static double InHostUnits(double value, DB.ParameterType type, RhinoDoc rhinoDoc)
{
if (rhinoDoc is null)
{
return(double.NaN);
}
switch (type)
{
case DB.ParameterType.Length:
return(value * RhinoMath.UnitScale(rhinoDoc.ModelUnitSystem, UnitSystem.Feet));
//value *= Math.Pow(RhinoMath.UnitScale(rhinoDoc.ModelUnitSystem, UnitSystem.Millimeters), 1.0);
//return DB.UnitUtils.ConvertToInternalUnits(value, DB.DisplayUnitType.DUT_MILLIMETERS);
case DB.ParameterType.Area:
return(value * Math.Pow(RhinoMath.UnitScale(rhinoDoc.ModelUnitSystem, UnitSystem.Feet), 1.0));
//value *= Math.Pow(RhinoMath.UnitScale(rhinoDoc.ModelUnitSystem, UnitSystem.Millimeters), 2.0);
//return DB.UnitUtils.ConvertToInternalUnits(value, DB.DisplayUnitType.DUT_SQUARE_MILLIMETERS);
case DB.ParameterType.Volume:
return(value * Math.Pow(RhinoMath.UnitScale(rhinoDoc.ModelUnitSystem, UnitSystem.Feet), 1.0));
//value *= Math.Pow(RhinoMath.UnitScale(rhinoDoc.ModelUnitSystem, UnitSystem.Millimeters), 3.0);
//return DB.UnitUtils.ConvertToInternalUnits(value, DB.DisplayUnitType.DUT_CUBIC_MILLIMETERS);
default:
Debug.WriteLine(false, $"{nameof(InHostUnits)} do not implement conversion for {type}");
break;
}
return(value);
}
public static Dictionary <OSMTag, List <PolylineCurve> > WayPolylinesFromCoords(RequestHandler result)
{
var geometryResult = new Dictionary <OSMTag, List <PolylineCurve> >();
var unitScale = RhinoMath.UnitScale(UnitSystem.Meters, RhinoDoc.ActiveDoc.ModelUnitSystem); // OSM conversion assumes meters
Coord lengthPerDegree = GetDegreesPerAxis(result.MinBounds, result.MaxBounds, unitScale);
foreach (var entry in result.FoundData)
{
geometryResult[entry.Key] = new List <PolylineCurve>();
foreach (FoundItem item in entry.Value)
{
var linePoints = new List <Point3d>();
foreach (var coord in item.Coords)
{
var pt = GetPointFromLatLong(coord, lengthPerDegree, result.MinBounds);
linePoints.Add(pt);
}
var polyLine = new PolylineCurve(linePoints); // Creating a polylinecurve from scratch makes invalid geometry
geometryResult[entry.Key].Add(polyLine);
}
}
return(geometryResult);
}
static ToUnitSystemStatic()
{
foreach (var unit in DB.UnitUtils.GetValidDisplayUnits(DB.UnitType.UT_Length))
{
var revit = DB.UnitUtils.Convert(1.0, DB.DisplayUnitType.DUT_METERS, unit);
var rhino = RhinoMath.UnitScale(UnitSystem.Meters, unit.ToUnitSystem());
//Debug.Assert(Rhino.RhinoMath.EpsilonEquals(revit, rhino, Rhino.RhinoMath.ZeroTolerance), $"ToRhinoLengthUnits({unit}) fails!!");
}
}
public double ScaleToFitDocument(double input)
{
//The input is coming in from 0-300
//This correlates with roughly 20 feet
double scaledToFeet = input / 8;
UnitSystem currentDocUnits = RhinoDoc.ActiveDoc.ModelUnitSystem;
double unitSystemScaler = RhinoMath.UnitScale(UnitSystem.Feet, currentDocUnits);
return(scaledToFeet * unitSystemScaler);
}
public static double[] AreaOf(List <Curve> curves)
{
UnitSystem currentDocUnits = RhinoDoc.ActiveDoc.ModelUnitSystem;
double unitSystemScaler = RhinoMath.UnitScale(currentDocUnits, UnitSystem.Feet);
double[] areas = new double[curves.Count()];
for (int i = 0; i < curves.Count(); i++)
{
areas[i] = Math.Round(AreaMassProperties.Compute(curves[i]).Area *unitSystemScaler *unitSystemScaler, 2);
}
return(areas);
}
public static Result Import3DMFile(string filePath, Document doc, BuiltInCategory builtInCategory)
{
using (var model = File3dm.Read(filePath))
{
var scaleFactor = RhinoMath.UnitScale(model.Settings.ModelUnitSystem, Revit.ModelUnitSystem);
using (var trans = new Transaction(doc, "Import 3D Model"))
{
if (trans.Start() == TransactionStatus.Started)
{
var categoryId = new ElementId(builtInCategory);
var ds = DirectShape.CreateElement(doc, categoryId);
ds.Name = Path.GetFileName(filePath);
foreach (var obj in model.Objects)
{
if (!obj.Attributes.Visible)
{
continue;
}
var layer = model.AllLayers.FindIndex(obj.Attributes.LayerIndex);
if (layer?.IsVisible != true)
{
continue;
}
var geometryList = ImportObject(obj.Geometry, obj.Attributes, scaleFactor);
if (geometryList == null)
{
continue;
}
try { ds.AppendShape(geometryList); }
catch (Autodesk.Revit.Exceptions.ArgumentException) { }
}
if (trans.Commit() == TransactionStatus.Committed)
{
var elements = new ElementId[] { ds.Id };
Revit.ActiveUIDocument.Selection.SetElementIds(elements);
Revit.ActiveUIDocument.ShowElements(elements);
return(Result.Succeeded);
}
}
}
}
return(Result.Failed);
}
static void UpdateViewConstructionPlanesFrom(RhinoDoc rhinoDoc, DB.Document revitDoc)
{
if (!string.IsNullOrEmpty(rhinoDoc.TemplateFileUsed))
{
return;
}
if (rhinoDoc.IsCreating)
{
Revit.EnqueueAction(doc => UpdateViewConstructionPlanesFrom(rhinoDoc, doc));
return;
}
bool imperial = rhinoDoc.ModelUnitSystem == UnitSystem.Feet || rhinoDoc.ModelUnitSystem == UnitSystem.Inches;
var modelGridSpacing = imperial ?
1.0 * RhinoMath.UnitScale(UnitSystem.Yards, rhinoDoc.ModelUnitSystem) :
1.0 * RhinoMath.UnitScale(UnitSystem.Meters, rhinoDoc.ModelUnitSystem);
var modelSnapSpacing = imperial ?
1 / 16.0 * RhinoMath.UnitScale(UnitSystem.Inches, rhinoDoc.ModelUnitSystem) :
1.0 * RhinoMath.UnitScale(UnitSystem.Millimeters, rhinoDoc.ModelUnitSystem);
var modelThickLineFrequency = imperial ? 6 : 5;
// Views
{
foreach (var view in rhinoDoc.Views)
{
var cplane = view.MainViewport.GetConstructionPlane();
cplane.GridSpacing = modelGridSpacing;
cplane.SnapSpacing = modelSnapSpacing;
cplane.ThickLineFrequency = modelThickLineFrequency;
view.MainViewport.SetConstructionPlane(cplane);
var min = cplane.Plane.PointAt(-cplane.GridSpacing * cplane.GridLineCount, -cplane.GridSpacing * cplane.GridLineCount, 0.0);
var max = cplane.Plane.PointAt(+cplane.GridSpacing * cplane.GridLineCount, +cplane.GridSpacing * cplane.GridLineCount, 0.0);
var bbox = new BoundingBox(min, max);
// Zoom to grid
view.MainViewport.ZoomBoundingBox(bbox);
// Adjust to extens in case There is anything in the viewports like Grasshopper previews.
view.MainViewport.ZoomExtents();
}
}
}
public static void AddTextLabel(Point3d pt, string text)
{
UnitSystem currentDocUnits = RhinoDoc.ActiveDoc.ModelUnitSystem;
double unitSystemScaler = RhinoMath.UnitScale(UnitSystem.Feet, currentDocUnits);
var doc = RhinoDoc.ActiveDoc;
double height = (0.35 * unitSystemScaler);
const string font = "Arial";
Rhino.Geometry.Plane plane = doc.Views.ActiveView.ActiveViewport.ConstructionPlane();
plane.Origin = pt;
Guid id = doc.Objects.AddText(text, plane, height, font, false, false);
if (id != Guid.Empty)
{
doc.Views.Redraw();
}
}
static void AuditTolerances(RhinoDoc doc)
{
if (doc is object)
{
var maxDistanceTolerance = Revit.VertexTolerance * RhinoMath.UnitScale(UnitSystem.Feet, doc.ModelUnitSystem);
if (doc.ModelAbsoluteTolerance > maxDistanceTolerance)
{
doc.ModelAbsoluteTolerance = maxDistanceTolerance;
}
var maxAngleTolerance = Revit.AngleTolerance;
if (doc.ModelAngleToleranceRadians > maxAngleTolerance)
{
doc.ModelAngleToleranceRadians = maxAngleTolerance;
}
}
}
public static List <Rectangle3d> GetBoundariesFromResult(RequestHandler result)
{
var unitScale = RhinoMath.UnitScale(UnitSystem.Meters, RhinoDoc.ActiveDoc.ModelUnitSystem);
Coord lengthPerDegree = TranslateToXYManually.GetDegreesPerAxis(result.MinBounds, result.MaxBounds, unitScale);
var boundaries = new List <Rectangle3d>();
for (var i = 0; i < result.AllBounds.Count; i++)
{
var lowerCoord = result.AllBounds[i].Item1;
var upperCoord = result.AllBounds[i].Item2;
var lowerLeft = TranslateToXYManually.GetPointFromLatLong(lowerCoord, lengthPerDegree, result.MinBounds);
var upperRight = TranslateToXYManually.GetPointFromLatLong(upperCoord, lengthPerDegree, result.MinBounds);
var boundary = new Rectangle3d(Plane.WorldXY, lowerLeft, upperRight);
boundaries.Add(boundary);
}
return(boundaries);
}
public static Dictionary <OSMTag, List <Point3d> > NodePointsFromCoords(RequestHandler result)
{
var geometryResult = new Dictionary <OSMTag, List <Point3d> >();
var unitScale = RhinoMath.UnitScale(UnitSystem.Meters, RhinoDoc.ActiveDoc.ModelUnitSystem); // OSM conversion assumes meters
Coord lengthPerDegree = GetDegreesPerAxis(result.MinBounds, result.MaxBounds, unitScale);
foreach (var entry in result.FoundData)
{
geometryResult[entry.Key] = new List <Point3d>();
foreach (FoundItem item in entry.Value)
{
var pt = GetPointFromLatLong(item.Coords[0], lengthPerDegree, result.MinBounds);
geometryResult[entry.Key].Add(pt);
}
}
return(geometryResult);
}
public static Point3d AddTextLabel(Curve curve, string text, List <Point3d> oldPts)
{
UnitSystem currentDocUnits = RhinoDoc.ActiveDoc.ModelUnitSystem;
double unitSystemScaler = RhinoMath.UnitScale(UnitSystem.Feet, currentDocUnits);
double param;
curve.ClosestPoint(new Point3d(-1000 * unitSystemScaler, -1000 * unitSystemScaler, 0), out param);
Point3d pt = curve.PointAt(param);
foreach (Point3d point in oldPts)
{
if (pt.Y == point.Y && Math.Abs(pt.X - point.X) < 10 * unitSystemScaler)
{
pt = pt + new Point3d(0, 2 * unitSystemScaler, 0);
}
}
AddTextLabel(pt, text);
return(pt);
}
static void UpdateDocumentUnits(RhinoDoc rhinoDoc, DB.Document revitDoc = null)
{
bool docModified = rhinoDoc.Modified;
try
{
if (revitDoc is null)
{
rhinoDoc.ModelUnitSystem = UnitSystem.None;
rhinoDoc.ModelAbsoluteTolerance = Revit.VertexTolerance;
rhinoDoc.ModelAngleToleranceRadians = Revit.AngleTolerance;
}
else if (rhinoDoc.ModelUnitSystem == UnitSystem.None)
{
var units = revitDoc.GetUnits();
var lengthFormatoptions = units.GetFormatOptions(DB.UnitType.UT_Length);
rhinoDoc.ModelUnitSystem = lengthFormatoptions.DisplayUnits.ToRhinoLengthUnits();
rhinoDoc.ModelAngleToleranceRadians = Revit.AngleTolerance;
rhinoDoc.ModelDistanceDisplayPrecision = ((int)-Math.Log10(lengthFormatoptions.Accuracy)).Clamp(0, 7);
rhinoDoc.ModelAbsoluteTolerance = Revit.VertexTolerance * RhinoMath.UnitScale(UnitSystem.Feet, rhinoDoc.ModelUnitSystem);
//switch (rhinoDoc.ModelUnitSystem)
//{
// case UnitSystem.None: break;
// case UnitSystem.Feet:
// case UnitSystem.Inches:
// newDoc.ModelAbsoluteTolerance = (1.0 / 160.0) * RhinoMath.UnitScale(UnitSystem.Inches, newDoc.ModelUnitSystem);
// break;
// default:
// newDoc.ModelAbsoluteTolerance = 0.1 * RhinoMath.UnitScale(UnitSystem.Millimeters, newDoc.ModelUnitSystem);
// break;
//}
UpdateViewConstructionPlanesFrom(rhinoDoc, revitDoc);
}
}
finally
{
rhinoDoc.Modified = docModified;
}
}
public static MenuBarManager.CallbackStatus Import3DMFile(string filePath)
{
using (File3dm model = File3dm.Read(filePath))
{
var scaleFactor = RhinoMath.UnitScale(model.Settings.ModelUnitSystem, PartUnit.ToRhinoUnits());
var elements = new List <NXOpen.NXObject>();
//model.Objects.Select(obj => obj.Geometry.GetType().ToString()).ToList().ForEach(obj => obj.ListingWindowWriteLine());
foreach (var obj in model.Objects.Where(x => !x.Attributes.IsInstanceDefinitionObject && x.Attributes.Space == ActiveSpace.ModelSpace))
{
if (!obj.Attributes.Visible)
{
continue;
}
var layer = model.AllLayers.FindIndex(obj.Attributes.LayerIndex);
if (layer?.IsVisible != true)
{
continue;
}
var geometry = obj.Geometry;
if (geometry is Extrusion extrusion)
{
geometry = extrusion.ToBrep();
}
else if (geometry is SubD subD)
{
geometry = subD.ToBrep(new SubDToBrepOptions());
}
try
{
switch (geometry)
{
case Point point:
var referncePoint = WorkPart.Points.CreatePoint(point.Location.ToXYZ(scaleFactor));
referncePoint.SetVisibility(NXOpen.SmartObject.VisibilityOption.Visible);
elements.Add(referncePoint);
break;
case Curve curve:
if (curve.TryGetPlane(out var plane, DistanceTolerance)) // 平面曲线转换
{
if (CurveEncoder.ToNXCurve(curve, scaleFactor) is NXOpen.Curve crv)
{
elements.Add(crv);
}
}
else
{
var shape = curve.ToShape(scaleFactor);
elements.AddRange(shape);
}
break;
case Brep brep:
BrepEncoder.ToSolid(brep);
//if (brep.ToSolid(scaleFactor) is DB.Solid solid)
//{
// if (DB.FreeFormElement.Create(doc, solid) is DB.FreeFormElement freeForm)
// {
// elements.Add(freeForm.Id);
// {
// var categoryId = ImportLayer(doc, model, layer, categories, materials);
// if (categoryId != DB.ElementId.InvalidElementId)
// freeForm.get_Parameter(DB.BuiltInParameter.FAMILY_ELEM_SUBCATEGORY).Set(categoryId);
// }
// if (obj.Attributes.MaterialSource == ObjectMaterialSource.MaterialFromObject)
// {
// if (model.AllMaterials.FindIndex(obj.Attributes.MaterialIndex) is Material material)
// {
// var categoryId = ImportMaterial(doc, material, materials);
// if (categoryId != DB.ElementId.InvalidElementId)
// freeForm.get_Parameter(DB.BuiltInParameter.MATERIAL_ID_PARAM).Set(categoryId);
// }
// }
// }
//}
break;
}
}
catch (NXOpen.NXException ex) { }
}
}
return(MenuBarManager.CallbackStatus.Continue);
}
static void AuditUnits(RhinoDoc doc)
{
if (Command.InScriptRunnerCommand())
{
return;
}
if (Revit.ActiveUIDocument.Document is DB.Document revitDoc)
{
var units = revitDoc.GetUnits();
var lengthFormatoptions = units.GetFormatOptions(DB.UnitType.UT_Length);
var RevitModelUnitSystem = lengthFormatoptions.DisplayUnits.ToRhinoLengthUnits();
var GrasshopperModelUnitSystem = GH.Guest.ModelUnitSystem != UnitSystem.Unset ? GH.Guest.ModelUnitSystem : doc.ModelUnitSystem;
if (doc.ModelUnitSystem != RevitModelUnitSystem || doc.ModelUnitSystem != GrasshopperModelUnitSystem)
{
using
(
var taskDialog = new TaskDialog("Units")
{
MainIcon = TaskDialogIcons.IconInformation,
TitleAutoPrefix = true,
AllowCancellation = true,
MainInstruction = "Model units mismatch.",
MainContent = "What units do you want to use?",
ExpandedContent = $"The model you are opening is in {doc.ModelUnitSystem}{Environment.NewLine}Active Revit model '{revitDoc.Title}' units are {RevitModelUnitSystem}",
FooterText = "Current version: " + Addin.DisplayVersion
}
)
{
taskDialog.AddCommandLink(Autodesk.Revit.UI.TaskDialogCommandLinkId.CommandLink1, $"Continue opening in {doc.ModelUnitSystem}", $"Rhino and Grasshopper will work in {doc.ModelUnitSystem}");
taskDialog.AddCommandLink(Autodesk.Revit.UI.TaskDialogCommandLinkId.CommandLink2, $"Adjust Rhino model to {RevitModelUnitSystem} like Revit", $"Scale Rhino model by {RhinoMath.UnitScale(doc.ModelUnitSystem, RevitModelUnitSystem)}");
taskDialog.DefaultButton = Autodesk.Revit.UI.TaskDialogResult.CommandLink2;
if (GH.Guest.ModelUnitSystem != UnitSystem.Unset)
{
taskDialog.ExpandedContent += $"{Environment.NewLine}Documents opened in Grasshopper were working in {GH.Guest.ModelUnitSystem}";
if (GrasshopperModelUnitSystem != doc.ModelUnitSystem && GrasshopperModelUnitSystem != RevitModelUnitSystem)
{
taskDialog.AddCommandLink(Autodesk.Revit.UI.TaskDialogCommandLinkId.CommandLink3, $"Adjust Rhino model to {GH.Guest.ModelUnitSystem} like Grasshopper", $"Scale Rhino model by {RhinoMath.UnitScale(doc.ModelUnitSystem, GH.Guest.ModelUnitSystem)}");
taskDialog.DefaultButton = Autodesk.Revit.UI.TaskDialogResult.CommandLink3;
}
}
switch (taskDialog.Show())
{
case Autodesk.Revit.UI.TaskDialogResult.CommandLink2:
doc.ModelAngleToleranceRadians = Revit.AngleTolerance;
doc.ModelDistanceDisplayPrecision = ((int)-Math.Log10(lengthFormatoptions.Accuracy)).Clamp(0, 7);
doc.ModelAbsoluteTolerance = Revit.VertexTolerance * RhinoMath.UnitScale(UnitSystem.Feet, RevitModelUnitSystem);
doc.AdjustModelUnitSystem(RevitModelUnitSystem, true);
UpdateViewConstructionPlanesFrom(doc, revitDoc);
break;
case Autodesk.Revit.UI.TaskDialogResult.CommandLink3:
doc.ModelAngleToleranceRadians = Revit.AngleTolerance;
doc.ModelDistanceDisplayPrecision = Grasshopper.CentralSettings.FormatDecimalDigits.Clamp(0, 7);
doc.ModelAbsoluteTolerance = Revit.VertexTolerance * RhinoMath.UnitScale(UnitSystem.Feet, GH.Guest.ModelUnitSystem);
doc.AdjustModelUnitSystem(GH.Guest.ModelUnitSystem, true);
UpdateViewConstructionPlanesFrom(doc, revitDoc);
break;
default:
AuditTolerances(doc);
break;
}
}
}
}
}
public static Result Import3DMFile(string filePath, Document doc, BuiltInCategory builtInCategory)
{
try
{
DirectShapeLibrary.GetDirectShapeLibrary(doc).Reset();
using (var model = File3dm.Read(filePath))
{
var scaleFactor = RhinoMath.UnitScale(model.Settings.ModelUnitSystem, Revit.ModelUnitSystem);
using (var trans = new Transaction(doc, "Import 3D Model"))
{
if (trans.Start() == TransactionStatus.Started)
{
var categoryId = new ElementId(builtInCategory);
var materials = GetMaterialsByName(doc);
var type = DirectShapeType.Create(doc, Path.GetFileName(filePath), categoryId);
foreach (var obj in model.Objects.Where(x => !x.Attributes.IsInstanceDefinitionObject && x.Attributes.Space == ActiveSpace.ModelSpace))
{
if (!obj.Attributes.Visible)
{
continue;
}
var geometryList = ImportObject(model, obj.Geometry, obj.Attributes, doc, materials, scaleFactor).ToArray();
if (geometryList == null)
{
continue;
}
try { type.AppendShape(geometryList); }
catch (Autodesk.Revit.Exceptions.ArgumentException) { }
}
var ds = DirectShape.CreateElement(doc, type.Category.Id);
ds.SetTypeId(type.Id);
var library = DirectShapeLibrary.GetDirectShapeLibrary(doc);
if (!library.ContainsType(type.UniqueId))
{
library.AddDefinitionType(type.UniqueId, type.Id);
}
ds.SetShape(DirectShape.CreateGeometryInstance(doc, type.UniqueId, Autodesk.Revit.DB.Transform.Identity));
if (trans.Commit() == TransactionStatus.Committed)
{
var elements = new ElementId[] { ds.Id };
Revit.ActiveUIDocument.Selection.SetElementIds(elements);
Revit.ActiveUIDocument.ShowElements(elements);
return(Result.Succeeded);
}
}
}
}
}
finally
{
DirectShapeLibrary.GetDirectShapeLibrary(doc).Reset();
}
return(Result.Failed);
}
public static Dictionary <OSMTag, List <Brep> > BuildingBrepsFromCoords(ref RequestHandler result, bool outputHeighted)
{
var geometryResult = new Dictionary <OSMTag, List <Brep> >();
var unitScale = RhinoMath.UnitScale(UnitSystem.Meters, RhinoDoc.ActiveDoc.ModelUnitSystem); // OSM conversion assumes meters
var tolerance = RhinoDoc.ActiveDoc.ModelAbsoluteTolerance;
Coord lengthPerDegree = GetDegreesPerAxis(result.MinBounds, result.MaxBounds, unitScale);
foreach (var entry in result.FoundData)
{
geometryResult[entry.Key] = new List <Brep>();
for (int i = entry.Value.Count - 1; i >= 0; i--)
{
var outlinePoints = new List <Point3d>();
foreach (var coord in entry.Value[i].Coords)
{
outlinePoints.Add(GetPointFromLatLong(coord, lengthPerDegree, result.MinBounds));
}
var outline = new PolylineCurve(outlinePoints); // Creating a polylinecurve from scratch makes invalid geometry
if (!outline.IsClosed)
{
if (outline.IsClosable(ALLOWABLE_CLOSURE)) // Force-close the curve
{
outline.MakeClosed(ALLOWABLE_CLOSURE);
}
else // Skip this curve as no valid Brep can be made
{
entry.Value.RemoveAt(i);
continue;
}
}
var height = GetBuildingHeights.ParseHeight(entry.Value[i].Tags, unitScale);
if (outputHeighted && height > 0.0) // Output heighted buildings
{
var toHeight = new Vector3d(0, 0, height);
var envelope = Surface.CreateExtrusion(outline, toHeight);
var floor = Brep.CreatePlanarBreps(outline, tolerance);
outline.Translate(toHeight);
var roof = Brep.CreatePlanarBreps(outline, tolerance);
var volume = Brep.JoinBreps(new Brep[] { floor[0], envelope.ToBrep(), roof[0] }, tolerance);
geometryResult[entry.Key].Add(volume[0]);
}
else if (!outputHeighted && height == 0.0) // Output unheighted buildings
{
var builtSurface = Brep.CreatePlanarBreps(outline, tolerance);
if (builtSurface != null && builtSurface.Length > 0)
{
geometryResult[entry.Key].Add(builtSurface[0]);
}
}
else // Item wasn't matched, so should be removed from result so its metadata is not output
{
entry.Value.RemoveAt(i);
}
}
geometryResult[entry.Key].Reverse(); // We iterated in reverse order, so swap list back to right direction
}
return(geometryResult);
}
/// <summary>
/// Command.RunCommand override
/// </summary>
protected override Result RunCommand(RhinoDoc doc, RunMode mode)
{
Potrace.Clear();
// Prompt the user for the name of the image file to vectorize.
string path = GetImageFileName(mode);
if (string.IsNullOrEmpty(path))
{
return(Result.Cancel);
}
// Creates a bitmap from the specified file.
var bitmap = Image.FromFile(path) as Bitmap;
if (null == bitmap)
{
RhinoApp.WriteLine("The specified file cannot be identifed as a supported type.");
return(Result.Failure);
}
// Verify bitmap size
if (0 == bitmap.Width || 0 == bitmap.Height)
{
RhinoApp.WriteLine("Error reading the specified file.");
return(Result.Failure);
}
// Calculate scale factor so curves of a reasonable size are added to Rhino
var unit_scale = (doc.ModelUnitSystem != UnitSystem.Inches)
? RhinoMath.UnitScale(UnitSystem.Inches, doc.ModelUnitSystem)
: 1.0;
var scale = (double)(1.0 / bitmap.HorizontalResolution * unit_scale);
// I'm not convinced this is useful...
if (true)
{
var format = $"F{doc.DistanceDisplayPrecision}";
// Print image size in pixels
RhinoApp.WriteLine("Image size in pixels: {0} x {1}",
bitmap.Width,
bitmap.Height
);
// Print image size in inches
var width = (double)(bitmap.Width / bitmap.HorizontalResolution);
var height = (double)(bitmap.Height / bitmap.VerticalResolution);
RhinoApp.WriteLine("Image size in inches: {0} x {1}",
width.ToString(format, CultureInfo.InvariantCulture),
height.ToString(format, CultureInfo.InvariantCulture)
);
// Image size in in model units, if needed
if (doc.ModelUnitSystem != UnitSystem.Inches)
{
width = (double)(bitmap.Width / bitmap.HorizontalResolution * unit_scale);
height = (double)(bitmap.Height / bitmap.VerticalResolution * unit_scale);
RhinoApp.WriteLine("Image size in {0}: {1} x {2}",
doc.ModelUnitSystem.ToString().ToLower(),
width.ToString(format, CultureInfo.InvariantCulture),
height.ToString(format, CultureInfo.InvariantCulture)
);
}
}
// Convert the bitmap to an Eto bitmap
var eto_bitmap = ConvertBitmapToEto(bitmap);
if (null == eto_bitmap)
{
RhinoApp.WriteLine("Unable to convert image to Eto bitmap.");
return(Result.Failure);
}
// 12-Jan-2021 Dale Fugier
// This should prevent Eto.Drawing.BitmapData.GetPixels() from throwing an exception
if (!IsCompatibleBitmap(eto_bitmap))
{
RhinoApp.WriteLine("The image has an incompatible pixel format. Please select an image with 24 or 32 bits per pixel, or 8 bit indexed.");
return(Result.Failure);
}
// This bitmap is not needed anymore, so dispose of it
bitmap.Dispose();
// Gets the Potrace settings from the plug-in settings file
GetPotraceSettings();
// Create the conduit, which does most of the work
var conduit = new VectorizeConduit(
eto_bitmap,
scale,
doc.ModelAbsoluteTolerance,
m_select_output
? Rhino.ApplicationSettings.AppearanceSettings.SelectedObjectColor
: doc.Layers.CurrentLayer.Color
)
{
Enabled = true
};
if (mode == RunMode.Interactive)
{
// Show the interactive dialog box
var dialog = new VectorizeDialog(doc, conduit);
dialog.RestorePosition();
var result = dialog.ShowSemiModal(doc, RhinoEtoApp.MainWindow);
dialog.SavePosition();
if (result != Result.Success)
{
conduit.Enabled = false;
Potrace.Clear();
doc.Views.Redraw();
return(Result.Cancel);
}
}
else
{
// Show the command line options
var go = new GetOption();
go.SetCommandPrompt("Vectorization options. Press Enter when done");
go.AcceptNothing(true);
while (true)
{
conduit.TraceBitmap();
doc.Views.Redraw();
go.ClearCommandOptions();
// IgnoreArea
var turdsize_opt = new OptionInteger(Potrace.turdsize, 2, 100);
var turdsize_idx = go.AddOptionInteger("FilterSize", ref turdsize_opt, "Filter speckles of up to this size in pixels");
// TurnPolicy
var turnpolicy_idx = go.AddOptionEnumList("TurnPolicy", Potrace.turnpolicy);
// Optimizing
var curveoptimizing_opt = new OptionToggle(Potrace.curveoptimizing, "No", "Yes");
var curveoptimizing_idx = go.AddOptionToggle("Optimizing", ref curveoptimizing_opt);
// Tolerance
var opttolerance_opt = new OptionDouble(Potrace.opttolerance, 0.0, 1.0);
var opttolerance_idx = go.AddOptionDouble("Tolerance", ref opttolerance_opt, "Optimizing tolerance");
// CornerThreshold
var alphamax_opt = new OptionDouble(Potrace.alphamax, 0.0, 100.0);
var alphamax_idx = go.AddOptionDouble("CornerRounding", ref alphamax_opt, "Corner rounding threshold");
// Threshold
var threshold_opt = new OptionDouble(Potrace.Treshold, 0.0, 100.0);
var threshold_idx = go.AddOptionDouble("Threshold", ref threshold_opt, "Threshold");
// RestoreDefaults
var defaults_idx = go.AddOption("RestoreDefaults");
var res = go.Get();
if (res == GetResult.Option)
{
var option = go.Option();
if (null != option)
{
if (turdsize_idx == option.Index)
{
Potrace.turdsize = turdsize_opt.CurrentValue;
}
if (turnpolicy_idx == option.Index)
{
var list = Enum.GetValues(typeof(TurnPolicy)).Cast <TurnPolicy>().ToList();
Potrace.turnpolicy = list[option.CurrentListOptionIndex];
}
if (curveoptimizing_idx == option.Index)
{
Potrace.curveoptimizing = curveoptimizing_opt.CurrentValue;
}
if (opttolerance_idx == option.Index)
{
Potrace.opttolerance = opttolerance_opt.CurrentValue;
}
if (alphamax_idx == option.Index)
{
Potrace.alphamax = alphamax_opt.CurrentValue;
}
if (threshold_idx == option.Index)
{
Potrace.Treshold = threshold_opt.CurrentValue;
}
if (defaults_idx == option.Index)
{
Potrace.RestoreDefaults();
}
}
continue;
}
if (res != GetResult.Nothing)
{
conduit.Enabled = false;
doc.Views.Redraw();
Potrace.Clear();
return(Result.Cancel);
}
break;
}
}
// Group curves
var attributes = doc.CreateDefaultAttributes();
attributes.AddToGroup(doc.Groups.Add());
for (var i = 0; i < conduit.OutlineCurves.Count; i++)
{
var rhobj_id = doc.Objects.AddCurve(conduit.OutlineCurves[i], attributes);
if (m_select_output)
{
var rhobj = doc.Objects.Find(rhobj_id);
if (null != rhobj)
{
rhobj.Select(true);
}
}
}
conduit.Enabled = false;
Potrace.Clear();
doc.Views.Redraw();
// Set the Potrace settings to the plug -in settings file.
SetPotraceSettings();
return(Result.Success);
}
protected override void SolveInstance(IGH_DataAccess DA)
{
string val = "";
if (!DA.GetData("Formatted Value", ref val))
{
return;
}
string splitchars = "'";
string[] ftParts = val.Split(splitchars.ToCharArray());
string ftPart = ftParts[0];
string remains = String.Join("", ftParts, 1, ftParts.Length - 1);
double ft;
Double.TryParse(ftPart, out ft);
splitchars = "- \"";
string[] inchParts = remains.Split(splitchars.ToCharArray());
double inchVal = 0.0;
foreach (string str in removeEmpties(inchParts))
{
//Print(String.Format("parsing string chunk {0}", str));
double tempVal = 0;
if (str.Contains("/"))
{
try
{
string[] fracParts = removeEmpties(str.Split("/".ToCharArray()));
double tempVal2 = 1.0;
Double.TryParse(fracParts[0], out tempVal);
Double.TryParse(fracParts[1], out tempVal2);
if (tempVal2 != 0)
{
//Print(String.Format("Adding Fraction {0}/{1} = {2}", tempVal, tempVal2, (tempVal / tempVal2)));
inchVal += (tempVal / tempVal2);
}
}
catch (Exception ex)
{
AddRuntimeMessage(GH_RuntimeMessageLevel.Warning, ex.Message);
//Print(ex.ToString());
}
}
else
{
Double.TryParse(str, out tempVal);
inchVal += tempVal;
}
//Print(String.Format("inchVal = {0}", inchVal));
}
//Print(String.Format("inchVal/12 = {0}", inchVal / 12.0));
double feet = ft + inchVal / 12.0;
double inches = ft * 12 + inchVal;
DA.SetData("Value in Feet", feet);
DA.SetData("Value in Inches", inches);
//Convert to document units
UnitSystem docUnits = RhinoDoc.ActiveDoc.ModelUnitSystem;
double unitConvert = RhinoMath.UnitScale(Rhino.UnitSystem.Feet, docUnits);
double docUnitVal = feet * unitConvert;
DA.SetData("Value in Document Units", docUnitVal);
}
static Result Import3DMFileToFamily
(
DB.Document doc,
string filePath
)
{
using (var model = File3dm.Read(filePath))
{
var scaleFactor = RhinoMath.UnitScale(model.Settings.ModelUnitSystem, Revit.ModelUnitSystem);
using (var trans = new DB.Transaction(doc, "Import 3D Model"))
{
if (trans.Start() == DB.TransactionStatus.Started)
{
var materials = GetMaterialsByName(doc);
var categories = GetCategoriesByName(doc);
var elements = new List <DB.ElementId>();
var view3D = default(DB.View);
using (var collector = new DB.FilteredElementCollector(doc))
{
var elementCollector = collector.OfClass(typeof(DB.View3D));
view3D = elementCollector.Cast <DB.View3D>().Where(x => x.Name == "{3D}").FirstOrDefault();
}
if (view3D is object)
{
foreach (var cplane in model.AllNamedConstructionPlanes)
{
var plane = cplane.Plane;
var bubbleEnd = plane.Origin.ToXYZ(scaleFactor);
var freeEnd = (plane.Origin + plane.XAxis).ToXYZ(scaleFactor);
var cutVec = plane.YAxis.ToXYZ();
var refrencePlane = doc.FamilyCreate.NewReferencePlane(bubbleEnd, freeEnd, cutVec, view3D);
refrencePlane.Name = cplane.Name;
refrencePlane.Maximize3DExtents();
}
}
foreach (var obj in model.Objects.Where(x => !x.Attributes.IsInstanceDefinitionObject && x.Attributes.Space == ActiveSpace.ModelSpace))
{
if (!obj.Attributes.Visible)
{
continue;
}
var layer = model.AllLayers.FindIndex(obj.Attributes.LayerIndex);
if (layer?.IsVisible != true)
{
continue;
}
var geometry = obj.Geometry;
if (geometry is Extrusion extrusion)
{
geometry = extrusion.ToBrep();
}
else if (geometry is SubD subD)
{
geometry = subD.ToBrep(SubDToBrepOptions.Default);
}
try
{
switch (geometry)
{
case Point point:
if (doc.OwnerFamily.IsConceptualMassFamily)
{
var referncePoint = doc.FamilyCreate.NewReferencePoint(point.Location.ToXYZ(scaleFactor));
elements.Add(referncePoint.Id);
}
break;
case Curve curve:
if (curve.TryGetPlane(out var plane, Revit.VertexTolerance))
{
if (curve.ToCurve(scaleFactor) is DB.Curve crv)
{
var sketchPlane = DB.SketchPlane.Create(doc, plane.ToPlane(scaleFactor));
var modelCurve = doc.FamilyCreate.NewModelCurve(crv, sketchPlane);
elements.Add(modelCurve.Id);
{
var subCategoryId = ImportLayer(doc, model, layer, categories, materials);
if (DB.Category.GetCategory(doc, subCategoryId) is DB.Category subCategory)
{
var familyGraphicsStyle = subCategory?.GetGraphicsStyle(DB.GraphicsStyleType.Projection);
if (familyGraphicsStyle is object)
{
modelCurve.Subcategory = familyGraphicsStyle;
}
}
}
}
}
else if (DB.DirectShape.IsSupportedDocument(doc) && DB.DirectShape.IsValidCategoryId(doc.OwnerFamily.FamilyCategory.Id, doc))
{
var subCategoryId = ImportLayer(doc, model, layer, categories, materials);
var shape = curve.ToShape();
if (shape.Length > 0)
{
var ds = DB.DirectShape.CreateElement(doc, doc.OwnerFamily.FamilyCategory.Id);
ds.SetShape(shape);
elements.Add(ds.Id);
}
}
break;
case Brep brep:
if (brep.ToSolid(scaleFactor) is DB.Solid solid)
{
if (DB.FreeFormElement.Create(doc, solid) is DB.FreeFormElement freeForm)
{
elements.Add(freeForm.Id);
{
var categoryId = ImportLayer(doc, model, layer, categories, materials);
if (categoryId != DB.ElementId.InvalidElementId)
{
freeForm.get_Parameter(DB.BuiltInParameter.FAMILY_ELEM_SUBCATEGORY).Set(categoryId);
}
}
if (obj.Attributes.MaterialSource == ObjectMaterialSource.MaterialFromObject)
{
if (model.AllMaterials.FindIndex(obj.Attributes.MaterialIndex) is Material material)
{
var categoryId = ImportMaterial(doc, material, materials);
if (categoryId != DB.ElementId.InvalidElementId)
{
freeForm.get_Parameter(DB.BuiltInParameter.MATERIAL_ID_PARAM).Set(categoryId);
}
}
}
}
}
break;
}
}
catch (Autodesk.Revit.Exceptions.ArgumentException) { }
}
if (trans.Commit() == DB.TransactionStatus.Committed)
{
Revit.ActiveUIDocument.Selection.SetElementIds(elements);
Revit.ActiveUIDocument.ShowElements(elements);
return(Result.Succeeded);
}
}
}
}
return(Result.Failed);
}
/// <summary>
/// Generate a series of planes on the glulam cross-section. TODO: Re-implement as GlulamOrientation function
/// </summary>
/// <param name="N">Number of planes to extract.</param>
/// <param name="extension">Extension of the centreline curve</param>
/// <param name="frames">Output cross-section planes.</param>
/// <param name="parameters">Output t-values along centreline curve.</param>
/// <param name="interpolation">Type of interpolation to use (default is Linear).</param>
public override void GenerateCrossSectionPlanes(int N, out Plane[] frames, out double[] parameters, GlulamData.Interpolation interpolation = GlulamData.Interpolation.LINEAR)
{
Curve curve = Centreline;
double multiplier = RhinoMath.UnitScale(Rhino.RhinoDoc.ActiveDoc.ModelUnitSystem, UnitSystem.Millimeters);
//PolylineCurve discrete = curve.ToPolyline(Glulam.Tolerance * 10, Glulam.AngleTolerance, 0.0, 0.0);
PolylineCurve discrete = curve.ToPolyline(multiplier * Tolerance, AngleTolerance, multiplier * MininumSegmentLength, curve.GetLength() / MinimumNumSegments);
if (discrete.TryGetPolyline(out Polyline discrete2))
{
N = discrete2.Count;
parameters = new double[N];
for (int i = 0; i < N; ++i)
{
curve.ClosestPoint(discrete2[i], out parameters[i]);
}
}
else
{
parameters = curve.DivideByCount(N - 1, true).ToArray();
}
//frames = parameters.Select(x => GetPlane(x)).ToArray();
//return;
frames = new Plane[parameters.Length];
var vectors = Orientation.GetOrientations(curve, parameters);
Plane temp;
for (int i = 0; i < parameters.Length; ++i)
{
temp = Misc.PlaneFromNormalAndYAxis(
curve.PointAt(parameters[i]),
curve.TangentAt(parameters[i]),
vectors[i]);
if (temp.IsValid)
{
frames[i] = temp;
}
else
{
throw new Exception(string.Format("Plane is invalid: vector {0} tangent {1}", vectors[i], curve.TangentAt(parameters[i])));
}
// TODO: Make back-up orientation direction in this case.
}
return;
N = Math.Max(N, 2);
frames = new Plane[N];
Curve CL;
double extension = 0;
if (Centreline.IsClosed)
{
CL = Centreline.DuplicateCurve();
}
else
{
CL = Centreline.Extend(CurveEnd.Both, extension, CurveExtensionStyle.Smooth);
}
parameters = CL.DivideByCount(N - 1, true);
GlulamOrientation TempOrientation = Orientation.Duplicate();
TempOrientation.Remap(Centreline, CL);
for (int i = 0; i < N; ++i)
{
Vector3d v = TempOrientation.GetOrientation(CL, parameters[i]);
frames[i] = tas.Core.Util.Misc.PlaneFromNormalAndYAxis(CL.PointAt(parameters[i]), CL.TangentAt(parameters[i]), v);
}
return;
/*
* double[] ft = new double[Frames.Count];
* double[] fa = new double[Frames.Count];
*
* Plane temp;
* for (int i = 0; i < Frames.Count; ++i)
* {
* CL.PerpendicularFrameAt(Frames[i].Item1, out temp);
* ft[i] = Frames[i].Item1;
* //fa[i] = Math.Acos(temp.YAxis * Frames[i].Item2.YAxis);
* fa[i] = Vector3d.VectorAngle(temp.YAxis, Frames[i].Item2.YAxis, Frames[i].Item2);
* }
*
* for (int i = 1; i < fa.Length; ++i)
* {
* if (fa[i] - fa[i - 1] > Math.PI)
* fa[i] -= Constants.Tau;
* else if (fa[i] - fa[i - 1] < -Math.PI)
* fa[i] += Constants.Tau;
* }
*
* int res;
* int max = ft.Length - 1;
* double mu;
*
* double[] angles = new double[N];
*
* if (Frames.Count < 3)
* interpolation = GlulamData.Interpolation.LINEAR;
*
* switch (interpolation)
* {
* case (GlulamData.Interpolation.HERMITE): // Hermite Interpolation
* for (int i = 0; i < N; ++i)
* {
* if (t[i] < ft[0])
* {
* angles[i] = fa[0];
* continue;
* }
* else if (t[i] > ft.Last())
* {
* angles[i] = fa.Last();
* continue;
* }
*
* res = Array.BinarySearch(ft, t[i]);
* if (res < 0)
* {
* res = ~res;
* res--;
* }
*
* if (res == 0 && res < max - 1)
* {
* mu = (t[i] - ft[0]) / (ft[1] - ft[0]);
* angles[i] = Interpolation.HermiteInterpolate(fa[0], fa[0], fa[1], fa[2], mu, 0, 0);
* }
* else if (res > 0 && res < max - 1)
* {
* mu = (t[i] - ft[res]) / (ft[res + 1] - ft[res]);
* angles[i] = Interpolation.HermiteInterpolate(fa[res - 1], fa[res], fa[res + 1], fa[res + 2], mu, 0, 0);
*
* }
* else if (res > 0 && res < max)
* {
* mu = (t[i] - ft[res]) / (ft[res + 1] - ft[res]);
* angles[i] = Interpolation.HermiteInterpolate(fa[res - 1], fa[res], fa[res + 1], fa[res + 1], mu, 0, 0);
* }
* else if (res == max)
* {
* angles[i] = fa[res];
* }
*
* else
* continue;
* }
* break;
*
* case (GlulamData.Interpolation.CUBIC): // Cubic Interpolation
* for (int i = 0; i < N; ++i)
* {
* if (t[i] <= ft[0])
* {
* angles[i] = fa[0];
* continue;
* }
* else if (t[i] >= ft.Last())
* {
* angles[i] = fa.Last();
* continue;
* }
*
* res = Array.BinarySearch(ft, t[i]);
* if (res < 0)
* {
* res = ~res;
* res--;
* }
*
* if (res == 0 && res < max - 1)
* {
* mu = (t[i] - ft[0]) / (ft[1] - ft[0]);
* angles[i] = Interpolation.CubicInterpolate(fa[0], fa[0], fa[1], fa[2], mu);
* }
* else if (res > 0 && res < max - 1)
* {
* mu = (t[i] - ft[res]) / (ft[res + 1] - ft[res]);
* angles[i] = Interpolation.CubicInterpolate(fa[res - 1], fa[res], fa[res + 1], fa[res + 2], mu);
*
* }
* else if (res > 0 && res < max)
* {
* mu = (t[i] - ft[res]) / (ft[res + 1] - ft[res]);
* angles[i] = Interpolation.CubicInterpolate(fa[res - 1], fa[res], fa[res + 1], fa[res + 1], mu);
* }
* else if (res == max)
* {
* angles[i] = fa[res];
* }
*
* else
* continue;
* }
* break;
*
* default: // Default linear interpolation
* for (int i = 0; i < N; ++i)
* {
* res = Array.BinarySearch(ft, t[i]);
* if (res < 0)
* {
* res = ~res;
* res--;
* }
* if (res >= 0 && res < max)
* {
* if (ft[res + 1] - ft[res] == 0)
* mu = 0.5;
* else
* mu = Math.Min(1.0, Math.Max(0, (t[i] - ft[res]) / (ft[res + 1] - ft[res])));
* angles[i] = Interpolation.Lerp(fa[res], fa[res + 1], mu);
* }
* else if (res < 0)
* angles[i] = fa[0];
* else if (res >= max)
* angles[i] = fa[max];
* }
* break;
* }
*
* for (int i = 0; i < N; ++i)
* {
* CL.PerpendicularFrameAt(t[i], out temp);
* temp.Transform(Rhino.Geometry.Transform.Rotation(angles[i], temp.ZAxis, temp.Origin));
* planes[i] = temp;
* }
*/
}
internal static bool LoadScan(string path, int step)
{
LoadSettings();
//Task.Run(() => ProcessDataAsync(path));
Task.Run(() =>
{
PointCloud temp = null;
if (path.EndsWith("fls"))
{
Workspace.Initialize();
Rhino.RhinoApp.WriteLine("FaroScan: Initialized. Loading scan...");
Workspace.ReflectionMode(2);
FNResult res = Workspace.Load(path);
if (res != FNResult.Success)
{
Rhino.RhinoApp.WriteLine("FaroScan: Failed to load scan: " + res.ToString());
return;
}
double[] points_raw;
int[] color_raw;
Workspace.GetXYZPoints(0, out points_raw, out color_raw, step);
foreach (var attrName in Workspace.attribute_names)
{
Rhino.RhinoApp.WriteLine(string.Format("{0} : {1}", attrName, Workspace.GetAttribute(attrName)));
}
var children = Workspace.GetChildren();
foreach (string str in children)
{
RhinoApp.WriteLine(str);
}
Workspace.Unload(0);
Workspace.Uninitialize();
Rhino.RhinoApp.WriteLine("FaroScan: Faro done.");
int N = points_raw.Length / 3;
Point3d[] points = new Point3d[N];
Color[] colors = new Color[N];
double factor = RhinoMath.UnitScale(UnitSystem.Meters, RhinoDoc.ActiveDoc.ModelUnitSystem);
for (int i = 0; i < N; ++i)
{
if (RFContext.Abort)
{
Abort = false;
break;
}
if (N % 1000000 == 0)
{
RhinoApp.WriteLine("Still working: {0}", N);
}
points[i] = new Point3d(points_raw[i * 3] * factor, points_raw[i * 3 + 1] * factor, points_raw[i * 3 + 2] * factor);
colors[i] = Color.FromArgb(color_raw[i]);
}
temp = new PointCloud(points);
for (int i = 0; i < temp.Count; ++i)
{
temp[i].Color = colors[i];
}
Rhino.RhinoApp.WriteLine("Farhino: Loaded " + path + " finally.");
}
/*
* else if (path.EndsWith("pcd"))
* {
* tasTools.IO.PCD_Importer pcd = new tasTools.IO.PCD_Importer();
* pcd.use_transform = true;
* pcd.Import(path, out temp, true);
*
* Rhino.RhinoApp.WriteLine("PCD: Loaded " + path + " finally.");
* Rhino.RhinoDoc.ActiveDoc.Views.Redraw();
* }
*/
temp.Transform(Xform);
if (Clip)
{
Rhino.RhinoApp.WriteLine("Using clipping box.");
List <int> indices = new List <int>();
for (int i = 0; i < temp.Count; ++i)
{
if (ClippingBox.Contains(temp[i].Location))
{
indices.Add(i);
}
}
PointCloud cliptemp = new PointCloud();
List <Color> colors = new List <Color>();
for (int i = 0; i < indices.Count; ++i)
{
cliptemp.Add(temp[indices[i]].Location);
colors.Add(temp[indices[i]].Color);
}
for (int i = 0; i < colors.Count; ++i)
{
cliptemp[i].Color = colors[i];
}
Cloud = cliptemp;
}
else
{
Cloud = temp;
}
Rhino.RhinoDoc.ActiveDoc.Views.Redraw();
});
Rhino.RhinoApp.WriteLine("Farhino: Loading " + path + " asynchronously. Keep working, it will appear soon.");
return(true);
}
static double InOtherUnits(double value, DB.ParameterType type, UnitSystem from, UnitSystem to)
{
switch (type)
{
#region Length
case DB.ParameterType.Length:
case DB.ParameterType.ForceLengthPerAngle:
case DB.ParameterType.LinearForceLengthPerAngle:
case DB.ParameterType.ReinforcementLength:
case DB.ParameterType.AreaForcePerLength:
case DB.ParameterType.ReinforcementAreaPerUnitLength:
return(value * RhinoMath.UnitScale(from, to));
case DB.ParameterType.ForcePerLength:
case DB.ParameterType.LinearForcePerLength:
case DB.ParameterType.MassPerUnitLength:
case DB.ParameterType.WeightPerUnitLength:
case DB.ParameterType.PipeMassPerUnitLength:
return(value / RhinoMath.UnitScale(from, to));
#endregion
#region Area
case DB.ParameterType.Area:
case DB.ParameterType.AreaForce:
case DB.ParameterType.HVACAreaDividedByCoolingLoad:
case DB.ParameterType.HVACAreaDividedByHeatingLoad:
case DB.ParameterType.SurfaceArea:
case DB.ParameterType.ReinforcementArea:
case DB.ParameterType.SectionArea:
return(value * Math.Pow(RhinoMath.UnitScale(from, to), 2.0));
case DB.ParameterType.HVACCoolingLoadDividedByArea:
case DB.ParameterType.HVACHeatingLoadDividedByArea:
case DB.ParameterType.MassPerUnitArea:
return(value / Math.Pow(RhinoMath.UnitScale(from, to), 2.0));
#endregion
#region Volume
case DB.ParameterType.Volume:
case DB.ParameterType.PipingVolume:
case DB.ParameterType.ReinforcementVolume:
return(value * Math.Pow(RhinoMath.UnitScale(from, to), 3.0));
case DB.ParameterType.HVACCoolingLoadDividedByVolume:
case DB.ParameterType.HVACHeatingLoadDividedByVolume:
case DB.ParameterType.HVACAirflowDividedByVolume:
return(value * Math.Pow(RhinoMath.UnitScale(from, to), 3.0));
#endregion
default:
Debug.WriteLine($"{nameof(InOtherUnits)} do not implement conversion for {type}");
break;
}
return(value);
}
public static void PlaceDoorsAt(string schemeName)
{
string inputLayerPath = schemeName + "::EJLT Shapes";
string outputLayerPath = schemeName + "::Doors";
UnitSystem currentDocUnits = RhinoDoc.ActiveDoc.ModelUnitSystem;
double unitSystemScaler = RhinoMath.UnitScale(UnitSystem.Feet, currentDocUnits);
double doorW = 2.5 * unitSystemScaler;
double doorH = 0.2 * unitSystemScaler;
// get curves
List <int> layerIndexs;
List <Curve> curves = LayerHelper.GetCurvesFromChild(inputLayerPath, out layerIndexs);
// explode curves
List <Polyline> polies = new List <Polyline>();
List <Line[]> exploded = new List <Line[]>();
foreach (Curve c in curves)
{
Polyline poly;
c.TryGetPolyline(out poly);
polies.Add(poly);
exploded.Add(poly.GetSegments());
}
List <Point3d> centers = new List <Point3d>();
List <bool> vertical = new List <bool>();
// find overlapping curves, find center, find direction of lines
for (int i = 0; i < polies.Count; i++)
{
foreach (Line line in exploded[i])
{
for (int j = 0; j < polies.Count; j++)
{
if (i == j)
{
continue; // skip intersection check with current rectangle
}
foreach (Line otherline in exploded[j])
{
Curve c1 = line.ToNurbsCurve();
Curve c2 = otherline.ToNurbsCurve();
// get all intersections
var intersects = Intersection.CurveCurve(c1, c2, Rhino.RhinoDoc.ActiveDoc.ModelAbsoluteTolerance, 0.1);
if (intersects != null && intersects.Count > 0)
{
foreach (var inter in intersects)
{
if (inter.IsOverlap) // a overlap found
{
double length = inter.OverlapA.Length * c1.GetLength();
if (length > 3.5 * unitSystemScaler) // overlap is long enough
{
Point3d mid = c1.PointAt(inter.OverlapA.Mid);
double mindis = 10000.0;
foreach (Point3d oldpt in centers)
{
double distance = mid.DistanceTo(oldpt);
if (distance < mindis)
{
mindis = distance;
}
}
if (mindis > 1.0) // no duplicates
{
centers.Add(c1.PointAt(inter.OverlapA.Mid));
if (c1.PointAt(0).X == c1.PointAt(1).X)
{
vertical.Add(true);
}
else
{
vertical.Add(false);
}
}
}
}
}
}
}
}
}
}
// draws rectangle
for (int i = 0; i < centers.Count; i++)
{
if (vertical[i])
{
Point3d corner = new Point3d(centers[i].X - doorH / 2, centers[i].Y - doorW / 2, 0.0);
Rectangle3d rec = new Rectangle3d(new Plane(corner, Vector3d.ZAxis), doorH, doorW);
LayerHelper.BakeObjectToLayer(rec.ToPolyline().ToPolylineCurve(), "Doors", schemeName);
}
else
{
Point3d corner = new Point3d(centers[i].X - doorW / 2, centers[i].Y - doorH / 2, 0.0);
Rectangle3d rec = new Rectangle3d(new Plane(corner, Vector3d.ZAxis), doorW, doorH);
LayerHelper.BakeObjectToLayer(rec.ToPolyline().ToPolylineCurve(), "Doors", schemeName);
}
}
Rhino.RhinoDoc.ActiveDoc.Views.Redraw();
}
/// <summary>
/// Generate a series of planes on the glulam cross-section. TODO: Re-implement as GlulamOrientation function
/// </summary>
/// <param name="N">Number of planes to extract.</param>
/// <param name="extension">Extension of the centreline curve</param>
/// <param name="frames">Output cross-section planes.</param>
/// <param name="parameters">Output t-values along centreline curve.</param>
/// <param name="interpolation">Type of interpolation to use (default is Linear).</param>
public override void GenerateCrossSectionPlanes(int N, out Plane[] frames, out double[] parameters, GlulamData.Interpolation interpolation = GlulamData.Interpolation.LINEAR)
{
Curve curve = Centreline;
double multiplier = RhinoMath.UnitScale(UnitSystem.Millimeters, Rhino.RhinoDoc.ActiveDoc.ModelUnitSystem);
//PolylineCurve discrete = curve.ToPolyline(Glulam.Tolerance * 10, Glulam.AngleTolerance, 0.0, 0.0);
PolylineCurve discrete = curve.ToPolyline(multiplier * Tolerance, AngleTolerance, multiplier * MininumSegmentLength, curve.GetLength() / MinimumNumSegments);
if (discrete == null)
{
parameters = curve.DivideByCount(N - 1, true).ToArray();
//discrete = new PolylineCurve(new Point3d[] { curve.PointAtStart, curve.PointAtEnd });
}
else
{
if (discrete.TryGetPolyline(out Polyline discrete2))
{
N = discrete2.Count;
parameters = new double[N];
for (int i = 0; i < N; ++i)
{
curve.ClosestPoint(discrete2[i], out parameters[i]);
}
}
else
{
parameters = curve.DivideByCount(N - 1, true).ToArray();
}
}
//frames = parameters.Select(x => GetPlane(x)).ToArray();
//return;
frames = new Plane[parameters.Length];
var vectors = Orientation.GetOrientations(curve, parameters);
Plane temp;
for (int i = 0; i < parameters.Length; ++i)
{
temp = Utility.PlaneFromNormalAndYAxis(
curve.PointAt(parameters[i]),
curve.TangentAt(parameters[i]),
vectors[i]);
if (temp.IsValid)
{
frames[i] = temp;
}
else
{
throw new Exception(string.Format("Plane is invalid: vector {0} tangent {1}", vectors[i], curve.TangentAt(parameters[i])));
}
}
return;
}
public static void Make3d(string schemeName)
{
string inputLayerPath = schemeName + "::EJLT Shapes";
string outputLayerPath = schemeName + "::Walls";
string doorsLayerPath = schemeName + "::Doors";
List <int> layerIndexs;
List <Curve> curves = LayerHelper.GetCurvesFromChild(inputLayerPath, out layerIndexs);
List <Curve> doors = LayerHelper.GetCurvesFrom(doorsLayerPath);
List <LineCurve> afterCut = new List <LineCurve>();
List <Line> exploded = new List <Line>();
foreach (Curve c in curves)
{
Polyline poly;
c.TryGetPolyline(out poly);
exploded.AddRange(poly.GetSegments());
}
List <Line> lineSegDoor = new List <Line>();
List <List <LineCurve> > doorsPerSeg = new List <List <LineCurve> >();
foreach (Line lineSeg in exploded)
{
List <LineCurve> doorsThisSeg = new List <LineCurve>();
foreach (Curve door in doors)
{
CurveIntersections inter = Intersection.CurveLine(door, lineSeg, Rhino.RhinoDoc.ActiveDoc.ModelAbsoluteTolerance, 0.0);
if (inter.Count == 2)
{
LineCurve l1;
Point3d p1 = inter.First().PointA;
Point3d p2 = inter[1].PointA;
l1 = new LineCurve(p1, p2);
doorsThisSeg.Add(l1);
}
}
if (doorsThisSeg.Count > 0)
{
lineSegDoor.Add(lineSeg);
doorsPerSeg.Add(doorsThisSeg);
}
else
{
// no intersection, add to after cut
afterCut.Add(new LineCurve(lineSeg));
}
}
for (int i = 0; i < lineSegDoor.Count; i++)
{
// points from all intersection points
List <Point3d> intersectionPts = new List <Point3d>();
intersectionPts.Add(lineSegDoor[i].From);
intersectionPts.Add(lineSegDoor[i].To);
foreach (LineCurve doorLine in doorsPerSeg[i])
{
intersectionPts.Add(doorLine.PointAtStart);
intersectionPts.Add(doorLine.PointAtEnd);
}
List <Point3d> sortedPoints = intersectionPts.OrderBy(pnt => pnt.Y).ThenBy(pnt => pnt.X).ToList();
// construct line segments
for (int pi = 0; pi < sortedPoints.Count; pi = pi + 2)
{
LineCurve cuttedSegment = new LineCurve(sortedPoints[pi], sortedPoints[pi + 1]);
bool indoor = false;
foreach (Curve door in doors)
{
if (door.Contains(cuttedSegment.PointAt(0.5), Plane.WorldXY, Rhino.RhinoDoc.ActiveDoc.ModelAbsoluteTolerance) == PointContainment.Inside)
{
indoor = true;
break;
}
}
if (!indoor)
{
afterCut.Add(cuttedSegment);
}
}
}
UnitSystem currentDocUnits = RhinoDoc.ActiveDoc.ModelUnitSystem;
double unitSystemScaler = RhinoMath.UnitScale(UnitSystem.Feet, currentDocUnits);
foreach (LineCurve wallLine in afterCut)
{
LayerHelper.BakeObjectToLayer(Extrusion.Create(wallLine, 8 * unitSystemScaler, false).ToBrep(), "Walls", schemeName);
}
Rhino.RhinoDoc.ActiveDoc.Views.Redraw();
}
