protected override GH_GetterResult Prompt_Singular(ref IGH_Goo value) { Rhino.Input.Custom.GetPoint gpC = new Rhino.Input.Custom.GetPoint(); gpC.SetCommandPrompt("Set default tool center point."); gpC.AcceptNothing(true); Rhino.Input.Custom.GetOption go = new Rhino.Input.Custom.GetOption(); go.SetCommandPrompt("Set default tool."); go.AcceptNothing(true); go.AddOption("True"); switch (go.Get()) { case Rhino.Input.GetResult.Option: if (go.Option().EnglishName == "True") { value = ABBTool.Default; } return(GH_GetterResult.success); case Rhino.Input.GetResult.Nothing: return(GH_GetterResult.accept); default: return(GH_GetterResult.cancel); } }
public static Rhino.Commands.Result AddLine(Rhino.RhinoDoc doc) { Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Start of line"); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) { return(gp.CommandResult()); } Rhino.Geometry.Point3d pt_start = gp.Point(); gp.SetCommandPrompt("End of line"); gp.SetBasePoint(pt_start, false); gp.DrawLineFromPoint(pt_start, true); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) { return(gp.CommandResult()); } Rhino.Geometry.Point3d pt_end = gp.Point(); Rhino.Geometry.Vector3d v = pt_end - pt_start; if (v.IsTiny(Rhino.RhinoMath.ZeroTolerance)) { return(Rhino.Commands.Result.Nothing); } if (doc.Objects.AddLine(pt_start, pt_end) != Guid.Empty) { doc.Views.Redraw(); return(Rhino.Commands.Result.Success); } return(Rhino.Commands.Result.Failure); }
protected override Result RunCommand(RhinoDoc doc, RunMode mode) { SampleCsGetMultiplePointsConduit conduit = new SampleCsGetMultiplePointsConduit(); conduit.Enabled = true; Rhino.Commands.Result rc = Result.Nothing; Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); while (true) { if (0 == conduit.PointCount) { gp.SetCommandPrompt("Location of point object."); gp.AcceptNothing(false); gp.ClearCommandOptions(); } else { gp.SetCommandPrompt("Location of point object. Press Enter when done"); gp.AcceptNothing(true); gp.AddOption("Undo"); } Rhino.Input.GetResult res = gp.Get(); if (res == Rhino.Input.GetResult.Point) { conduit.AddPoint(gp.Point()); doc.Views.Redraw(); } else if (res == Rhino.Input.GetResult.Option) { conduit.RemoveLastPoint(); doc.Views.Redraw(); } else if (res == Rhino.Input.GetResult.Nothing) { rc = Rhino.Commands.Result.Success; break; } else { rc = Rhino.Commands.Result.Cancel; break; } } if (rc == Result.Success && conduit.PointCount > 0) { doc.Objects.AddPoints(conduit.Points); } conduit.Enabled = false; doc.Views.Redraw(); return(rc); }
public static Rhino.Commands.Result ConstrainedCopy(Rhino.RhinoDoc doc) { // Get a single planar closed curve var go = new Rhino.Input.Custom.GetObject(); go.SetCommandPrompt("Select curve"); go.GeometryFilter = Rhino.DocObjects.ObjectType.Curve; go.GeometryAttributeFilter = Rhino.Input.Custom.GeometryAttributeFilter.ClosedCurve; go.Get(); if (go.CommandResult() != Rhino.Commands.Result.Success) { return(go.CommandResult()); } var objref = go.Object(0); var base_curve = objref.Curve(); var first_point = objref.SelectionPoint(); if (base_curve == null || !first_point.IsValid) { return(Rhino.Commands.Result.Cancel); } Rhino.Geometry.Plane plane; if (!base_curve.TryGetPlane(out plane)) { return(Rhino.Commands.Result.Cancel); } // Get a point constrained to a line passing through the initial selection // point and parallel to the plane's normal var gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Offset point"); gp.DrawLineFromPoint(first_point, true); var line = new Rhino.Geometry.Line(first_point, first_point + plane.Normal); gp.Constrain(line); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) { return(gp.CommandResult()); } var second_point = gp.Point(); Rhino.Geometry.Vector3d vec = second_point - first_point; if (vec.Length > 0.001) { var xf = Rhino.Geometry.Transform.Translation(vec); Guid id = doc.Objects.Transform(objref, xf, false); if (id != Guid.Empty) { doc.Views.Redraw(); return(Rhino.Commands.Result.Success); } } return(Rhino.Commands.Result.Cancel); }
protected override Result RunCommand(RhinoDoc doc, RunMode mode) { ObjRef obj_ref; var rc = RhinoGet.GetOneObject("Select surface for curvature measurement", true, ObjectType.Surface, out obj_ref); if (rc != Result.Success) return rc; var surface = obj_ref.Surface(); var gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Select point on surface for curvature measurement"); gp.Constrain(surface, false); gp.Get(); if (gp.CommandResult() != Result.Success) return gp.CommandResult(); var point_on_surface = gp.Point(); double u, v; if (!surface.ClosestPoint(point_on_surface, out u, out v)) return Result.Failure; var surface_curvature = surface.CurvatureAt(u, v); if (surface_curvature == null) return Result.Failure; RhinoApp.WriteLine("Surface curvature evaluation at parameter: ({0}, {1})", u, v); RhinoApp.WriteLine(" 3-D Point: ({0}, {1}, {2})", surface_curvature.Point.X, surface_curvature.Point.Y, surface_curvature.Point.Z); RhinoApp.WriteLine(" 3-D Normal: ({0}, {1}, {2})", surface_curvature.Normal.X, surface_curvature.Normal.Y, surface_curvature.Normal.Z); RhinoApp.WriteLine(string.Format(" Maximum principal curvature: {0} ({1}, {2}, {3})", surface_curvature.Kappa(0), surface_curvature.Direction(0).X, surface_curvature.Direction(0).Y, surface_curvature.Direction(0).Z)); RhinoApp.WriteLine(string.Format(" Minimum principal curvature: {0} ({1}, {2}, {3})", surface_curvature.Kappa(1), surface_curvature.Direction(1).X, surface_curvature.Direction(1).Y, surface_curvature.Direction(1).Z)); RhinoApp.WriteLine(" Gaussian curvature: {0}", surface_curvature.Gaussian); RhinoApp.WriteLine(" Mean curvature: {0}", surface_curvature.Mean); return Result.Success; }
/// <since>5.0</since> public bool PickGumball(Rhino.Input.Custom.PickContext pickContext, Rhino.Input.Custom.GetPoint getPoint) { IntPtr pThis = NonConstPointer(); IntPtr pConstPickContext = pickContext.ConstPointer(); IntPtr pGetPoint = IntPtr.Zero; if (getPoint != null) { getPoint.NonConstPointer(); } return(UnsafeNativeMethods.CRhinoGumballDisplayConduit_PickGumball(pThis, pConstPickContext, pGetPoint)); }
protected override Rhino.Commands.Result RunCommand(RhinoDoc doc, Rhino.Commands.RunMode mode) { Mesh meshObj; Point3d pointObj = new Point3d(0.0,0.0,0.0); RhinoApp.WriteLine("dikka dikka dikka..."); Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Start of ray"); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) return gp.CommandResult(); pointObj = gp.Point(); doc.Objects.AddPoint(pointObj); Rhino.Input.Custom.GetObject go = new Rhino.Input.Custom.GetObject(); go.SetCommandPrompt("Select the mesh to print"); go.Get(); Result rc = go.CommandResult(); if (rc != Rhino.Commands.Result.Success) { RhinoApp.WriteLine("sdfafadsfda"); return rc; } RhinoApp.WriteLine("2 2 dikka dikka dikka..."); meshObj = new Mesh(); if (go.ObjectCount == 1) { ObjRef tmpRef = new ObjRef(go.Object(0).ObjectId); meshObj = tmpRef.Mesh(); if (meshObj == null) { return rc; } } Ray3d rayObj = new Ray3d(pointObj, new Vector3d(1.0, 1.0, 1.0)); doc.Objects.AddPoint(rayObj.PointAt(1.0)); doc.Objects.AddPoint(rayObj.PointAt(2.0)); doc.Objects.AddPoint(rayObj.PointAt(3.0)); double p = Intersection.MeshRay(meshObj, rayObj); string a = string.Format("mesh ray gives {0:0.00}",p); doc.Objects.AddPoint(rayObj.PointAt(p)); RhinoApp.WriteLine(a); return Rhino.Commands.Result.Success; }
public static Rhino.Commands.Result CommandLineOptions(Rhino.RhinoDoc doc) { // For this example we will use a GetPoint class, but all of the custom // "Get" classes support command line options. Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("GetPoint with options"); // set up the options Rhino.Input.Custom.OptionInteger intOption = new Rhino.Input.Custom.OptionInteger(1, 1, 99); Rhino.Input.Custom.OptionDouble dblOption = new Rhino.Input.Custom.OptionDouble(2.2, 0, 99.9); Rhino.Input.Custom.OptionToggle boolOption = new Rhino.Input.Custom.OptionToggle(true, "Off", "On"); string[] listValues = new string[] { "Item0", "Item1", "Item2", "Item3", "Item4" }; gp.AddOptionInteger("Integer", ref intOption); gp.AddOptionDouble("Double", ref dblOption); gp.AddOptionToggle("Boolean", ref boolOption); int listIndex = 3; int opList = gp.AddOptionList("List", listValues, listIndex); while (true) { // perform the get operation. This will prompt the user to input a point, but also // allow for command line options defined above Rhino.Input.GetResult get_rc = gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) { return(gp.CommandResult()); } if (get_rc == Rhino.Input.GetResult.Point) { doc.Objects.AddPoint(gp.Point()); doc.Views.Redraw(); Rhino.RhinoApp.WriteLine("Command line option values are"); Rhino.RhinoApp.WriteLine(" Integer = {0}", intOption.CurrentValue); Rhino.RhinoApp.WriteLine(" Double = {0}", dblOption.CurrentValue); Rhino.RhinoApp.WriteLine(" Boolean = {0}", boolOption.CurrentValue); Rhino.RhinoApp.WriteLine(" List = {0}", listValues[listIndex]); } else if (get_rc == Rhino.Input.GetResult.Option) { if (gp.OptionIndex() == opList) { listIndex = gp.Option().CurrentListOptionIndex; } continue; } break; } return(Rhino.Commands.Result.Success); }
public static Rhino.Commands.Result CommandLineOptions(Rhino.RhinoDoc doc) { // For this example we will use a GetPoint class, but all of the custom // "Get" classes support command line options. Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("GetPoint with options"); // set up the options Rhino.Input.Custom.OptionInteger intOption = new Rhino.Input.Custom.OptionInteger(1, 1, 99); Rhino.Input.Custom.OptionDouble dblOption = new Rhino.Input.Custom.OptionDouble(2.2, 0, 99.9); Rhino.Input.Custom.OptionToggle boolOption = new Rhino.Input.Custom.OptionToggle(true, "Off", "On"); string[] listValues = new string[] { "Item0", "Item1", "Item2", "Item3", "Item4" }; gp.AddOptionInteger("Integer", ref intOption); gp.AddOptionDouble("Double", ref dblOption); gp.AddOptionToggle("Boolean", ref boolOption); int listIndex = 3; int opList = gp.AddOptionList("List", listValues, listIndex); while (true) { // perform the get operation. This will prompt the user to input a point, but also // allow for command line options defined above Rhino.Input.GetResult get_rc = gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) return gp.CommandResult(); if (get_rc == Rhino.Input.GetResult.Point) { doc.Objects.AddPoint(gp.Point()); doc.Views.Redraw(); Rhino.RhinoApp.WriteLine("Command line option values are"); Rhino.RhinoApp.WriteLine(" Integer = {0}", intOption.CurrentValue); Rhino.RhinoApp.WriteLine(" Double = {0}", dblOption.CurrentValue); Rhino.RhinoApp.WriteLine(" Boolean = {0}", boolOption.CurrentValue); Rhino.RhinoApp.WriteLine(" List = {0}", listValues[listIndex]); } else if (get_rc == Rhino.Input.GetResult.Option) { if (gp.OptionIndex() == opList) listIndex = gp.Option().CurrentListOptionIndex; continue; } break; } return Rhino.Commands.Result.Success; }
public static Rhino.Commands.Result AddNamedView(Rhino.RhinoDoc doc) { Rhino.Display.RhinoView view; Rhino.Commands.Result rc = Rhino.Input.RhinoGet.GetView("Select view to adjust", out view); if (rc != Rhino.Commands.Result.Success) { return(rc); } Rhino.Geometry.Point3d location; rc = Rhino.Input.RhinoGet.GetPoint("Camera Location", false, out location); if (rc != Rhino.Commands.Result.Success) { return(rc); } Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Look At Location"); gp.DrawLineFromPoint(location, false); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) { return(gp.CommandResult()); } Rhino.Geometry.Point3d lookat = gp.Point(); string name = view.ActiveViewport.Name; rc = Rhino.Input.RhinoGet.GetString("Name", true, ref name); if (rc != Rhino.Commands.Result.Success) { return(rc); } Rhino.Display.RhinoViewport vp = view.ActiveViewport; // save the current viewport projection vp.PushViewProjection(); vp.CameraUp = Rhino.Geometry.Vector3d.ZAxis; vp.SetCameraLocation(location, false); vp.SetCameraDirection(lookat - location, true); vp.Name = name; doc.NamedViews.Add(name, vp.Id); view.Redraw(); return(Rhino.Commands.Result.Success); }
protected override Result RunCommand(RhinoDoc doc, RunMode mode) { var view = doc.Views.ActiveView; var vp = view.ActiveViewport; var target = vp.CameraTarget; var camera = vp.CameraLocation; var gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("New target location"); gp.SetDefaultPoint(target); gp.Get(); if (gp.CommandResult() != Result.Success) { return(gp.CommandResult()); } target = gp.Point(); gp.ClearDefault(); gp.SetCommandPrompt("New camera location"); gp.SetDefaultPoint(camera); gp.SetBasePoint(target, true); gp.DrawLineFromPoint(target, true); gp.Get(); if (gp.CommandResult() != Result.Success) { return(gp.CommandResult()); } camera = gp.Point(); var camdir = target - camera; camdir.Unitize(); if (camdir.IsTiny()) { return(Result.Cancel); } vp.SetCameraLocations(target, camera); view.Redraw(); return(Result.Success); }
public static Rhino.Commands.Result InsertKnot(Rhino.RhinoDoc doc) { const ObjectType filter = Rhino.DocObjects.ObjectType.Curve; Rhino.DocObjects.ObjRef objref; Result rc = Rhino.Input.RhinoGet.GetOneObject("Select curve for knot insertion", false, filter, out objref); if (rc != Rhino.Commands.Result.Success) { return(rc); } Rhino.Geometry.Curve curve = objref.Curve(); if (null == curve) { return(Rhino.Commands.Result.Failure); } Rhino.Geometry.NurbsCurve nurb = curve.ToNurbsCurve(); if (null == nurb) { return(Rhino.Commands.Result.Failure); } Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Point on curve to add knot"); gp.Constrain(nurb, false); gp.Get(); if (gp.CommandResult() == Rhino.Commands.Result.Success) { double t; Rhino.Geometry.Curve crv = gp.PointOnCurve(out t); if (crv != null && nurb.Knots.InsertKnot(t)) { doc.Objects.Replace(objref, nurb); doc.Views.Redraw(); } } return(Rhino.Commands.Result.Success); }
public static Rhino.Commands.Result PickPoints(RhinoDoc doc) { var conduit = new PointsConduit(m_conduit_points); conduit.Enabled = true; var gp = new Rhino.Input.Custom.GetPoint(); while (true) { gp.SetCommandPrompt("click location to create point. (<ESC> exit)"); gp.AcceptNothing(true); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) { break; } m_conduit_points.Add(new ConduitPoint(gp.Point())); doc.Views.Redraw(); } var gcp = new GetConduitPoint(m_conduit_points); while (true) { gcp.SetCommandPrompt("select conduit point. (<ESC> to exit)"); gcp.AcceptNothing(true); gcp.Get(true); doc.Views.Redraw(); if (gcp.CommandResult() != Rhino.Commands.Result.Success) { break; } } return(Rhino.Commands.Result.Success); }
public static Rhino.Commands.Result AddNamedView(Rhino.RhinoDoc doc) { Rhino.Display.RhinoView view; Rhino.Commands.Result rc = Rhino.Input.RhinoGet.GetView("Select view to adjust", out view); if (rc != Rhino.Commands.Result.Success) return rc; Rhino.Geometry.Point3d location; rc = Rhino.Input.RhinoGet.GetPoint("Camera Location", false, out location); if (rc != Rhino.Commands.Result.Success) return rc; Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Look At Location"); gp.DrawLineFromPoint(location, false); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) return gp.CommandResult(); Rhino.Geometry.Point3d lookat = gp.Point(); string name = view.ActiveViewport.Name; rc = Rhino.Input.RhinoGet.GetString("Name", true, ref name); if (rc != Rhino.Commands.Result.Success) return rc; Rhino.Display.RhinoViewport vp = view.ActiveViewport; // save the current viewport projection vp.PushViewProjection(); vp.CameraUp = Rhino.Geometry.Vector3d.ZAxis; vp.SetCameraLocation(location, false); vp.SetCameraDirection(lookat - location, true); vp.Name = name; doc.NamedViews.Add(name, vp.Id); view.Redraw(); return Rhino.Commands.Result.Success; }
protected override Result RunCommand(RhinoDoc doc, RunMode mode) { const ObjectType filter = ObjectType.Brep | ObjectType.Extrusion | ObjectType.Mesh; var rc = RhinoGet.GetMultipleObjects("Select objects to contour", false, filter, out var objrefs); if (rc != Result.Success) { return(rc); } if (objrefs == null || objrefs.Length < 1) { return(Result.Failure); } rc = RhinoGet.GetPoint("Contour plane base point", false, out var base_point); if (rc != Result.Success) { return(rc); } var gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Direction perpendicular to contour planes"); gp.DrawLineFromPoint(base_point, false); gp.Get(); if (gp.CommandResult() != Result.Success) { return(gp.CommandResult()); } var end_point = gp.Point(); var interval = 1.0; rc = RhinoGet.GetNumber("Distance between contours", true, ref interval, 0.001, 10000); if (rc != Result.Success) { return(rc); } var bounds = BoundingBox.Unset; var geometries = new List <GeometryBase>(); foreach (var objref in objrefs) { var geometry = objref.Geometry(); if (geometry is Extrusion) { geometry = objref.Brep(); } geometries.Add(geometry); var bbox = geometry.GetBoundingBox(false); bounds.Union(bbox); } var normal = end_point - base_point; normal.Unitize(); var curplane = new Plane(base_point, normal); if (!curplane.DistanceTo(bounds, out var min_t, out var max_t)) { return(Result.Failure); } min_t -= interval; max_t += interval; min_t = Math.Floor(min_t / interval); max_t = Math.Ceiling(max_t / interval); var tolerance = doc.ModelAbsoluteTolerance; var tasks = new List <Task <Curve[]> >(); var gc = new Rhino.Input.Custom.GetCancel(); for (var t = min_t; t <= max_t; t += 1.0) { var offset = t * interval; var point = base_point + normal * offset; var plane = new Plane(point, normal); foreach (var geom in geometries) { var geom1 = geom; var task = Task.Run(() => Section(plane, geom1, tolerance), gc.Token); tasks.Add(task); } } gc.TaskCompleted += OnTaskCompleted; rc = gc.WaitAll(tasks, doc); return(rc); }
protected override Rhino.Commands.Result RunCommand(RhinoDoc doc, Rhino.Commands.RunMode mode) { Rhino.DocObjects.ObjRef objref; var rc = Rhino.Input.RhinoGet.GetOneObject("Select object", true, Rhino.DocObjects.ObjectType.AnyObject, out objref); if (rc != Rhino.Commands.Result.Success) { return(rc); } rc = Rhino.Input.RhinoGet.GetPoint("Start point", false, out m_point_start); if (rc != Rhino.Commands.Result.Success) { return(rc); } var obj = objref.Object(); if (obj == null) { return(Rhino.Commands.Result.Failure); } // create an instance of a GetPoint class and add a delegate // for the DynamicDraw event var gp = new Rhino.Input.Custom.GetPoint(); gp.DrawLineFromPoint(m_point_start, true); var optdouble = new Rhino.Input.Custom.OptionDouble(m_distance); bool constrain = false; var optconstrain = new Rhino.Input.Custom.OptionToggle(constrain, "Off", "On"); gp.AddOptionDouble("Distance", ref optdouble); gp.AddOptionToggle("Constrain", ref optconstrain); gp.DynamicDraw += ArrayByDistanceDraw; gp.Tag = obj; while (gp.Get() == Rhino.Input.GetResult.Option) { m_distance = optdouble.CurrentValue; if (constrain != optconstrain.CurrentValue) { constrain = optconstrain.CurrentValue; if (constrain) { var gp2 = new Rhino.Input.Custom.GetPoint(); gp2.DrawLineFromPoint(m_point_start, true); gp2.SetCommandPrompt("Second point on constraint line"); if (gp2.Get() == Rhino.Input.GetResult.Point) { gp.Constrain(m_point_start, gp2.Point()); } else { gp.ClearCommandOptions(); optconstrain.CurrentValue = false; constrain = false; gp.AddOptionDouble("Distance", ref optdouble); gp.AddOptionToggle("Constrain", ref optconstrain); } } else { gp.ClearConstraints(); } } } if (gp.CommandResult() == Rhino.Commands.Result.Success) { m_distance = optdouble.CurrentValue; var pt = gp.Point(); var vec = pt - m_point_start; double length = vec.Length; vec.Unitize(); int count = (int)(length / m_distance); for (int i = 1; i < count; i++) { var translate = vec * (i * m_distance); var xf = Rhino.Geometry.Transform.Translation(translate); doc.Objects.Transform(obj, xf, false); } doc.Views.Redraw(); } return(gp.CommandResult()); }
protected override Result RunCommand(RhinoDoc doc, RunMode mode) { // mimic the functionality of the contour command using a background threads // The tricky parts to the contour command are that it dynamically adds // sections as they are found const ObjectType filter = ObjectType.Brep | ObjectType.Extrusion | ObjectType.Mesh; ObjRef[] objrefs; var rc = RhinoGet.GetMultipleObjects("Select objects for contours", false, filter, out objrefs); if (rc != Result.Success) { return(rc); } if (objrefs == null || objrefs.Length < 1) { return(Result.Failure); } Point3d base_point; rc = RhinoGet.GetPoint("Contour plane base point", false, out base_point); if (rc != Result.Success) { return(rc); } var gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Direction perpendicular to contour planes"); gp.DrawLineFromPoint(base_point, false); gp.Get(); if (gp.CommandResult() != Result.Success) { return(gp.CommandResult()); } Point3d end_point = gp.Point(); double interval = 1; rc = RhinoGet.GetNumber("Distance between contours", true, ref interval, 0.001, 10000); if (rc != Result.Success) { return(rc); } // figure out the combined bounding box of all the selected geometry BoundingBox bounds = BoundingBox.Unset; var geometries = new List <GeometryBase>(); foreach (var objref in objrefs) { var geometry = objref.Geometry(); var extrusion = geometry as Extrusion; if (extrusion != null) { geometry = objref.Brep(); } geometries.Add(geometry); var bbox = geometry.GetBoundingBox(false); bounds.Union(bbox); } Vector3d normal = end_point - base_point; normal.Unitize(); var curplane = new Plane(base_point, normal); double min_t, max_t; if (!curplane.DistanceTo(bounds, out min_t, out max_t)) { return(Result.Failure); } min_t -= interval; max_t += interval; min_t = Math.Floor(min_t / interval); max_t = Math.Ceiling(max_t / interval); double tolerance = doc.ModelAbsoluteTolerance; var tasks = new List <Task <Curve[]> >(); var gc = new Rhino.Input.Custom.GetCancel(); for (double t = min_t; t <= max_t; t += 1.0) { double offset = t * interval; var point = base_point + normal * offset; var plane = new Plane(point, normal); foreach (var geom in geometries) { var geom1 = geom; var task = Task.Run(() => Section(plane, geom1, tolerance), gc.Token); tasks.Add(task); } } gc.TaskCompleted += OnTaskCompleted; rc = gc.WaitAll(tasks, doc); return(rc); }
protected override Rhino.Commands.Result RunCommand(RhinoDoc doc, Rhino.Commands.RunMode mode) { // Select objects to scale var list = new Rhino.Collections.TransformObjectList(); var rc = SelectObjects("Select objects to scale", list); if (rc != Rhino.Commands.Result.Success) return rc; var anchor = new Point3d(); var _ref = new Point3d(); Plane plane = new Plane(); // Origin point var gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Origin point"); var copy = new Rhino.Input.Custom.OptionToggle(m_copy,"No", "Yes"); gp.AddOptionToggle("Copy", ref copy); for (; ; ) { var res = gp.Get(); if (res == Rhino.Input.GetResult.Point) { var view = gp.View(); if (view == null) return Rhino.Commands.Result.Failure; plane = view.ActiveViewport.ConstructionPlane(); anchor = gp.Point(); break; } if (res == Rhino.Input.GetResult.Option) continue; return Rhino.Commands.Result.Cancel; } bool bAcceptDefault = true; // Scale factor or first reference point gp.SetCommandPrompt("Scale factor or first reference point"); gp.SetBasePoint(anchor, true); gp.DrawLineFromPoint(anchor, true); gp.ConstrainToConstructionPlane(true); for (; ; ) { if (bAcceptDefault) { gp.AcceptNumber(true, false); gp.SetDefaultNumber(m_scale); } else { gp.AcceptNothing(true); gp.ClearDefault(); } var res = gp.Get(); if (res == Rhino.Input.GetResult.Point) { _ref = gp.Point(); break; } if (res == Rhino.Input.GetResult.Number) { double scale = Math.Abs(gp.Number()); const double EPS_DIVIDE = 0.000001; if (scale < EPS_DIVIDE) continue; m_scale = scale; plane.Origin = anchor; var xform = Transform.Scale(plane, m_scale, m_scale, m_scale); TransformObjects(list, xform, copy.CurrentValue, copy.CurrentValue); m_copy = copy.CurrentValue; if (m_copy) { bAcceptDefault = false; continue; } doc.Views.Redraw(); return Rhino.Commands.Result.Success; } if (res == Rhino.Input.GetResult.Nothing) { if (bAcceptDefault == false) return Rhino.Commands.Result.Success; plane.Origin = anchor; var xform = Transform.Scale(plane, m_scale, m_scale, m_scale); TransformObjects(list, xform, copy.CurrentValue, copy.CurrentValue); m_copy = copy.CurrentValue; if (m_copy) { bAcceptDefault = false; continue; } doc.Views.Redraw(); return Rhino.Commands.Result.Success; } if (res == Rhino.Input.GetResult.Option) continue; return Rhino.Commands.Result.Cancel; } // Second reference point var gx = new GetScaleXform(); gx.SetCommandPrompt("Second reference point"); gx.AddOptionToggle("copy", ref copy); gx.AddTransformObjects(list); gx.SetBasePoint(anchor, true); gx.DrawLineFromPoint(anchor, true); gx.ConstrainToConstructionPlane(true); gx.Plane = plane; gx.RefPoint = _ref; gx.AcceptNothing(true); gx.AcceptNumber(true, false); rc = Rhino.Commands.Result.Cancel; for (; ; ) { var res = gx.GetXform(); if (res == Rhino.Input.GetResult.Point) { var view = gx.View(); if (view == null) { rc = Rhino.Commands.Result.Failure; break; } var xform = gx.CalculateTransform(view.ActiveViewport, gx.Point()); if (xform.IsValid && xform != Transform.Identity) { TransformObjects(list, xform, copy.CurrentValue, copy.CurrentValue); rc = Rhino.Commands.Result.Success; m_scale = gx.Scale; } m_copy = copy.CurrentValue; if (m_copy) continue; break; } if (res == Rhino.Input.GetResult.Number) { var view = gx.View(); if (view == null) { rc = Rhino.Commands.Result.Failure; break; } var xform = gx.CalculateTransform(view.ActiveViewport, gx.Number()); if (xform.IsValid && xform != Transform.Identity) { TransformObjects(list, xform, copy.CurrentValue, copy.CurrentValue); rc = Rhino.Commands.Result.Success; m_scale = gx.Scale; } m_copy = copy.CurrentValue; if (m_copy) continue; break; } if (res == Rhino.Input.GetResult.Option) continue; if (res == Rhino.Input.GetResult.Nothing) break; break; } doc.Views.Redraw(); return rc; }
protected override Result RunCommand(RhinoDoc doc, RunMode mode) { Rhino.DocObjects.ObjRef obj_ref; Result rc = Rhino.Input.RhinoGet.GetOneObject("Select curve", false, Rhino.DocObjects.ObjectType.Curve, out obj_ref); if (rc != Result.Success) { return(rc); } Rhino.DocObjects.RhinoObject obj = obj_ref.Object(); if (null == obj) { return(Result.Failure); } obj_ref.Object().Select(false); doc.Views.Redraw(); Rhino.Geometry.Curve crv = obj_ref.Curve(); if (null == crv) { return(Result.Failure); } Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("First point on curve"); gp.Constrain(crv, false); gp.Get(); rc = gp.CommandResult(); if (rc != Result.Success) { return(rc); } double t0 = Rhino.RhinoMath.UnsetValue; if (null == gp.PointOnCurve(out t0)) { return(Result.Failure); } gp.SetCommandPrompt("Second point on curve"); gp.Get(); rc = gp.CommandResult(); if (rc != Result.Success) { return(rc); } double t1 = Rhino.RhinoMath.UnsetValue; if (null == gp.PointOnCurve(out t1)) { return(Result.Failure); } if (System.Math.Abs(t1 - t0) < Rhino.RhinoMath.ZeroTolerance) { return(Result.Failure); } if (crv.IsClosed || (!crv.IsClosed && t0 > t1)) { double t = t0; t0 = t1; t1 = t; } Rhino.Geometry.Interval range = new Rhino.Geometry.Interval(t0, t1); Rhino.Geometry.Curve subcrv = crv.Trim(range); if (null != subcrv) { System.Guid id = doc.Objects.Add(subcrv); obj = doc.Objects.Find(id); if (null != obj) { obj.Select(true); } } doc.Views.Redraw(); return(Result.Success); }
public static Rhino.Commands.Result AddBackgroundBitmap(Rhino.RhinoDoc doc) { // Allow the user to select a bitmap file var fd = new Rhino.UI.OpenFileDialog { Filter = "Image Files (*.bmp;*.png;*.jpg)|*.bmp;*.png;*.jpg" }; if (!fd.ShowOpenDialog()) { return(Rhino.Commands.Result.Cancel); } // Verify the file that was selected System.Drawing.Image image; try { image = System.Drawing.Image.FromFile(fd.FileName); } catch (Exception) { return(Rhino.Commands.Result.Failure); } // Allow the user to pick the bitmap origin var gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Bitmap Origin"); gp.ConstrainToConstructionPlane(true); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) { return(gp.CommandResult()); } // Get the view that the point was picked in. // This will be the view that the bitmap appears in. var view = gp.View(); if (view == null) { view = doc.Views.ActiveView; if (view == null) { return(Rhino.Commands.Result.Failure); } } // Allow the user to specify the bitmap width in model units var gn = new Rhino.Input.Custom.GetNumber(); gn.SetCommandPrompt("Bitmap width"); gn.SetLowerLimit(1.0, false); gn.Get(); if (gn.CommandResult() != Rhino.Commands.Result.Success) { return(gn.CommandResult()); } // Cook up some scale factors var w = gn.Number(); var image_width = image.Width; var image_height = image.Height; var h = w * (image_height / image_width); var plane = view.ActiveViewport.ConstructionPlane(); plane.Origin = gp.Point(); view.ActiveViewport.SetTraceImage(fd.FileName, plane, w, h, false, false); view.Redraw(); return(Rhino.Commands.Result.Success); }
protected override Result RunCommand(RhinoDoc doc, RunMode mode) { ObjRef obj_ref; var rc = RhinoGet.GetOneObject("Select surface for curvature measurement", true, ObjectType.Surface, out obj_ref); if (rc != Result.Success) { return(rc); } var surface = obj_ref.Surface(); var gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Select point on surface for curvature measurement"); gp.Constrain(surface, false); gp.Get(); if (gp.CommandResult() != Result.Success) { return(gp.CommandResult()); } var point_on_surface = gp.Point(); double u, v; if (!surface.ClosestPoint(point_on_surface, out u, out v)) { return(Result.Failure); } var surface_curvature = surface.CurvatureAt(u, v); if (surface_curvature == null) { return(Result.Failure); } RhinoApp.WriteLine("Surface curvature evaluation at parameter: ({0}, {1})", u, v); RhinoApp.WriteLine(" 3-D Point: ({0}, {1}, {2})", surface_curvature.Point.X, surface_curvature.Point.Y, surface_curvature.Point.Z); RhinoApp.WriteLine(" 3-D Normal: ({0}, {1}, {2})", surface_curvature.Normal.X, surface_curvature.Normal.Y, surface_curvature.Normal.Z); RhinoApp.WriteLine(string.Format(" Maximum principal curvature: {0} ({1}, {2}, {3})", surface_curvature.Kappa(0), surface_curvature.Direction(0).X, surface_curvature.Direction(0).Y, surface_curvature.Direction(0).Z)); RhinoApp.WriteLine(string.Format(" Minimum principal curvature: {0} ({1}, {2}, {3})", surface_curvature.Kappa(1), surface_curvature.Direction(1).X, surface_curvature.Direction(1).Y, surface_curvature.Direction(1).Z)); RhinoApp.WriteLine(" Gaussian curvature: {0}", surface_curvature.Gaussian); RhinoApp.WriteLine(" Mean curvature: {0}", surface_curvature.Mean); return(Result.Success); }
public static Rhino.Commands.Result OrientOnSrf(Rhino.RhinoDoc doc) { // Select objects to orient Rhino.Input.Custom.GetObject go = new Rhino.Input.Custom.GetObject(); go.SetCommandPrompt("Select objects to orient"); go.SubObjectSelect = false; go.GroupSelect = true; go.GetMultiple(1, 0); if (go.CommandResult() != Rhino.Commands.Result.Success) { return(go.CommandResult()); } // Point to orient from Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Point to orient from"); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) { return(gp.CommandResult()); } // Define source plane Rhino.Display.RhinoView view = gp.View(); if (view == null) { view = doc.Views.ActiveView; if (view == null) { return(Rhino.Commands.Result.Failure); } } Rhino.Geometry.Plane source_plane = view.ActiveViewport.ConstructionPlane(); source_plane.Origin = gp.Point(); // Surface to orient on Rhino.Input.Custom.GetObject gs = new Rhino.Input.Custom.GetObject(); gs.SetCommandPrompt("Surface to orient on"); gs.GeometryFilter = Rhino.DocObjects.ObjectType.Surface; gs.SubObjectSelect = true; gs.DeselectAllBeforePostSelect = false; gs.OneByOnePostSelect = true; gs.Get(); if (gs.CommandResult() != Rhino.Commands.Result.Success) { return(gs.CommandResult()); } Rhino.DocObjects.ObjRef objref = gs.Object(0); // get selected surface object Rhino.DocObjects.RhinoObject obj = objref.Object(); if (obj == null) { return(Rhino.Commands.Result.Failure); } // get selected surface (face) Rhino.Geometry.Surface surface = objref.Surface(); if (surface == null) { return(Rhino.Commands.Result.Failure); } // Unselect surface obj.Select(false); // Point on surface to orient to gp.SetCommandPrompt("Point on surface to orient to"); gp.Constrain(surface, false); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) { return(gp.CommandResult()); } // Do transformation Rhino.Commands.Result rc = Rhino.Commands.Result.Failure; double u, v; if (surface.ClosestPoint(gp.Point(), out u, out v)) { Rhino.Geometry.Plane target_plane; if (surface.FrameAt(u, v, out target_plane)) { // Build transformation Rhino.Geometry.Transform xform = Rhino.Geometry.Transform.PlaneToPlane(source_plane, target_plane); // Do the transformation. In this example, we will copy the original objects const bool delete_original = false; for (int i = 0; i < go.ObjectCount; i++) { doc.Objects.Transform(go.Object(i), xform, delete_original); } doc.Views.Redraw(); rc = Rhino.Commands.Result.Success; } } return(rc); }
public static Rhino.Commands.Result OrientOnSrf(Rhino.RhinoDoc doc) { // Select objects to orient Rhino.Input.Custom.GetObject go = new Rhino.Input.Custom.GetObject(); go.SetCommandPrompt("Select objects to orient"); go.SubObjectSelect = false; go.GroupSelect = true; go.GetMultiple(1, 0); if (go.CommandResult() != Rhino.Commands.Result.Success) return go.CommandResult(); // Point to orient from Rhino.Input.Custom.GetPoint gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Point to orient from"); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) return gp.CommandResult(); // Define source plane Rhino.Display.RhinoView view = gp.View(); if (view == null) { view = doc.Views.ActiveView; if (view == null) return Rhino.Commands.Result.Failure; } Rhino.Geometry.Plane source_plane = view.ActiveViewport.ConstructionPlane(); source_plane.Origin = gp.Point(); // Surface to orient on Rhino.Input.Custom.GetObject gs = new Rhino.Input.Custom.GetObject(); gs.SetCommandPrompt("Surface to orient on"); gs.GeometryFilter = Rhino.DocObjects.ObjectType.Surface; gs.SubObjectSelect = true; gs.DeselectAllBeforePostSelect = false; gs.OneByOnePostSelect = true; gs.Get(); if (gs.CommandResult() != Rhino.Commands.Result.Success) return gs.CommandResult(); Rhino.DocObjects.ObjRef objref = gs.Object(0); // get selected surface object Rhino.DocObjects.RhinoObject obj = objref.Object(); if (obj == null) return Rhino.Commands.Result.Failure; // get selected surface (face) Rhino.Geometry.Surface surface = objref.Surface(); if (surface == null) return Rhino.Commands.Result.Failure; // Unselect surface obj.Select(false); // Point on surface to orient to gp.SetCommandPrompt("Point on surface to orient to"); gp.Constrain(surface, false); gp.Get(); if (gp.CommandResult() != Rhino.Commands.Result.Success) return gp.CommandResult(); // Do transformation Rhino.Commands.Result rc = Rhino.Commands.Result.Failure; double u, v; if (surface.ClosestPoint(gp.Point(), out u, out v)) { Rhino.Geometry.Plane target_plane; if (surface.FrameAt(u, v, out target_plane)) { // Build transformation Rhino.Geometry.Transform xform = Rhino.Geometry.Transform.PlaneToPlane(source_plane, target_plane); // Do the transformation. In this example, we will copy the original objects const bool delete_original = false; for (int i = 0; i < go.ObjectCount; i++) doc.Objects.Transform(go.Object(i), xform, delete_original); doc.Views.Redraw(); rc = Rhino.Commands.Result.Success; } } return rc; }
protected override Rhino.Commands.Result RunCommand(RhinoDoc doc, Rhino.Commands.RunMode mode) { // Select objects to scale var list = new Rhino.Collections.TransformObjectList(); var rc = SelectObjects("Select objects to scale", list); if (rc != Rhino.Commands.Result.Success) { return(rc); } Point3d anchor; Point3d _ref; Plane plane; // Origin point var gp = new Rhino.Input.Custom.GetPoint(); gp.SetCommandPrompt("Origin point"); var copy = new Rhino.Input.Custom.OptionToggle(m_copy, "No", "Yes"); gp.AddOptionToggle("Copy", ref copy); for (; ;) { var res = gp.Get(); if (res == Rhino.Input.GetResult.Point) { var view = gp.View(); if (view == null) { return(Rhino.Commands.Result.Failure); } plane = view.ActiveViewport.ConstructionPlane(); anchor = gp.Point(); break; } if (res == Rhino.Input.GetResult.Option) { continue; } return(Rhino.Commands.Result.Cancel); } bool bAcceptDefault = true; // Scale factor or first reference point gp.SetCommandPrompt("Scale factor or first reference point"); gp.SetBasePoint(anchor, true); gp.DrawLineFromPoint(anchor, true); gp.ConstrainToConstructionPlane(true); for (; ;) { if (bAcceptDefault) { gp.AcceptNumber(true, false); gp.SetDefaultNumber(m_scale); } else { gp.AcceptNothing(true); gp.ClearDefault(); } var res = gp.Get(); if (res == Rhino.Input.GetResult.Point) { _ref = gp.Point(); break; } if (res == Rhino.Input.GetResult.Number) { double scale = Math.Abs(gp.Number()); const double EPS_DIVIDE = 0.000001; if (scale < EPS_DIVIDE) { continue; } m_scale = scale; plane.Origin = anchor; var xform = Transform.Scale(plane, m_scale, m_scale, m_scale); TransformObjects(list, xform, copy.CurrentValue, copy.CurrentValue); m_copy = copy.CurrentValue; if (m_copy) { bAcceptDefault = false; continue; } doc.Views.Redraw(); return(Rhino.Commands.Result.Success); } if (res == Rhino.Input.GetResult.Nothing) { if (bAcceptDefault == false) { return(Rhino.Commands.Result.Success); } plane.Origin = anchor; var xform = Transform.Scale(plane, m_scale, m_scale, m_scale); TransformObjects(list, xform, copy.CurrentValue, copy.CurrentValue); m_copy = copy.CurrentValue; if (m_copy) { bAcceptDefault = false; continue; } doc.Views.Redraw(); return(Rhino.Commands.Result.Success); } if (res == Rhino.Input.GetResult.Option) { continue; } return(Rhino.Commands.Result.Cancel); } // Second reference point var gx = new GetScaleXform(); gx.SetCommandPrompt("Second reference point"); gx.AddOptionToggle("copy", ref copy); gx.AddTransformObjects(list); gx.SetBasePoint(anchor, true); gx.DrawLineFromPoint(anchor, true); gx.ConstrainToConstructionPlane(true); gx.Plane = plane; gx.RefPoint = _ref; gx.AcceptNothing(true); gx.AcceptNumber(true, false); rc = Rhino.Commands.Result.Cancel; for (; ;) { var res = gx.GetXform(); if (res == Rhino.Input.GetResult.Point) { var view = gx.View(); if (view == null) { rc = Rhino.Commands.Result.Failure; break; } var xform = gx.CalculateTransform(view.ActiveViewport, gx.Point()); if (xform.IsValid && xform != Transform.Identity) { TransformObjects(list, xform, copy.CurrentValue, copy.CurrentValue); rc = Rhino.Commands.Result.Success; m_scale = gx.Scale; } m_copy = copy.CurrentValue; if (m_copy) { continue; } break; } if (res == Rhino.Input.GetResult.Number) { var view = gx.View(); if (view == null) { rc = Rhino.Commands.Result.Failure; break; } var xform = gx.CalculateTransform(view.ActiveViewport, gx.Number()); if (xform.IsValid && xform != Transform.Identity) { TransformObjects(list, xform, copy.CurrentValue, copy.CurrentValue); rc = Rhino.Commands.Result.Success; m_scale = gx.Scale; } m_copy = copy.CurrentValue; if (m_copy) { continue; } break; } if (res == Rhino.Input.GetResult.Option) { continue; } break; } doc.Views.Redraw(); return(rc); }
protected override Result RunCommand(RhinoDoc doc, RunMode mode) { // Get a polyframe // Get a new point // Create the pipes and lines in the new location // the lines will be from an edge container of the PolyFrame // The pipes will be added extra. This will allow for the pipes to be used as a PolyFrame var primal = new PFoam(); var dual = new PFoam(); try { var guids = LoadData.LoadPrimalDual(out primal, out dual, out ContainerType container); if (primal.Cells.Count < 1) { Rhino.RhinoApp.WriteLine("Error loading PolyFrame from provided data!"); return(Result.Failure); } var form = primal.Edges.Where(e => e.Id > 0).Any(x => x.Faces.Count < 2); if (dual.Cells.Count < 1) { RhinoApp.WriteLine("Could not load dual from the selected PolyFrame."); return(Result.Failure); } double minLen; double maxLen; var pipePolyFrame = new PFoam(); if (form) { pipePolyFrame = primal; } else { pipePolyFrame = dual; } var edgeLengths = pipePolyFrame.Edges.Select(x => x.GetLength()); minLen = edgeLengths.Min(); maxLen = edgeLengths.Max(); //var medLen = edgeLengths.Average(); var gp = new Rhino.Input.Custom.GetPoint(); var minRadius = new Rhino.Input.Custom.OptionDouble(minLen / 10, true, double.Epsilon); var maxRadius = new Rhino.Input.Custom.OptionDouble(minLen / 2, true, double.Epsilon); gp.SetCommandPrompt("Place the Pipes. Hit <Enter> to replace Input"); gp.SetDefaultPoint(primal.Centroid); gp.AcceptPoint(true); gp.AddOptionDouble("MinRadius", ref minRadius); gp.AddOptionDouble("MaxRadius", ref maxRadius); while (true) { gp.Get(); if (gp.Result() == Rhino.Input.GetResult.Point) { break; } else if (gp.Result() == Rhino.Input.GetResult.Cancel) { return(Result.Failure); } } var moveVect = gp.Point() - pipePolyFrame.Centroid; pipePolyFrame.Offset(moveVect); if (gp.GotDefault()) { if (!form) { moveVect = primal.Centroid - dual.Centroid; } doc.Objects.Delete(guids, true); doc.Views.Redraw(); } var pipeLayer = new Rhino.DocObjects.Layer() { Name = "_Pipes" }; if (doc.Layers.All(x => x.Name != pipeLayer.Name)) { doc.Layers.Add(pipeLayer); } pipeLayer = doc.Layers.First(x => x.Name == "_Pipes"); var pipeCol = pipePolyFrame.PipeGeoDual(minRadius.CurrentValue, maxRadius.CurrentValue, pipePolyFrame.Edges.Select(x => x.Id).ToList()); var pipeGuids = new List <Guid>(); foreach (var pc in pipeCol) { var att = new Rhino.DocObjects.ObjectAttributes { LayerIndex = pipeLayer.Index, ObjectColor = pc.Item2, ColorSource = Rhino.DocObjects.ObjectColorSource.ColorFromObject }; pipeGuids.Add(doc.Objects.AddBrep(pc.Item1, att)); } doc.Groups.Add(pipePolyFrame.Id.ToString() + "_Pipes", pipeGuids); pipePolyFrame.SaveAsEdges(); doc.Views.Redraw(); } catch (PolyFrameworkException pfE) { RhinoApp.WriteLine(pfE.Message); primal.Hide(); dual.Hide(); return(Result.Failure); } return(Result.Success); }