""" build123d imports name: test_wire.py by: Gumyr date: January 22, 2025 desc: This python module contains tests for the build123d project. license: Copyright 2025 Gumyr Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. """ import math import random import unittest import numpy as np from build123d.topology.shape_core import TOLERANCE from build123d.build_enums import GeomType, Side from build123d.build_line import BuildLine from build123d.geometry import Axis, Color, Location, Plane, Vector from build123d.objects_curve import Curve, Line, PolarLine, Polyline, Spline from build123d.objects_sketch import Circle, Rectangle, RegularPolygon from build123d.operations_generic import fillet from build123d.topology import Edge, Face, Wire from OCP.BRepAdaptor import BRepAdaptor_CompCurve class TestWire(unittest.TestCase): def test_ellipse_arc(self): full_ellipse = Wire.make_ellipse(2, 1) half_ellipse = Wire.make_ellipse( 2, 1, start_angle=0, end_angle=180, closed=True ) self.assertAlmostEqual(full_ellipse.area / 2, half_ellipse.area, 5) def test_stitch(self): half_ellipse1 = Wire.make_ellipse( 2, 1, start_angle=0, end_angle=180, closed=False ) half_ellipse2 = Wire.make_ellipse( 2, 1, start_angle=180, end_angle=360, closed=False ) ellipse = half_ellipse1.stitch(half_ellipse2) self.assertEqual(len(ellipse.wires()), 1) def test_fillet_2d(self): square = Wire.make_rect(1, 1) squaroid = square.fillet_2d(0.1, square.vertices()) self.assertAlmostEqual( squaroid.length, 4 * (1 - 2 * 0.1) + 2 * math.pi * 0.1, 5 ) square.wrapped = None with self.assertRaises(ValueError): square.fillet_2d(0.1, square.vertices()) def test_chamfer_2d(self): square = Wire.make_rect(1, 1) squaroid = square.chamfer_2d(0.1, 0.1, square.vertices()) self.assertAlmostEqual( squaroid.length, 4 * (1 - 2 * 0.1 + 0.1 * math.sqrt(2)), 5 ) verts = square.vertices() verts[0].wrapped = None three_corners = square.chamfer_2d(0.1, 0.1, verts) self.assertEqual(len(three_corners.edges()), 7) square.wrapped = None with self.assertRaises(ValueError): square.chamfer_2d(0.1, 0.1, square.vertices()) def test_close(self): t = Polyline((0, 0), (1, 0), (0, 1), close=True) self.assertIs(t, t.close()) def test_chamfer_2d_edge(self): square = Wire.make_rect(1, 1) edge = square.edges().sort_by(Axis.Y)[0] vertex = edge.vertices().sort_by(Axis.X)[0] square = square.chamfer_2d( distance=0.1, distance2=0.2, vertices=[vertex], edge=edge ) self.assertAlmostEqual(square.edges().sort_by(Axis.Y)[0].length, 0.9) def test_make_convex_hull(self): # overlapping_edges = [ # Edge.make_circle(10, end_angle=60), # Edge.make_circle(10, start_angle=30, end_angle=90), # Edge.make_line((-10, 10), (10, -10)), # ] # with self.assertRaises(ValueError): # Wire.make_convex_hull(overlapping_edges) adjoining_edges = [ Edge.make_circle(10, end_angle=45), Edge.make_circle(10, start_angle=315, end_angle=360), Edge.make_line((-10, 10), (-10, -10)), ] hull_wire = Wire.make_convex_hull(adjoining_edges) self.assertAlmostEqual(Face(hull_wire).area, 319.9612, 4) def test_fix_degenerate_edges(self): e0 = Edge.make_line((0, 0), (1, 0)) e1 = Edge.make_line((2, 0), (1, 0)) w = Wire([e0, e1]) w.wrapped = None with self.assertRaises(ValueError): w.fix_degenerate_edges(0.1) # # Can't find a way to create one # edge0 = Edge.make_line((0, 0, 0), (1, 0, 0)) # edge1 = Edge.make_line(edge0 @ 0, edge0 @ 0 + Vector(0, 1, 0)) # edge1a = edge1.trim(0, 1e-7) # edge1b = edge1.trim(1e-7, 1.0) # edge2 = Edge.make_line(edge1 @ 1, edge1 @ 1 + Vector(1, 1, 0)) # wire = Wire([edge0, edge1a, edge1b, edge2]) # fixed_wire = wire.fix_degenerate_edges(1e-6) # self.assertEqual(len(fixed_wire.edges()), 2) def test_trim(self): e0 = Edge.make_line((0, 0), (1, 0)) e1 = Edge.make_line((2, 0), (1, 0)) e2 = Edge.make_line((2, 0), (3, 0)) w1 = Wire([e0, e1, e2]) t1 = w1.trim(0.2, 0.9).move(Location((0, 0.1, 0))) self.assertAlmostEqual(t1.length, 2.1, 5) e = Edge.make_three_point_arc((0, -20), (5, 0), (0, 20)) # Three edges are created 0->0.5->0.75->1.0 o = e.offset_2d(10, side=Side.RIGHT, closed=False) t2 = o.trim(0.1, 0.9) self.assertAlmostEqual(t2.length, o.length * 0.8, 5) t3 = o.trim(0.5, 1.0) self.assertAlmostEqual(t3.length, o.length * 0.5, 5) t4 = o.trim(0.5, 0.75) self.assertAlmostEqual(t4.length, o.length * 0.25, 5) w0 = Polyline((0, 0), (0, 1), (1, 1), (1, 0)) w2 = w0.trim(0, (0.5, 1)) self.assertAlmostEqual(w2 @ 1, (0.5, 1), 5) spline = Spline( (0, 0, 0), (0, 10, 0), tangents=((0, 0, 1), (0, 0, -1)), tangent_scalars=(2, 2), ) half = spline.trim(0.5, 1) self.assertAlmostEqual(spline @ 0.5, half @ 0, 4) self.assertAlmostEqual(spline @ 1, half @ 1, 4) w = Rectangle(3, 1).wire() t5 = w.trim(0, 0.5) self.assertAlmostEqual(t5.length, 4, 5) t6 = w.trim(0.5, 1) self.assertAlmostEqual(t6.length, 4, 5) p = RegularPolygon(10, 20).wire() t7 = p.trim(0.1, 0.2) self.assertAlmostEqual(p.length * 0.1, t7.length, 5) c = Circle(10).wire() t8 = c.trim(0.4, 0.9) self.assertAlmostEqual(c.length * 0.5, t8.length, 5) def test_param_at_point(self): e = Edge.make_three_point_arc((0, -20), (5, 0), (0, 20)) # Three edges are created 0->0.5->0.75->1.0 o = e.offset_2d(10, side=Side.RIGHT, closed=False) e0 = Edge.make_line((0, 0), (1, 0)) e1 = Edge.make_line((2, 0), (1, 0)) e2 = Edge.make_line((2, 0), (3, 0)) w1 = Wire([e0, e1, e2]) for wire in [o, w1]: u_value = random.random() position = wire.position_at(u_value) self.assertAlmostEqual(wire.param_at_point(position), u_value, 4) with self.assertRaises(ValueError): o.param_at_point((-1, 1)) with self.assertRaises(ValueError): w1.param_at_point((20, 20, 20)) w1.wrapped = None with self.assertRaises(ValueError): w1.param_at_point((0, 0)) def test_param_at_point_reversed_edges(self): with BuildLine(Plane.YZ) as wing_line: l1 = Line((0, 65), (80 / 2 + 1.526 * 4, 65)) PolarLine( l1 @ 1, 20.371288916, direction=Vector(0, 1, 0).rotate(Axis.X, -75) ) fillet(wing_line.vertices(), 7) w = wing_line.wire() params = [w.param_at_point(w @ (i / 20)) for i in range(21)] self.assertTrue(params == sorted(params)) for i, param in enumerate(params): self.assertAlmostEqual(param, i / 20, 6) def test_tangent_at_reversed_edges(self): with BuildLine(Plane.YZ) as wing_line: l1 = Line((0, 65), (80 / 2 + 1.526 * 4, 65)) PolarLine( l1 @ 1, 20.371288916, direction=Vector(0, 1, 0).rotate(Axis.X, -75) ) fillet(wing_line.vertices(), 7) w = wing_line.wire() self.assertAlmostEqual( w.tangent_at(0), (0, -0.2588190451025, 0.9659258262891), 6 ) self.assertAlmostEqual(w.tangent_at(1), (0, -1, 0), 6) def test_order_edges(self): w1 = Wire( [ Edge.make_line((0, 0), (1, 0)), Edge.make_line((1, 1), (1, 0)), Edge.make_line((0, 1), (1, 1)), ] ) ordered_edges = w1.order_edges() self.assertAlmostEqual(ordered_edges[0] @ 0, (0, 0, 0), 5) self.assertAlmostEqual(ordered_edges[1] @ 0, (1, 0, 0), 5) self.assertAlmostEqual(ordered_edges[2] @ 0, (1, 1, 0), 5) def test_geom_adaptor(self): w = Polyline((0, 0), (1, 0), (1, 1)) self.assertTrue(isinstance(w.geom_adaptor(), BRepAdaptor_CompCurve)) w.wrapped = None with self.assertRaises(ValueError): w.geom_adaptor() def test_constructor(self): e0 = Edge.make_line((0, 0), (1, 0)) e1 = Edge.make_line((1, 0), (1, 1)) w0 = Wire.make_circle(1) w1 = Wire(e0) self.assertTrue(w1.is_valid) w2 = Wire([e0]) self.assertAlmostEqual(w2.length, 1, 5) self.assertTrue(w2.is_valid) w3 = Wire([e0, e1]) self.assertTrue(w3.is_valid) self.assertAlmostEqual(w3.length, 2, 5) w4 = Wire(w0.wrapped) self.assertTrue(w4.is_valid) w5 = Wire(obj=w0.wrapped) self.assertTrue(w5.is_valid) w6 = Wire(obj=w0.wrapped, label="w6", color=Color("red")) self.assertTrue(w6.is_valid) self.assertEqual(w6.label, "w6") np.testing.assert_allclose(tuple(w6.color), (1.0, 0.0, 0.0, 1.0), 1e-5) w7 = Wire(w6) self.assertTrue(w7.is_valid) c0 = Polyline((0, 0), (1, 0), (1, 1)) w8 = Wire(c0) self.assertTrue(w8.is_valid) w9 = Wire(Curve([e0, e1])) self.assertTrue(w9.is_valid) with self.assertRaises(ValueError): Wire(bob="fred") class TestWireToBSpline(unittest.TestCase): def setUp(self): # A simple rectilinear, multi-segment wire: # p0 ── p1 # │ # p2 ── p3 self.p0 = Vector(0, 0, 0) self.p1 = Vector(20, 0, 0) self.p2 = Vector(20, 10, 0) self.p3 = Vector(35, 10, 0) e01 = Edge.make_line(self.p0, self.p1) e12 = Edge.make_line(self.p1, self.p2) e23 = Edge.make_line(self.p2, self.p3) self.wire = Wire([e01, e12, e23]) def test_to_bspline_basic_properties(self): bs = self.wire._to_bspline() # 1) Type/geom check self.assertIsInstance(bs, Edge) self.assertEqual(bs.geom_type, GeomType.BSPLINE) # 2) Endpoint preservation self.assertLess((Vector(bs.vertices()[0]) - self.p0).length, TOLERANCE) self.assertLess((Vector(bs.vertices()[-1]) - self.p3).length, TOLERANCE) # 3) Length preservation (within numerical tolerance) self.assertAlmostEqual(bs.length, self.wire.length, delta=1e-6) # 4) Topology collapse: single edge has only 2 vertices (start/end) self.assertEqual(len(bs.vertices()), 2) # 5) The composite BSpline should pass through former junctions for junction in (self.p1, self.p2): self.assertLess(bs.distance_to(junction), 1e-6) # 6) Normalized parameter increases along former junctions u_p1 = bs.param_at_point(self.p1) u_p2 = bs.param_at_point(self.p2) self.assertGreater(u_p1, 0.0) self.assertLess(u_p2, 1.0) self.assertLess(u_p1, u_p2) # 7) Re-evaluating at those parameters should be close to the junctions self.assertLess((bs.position_at(u_p1) - self.p1).length, 1e-6) self.assertLess((bs.position_at(u_p2) - self.p2).length, 1e-6) w = self.wire w.wrapped = None with self.assertRaises(ValueError): w._to_bspline() def test_to_bspline_orientation(self): # Ensure the BSpline follows the wire's topological order bs = self.wire._to_bspline() # Start ~ p0, end ~ p3 self.assertLess((bs.position_at(0.0) - self.p0).length, 1e-6) self.assertLess((bs.position_at(1.0) - self.p3).length, 1e-6) # Parameters at interior points should sit between 0 and 1 u0 = bs.param_at_point(self.p1) u1 = bs.param_at_point(self.p2) self.assertTrue(0.0 < u0 < 1.0) self.assertTrue(0.0 < u1 < 1.0) if __name__ == "__main__": unittest.main()