private PrintMeshAssembly PrintMeshAssemblyFromMeshes(IEnumerable <DMesh3> meshes) { if (AcceptsParts) { var printMeshAssembly = new PrintMeshAssembly(); printMeshAssembly.AddMeshes(meshes, PrintMeshOptionsFactory.Default()); return(printMeshAssembly); } return(null); }
public int AddMesh(DMesh3 mesh) { return(AddMesh(mesh, PrintMeshOptionsFactory.Default())); }
/// <summary> /// Slice the meshes and return the slice stack. /// </summary> public Result Compute() { Result result = new Result(); if (Meshes.Count == 0) { return(result); } // find Z interval we want to slice in Interval1d zrange = Interval1d.Empty; foreach (var meshinfo in Meshes) { zrange.Contain(meshinfo.bounds.Min.z); zrange.Contain(meshinfo.bounds.Max.z); } if (SetMinZValue != double.MinValue) { zrange.a = SetMinZValue; } result.TopZ = Math.Round(zrange.b, PrecisionDigits); result.BaseZ = Math.Round(zrange.a, PrecisionDigits); // [TODO] might be able to make better decisions if we took flat regions // into account when constructing initial Z-heights? if we have large flat // region just below Zstep, might make sense to do two smaller Z-steps so we // can exactly hit it?? // construct list of clearing Z-heights List <double> clearingZLayers = new List <double>(); double cur_layer_z = zrange.b; int layer_i = 0; while (cur_layer_z > zrange.a) { double layer_height = get_layer_height(layer_i); cur_layer_z -= layer_height; double z = Math.Round(cur_layer_z, PrecisionDigits); clearingZLayers.Add(z); layer_i++; } if (clearingZLayers.Last() < result.BaseZ) { clearingZLayers[clearingZLayers.Count - 1] = result.BaseZ; } if (clearingZLayers.Last() == clearingZLayers[clearingZLayers.Count - 2]) { clearingZLayers.RemoveAt(clearingZLayers.Count - 1); } // construct layer slices from Z-heights List <PlanarSlice> clearing_slice_list = new List <PlanarSlice>(); layer_i = 0; for (int i = 0; i < clearingZLayers.Count; ++i) { double layer_height = (i == clearingZLayers.Count - 1) ? (result.TopZ - clearingZLayers[i]) : (clearingZLayers[i + 1] - clearingZLayers[i]); double z = clearingZLayers[i]; Interval1d zspan = new Interval1d(z, z + layer_height); if (SliceLocation == SliceLocations.EpsilonBase) { z += 0.001; } PlanarSlice slice = SliceFactoryF(zspan, z, layer_i); clearing_slice_list.Add(slice); layer_i++; } int NH = clearing_slice_list.Count; if (NH > MaxLayerCount) { throw new Exception("MeshPlanarSlicer.Compute: exceeded layer limit. Increase .MaxLayerCount."); } PlanarSlice[] clearing_slices = clearing_slice_list.ToArray(); // assume Resolve() takes 2x as long as meshes... TotalCompute = (Meshes.Count * NH) + (2 * NH); Progress = 0; // compute slices separately for each mesh for (int mi = 0; mi < Meshes.Count; ++mi) { if (Cancelled()) { break; } DMesh3 mesh = Meshes[mi].mesh; PrintMeshOptions mesh_options = Meshes[mi].options; // [TODO] should we hang on to this spatial? or should it be part of assembly? DMeshAABBTree3 spatial = new DMeshAABBTree3(mesh, true); AxisAlignedBox3d bounds = Meshes[mi].bounds; bool is_cavity = mesh_options.IsCavity; bool is_crop = mesh_options.IsCropRegion; bool is_support = mesh_options.IsSupport; bool is_closed = (mesh_options.IsOpen) ? false : mesh.IsClosed(); var useOpenMode = (mesh_options.OpenPathMode == OpenPathsModes.Default) ? DefaultOpenPathMode : mesh_options.OpenPathMode; if (is_crop || is_support) { throw new Exception("Not supported!"); } // each layer is independent so we can do in parallel gParallel.ForEach(Interval1i.Range(NH), (i) => { if (Cancelled()) { return; } double z = clearing_slices[i].Z; if (z < bounds.Min.z || z > bounds.Max.z) { return; } // compute cut Polygon2d[] polys; PolyLine2d[] paths; ComputeSlicePlaneCurves(mesh, spatial, z, is_closed, out polys, out paths); if (is_closed) { // construct planar complex and "solids" // (ie outer polys and nested holes) PlanarComplex complex = new PlanarComplex(); foreach (Polygon2d poly in polys) { complex.Add(poly); } PlanarComplex.FindSolidsOptions options = PlanarComplex.FindSolidsOptions.Default; options.WantCurveSolids = false; options.SimplifyDeviationTolerance = 0.001; options.TrustOrientations = true; options.AllowOverlappingHoles = true; PlanarComplex.SolidRegionInfo solids = complex.FindSolidRegions(options); List <GeneralPolygon2d> solid_polygons = ApplyValidRegions(solids.Polygons); if (is_cavity) { add_cavity_polygons(clearing_slices[i], solid_polygons, mesh_options); } else { if (ExpandStockAmount > 0) { solid_polygons = ClipperUtil.MiterOffset(solid_polygons, ExpandStockAmount); } add_solid_polygons(clearing_slices[i], solid_polygons, mesh_options); } } Interlocked.Increment(ref Progress); }); // end of parallel.foreach } // end mesh iter // resolve planar intersections, etc gParallel.ForEach(Interval1i.Range(NH), (i) => { if (Cancelled()) { return; } clearing_slices[i].Resolve(); Interlocked.Add(ref Progress, 2); }); // add to clearing stack result.Clearing = SliceStackFactoryF(); for (int k = 0; k < clearing_slices.Length; ++k) { result.Clearing.Add(clearing_slices[k]); } /* * Horizontal planar regions finishing pass. * First we find all planar horizontal Z-regions big enough to mill. * Then we add slices at the Z's we haven't touched yet. * * Cannot just 'fill' planar regions because we will miss edges that might * be millable. So we grow region and then intersect with full-slice millable area. */ // find set of horizontal flat regions Dictionary <double, List <PlanarRegion> > flat_regions = FindPlanarZRegions(ToolDiameter); if (flat_regions.Count == 0) { goto done_slicing; } // if we have already milled this exact Z-height in clearing pass, then we can skip it List <double> doneZ = new List <double>(); foreach (double z in flat_regions.Keys) { if (clearingZLayers.Contains(z)) { doneZ.Add(z); } } foreach (var z in doneZ) { flat_regions.Remove(z); } // create slice for each layer PlanarSlice[] horz_slices = new PlanarSlice[flat_regions.Count]; List <double> flatZ = new List <double>(flat_regions.Keys); flatZ.Sort(); for (int k = 0; k < horz_slices.Length; ++k) { double z = flatZ[k]; Interval1d zspan = new Interval1d(z, z + LayerHeightMM); horz_slices[k] = SliceFactoryF(zspan, z, k); // compute full millable region slightly above this slice. PlanarSlice clip_slice = ComputeSolidSliceAtZ(z + 0.0001, false); clip_slice.Resolve(); // extract planar polys List <Polygon2d> polys = GetPlanarPolys(flat_regions[z]); PlanarComplex complex = new PlanarComplex(); foreach (Polygon2d poly in polys) { complex.Add(poly); } // convert to planar solids PlanarComplex.FindSolidsOptions options = PlanarComplex.FindSolidsOptions.SortPolygons; options.SimplifyDeviationTolerance = 0.001; options.TrustOrientations = true; options.AllowOverlappingHoles = true; PlanarComplex.SolidRegionInfo solids = complex.FindSolidRegions(options); List <GeneralPolygon2d> solid_polygons = ApplyValidRegions(solids.Polygons); // If planar solid has holes, then when we do inset later, we might lose // too-thin parts. Shrink the holes to avoid this case. //FilterHoles(solid_polygons, 0.55 * ToolDiameter); // ok now we need to expand region and intersect with full region. solid_polygons = ClipperUtil.MiterOffset(solid_polygons, ToolDiameter * 0.5, 0.0001); solid_polygons = ClipperUtil.Intersection(solid_polygons, clip_slice.Solids, 0.0001); // Same idea as above, but if we do after, we keep more of the hole and // hence do less extra clearing. // Also this could then be done at the slicer level instead of here... // (possibly this entire thing should be done at slicer level, except we need clip_slice!) FilterHoles(solid_polygons, 1.1 * ToolDiameter); add_solid_polygons(horz_slices[k], solid_polygons, PrintMeshOptionsFactory.Default()); } // resolve planar intersections, etc int NF = horz_slices.Length; gParallel.ForEach(Interval1i.Range(NF), (i) => { if (Cancelled()) { return; } horz_slices[i].Resolve(); Interlocked.Add(ref Progress, 2); }); // add to clearing stack result.HorizontalFinish = SliceStackFactoryF(); for (int k = 0; k < horz_slices.Length; ++k) { result.HorizontalFinish.Add(horz_slices[k]); } done_slicing: return(result); }
public void AddMeshes(IEnumerable <DMesh3> meshes) { AddMeshes(meshes, PrintMeshOptionsFactory.Default()); }
public void AddMesh(DMesh3 mesh) { AddMesh(mesh, PrintMeshOptionsFactory.Default()); }