxis * addedTan;
            topCorners[2] = corners[2] - zaxis * (obeam.Height * 0.5 + added) + xaxis * addedTan;
            topCorners[3] = corners[3] - zaxis * (obeam.Height * 0.5 + added);



            var btmCorners = new Point3d[4];
            btmCorners[0] = corners[0] + zaxis * (obeam.Height * 0.5 + added) + yaxis * addedTan;
            btmCorners[1] = corners[1] + zaxis * (obeam.Height * 0.5 + added) + yaxis * addedTan + xaxis * addedTan;
            btmCorners[2] = corners[2] + zaxis * (obeam.Height * 0.5 + added) + xaxis * addedTan;
            btmCorners[3] = corners[3] + zaxis * (obeam.Height * 0.5 + added);

#if DEBUG
            debug.Add(corners[0]);
            debug.Add(corners[1]);
            debug.Add(corners[2]);
            debug.Add(corners[3]);

            debug.Add(offsetCorners[0]);
            debug.Add(offsetCorners[1]);
            debug.Add(offsetCorners[2]);

            debug.Add(topCorners[0]);
            debug.Add(topCorners[1]);
            debug.Add(topCorners[2]);
            debug.Add(topCorners[3]);

            debug.Add(btmCorners[0]);
            debug.Add(btmCorners[1]);
            debug.Add(btmCorners[2]);
            debug.Add(btmCorners[3]);
#endif

            var overSrf = new Brep[6];
            overSrf[0] = Brep.CreateFromCornerPoints(offsetCorners[0], offsetCorners[1],
              offsetCorners[2] - yaxis * added, corners[3] - yaxis * added,
              0.01);
            overSrf[1] = Brep.CreateFromCornerPoints(offsetCorners[0], btmCorners[0], btmCorners[1], offsetCorners[1],
              0.01);
            overSrf[2] = Brep.CreateFromCornerPoints(offsetCorners[1], topCorners[1],
              topCorners[2] - yaxis * added, offsetCorners[2] - yaxis * added,
              0.01);
            overSrf[3] = Brep.CreateFromCornerPoints(corners[3] - yaxis * added, topCorners[3] - yaxis * added,
              topCorners[0], offsetCorners[0],
              0.01);
            overSrf[4] = Brep.CreateFromCornerPoints(topCorners[0], offsetCorners[0], btmCorners[0],
              0.01);
            overSrf[5] = Brep.CreateFromCornerPoints(topCorners[1], offsetCorners[1], btmCorners[1],
              0.01);

            Over.Geometry.AddRange(Brep.JoinBreps(overSrf, 0.01));
            Brep brepOver = Over.Geometry[0];
            brepOver.MergeCoplanarFaces(0.01);

            /* UNDER */
            var underSrf = new Brep[6];
            underSrf[0] = Brep.CreateFromCornerPoints(offsetCorners[0] - xaxis * added, offsetCorners[1],
              offsetCorners[2], corners[3] - xaxis * added,
              0.01);
            underSrf[1] = Brep.CreateFromCornerPoints(offsetCorners[0] - xaxis * added, btmCorners[0] - xaxis * added,
              btmCorners[1], offsetCorners[1],
              0.01);
            underSrf[2] = Brep.CreateFromCornerPoints(offsetCorners[1], topCorners[1],
              topCorners[2], offsetCorners[2],
              0.01);
            underSrf[3] = Brep.CreateFromCornerPoints(offsetCorners[2], btmCorners[2],
              btmCorners[3] - xaxis * added, corners[3] - xaxis * added,
              0.01);
            underSrf[4] = Brep.CreateFromCornerPoints(topCorners[2], offsetCorners[2], btmCorners[2],
              0.01);
            underSrf[5] = Brep.CreateFromCornerPoints(topCorners[1], offsetCorners[1], btmCorners[1],
              0.01);

            Under.Geometry.AddRange(Brep.JoinBreps(underSrf, 0.01));

            Brep brepUnder = Under.Geometry[0];
            brepUnder.MergeCoplanarFaces(0.01);

            return true;
        }
コード例 #26
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)
        {
            List <Curve> curves = new List <Curve>();
            double       angle  = 0;

            if (!DA.GetDataList(0, curves))
            {
                return;
            }
            if (!DA.GetData(1, ref angle))
            {
                return;
            }
            if (p.UseDegrees)///设置的是角度则转换为弧度
            {
                angle = RhinoMath.ToRadians(angle);
            }
            DataTree <Curve> last    = new DataTree <Curve>();
            DataTree <int>   indexes = new DataTree <int>();
            List <Curve>     collect = new List <Curve>();
            List <int>       index   = new List <int>();
            int   mem    = 0;
            int   branch = DA.Iteration;
            bool  flag1  = false;
            bool  flag2  = false;
            bool  flag3  = true;
            Curve c1     = null;

            for (int i = 0; i < curves.Count; i++)
            {
                if (curves[i] == null)
                {
                    continue;
                }
                if (!flag1)
                {
                    c1 = curves[i];
                }
                if (flag3)
                {
                    collect.Add(curves[i]);
                    index.Add(i);
                }
                flag1 = false;
                Vector3d v1 = Point3d.Subtract(c1.PointAtEnd, c1.PointAtStart);
                for (int q = 0; q < curves.Count; q++)
                {
                    if (curves[q] == null || i == q)
                    {
                        continue;
                    }
                    Curve    c2 = curves[q];
                    Vector3d v2 = Point3d.Subtract(c2.PointAtEnd, c2.PointAtStart);
                    if (Rhino.Geometry.Intersect.Intersection.CurveCurve(c1, c2, 0, 0).Count == 1 && zhefan(c1, c2))///有一个交点
                    {
                        double ag = Vector3d.VectorAngle(v1, v2);
                        if (ag > Math.PI * 0.5)
                        {
                            ag = Math.PI - ag;
                        }
                        if (ag <= angle)////角度满足要求
                        {
                            index.Add(q);
                            collect.Add(curves[q]);
                            c1        = collect[collect.Count - 1];
                            curves[q] = null;
                            flag1     = true;
                            break;
                        }
                    }
                }
                if (flag1)////如果有满足情况的曲线,则继续执行上一步操作
                {
                    flag3 = false;
                    i--;
                    continue;
                }
                //////////////////////////////////////////////////////////////////先判断第一个方向所有满足条件的线
                //////////////////////////////////////////////////////////////////
                if (!flag2)
                {
                    flag1 = false;
                    flag2 = true;
                    i--;
                    flag3 = false;
                    index.Reverse();
                    collect.Reverse();
                    continue;
                }
                last.AddRange(collect, new GH_Path(0, branch, mem));
                indexes.AddRange(index, new GH_Path(0, branch, mem));
                mem++;
                curves[i] = null;
                collect.Clear();
                index.Clear();
                flag3 = true;
                flag2 = false;
                flag1 = false;
            }
            DA.SetDataTree(0, last);
            DA.SetDataTree(1, indexes);
        }
コード例 #27
0
 public Circle LongitudeDegrees(double degrees)
 {
     return(LongitudeRadians(RhinoMath.ToRadians(degrees)));
 }
コード例 #28
0
        protected override void SolveInstance(IGH_DataAccess access)
        {
            Curve         curve = null;
            List <string> edges = new List <string>();
            List <string> fills = new List <string>();
            bool          order = true;

            if (!access.GetData(0, ref curve))
            {
                return;
            }
            if (!access.GetData(3, ref order))
            {
                return;
            }

            access.GetDataList(1, edges);
            access.GetDataList(2, fills);

            for (int i = edges.Count - 1; i >= 0; i--)
            {
                if (string.IsNullOrWhiteSpace(edges[i]))
                {
                    edges.RemoveAt(i);
                }
            }

            for (int i = fills.Count - 1; i >= 0; i--)
            {
                if (string.IsNullOrWhiteSpace(fills[i]))
                {
                    fills.RemoveAt(i);
                }
            }

            if (edges.Count == 0 && fills.Count == 0)
            {
                AddRuntimeMessage(GH_RuntimeMessageLevel.Warning, "At least a single edge or fill is required.");
                return;
            }

            Polyline polyline;

            if (!curve.TryGetPolyline(out polyline))
            {
                curve = curve.ToPolyline(0.1, RhinoMath.ToRadians(0.2), 0.01, 100);
                curve.TryGetPolyline(out polyline);
            }
            if (polyline == null)
            {
                AddRuntimeMessage(GH_RuntimeMessageLevel.Error, "Curve could not be converted to polyline.");
                return;
            }

            GdiShapeGoo goo = new GdiShapeGoo(polyline, edges, fills)
            {
                DrawFillsBeforeEdges = order
            };

            access.SetData(0, goo);
        }
コード例 #29
0
 public DisplayBitmapDrawList()
 {
     MaximumCachedSortLists = 10;
     SortAngleTolerance     = RhinoMath.ToRadians(5);
 }
コード例 #30
0
        public void ConstructJointsEdgeJoints(int sideDivisions = 2, double dovetailAngleDegrees = 5)
        {
            sidePlanesR90SideJoints = new Plane[n][];
            if (sideDivisions % 2 == 1)
            {
                sideDivisions -= 1;
            }
            //sideDivisions = Math.Max(sideDivisions, 0);


            //1 addPlanes at each corner

            for (int i = 0; i < n; i++)
            {
                //if (sidePlanesBiFlags[i]) { //Check if not bisector
                int next = NGonsCore.MathUtil.Wrap(i + 1, n);
                int prev = NGonsCore.MathUtil.Wrap(i - 1, n);

                sidePlanesR90SideJoints[i] = new Plane[sideDivisions];

                //i - side polyline  1 - two polylines
                //2---1
                //3---0

                //Interpolate polyline
                Point3d[] interpolatedPts = NGonsCore.PointUtil.InterpolatePoints(
                    (sideOutlines0[i][0][2] + sideOutlines1[i][1][2]) * 0.5,
                    (sideOutlines0[i][0][3] + sideOutlines1[i][1][3]) * 0.5,
                    sideDivisions, false);

                for (int j = 0; j < sideDivisions; j++)
                {
                    int shift = (j % 2 == 0) ? 1 : -1;
                    sidePlanesR90SideJoints[i][j] = new Plane(sidePlanesR90[i]);
                    sidePlanesR90SideJoints[i][j].Rotate(angle90, sidePlanesR90SideJoints[i][j].XAxis);
                    sidePlanesR90SideJoints[i][j].Rotate(shift * RhinoMath.ToRadians(dovetailAngleDegrees), sidePlanesR90SideJoints[i][j].YAxis);
                    sidePlanesR90SideJoints[i][j].Origin = interpolatedPts[j];
                    //Rhino.RhinoDoc.ActiveDoc.Objects.AddRectangle(new Rectangle3d(sidePlanesR90SideJoints[i][j], new Interval(-0.05, 0.05), new Interval(-0.05, 0.05)));
                }
                //} else sidePlanesR90SideJoints[i] = null;
            }

            //2 Create zigzag Polylines

            for (int i = 0; i < n; i++)
            {
                Polyline zigzag0;
                Polyline zigzag1;

                if (i != 0)
                {
                    zigzag0 = new Polyline()
                    {
                        sideOutlines0[i][0][2]
                    };
                    zigzag1 = new Polyline()
                    {
                        sideOutlines0[i][1][2]
                    };
                }
                else
                {
                    zigzag0 = new Polyline()
                    {
                        sideOutlines1[i][0][2]
                    };
                    zigzag1 = new Polyline()
                    {
                        sideOutlines1[i][1][2]
                    };
                }

                int next = NGonsCore.MathUtil.Wrap(i + 1, n);
                int prev = NGonsCore.MathUtil.Wrap(i - 1, n);

                //Rhino.RhinoApp.WriteLine(sidePlanesBiFlags[i].ToString() + " " + i.ToString());

                if (sidePlanesBiFlags[prev] && i != 0)
                {
                    for (int j = 0; j < sideDivisions; j++)
                    {
                        zigzag0.AddRange(IntersectTwoLinesWithOnePlane(sideOutlines0[i][0].SegmentAt(2), sideOutlines1[i][0].SegmentAt(2), sidePlanesR90SideJoints[i][j], j));
                        zigzag1.AddRange(IntersectTwoLinesWithOnePlane(sideOutlines0[i][1].SegmentAt(2), sideOutlines1[i][1].SegmentAt(2), sidePlanesR90SideJoints[i][j], j));
                    }
                }

                if (i != 0)
                {
                    zigzag0.Add(sideOutlines0[i][0][3]);
                    zigzag1.Add(sideOutlines0[i][1][3]);
                }
                else
                {
                    zigzag0.Add(sideOutlines1[i][0][3]);
                    zigzag1.Add(sideOutlines1[i][1][3]);
                }

                if (i != n - 1)
                {
                    zigzag0.Add(sideOutlines0[i][0][0]);
                    zigzag1.Add(sideOutlines0[i][1][0]);
                }
                else
                {
                    zigzag0.Add(sideOutlines1[i][0][0]);
                    zigzag1.Add(sideOutlines1[i][1][0]);
                }



                if (sidePlanesBiFlags[i] && i != n - 1)
                {
                    for (int j = sideDivisions - 1; j >= 0; j--)
                    {
                        zigzag0.AddRange(IntersectTwoLinesWithOnePlane(sideOutlines0[i][0].SegmentAt(0), sideOutlines1[i][0].SegmentAt(0), sidePlanesR90SideJoints[next][j], j, 1));
                        zigzag1.AddRange(IntersectTwoLinesWithOnePlane(sideOutlines0[i][1].SegmentAt(0), sideOutlines1[i][1].SegmentAt(0), sidePlanesR90SideJoints[next][j], j, 1));
                    }
                }


                if (i != n - 1)
                {
                    zigzag0.Add(sideOutlines0[i][0][1]);
                    zigzag1.Add(sideOutlines0[i][1][1]);
                }
                else
                {
                    zigzag0.Add(sideOutlines1[i][0][1]);
                    zigzag1.Add(sideOutlines1[i][1][1]);
                }


                zigzag0.Close();
                zigzag1.Close();

                //Rhino.RhinoDoc.ActiveDoc.Objects.AddPolyline(zigzag0);
                //Rhino.RhinoDoc.ActiveDoc.Objects.AddPolyline(zigzag1);

                sideOutlines0[i][0] = zigzag0;
                sideOutlines0[i][1] = zigzag1;
                //RhinoDoc.ActiveDoc.Objects.AddPolyline(zigzag0);
            }
        }