private void CreateTessellatedShapeInternal(IFCImportShapeEditScope shapeEditScope, Transform scaledLcs)
{
TessellatedShapeBuilderScope tsBuilderScope = shapeEditScope.BuilderScope as TessellatedShapeBuilderScope;
if (tsBuilderScope == null)
{
throw new InvalidOperationException("Expect a TessellatedShapeBuilderScope, but get a BrepBuilderScope instead");
}
IList <XYZ> loopVertices = Bound.LoopVertices;
int count = 0;
if (loopVertices == null || ((count = loopVertices.Count) == 0))
{
throw new InvalidOperationException("#" + Id + ": missing loop vertices, ignoring.");
}
if (count < 3)
{
throw new InvalidOperationException("#" + Id + ": too few loop vertices (" + count + "), ignoring.");
}
if (!Orientation)
{
loopVertices.Reverse();
}
// Apply the transform
IList <XYZ> transformedVertices = new List <XYZ>();
foreach (XYZ vertex in loopVertices)
{
transformedVertices.Add(scaledLcs.OfPoint(vertex));
}
// Check that the loop vertices don't contain points that are very close to one another;
// if so, throw the point away and hope that the TessellatedShapeBuilder can repair the result.
// Warn in this case. If the entire boundary is bad, report an error and don't add the loop vertices.
IList <XYZ> validVertices;
IFCGeometryUtil.CheckAnyDistanceVerticesWithinTolerance(Id, shapeEditScope, transformedVertices, out validVertices);
// We are going to catch any exceptions if the loop is invalid.
// We are going to hope that we can heal the parent object in the TessellatedShapeBuilder.
bool bPotentiallyAbortFace = false;
count = validVertices.Count;
if (validVertices.Count < 3)
{
Importer.TheLog.LogComment(Id, "Too few distinct loop vertices (" + count + "), ignoring.", false);
bPotentiallyAbortFace = true;
}
else
{
if (!tsBuilderScope.AddLoopVertices(Id, validVertices))
{
bPotentiallyAbortFace = true;
}
}
if (bPotentiallyAbortFace && IsOuter)
{
tsBuilderScope.AbortCurrentFace();
}
}
protected override void CreateShapeInternal(IFCImportShapeEditScope shapeEditScope, Transform lcs, Transform scaledLcs, string guid)
{
using (BuilderScope bs = shapeEditScope.InitializeBuilder(IFCShapeBuilderType.TessellatedShapeBuilder))
{
base.CreateShapeInternal(shapeEditScope, lcs, scaledLcs, guid);
TessellatedShapeBuilderScope tsBuilderScope = bs as TessellatedShapeBuilderScope;
tsBuilderScope.StartCollectingFaceSet();
// Create triangle face set from CoordIndex. We do not support the Normals yet at this point
foreach (List <int> triIndex in CoordIndex)
{
// This is a defensive check in an unlikely situation that the index is larger than the data
if (triIndex[0] > Coordinates.CoordList.Count || triIndex[1] > Coordinates.CoordList.Count || triIndex[2] > Coordinates.CoordList.Count)
{
continue;
}
tsBuilderScope.StartCollectingFace(GetMaterialElementId(shapeEditScope));
IList <XYZ> loopVertices = new List <XYZ>();
for (int ii = 0; ii < 3; ++ii)
{
int actualVIdx = triIndex[ii] - 1;
if (PnIndex != null)
{
actualVIdx = PnIndex[actualVIdx] - 1;
}
IList <double> v = Coordinates.CoordList[actualVIdx];
loopVertices.Add(new XYZ(v[0], v[1], v[2]));
}
IList <XYZ> transformedVertices = new List <XYZ>();
foreach (XYZ vertex in loopVertices)
{
// Need to apply the project unit scaling here
XYZ scaledVertex = applyProjectUnitScaleVertex(vertex);
transformedVertices.Add(scaledLcs.OfPoint(scaledVertex));
}
// Check triangle that is too narrow (2 vertices are within the tolerance
IList <XYZ> validVertices;
IFCGeometryUtil.CheckAnyDistanceVerticesWithinTolerance(Id, shapeEditScope, transformedVertices, out validVertices);
// We are going to catch any exceptions if the loop is invalid.
// We are going to hope that we can heal the parent object in the TessellatedShapeBuilder.
bool bPotentiallyAbortFace = false;
int count = validVertices.Count;
if (validVertices.Count < 3)
{
Importer.TheLog.LogComment(Id, "Too few distinct loop vertices (" + count + "), ignoring.", false);
bPotentiallyAbortFace = true;
}
else
{
if (!tsBuilderScope.AddLoopVertices(Id, validVertices))
{
bPotentiallyAbortFace = true;
}
}
if (bPotentiallyAbortFace)
{
tsBuilderScope.AbortCurrentFace();
}
else
{
tsBuilderScope.StopCollectingFace();
}
}
IList <GeometryObject> createdGeometries = tsBuilderScope.CreateGeometry(guid);
if (createdGeometries != null)
{
foreach (GeometryObject createdGeometry in createdGeometries)
{
shapeEditScope.AddGeometry(IFCSolidInfo.Create(Id, createdGeometry));
}
}
}
}
private void CreateTessellatedShapeInternal(IFCImportShapeEditScope shapeEditScope, Transform scaledLcs)
{
TessellatedShapeBuilderScope tsBuilderScope = shapeEditScope.BuilderScope as TessellatedShapeBuilderScope;
if (tsBuilderScope == null)
{
throw new InvalidOperationException("Expect a TessellatedShapeBuilderScope, but get a BrepBuilderScope instead");
}
IList <XYZ> loopVertices = Bound.LoopVertices;
int count = 0;
if (loopVertices == null || ((count = loopVertices.Count) == 0))
{
throw new InvalidOperationException("#" + Id + ": missing loop vertices, ignoring.");
}
if (count < 3)
{
throw new InvalidOperationException("#" + Id + ": too few loop vertices (" + count + "), ignoring.");
}
if (!Orientation)
{
loopVertices.Reverse();
}
// Apply the transform
IList <XYZ> transformedVertices = new List <XYZ>();
foreach (XYZ vertex in loopVertices)
{
transformedVertices.Add(scaledLcs.OfPoint(vertex));
}
// Check that the loop vertices don't contain points that are very close to one another;
// if so, throw the point away and hope that the TessellatedShapeBuilder can repair the result.
// Warn in this case. If the entire boundary is bad, report an error and don't add the loop vertices.
List <XYZ> validVertices = null;
for (int pass = 0; pass < 2; pass++)
{
if (pass == 1 && !tsBuilderScope.RevertToMeshIfPossible())
{
break;
}
IFCGeometryUtil.CheckAnyDistanceVerticesWithinTolerance(Id, shapeEditScope, transformedVertices, out validVertices);
count = validVertices.Count;
if (count >= 3 || !IsOuter)
{
break;
}
}
// We are going to catch any exceptions if the loop is invalid.
// We are going to hope that we can heal the parent object in the TessellatedShapeBuilder.
bool bPotentiallyAbortFace = (count < 3);
if (bPotentiallyAbortFace)
{
Importer.TheLog.LogComment(Id, "Too few distinct loop vertices (" + count + "), ignoring.", false);
}
else
{
bool maybeTryToTriangulate = tsBuilderScope.CanProcessDelayedFaceBoundary && (count == 4);
bool tryToTriangulate = false;
// Last check: check to see if the vertices are actually planar.
// We are not going to be particularly fancy about how we pick the plane.
if (count > 3)
{
XYZ planeNormal = null;
XYZ firstPoint = validVertices[0];
XYZ secondPoint = validVertices[1];
XYZ firstDir = secondPoint - firstPoint;
double bestLength = 0;
for (int index = 2; index <= count; index++)
{
XYZ thirdPoint = validVertices[(index % count)];
XYZ currentPlaneNormal = firstDir.CrossProduct(thirdPoint - firstPoint);
double planeNormalLength = currentPlaneNormal.GetLength();
if (planeNormalLength > 0.01)
{
planeNormal = currentPlaneNormal.Normalize();
break;
}
else if (maybeTryToTriangulate && (planeNormalLength > bestLength))
{
planeNormal = currentPlaneNormal.Normalize();
bestLength = planeNormalLength;
}
firstPoint = secondPoint;
secondPoint = thirdPoint;
firstDir = secondPoint - firstPoint;
}
if (planeNormal == null)
{
// Even if we don't find a good normal, we will still see if the internal function can make sense of it.
Importer.TheLog.LogComment(Id, "Bounded loop plane is likely non-planar, may triangulate.", false);
}
else
{
double vertexEps = IFCImportFile.TheFile.VertexTolerance;
for (int index = 0; index < count; index++)
{
XYZ pointOnPlane = validVertices[index] -
(validVertices[index] - firstPoint).DotProduct(planeNormal) * planeNormal;
double distance = pointOnPlane.DistanceTo(validVertices[index]);
if (distance > vertexEps * 10.0)
{
Importer.TheLog.LogComment(Id, "Bounded loop plane is non-planar, may triangulate.", false);
tryToTriangulate = maybeTryToTriangulate;
bPotentiallyAbortFace = !tryToTriangulate;
break;
}
else if (distance > vertexEps)
{
if (!maybeTryToTriangulate)
{
Importer.TheLog.LogComment(Id, "Bounded loop plane is slightly non-planar, correcting.", false);
validVertices[index] = pointOnPlane;
}
else
{
Importer.TheLog.LogComment(Id, "Bounded loop plane is slightly non-planar, will triangulate.", false);
tryToTriangulate = maybeTryToTriangulate;
}
}
}
}
}
if (!bPotentiallyAbortFace)
{
if (tryToTriangulate)
{
tsBuilderScope.DelayedFaceBoundary = validVertices;
}
else
{
bPotentiallyAbortFace = !tsBuilderScope.AddLoopVertices(Id, validVertices);
}
}
}
if (bPotentiallyAbortFace && IsOuter)
{
tsBuilderScope.AbortCurrentFace();
}
}
protected override void CreateShapeInternal(IFCImportShapeEditScope shapeEditScope, Transform lcs, Transform scaledLcs, string guid)
{
using (BuilderScope bs = shapeEditScope.InitializeBuilder(IFCShapeBuilderType.TessellatedShapeBuilder))
{
base.CreateShapeInternal(shapeEditScope, lcs, scaledLcs, guid);
TessellatedShapeBuilderScope tsBuilderScope = bs as TessellatedShapeBuilderScope;
tsBuilderScope.StartCollectingFaceSet();
// Create the face set from IFCIndexedPolygonalFace
foreach (IFCIndexedPolygonalFace face in Faces)
{
// TODO: Consider adding ability to triangulate here.
tsBuilderScope.StartCollectingFace(GetMaterialElementId(shapeEditScope), false);
IList <XYZ> loopVertices = new List <XYZ>();
foreach (int vertInd in face.CoordIndex)
{
int actualVIdx = vertInd - 1; // IFC starts the list position at 1
if (PnIndex != null)
{
actualVIdx = PnIndex[actualVIdx] - 1;
}
XYZ vertex = Coordinates.CoordList[actualVIdx];
loopVertices.Add(scaledLcs.OfPoint(vertex));
}
List <XYZ> validVertices;
IFCGeometryUtil.CheckAnyDistanceVerticesWithinTolerance(Id, shapeEditScope, loopVertices, out validVertices);
bool bPotentiallyAbortFace = false;
if (!tsBuilderScope.AddLoopVertices(Id, validVertices))
{
bPotentiallyAbortFace = true;
}
// Handle holes
if (face.InnerCoordIndices != null)
{
foreach (IList <int> innerLoop in face.InnerCoordIndices)
{
IList <XYZ> innerLoopVertices = new List <XYZ>();
foreach (int innerVerIdx in innerLoop)
{
int actualVIdx = innerVerIdx - 1;
if (PnIndex != null)
{
actualVIdx = PnIndex[actualVIdx] - 1;
}
XYZ vertex = Coordinates.CoordList[actualVIdx];
// add vertex to the loop
innerLoopVertices.Add(scaledLcs.OfPoint(vertex));
}
List <XYZ> validInnerV;
IFCGeometryUtil.CheckAnyDistanceVerticesWithinTolerance(Id, shapeEditScope, innerLoopVertices, out validInnerV);
if (!tsBuilderScope.AddLoopVertices(Id, validInnerV))
{
bPotentiallyAbortFace = true;
}
}
}
tsBuilderScope.StopCollectingFace(!bPotentiallyAbortFace, false);
}
IList <GeometryObject> createdGeometries = tsBuilderScope.CreateGeometry(guid);
if (createdGeometries != null)
{
foreach (GeometryObject createdGeometry in createdGeometries)
{
shapeEditScope.AddGeometry(IFCSolidInfo.Create(Id, createdGeometry));
}
}
}
}
private void CreateTessellatedShapeInternal(IFCImportShapeEditScope shapeEditScope, Transform scaledLcs)
{
TessellatedShapeBuilderScope tsBuilderScope = shapeEditScope.BuilderScope as TessellatedShapeBuilderScope;
if (tsBuilderScope == null)
{
throw new InvalidOperationException("Expect a TessellatedShapeBuilderScope, but get a BrepBuilderScope instead");
}
IList <XYZ> loopVertices = Bound.LoopVertices;
int count = 0;
if (loopVertices == null || ((count = loopVertices.Count) == 0))
{
throw new InvalidOperationException("#" + Id + ": missing loop vertices, ignoring.");
}
if (count < 3)
{
throw new InvalidOperationException("#" + Id + ": too few loop vertices (" + count + "), ignoring.");
}
if (!Orientation)
{
loopVertices.Reverse();
}
// Apply the transform
IList <XYZ> transformedVertices = new List <XYZ>();
foreach (XYZ vertex in loopVertices)
{
transformedVertices.Add(scaledLcs.OfPoint(vertex));
}
// Check that the loop vertices don't contain points that are very close to one another;
// if so, throw the point away and hope that the TessellatedShapeBuilder can repair the result.
// Warn in this case. If the entire boundary is bad, report an error and don't add the loop vertices.
IList <XYZ> validVertices;
IFCGeometryUtil.CheckAnyDistanceVerticesWithinTolerance(Id, shapeEditScope, transformedVertices, out validVertices);
// We are going to catch any exceptions if the loop is invalid.
// We are going to hope that we can heal the parent object in the TessellatedShapeBuilder.
bool bPotentiallyAbortFace = false;
count = validVertices.Count;
if (count < 3)
{
Importer.TheLog.LogComment(Id, "Too few distinct loop vertices (" + count + "), ignoring.", false);
bPotentiallyAbortFace = true;
}
else
{
// Last check: check to see if the vertices are actually planar. If not, for the vertices to be planar.
// We are not going to be particularly fancy about how we pick the plane.
XYZ planeNormal = null;
bool foundNormal = false;
XYZ firstPoint = validVertices[0];
XYZ secondPoint = validVertices[1];
XYZ firstDir = secondPoint - firstPoint;
int thirdPointIndex = 2;
for (; thirdPointIndex < count; thirdPointIndex++)
{
XYZ thirdPoint = validVertices[thirdPointIndex];
planeNormal = firstDir.CrossProduct(thirdPoint - firstPoint);
if (!planeNormal.IsZeroLength())
{
planeNormal = planeNormal.Normalize();
foundNormal = true;
break;
}
}
if (!foundNormal)
{
Importer.TheLog.LogComment(Id, "Loop is degenerate, ignoring.", false);
bPotentiallyAbortFace = true;
}
else
{
double vertexEps = IFCImportFile.TheFile.Document.Application.VertexTolerance;
for (++thirdPointIndex; thirdPointIndex < count; thirdPointIndex++)
{
XYZ pointOnPlane = validVertices[thirdPointIndex] -
(validVertices[thirdPointIndex] - firstPoint).DotProduct(planeNormal) * planeNormal;
if (pointOnPlane.DistanceTo(validVertices[thirdPointIndex]) > vertexEps)
{
Importer.TheLog.LogComment(Id, "Bounded loop plane is slightly non-planar, correcting.", false);
validVertices[thirdPointIndex] = pointOnPlane;
}
}
if (!tsBuilderScope.AddLoopVertices(Id, validVertices))
{
bPotentiallyAbortFace = true;
}
}
}
if (bPotentiallyAbortFace && IsOuter)
{
tsBuilderScope.AbortCurrentFace();
}
}
