diff --git a/tests/TestAssembleEdges.py b/tests/TestAssembleEdges.py deleted file mode 100644 index 838a797c..00000000 --- a/tests/TestAssembleEdges.py +++ /dev/null @@ -1,79 +0,0 @@ -""" - Tests AssembleEdges functionality -""" - -import cadquery as cq -from tests import BaseTest - -class TestAssembleEdges(BaseTest): - - def edge_wire_1(self): - # Plate with 5 sides and 2 bumps, one side is not co-planar with the other sides - thickness = 0.1 - edge_points = [[-7.,-7.,0.], [-3.,-10.,3.], [7.,-7.,0.], [7.,7.,0.], [-7.,7.,0.]] - edge_wire = cq.Workplane('XY').polyline([(-7.,-7.), (7.,-7.), (7.,7.), (-7.,7.)]) - edge_wire = edge_wire.add(cq.Workplane('YZ').workplane().transformed(offset=cq.Vector(0, 0, -7), rotate=cq.Vector(45, 0, 0)).spline([(-7.,0.), (3,-3), (7.,0.)])) - edge_wire = [o.vals()[0] for o in edge_wire.all()] - edge_wire = cq.Wire.assembleEdges(edge_wire) - - return edge_wire - - - def edge_wire_2(self): - # Embossed star, need to change optional parameters to obtain nice looking result. - r1=3. - r2=10. - fn=6 - thickness = 0.1 - edge_points = [[r1*cos(i * pi/fn), r1*sin(i * pi/fn)] if i%2==0 else [r2*cos(i * pi/fn), r2*sin(i * pi/fn)] for i in range(2*fn+1)] - edge_wire = cq.Workplane('XY').polyline(edge_points) - edge_wire = [o.vals()[0] for o in edge_wire.all()] - edge_wire = cq.Wire.assembleEdges(edge_wire) - - return edge_wire - - - def edge_wire_3(self): - # Points on hexagonal pattern coordinates, use of pushpoints. - r1 = 1. - N = 3 - ca = cos(30. * pi/180.) - sa = sin(30. * pi/180.) - # EVEN ROWS - x_p = np.arange(-N*r1, N*r1, ca*2*r1) - y_p = np.arange(-N*r1, N*r1, 3*r1) - x_p, y_p = np.meshgrid(x_p, y_p) - xy_p_even = [(x,y) for x,y in zip(x_p.flatten(), y_p.flatten())] - # ODD ROWS - x_p = np.arange(-(N-0.5)*r1*ca, (N+1.5)*r1*ca, ca*2*r1) - y_p = np.arange(-(N-2+sa)*r1, (N+1+sa)*r1, 3*r1) - x_p, y_p = np.meshgrid(x_p, y_p) - xy_p_odd = [(x,y) for x,y in zip(x_p.flatten(), y_p.flatten())] - pts = xy_p_even + xy_p_odd - # Spike surface - thickness = 0.1 - fn = 6 - edge_points = [[r1*cos(i * 2*pi/fn), r1*sin(i * 2*pi/fn)] for i in range(fn+1)] - surface_points = [[0.25,0,0.75], [-0.25,0,0.75], [0,0.25,0.75], [0,-0.25,0.75], [0,0,2]] - edge_wire = cq.Workplane('XY').polyline(edge_points) - edge_wire = [o.vals()[0] for o in edge_wire.all()] - edge_wire = cq.Wire.assembleEdges(edge_wire) - - return edge_wire - - - def edge_wire_4(self): - # Gyroïd, all edges are splines on different workplanes. - thickness = 0.1 - edge_points = [[[3.54, 3.54], [1.77, 0.0], [3.54, -3.54]], [[-3.54, -3.54], [0.0, -1.77], [3.54, -3.54]], [[-3.54, -3.54], [0.0, -1.77], [3.54, -3.54]], [[-3.54, -3.54], [-1.77, 0.0], [-3.54, 3.54]], [[3.54, 3.54], [0.0, 1.77], [-3.54, 3.54]], [[3.54, 3.54], [0.0, 1.77], [-3.54, 3.54]]] - plane_list = ['XZ', 'XY', 'YZ', 'XZ', 'YZ', 'XY'] - offset_list = [-3.54, 3.54, 3.54, 3.54, -3.54, -3.54] - edge_wire = cq.Workplane(plane_list[0]).workplane(offset=-offset_list[0]).spline(edge_points[0]) - for i in range(len(edge_points)-1): - edge_wire = edge_wire.add(cq.Workplane(plane_list[i+1]).workplane(offset=-offset_list[i+1]).spline(edge_points[i+1])) - edge_wire = [o.vals()[0] for o in edge_wire.all()] - edge_wire = cq.Wire.assembleEdges(edge_wire) - - return edge_wire - -