def make_brep_geometry(self): self.free_shapes = [shp_info for shp_info in self.all_shapes if shp_info.free] # sort down from solids to vertices self.free_shapes.sort(key=lambda shp: shp.dim(), reverse=True) free_shapes = [shp_info.shape for shp_info in self.free_shapes] compound = bw.Compound(free_shapes) compound.set_free_shapes() self.brep_file = os.path.abspath(self.basename + ".brep") with open(self.brep_file, 'w') as f: bw.write_model(f, compound, bw.Location()) self.make_gmsh_shape_dict()
def make_shell_brep(surface_3d): # Make surface bw_surface = bw.surface_from_bs(surface_3d) # make Vertices for the corners vertices = [bw.Vertex.on_surface(u, v, bw_surface) for u, v in [(0,0), (1,0), (1,1), (0,1)]] vertices.append(vertices[0]) edges = [bw.Edge(vertices[i:i+2]).attach_to_surface(bw_surface) for i in range(4)] face = bw.Face([bw.Wire(edges)],bw_surface) shell = bw.Shell([face]) compound = bw.Compound([shell]) compound.set_free_shapes() return compound
def prism_perturbed(): # 0, 0; top, bottom v1=bw.Vertex((0.0, 0.0, 1.0)) v2=bw.Vertex((0.0, 0.0, 0.0)) v3=bw.Vertex((0.0, 1.0, 1.0)) v4=bw.Vertex((0.0, 1.0, 0.0)) v5=bw.Vertex((1.0, 0.0, 1.0)) v6=bw.Vertex((1.0, 0.0, 0.0)) # face v12 - v34 # top e4=bw.Edge([v1,v3]) # top e6=bw.Edge([v3, v5]) # top e8=bw.Edge([v5, v1]) # top cup f4 = bw.Face([e4, e6, e8]) # bottom e5=bw.Edge([v2,v4]) # face v34 - v56 # bottom e7=bw.Edge([v4, v6]) # face v56 - v12 # bottom e9=bw.Edge([v6, v2]) # bot cup w5=bw.Wire([e5, e7, e9]) f5 = bw.Face([w5.m()]) # vertical edges e1=bw.Edge([v1,v2]) e2=bw.Edge([v3,v4]) e3=bw.Edge([v5,v6]) f1 = bw.Face([e1.m(), e4, e2, e5.m()]) f2 = bw.Face([e2.m(), e6, e3, e7.m()]) f3 = bw.Face([e3.m(), e8, e1, e9.m()]) shell = bw.Shell([ f4, f5.m(), f1, f2, f3 ]) cube_solid = bw.Solid([ shell ]) model = bw.Compound([cube_solid]) return model, composed_location()
def test_cube(self): shell = self._cube() #shell = self._permuted_cube() s1=bw.Solid([ shell ]) c1=bw.Compound([s1]) loc1=bw.Location([[0,0,1,0],[1,0,0,0],[0,1,0,0]]) loc2=bw.Location([[0,0,1,0],[1,0,0,0],[0,1,0,0]]) #dej tam tu druhou z prikladu cloc=bw.ComposedLocation([(loc1,1),(loc2,1)]) with open("_out_test_prism.brep", "w") as f: bw.write_model(f, c1, cloc) #bw.write_model(sys.stdout, c1, cloc) print(c1)
def tetrahedron(): v0 = bw.Vertex([0,0,0]) v1 = bw.Vertex([1,0,0]) v2 = bw.Vertex([0,1,0]) v3 = bw.Vertex([0,0,1]) e01 = bw.Edge([v0, v1]) e02 = bw.Edge([v0, v2]) e03 = bw.Edge([v0, v3]) e12 = bw.Edge([v1, v2]) e23 = bw.Edge([v2, v3]) e13 = bw.Edge([v1, v3]) f1 = bw.Face([e01, e12, e02.m()]) f2 = bw.Face([e02, e23, e03.m()]) f3 = bw.Face([e03, e13.m(), e01.m()]) f4 = bw.Face([e12, e23, e13.m()]) shell = bw.Shell([f1, f2, f3, f4]) s = bw.Solid([shell]) return bw.Compound([s]), bw.Identity
def gen(gallery_mesh_file, out_brep_file, mesh_cut_tool_param, inv_par, project_conf): el_char_len = 1.0 other_char_len = 10.0 if inv_par.meshFrom == MeshFrom.GALLERY_CLOUD: offset = np.array([ project_conf.point_cloud_origin_x, project_conf.point_cloud_origin_y, project_conf.point_cloud_origin_z ]) else: offset = np.array([ project_conf.gallery_mesh_origin_x, project_conf.gallery_mesh_origin_y, project_conf.gallery_mesh_origin_z ]) gallery_mesh = GmshIO(gallery_mesh_file) #gallery_origin = np.array(gallery_origin) for id, node in gallery_mesh.nodes.items(): gallery_mesh.nodes[id] = gallery_mesh.nodes[ id] #+ np.array([-622000.0, -1128000.0, 0.0]) base_point, gen_vecs = cut_tool_to_gen_vecs(mesh_cut_tool_param) opposite_pont = base_point + gen_vecs[0] + gen_vecs[1] + gen_vecs[2] planes = [(base_point, gen_vecs[0], gen_vecs[1]), (base_point, gen_vecs[1], gen_vecs[2]), (base_point, gen_vecs[2], gen_vecs[0]), (opposite_pont, gen_vecs[0], -gen_vecs[1]), (opposite_pont, gen_vecs[1], -gen_vecs[2]), (opposite_pont, gen_vecs[2], -gen_vecs[0])] b = inv_tr(gen_vecs) class VertInfo: def __init__(self, node): self.plane_pos = [0] * 6 self.cut = [False] * 6 for i in range(6): pv = np.cross(planes[i][1], planes[i][2]) w = np.array(node) - planes[i][0] self.plane_pos[i] = np.sign(np.dot(pv, w)) # sign zbytecny #v1 = bw.Vertex(base_point + gen_vecs[0]) bw_vertices = {} vertices_tr = {} vert_info = {} for id, node in gallery_mesh.nodes.items(): node += offset #bw_vertices[id] = bw.Vertex(node + np.array([- 622000, - 1128000, 0]), tolerance=1e-3) bw_vertices[id] = bw.Vertex(node, tolerance=1e-3) vert_info[id] = VertInfo(node) vertices_tr[id] = b @ (np.array(node) - base_point) bw_edges = {} def get_edge(id0, id1): k = (id0, id1) if k in bw_edges: return bw_edges[k] elif (id1, id0) in bw_edges: return bw_edges[(id1, id0)].m() else: e = bw.Edge([bw_vertices[k[0]], bw_vertices[k[1]]]) bw_edges[k] = e return e bw_faces = [] vids_to_move = [[], [], [], [], [], []] plane_edges = [[], [], [], [], [], []] cut_triangles = [[], [], [], [], [], []] tri_map = {} def process_triangle(id0, id1, id2): for i in range(6): if vert_info[id0].plane_pos[i] <= 0 or vert_info[id1].plane_pos[ i] <= 0 or vert_info[id2].plane_pos[i] <= 0: id_out = set() for j in range(6): if j == i: continue # todo: zbytecne resi protilehlou stranu for k in [id0, id1, id2]: if vert_info[k].plane_pos[j] <= 0: id_out.add(k) if len(id_out) >= 3: return id_inside = [] for j in [id0, id1, id2]: if vert_info[j].plane_pos[i] > 0: vids_to_move[i].append(j) id_inside.append(j) if len(id_inside) == 2: edge = (id_inside[0], id_inside[1]) if edge in plane_edges[i]: plane_edges[i].remove(edge) elif (edge[1], edge[0]) in plane_edges[i]: plane_edges[i].remove((edge[1], edge[0])) else: plane_edges[i].append(edge) if len(id_inside) >= 1: cut_triangles[i].append((id0, id1, id2)) return e1 = get_edge(id0, id1) e2 = get_edge(id1, id2) e3 = get_edge(id2, id0) f = bw.Face([e1, e2, e3]) bw_faces.append(f) tri_map[(id0, id1, id2)] = f for id, data in gallery_mesh.elements.items(): el_type, tags, nodes = data if el_type != 2: continue process_triangle(*nodes) # remove duplicit vertices id vids_to_move_set = [set() for _ in range(6)] for i in range(6): vids_to_move_set[i] = set(vids_to_move[i]) vids_to_move[i] = list(vids_to_move_set[i]) # check if every border vertex belongs to only one plane for i in range(6): for j in range(6): if i == j: continue if not vids_to_move_set[i].isdisjoint(vids_to_move_set[j]): print("ERROR: Edge of cut body is to close to gallery mesh.") return False # remove triangles laying on plane for i in range(6): two_side = [] for id, data in gallery_mesh.elements.items(): el_type, tags, nodes = data if el_type != 2: continue count = 0 for n in nodes: if n in vids_to_move_set[i]: count += 1 if count == 3: two_side.append((*nodes, )) if (nodes[0], nodes[1]) in plane_edges[i]: plane_edges[i].remove((nodes[0], nodes[1])) elif (nodes[1], nodes[0]) in plane_edges[i]: plane_edges[i].remove((nodes[1], nodes[0])) else: plane_edges[i].append((nodes[0], nodes[1])) if (nodes[1], nodes[2]) in plane_edges[i]: plane_edges[i].remove((nodes[1], nodes[2])) elif (nodes[2], nodes[1]) in plane_edges[i]: plane_edges[i].remove((nodes[2], nodes[1])) else: plane_edges[i].append((nodes[1], nodes[2])) if (nodes[2], nodes[0]) in plane_edges[i]: plane_edges[i].remove((nodes[2], nodes[0])) elif (nodes[0], nodes[2]) in plane_edges[i]: plane_edges[i].remove((nodes[0], nodes[2])) else: plane_edges[i].append((nodes[2], nodes[0])) bw_faces.remove(tri_map[(*nodes, )]) # move border vertices ax_pos = [ (2, 0.0), (0, 0.0), (1, 0.0), (2, 1.0), (0, 1.0), (1, 1.0), ] for i in range(6): for vid in vids_to_move[i]: shift = ax_pos[i][1] - vertices_tr[vid][ax_pos[i][0]] vertices_tr[vid][ax_pos[i][0]] = ax_pos[i][1] bw_vertices[vid].point += shift * gen_vecs[ax_pos[i][0]] face_edges = [[], [], [], [], [], []] # todo: doresit dotekajici se wiry for i in range(6): if not plane_edges[i]: continue first_edge = last_edge = plane_edges[i].pop() first_vertex = last_edge[0] last_vertex = last_edge[1] wire = [first_edge] while plane_edges[i]: find = False cont_edges = [] for edge in list(plane_edges[i]): if last_vertex in edge: cont_edges.append(edge) if cont_edges: # find appropriate edge edge = cont_edges[0] wire.append(edge) plane_edges[i].remove(edge) if first_vertex in edge: # we have closed wire face_edges[i].append(wire) #print(wire) if not plane_edges[i]: break first_edge = last_edge = plane_edges[i].pop() first_vertex = last_edge[0] last_vertex = last_edge[1] wire = [first_edge] else: last_edge = edge last_vertex = edge[1] if last_vertex != edge[1] else edge[0] else: # not find closed wire if not plane_edges[i]: break first_edge = last_edge = plane_edges[i].pop() first_vertex = last_edge[0] last_vertex = last_edge[1] wire = [first_edge] v1 = bw.Vertex(base_point + gen_vecs[0]) v2 = bw.Vertex(base_point + gen_vecs[2] + gen_vecs[0]) v3 = bw.Vertex(base_point + gen_vecs[2] + gen_vecs[1] + gen_vecs[0]) v4 = bw.Vertex(base_point + gen_vecs[1] + gen_vecs[0]) v5 = bw.Vertex(base_point) v6 = bw.Vertex(base_point + gen_vecs[2]) v7 = bw.Vertex(base_point + gen_vecs[2] + gen_vecs[1]) v8 = bw.Vertex(base_point + gen_vecs[1]) e1 = bw.Edge([v1, v2]) e2 = bw.Edge([v2, v3]) e3 = bw.Edge([v3, v4]) e4 = bw.Edge([v4, v1]) faces = [] for i in [4]: #range(6): #surf, vtxs_uv = bw.Approx.plane([planes[i][0], planes[i][0] + planes[i][1], planes[i][0] + planes[i][2]]) surf, vtxs_uv = bw.Approx.plane( [v1.point, v1.point + gen_vecs[1], v1.point + gen_vecs[2]]) assert vtxs_uv == [(0, 0), (1, 0), (0, 1)] e1.attach_to_surface(surf, (0, 0), (0, 1)) e2.attach_to_surface(surf, (0, 1), (1, 1)) e3.attach_to_surface(surf, (1, 1), (1, 0)) e4.attach_to_surface(surf, (1, 0), (0, 0)) for j in range(len(face_edges[i])): for e in face_edges[i][j]: try: bw_edges[e].attach_to_surface(surf, vertices_tr[e[0]][1:], vertices_tr[e[1]][1:]) except KeyError: bw_edges[(e[1], e[0])].attach_to_surface(surf, vertices_tr[e[1]][1:], vertices_tr[e[0]][1:]) wire_list = [] for j in range(len(face_edges[i])): edge_list = [] for e in face_edges[i][j]: if e in bw_edges: edge_list.append(bw_edges[e]) else: edge_list.append(bw_edges[(e[1], e[0])]) wire_list.append(edge_list) # todo: face v dire nefunguje faces.append( bw.Face([ bw.Wire([e1, e2, e3, e4]), *[bw.Wire(edge_list) for edge_list in wire_list] ], surface=surf)) #f1 = bw.Face([bw.Wire([e1, e2, e3]), bw.Wire([e1x, e2x, e3x])], surface=surf) e5 = bw.Edge([v5, v6]) e6 = bw.Edge([v6, v7]) e7 = bw.Edge([v7, v8]) e8 = bw.Edge([v8, v5]) f2 = bw.Face([e5, e6, e7, e8]) e9 = bw.Edge([v1, v5]) e10 = bw.Edge([v2, v6]) e11 = bw.Edge([v3, v7]) e12 = bw.Edge([v4, v8]) # f3 = bw.Face([e1, e10, e5.m(), e9.m()]) # f4 = bw.Face([e2, e11, e6.m(), e10.m()]) # f5 = bw.Face([e3, e12, e7.m(), e11.m()]) # f6 = bw.Face([e4, e9, e8.m(), e12.m()]) for i in [2]: #range(6): surf, vtxs_uv = bw.Approx.plane( [v5.point, v5.point + gen_vecs[0], v5.point + gen_vecs[2]]) assert vtxs_uv == [(0, 0), (1, 0), (0, 1)] e1.attach_to_surface(surf, (1, 0), (1, 1)) e10.attach_to_surface(surf, (1, 1), (0, 1)) e5.attach_to_surface(surf, (0, 0), (0, 1)) e9.attach_to_surface(surf, (1, 0), (0, 0)) for j in range(len(face_edges[i])): for e in face_edges[i][j]: try: bw_edges[e].attach_to_surface(surf, vertices_tr[e[0]][0:3:2], vertices_tr[e[1]][0:3:2]) except KeyError: bw_edges[(e[1], e[0])].attach_to_surface( surf, vertices_tr[e[1]][0:3:2], vertices_tr[e[0]][0:3:2]) wire_list = [] for j in range(len(face_edges[i])): edge_list = [] for e in face_edges[i][j]: if e in bw_edges: edge_list.append(bw_edges[e]) else: edge_list.append(bw_edges[(e[1], e[0])]) wire_list.append(edge_list) faces.append( bw.Face([ bw.Wire([e1, e10, e5, e9]), *[bw.Wire(edge_list) for edge_list in wire_list] ], surface=surf)) for i in [5]: #range(6): surf, vtxs_uv = bw.Approx.plane( [v8.point, v8.point + gen_vecs[0], v8.point + gen_vecs[2]]) #print(vtxs_uv) e3.attach_to_surface(surf, (1, 1), (1, 0)) e12.attach_to_surface(surf, (1, 0), (0, 0)) e7.attach_to_surface(surf, (0, 1), (0, 0)) e11.attach_to_surface(surf, (1, 1), (0, 1)) for j in range(len(face_edges[i])): for e in face_edges[i][j]: try: bw_edges[e].attach_to_surface(surf, vertices_tr[e[0]][0:3:2], vertices_tr[e[1]][0:3:2]) except KeyError: bw_edges[(e[1], e[0])].attach_to_surface( surf, vertices_tr[e[1]][0:3:2], vertices_tr[e[0]][0:3:2]) wire_list = [] for j in range(len(face_edges[i])): edge_list = [] for e in face_edges[i][j]: if e in bw_edges: edge_list.append(bw_edges[e]) else: edge_list.append(bw_edges[(e[1], e[0])]) wire_list.append(edge_list) #wire_list2 = [wire_list[4]] #wire_list.remove(wire_list[4]) faces.append( bw.Face([ bw.Wire([e3, e12, e7, e11]), *[bw.Wire(edge_list) for edge_list in wire_list] ], surface=surf)) #faces.append(bw.Face([bw.Wire(edge_list)], surface=surf)) #faces.append(bw.Face([*[bw.Wire(edge_list) for edge_list in wire_list2]], surface=surf)) for i in [1]: #range(6): surf, vtxs_uv = bw.Approx.plane( [v5.point, v5.point + gen_vecs[1], v5.point + gen_vecs[2]]) #print(vtxs_uv) e5.attach_to_surface(surf, (0, 0), (0, 1)) e6.attach_to_surface(surf, (0, 1), (1, 1)) e7.attach_to_surface(surf, (1, 1), (1, 0)) e8.attach_to_surface(surf, (1, 0), (0, 0)) for j in range(len(face_edges[i])): for e in face_edges[i][j]: try: bw_edges[e].attach_to_surface(surf, vertices_tr[e[0]][1:], vertices_tr[e[1]][1:]) except KeyError: bw_edges[(e[1], e[0])].attach_to_surface(surf, vertices_tr[e[1]][1:], vertices_tr[e[0]][1:]) wire_list = [] for j in range(len(face_edges[i])): edge_list = [] for e in face_edges[i][j]: if e in bw_edges: edge_list.append(bw_edges[e]) else: edge_list.append(bw_edges[(e[1], e[0])]) wire_list.append(edge_list) faces.append( bw.Face([ bw.Wire([e5, e6, e7, e8]), *[bw.Wire(edge_list) for edge_list in wire_list] ], surface=surf)) for i in [3]: #range(6): surf, vtxs_uv = bw.Approx.plane( [v6.point, v6.point + gen_vecs[0], v6.point + gen_vecs[1]]) e2.attach_to_surface(surf, (1, 0), (1, 1)) e11.attach_to_surface(surf, (1, 1), (0, 1)) e6.attach_to_surface(surf, (0, 0), (0, 1)) e10.attach_to_surface(surf, (1, 0), (0, 0)) for j in range(len(face_edges[i])): for e in face_edges[i][j]: try: bw_edges[e].attach_to_surface(surf, vertices_tr[e[0]][:2], vertices_tr[e[1]][:2]) except KeyError: bw_edges[(e[1], e[0])].attach_to_surface(surf, vertices_tr[e[1]][:2], vertices_tr[e[0]][:2]) wire_list = [] for j in range(len(face_edges[i])): edge_list = [] for e in face_edges[i][j]: if e in bw_edges: edge_list.append(bw_edges[e]) else: edge_list.append(bw_edges[(e[1], e[0])]) wire_list.append(edge_list) faces.append( bw.Face([ bw.Wire([e2, e11, e6, e10]), *[bw.Wire(edge_list) for edge_list in wire_list] ], surface=surf)) for i in [0]: #range(6): surf, vtxs_uv = bw.Approx.plane( [v5.point, v5.point + gen_vecs[0], v5.point + gen_vecs[1]]) e4.attach_to_surface(surf, (1, 1), (1, 0)) e9.attach_to_surface(surf, (1, 0), (0, 0)) e8.attach_to_surface(surf, (0, 1), (0, 0)) e12.attach_to_surface(surf, (1, 1), (0, 1)) for j in range(len(face_edges[i])): for e in face_edges[i][j]: try: bw_edges[e].attach_to_surface(surf, vertices_tr[e[0]][:2], vertices_tr[e[1]][:2]) except KeyError: bw_edges[(e[1], e[0])].attach_to_surface(surf, vertices_tr[e[1]][:2], vertices_tr[e[0]][:2]) wire_list = [] for j in range(len(face_edges[i])): edge_list = [] for e in face_edges[i][j]: if e in bw_edges: edge_list.append(bw_edges[e]) else: edge_list.append(bw_edges[(e[1], e[0])]) wire_list.append(edge_list) faces.append( bw.Face([ bw.Wire([e4, e9, e8, e12]), *[bw.Wire(edge_list) for edge_list in wire_list] ], surface=surf)) shell = bw.Shell(bw_faces + faces) #shell = bw.Shell(faces) s1 = bw.Solid([shell]) c1 = bw.Compound([s1]) with open(out_brep_file, "w") as f: bw.write_model(f, c1) return True
def gen(cloud_file, out_brep_file, mesh_cut_tool_param): surf_approx = bs_approx.SurfaceApprox.approx_from_file(cloud_file) quad = surf_approx.compute_default_quad() nuv = surf_approx.compute_default_nuv() nuv = nuv / 5 surface = surf_approx.compute_approximation() #surface = surf_approx.compute_approximation(quad=quad, nuv=nuv) surface_3d = surface.make_full_surface() bw_surface = bw.surface_from_bs(surface_3d) a = bw_surface._bs_surface.eval(0, 0) b = bw_surface._bs_surface.eval(1, 0) c = bw_surface._bs_surface.eval(0, 1) base_point, gen_vecs = cut_tool_to_gen_vecs(mesh_cut_tool_param) a[2] = 0 b[2] = 0 c[2] = 0 ab = b - a ac = c - a tr = np.array([ab, ac, [0, 0, 1]]).T inv_tr = np.linalg.inv(tr) v1 = bw.Vertex(base_point + gen_vecs[0]) v2 = bw.Vertex(base_point + gen_vecs[2] + gen_vecs[0]) v3 = bw.Vertex(base_point + gen_vecs[2] + gen_vecs[1] + gen_vecs[0]) v4 = bw.Vertex(base_point + gen_vecs[1] + gen_vecs[0]) v5 = bw.Vertex(base_point) v6 = bw.Vertex(base_point + gen_vecs[2]) v7 = bw.Vertex(base_point + gen_vecs[2] + gen_vecs[1]) v8 = bw.Vertex(base_point + gen_vecs[1]) v2l = inv_tr @ (v2.point - a) v3l = inv_tr @ (v3.point - a) v6l = inv_tr @ (v6.point - a) v7l = inv_tr @ (v7.point - a) try: v2s = bw_surface._bs_surface.eval(v2l[0], v2l[1]) v3s = bw_surface._bs_surface.eval(v3l[0], v3l[1]) v6s = bw_surface._bs_surface.eval(v6l[0], v6l[1]) v7s = bw_surface._bs_surface.eval(v7l[0], v7l[1]) except IndexError: print("Error: Mesh cut area must be inside surface point cloud.") return False, bw_surface v2h = v2s[2] - base_point[2] v3h = v3s[2] - base_point[2] v6h = v6s[2] - base_point[2] v7h = v7s[2] - base_point[2] v2.point[2] = v2s[2] v3.point[2] = v3s[2] v6.point[2] = v6s[2] v7.point[2] = v7s[2] e1 = bw.Edge([v1, v2]) e2 = bw.Edge([v2, v3]) e3 = bw.Edge([v3, v4]) e4 = bw.Edge([v4, v1]) e5 = bw.Edge([v5, v6]) e6 = bw.Edge([v6, v7]) e7 = bw.Edge([v7, v8]) e8 = bw.Edge([v8, v5]) e9 = bw.Edge([v1, v5]) e10 = bw.Edge([v2, v6]) e11 = bw.Edge([v3, v7]) e12 = bw.Edge([v4, v8]) faces = [] # top e2.attach_to_surface(bw_surface, (v2l[0], v2l[1]), (v3l[0], v3l[1])) e11.attach_to_surface(bw_surface, (v3l[0], v3l[1]), (v7l[0], v7l[1])) e6.attach_to_surface(bw_surface, (v6l[0], v6l[1]), (v7l[0], v7l[1])) e10.attach_to_surface(bw_surface, (v2l[0], v2l[1]), (v6l[0], v6l[1])) faces.append(bw.Face([bw.Wire([e2, e11, e6, e10])], surface=bw_surface)) # bottom surf, vtxs_uv = bw.Approx.plane( [v5.point, v5.point + gen_vecs[0], v5.point + gen_vecs[1]]) e4.attach_to_surface(surf, (1, 1), (1, 0)) e9.attach_to_surface(surf, (1, 0), (0, 0)) e8.attach_to_surface(surf, (0, 1), (0, 0)) e12.attach_to_surface(surf, (1, 1), (0, 1)) faces.append(bw.Face([bw.Wire([e4, e9, e8, e12])], surface=surf)) def get_curves(v0, v1): n_points = 100 u_points = np.linspace(v0[0], v1[0], n_points) v_points = np.linspace(v0[1], v1[1], n_points) uv_points = np.stack((u_points, v_points), axis=1) xyz_points = bw_surface._bs_surface.eval_array(uv_points) curve_xyz = bs_approx.curve_from_grid(xyz_points) poles_z = curve_xyz.poles[:, 2].copy() x_diff, y_diff, z_diff = np.abs(xyz_points[-1] - xyz_points[0]) if x_diff > y_diff: axis = 0 else: axis = 1 poles_t = curve_xyz.poles[:, axis].copy() poles_t -= xyz_points[0][axis] poles_t /= (xyz_points[-1][axis] - xyz_points[0][axis]) poles_z -= base_point[2] poles_tz = np.stack((poles_t, poles_z), axis=1) curve_tz = bs.Curve(curve_xyz.basis, poles_tz) return bw.curve_from_bs(curve_tz), bw.curve_from_bs(curve_xyz) surf, vtxs_uv = bw.Approx.plane( [v1.point, v1.point + gen_vecs[1], v1.point + [0, 0, 1]]) assert vtxs_uv == [(0, 0), (1, 0), (0, 1)] e1.attach_to_surface(surf, (0, 0), (0, v2h)) curve_tz, curve_xyz = get_curves(v2l, v3l) e2.attach_to_2d_curve((0.0, 1.0), curve_tz, surf) e2.attach_to_3d_curve((0.0, 1.0), curve_xyz) e3.attach_to_surface(surf, (1, v3h), (1, 0)) e4.attach_to_surface(surf, (1, 0), (0, 0)) faces.append(bw.Face([bw.Wire([e1, e2, e3, e4])], surface=surf)) surf, vtxs_uv = bw.Approx.plane( [v5.point + gen_vecs[0], v5.point, v5.point + gen_vecs[0] + [0, 0, 1]]) assert vtxs_uv == [(0, 0), (1, 0), (0, 1)] e1.attach_to_surface(surf, (0, 0), (0, v2h)) curve_tz, curve_xyz = get_curves(v2l, v6l) e10.attach_to_2d_curve((0.0, 1.0), curve_tz, surf) e10.attach_to_3d_curve((0.0, 1.0), curve_xyz) e5.attach_to_surface(surf, (1, 0), (1, v6h)) e9.attach_to_surface(surf, (0, 0), (1, 0)) faces.append(bw.Face([bw.Wire([e1, e10, e5, e9])], surface=surf)) surf, vtxs_uv = bw.Approx.plane( [v8.point + gen_vecs[0], v8.point, v8.point + gen_vecs[0] + [0, 0, 1]]) assert vtxs_uv == [(0, 0), (1, 0), (0, 1)] e3.attach_to_surface(surf, (0, v3h), (0, 0)) e12.attach_to_surface(surf, (0, 0), (1, 0)) e7.attach_to_surface(surf, (1, v7h), (1, 0)) curve_tz, curve_xyz = get_curves(v3l, v7l) e11.attach_to_2d_curve((0.0, 1.0), curve_tz, surf) e11.attach_to_3d_curve((0.0, 1.0), curve_xyz) faces.append(bw.Face([bw.Wire([e3, e12, e7, e11])], surface=surf)) surf, vtxs_uv = bw.Approx.plane( [v5.point, v5.point + gen_vecs[1], v5.point + [0, 0, 1]]) assert vtxs_uv == [(0, 0), (1, 0), (0, 1)] e5.attach_to_surface(surf, (0, 0), (0, v6h)) curve_tz, curve_xyz = get_curves(v6l, v7l) e6.attach_to_2d_curve((0.0, 1.0), curve_tz, surf) e6.attach_to_3d_curve((0.0, 1.0), curve_xyz) e7.attach_to_surface(surf, (1, v7h), (1, 0)) e8.attach_to_surface(surf, (1, 0), (0, 0)) faces.append(bw.Face([bw.Wire([e5, e6, e7, e8])], surface=surf)) shell = bw.Shell(faces) s1 = bw.Solid([shell]) c1 = bw.Compound([s1]) with open(out_brep_file, "w") as f: bw.write_model(f, c1) return True, bw_surface