def execute(self, context): A = context.active_object polygon = new_polygon(sides=self.sides_number, length=self.sides_length, hide=True) add_abs_bevel(polygon, self.bevel_depth) polygon.parent = A polygon.rotation_euler[2] = math.radians(self.polygon_rotate) vertices = [] for i in range(int(self.sides_number)): s = new_point(radius=self.sphere_radius) position_on_curve(s, polygon, position=i / self.sides_number) add_driver(obj=s, prop='location', fields='Z', expr="0") vertices.append(s) for i in range(int(self.sides_number) - 1): line = new_line() segment(line, vertices[i], vertices[i + 1]) add_abs_bevel(line, self.bevel_depth) line.name = "Side of polygon" line = new_line() segment(line, vertices[0], vertices[int(self.sides_number) - 1]) add_abs_bevel(line, self.bevel_depth) line.name = "Side of polygon" return {'FINISHED'}
def execute(self, context): if (len(context.selected_objects) == 3): A = context.active_object others = context.selected_objects[-3:] others.remove(A) (B, C) = others line = new_line(hide=self.hide_extra) segment(line, B, C) obj = new_line(length=self.length) add_abs_bevel(obj, self.bevel_depth) parallel_line(obj, A, line, hide_extra=self.hide_extra) if (len(context.selected_objects) == 2): A = context.active_object others = context.selected_objects[-2:] others.remove(A) line = others[0] obj = new_line(length=self.length) add_abs_bevel(obj, self.bevel_depth) parallel_line(obj, A, line, hide_extra=self.hide_extra) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-2:] others.remove(A) B = others[0] arc_neo = new_arc(angle=360, sides=64, hide=self.hide_arc) copy_location(arc_neo, A) copy_rotation(arc_neo, A) locked_track(arc_neo, 'Z', 'X', B) for i in range(3): arc_neo.scale[i] = self.radius add_abs_bevel(arc_neo, self.bevel_depth) if not self.other_angle: arc_neo.data.bevel_factor_start = 0 arc_neo.data.bevel_factor_end = self.arc_angle / 360 end1 = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius, hide=self.hide_endpoints) end1.name = "Arc endpoint" end2 = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius, hide=self.hide_endpoints) end2.name = "Arc endpoint" position_on_curve(end1, arc_neo, position=0) position_on_curve(end2, arc_neo, position=self.arc_angle / 360) if self.display_sides: side1 = new_line() add_abs_bevel(side1, self.bevel_depth) side2 = new_line() add_abs_bevel(side2, self.bevel_depth) ray(side1, A, end1) ray(side2, A, end2) else: arc_neo.data.bevel_factor_start = self.arc_angle / 360 arc_neo.data.bevel_factor_end = 1 end1 = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius, hide=self.hide_endpoints) end1.name = "Arc endpoint" end2 = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius, hide=self.hide_endpoints) end2.name = "Arc endpoint" position_on_curve(end1, arc_neo, position=self.arc_angle / 360) position_on_curve(end2, arc_neo, position=1) if self.display_sides: side1 = new_line() add_abs_bevel(side1, self.bevel_depth) side2 = new_line() add_abs_bevel(side2, self.bevel_depth) ray(side1, A, end1) ray(side2, A, end2) return {'FINISHED'}
def execute(self, context): (A, B, C) = context.selected_objects[-3:] lines = [new_line(), new_line(), new_line()] segment(lines[0], A, B) segment(lines[1], B, C) segment(lines[2], C, A) for idx, line in enumerate(lines): line.name = f"Side {idx + 1}" add_abs_bevel(line, self.bevel_depth) return {'FINISHED'}
def execute(self, context): (A, B) = context.selected_objects[-2:] newline = new_line() line(newline, A, B, length=self.length) add_abs_bevel(newline, self.bevel_depth) newline.name = "Line" return {'FINISHED'}
def execute(self, context): (A, B) = context.selected_objects[-2:] line = new_line() segment(line, A, B) add_abs_bevel(line, self.bevel_depth) line.name = "Line Segment" return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-2:] others.remove(A) B = others[0] point1 = new_point() point2 = new_point() circle_tangent_points(point1, point2, B, A) line1 = new_line() add_abs_bevel(line1, self.bevel_depth) line2 = new_line() add_abs_bevel(line2, self.bevel_depth) circle_tangent_lines(line1, line2, B, A, hide_extra=self.hide_extra) return {'FINISHED'}
def execute(self, context): if (len(context.selected_objects) == 2): (B, C) = context.selected_objects[-2:] obj = new_line(length=self.length) add_abs_bevel(obj, self.bevel_depth) bisecting_line_of_points(obj, B, C, hide_extra=self.hide_extra) if (len(context.selected_objects) == 1): A = context.active_object obj = new_line(length=self.length) add_abs_bevel(obj, self.bevel_depth) bisecting_line_of_line(obj, A, hide_extra=self.hide_extra) return {'FINISHED'}
def execute(self, context): (A, B, C) = context.selected_objects[-3:] line1 = new_line(length=self.length) add_abs_bevel(line1, self.bevel_depth) euler_line(line1, A, B, C) return {'FINISHED'}
def execute(self, context): (A, B) = context.selected_objects[-2:] point_r = new_point(hide=True) radical_intercept(point_r, A, B) line1 = new_line(length=self.length) add_abs_bevel(line1, self.bevel_depth) radical_axis(line1, A, B) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-3:] others.remove(A) (B, C) = others med = new_line(length=self.length) add_abs_bevel(med, self.bevel_depth) external_bisector(med, A, B, C) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-2:] others.remove(A) B = others[0] line1 = new_line(length=self.length) add_abs_bevel(line1, self.bevel_depth) polar_line(line1, A, B, hide_extra=self.hide_extra) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-2:] others.remove(A) B = others[0] inv_line = new_line(length=self.length) add_abs_bevel(inv_line, self.bevel_depth) inversion_on_cicle(inv_line, A, B) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-2:] others.remove(A) B = others[0] line1 = new_line(length=self.length) add_abs_bevel(line1, self.bevel_depth) circle_tangent_line(line1, B, A) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-2:] others.remove(A) B = others[0] line = new_line() ray(line, A, B, length=self.length) add_abs_bevel(line, self.bevel_depth) line.name = "Ray" return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-3:] others.remove(A) (B, C) = others footp = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius, hide=self.hide_foot) alt = new_line() add_abs_bevel(alt, self.bevel_depth) altitude(alt, footp, A, B, C) return {'FINISHED'}
def execute(self, context): if (len(context.selected_objects) == 3): A = context.active_object others = context.selected_objects[-3:] others.remove(A) (B, C) = others obj = new_line(length=self.length) add_abs_bevel(obj, self.bevel_depth) orthogonal_line_to_points(obj, A, B, C, hide_extra=self.hide_extra) if (len(context.selected_objects) == 2): A = context.active_object others = context.selected_objects[-2:] others.remove(A) B = others[0] obj = new_line(length=self.length) add_abs_bevel(obj, self.bevel_depth) orthogonal_line_to_line(obj, A, B, hide_extra=self.hide_extra) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-3:] others.remove(A) (B, C) = others midp = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius, hide=self.hide_foot) med = new_line() add_abs_bevel(med, self.bevel_depth) angle_bisector(med, midp, A, B, C) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-3:] others.remove(A) (B, C) = others point1 = new_point(hide=True) angle_divider_foot(point1, A, B, C, influ=self.division_proportion) line1 = new_line() add_abs_bevel(line1, self.bevel_depth) if self.use_ray: ray(line1, A, point1) else: line(line1, A, point1) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-2:] others.remove(A) B = others[0] e_new = new_empty(hide=True) e_new.location[0] = self.bevel_depth e_new.location[1] = self.cone_length e_new.location[2] = self.cone_radius line = new_line() segment(line, B, A) add_abs_bevel(line, self.bevel_depth) line.name = "Vector" add_driver(obj=line.data, prop='bevel_factor_end', vars_def={ 'd': ('distance', A, B), 'b1': ('transform', B, 'location', '-'), 'a1': ('transform', A, 'location', '-'), 'bev': ('transform', e_new, 'location', 'X'), 'dep': ('transform', e_new, 'location', 'Y'), 'r1': ('transform', e_new, 'location', 'Z'), }, expr="1 - dep/d") cone = new_cone(radius1=self.cone_radius, depth=self.cone_length) bpy.ops.object.mode_set(mode='EDIT') cone.location.z -= self.cone_length / 2 bpy.ops.object.mode_set(mode='OBJECT') copy_location(cone, A) damped_track(cone, axis='-X', target=B) A.hide_viewport = self.hide_endpoint return {'FINISHED'}
def execute(self, context): _A, _B = context.selected_objects[-2:] A = objects.new_plane(hide=self.hide_extra) constraints.copy_transforms(A, _A, transforms='LR') B = objects.new_plane(hide=self.hide_extra) constraints.copy_transforms(B, _B, transforms='LR') # A point on the normal of Plane A A_norm = objects.new_empty(hide=self.hide_extra) A_norm.name = "A Norm" objects.uniform_scale(A_norm, 0.1) objects.set_parent(A_norm, A, keep_inverse=False) A_norm.location[2] = 1.0 # Empty located a A, but in the same orientation as B B_rot_at_A = objects.new_empty(hide=self.hide_extra) B_rot_at_A.name = "B_rot_at_A" constraints.copy_location(B_rot_at_A, A) constraints.copy_rotation(B_rot_at_A, B) # (B_norm_at_a - A) gives the normal direction of B B_norm_at_a = objects.new_empty(hide=self.hide_extra) B_norm_at_a.name = "B_norm_at_a" objects.set_parent(B_norm_at_a, B_rot_at_A, keep_inverse=False) B_norm_at_a.location[2] = 1.0 intersection_line = objects.new_line(axis='Z', length=self.length) objects.move_origin_center(intersection_line) objects.add_abs_bevel(intersection_line, self.bevel_depth) geometry.align_to_plane_of(intersection_line, A, A_norm, B_norm_at_a) constraints.project_along_axis(intersection_line, 'Y', B, opposite=True) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-2:] others.remove(A) B = others[0] e_help = new_empty(hide=self.hide_extra) e_help.name = "Object defining drivers" e_help.location[0] = self.ratio if not (isinstance(A.data, bpy.types.Curve)): new = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius) new.name = "Homothetic object" # Can try to duplicate instead and then clear all constraints if 'Line' in A.data.name: new = new_line() new.name = "Homothetic object" add_abs_bevel(new, self.bevel_depth) if 'Circle' in A.data.name: new = new_circle() new.name = "Homothetic object" add_abs_bevel(new, self.bevel_depth) copy_rotation(new, A) add_driver(obj=new, prop='location', fields='XYZ', vars_def={ 'x1': ('transform', e_help, 'location', 'X'), 'b1': ('transform', B, 'location', '-'), 'a1': ('transform', A, 'location', '-'), }, expr="b1 + x1*(a1-b1)") if 'Circle' in A.data.name: add_driver(obj=new, prop='scale', fields='XYZ', vars_def={ 'x1': ('transform', e_help, 'location', 'X'), 's1': ('transform', A, 'scale', 'X'), }, expr="x1*s1") if self.display_center: center = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius) copy_location(center, new) copy_rotation(center, new) if 'Line' in A.data.name: add_driver(obj=new, prop='scale', fields='XYZ', vars_def={ 'x1': ('transform', e_help, 'location', 'X'), 's1': ('transform', A, 'scale', 'X'), }, expr="x1*s1") end1 = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius) end2 = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius) line_ends(end1, end2, new) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-3:] others.remove(A) (B_test, arc_old_test) = others if 'Arc' in B_test.data.name: arc_old = B_test B = arc_old_test if 'Arc' in arc_old_test.data.name: arc_old = arc_old_test B = B_test empty1 = new_point(hide=True) empty1.parent = arc_old empty1.location[1] = -1 fl_arc_old = new_point(hide=True) copy_location(fl_arc_old, arc_old) locked_track(fl_arc_old, 'X', 'Y', empty1) arc_neo = new_arc(angle=360, sides=64, hide=self.hide_arc) uniform_scale(arc_neo, self.radius) add_abs_bevel(arc_neo, self.bevel_depth) copy_location(arc_neo, A) if self.other_side: copy_rotation(arc_neo, fl_arc_old) else: copy_rotation(arc_neo, arc_old) locked_track(arc_neo, 'Z', 'X', B) add_driver( obj=arc_neo.data, prop='bevel_factor_start', vars_def={ 'bev': ('datapath', arc_old, 'data.bevel_factor_start'), }, expr='bev' ) add_driver( obj=arc_neo.data, prop='bevel_factor_end', vars_def={ 'bev': ('datapath', arc_old, 'data.bevel_factor_end'), }, expr='bev' ) end1 = new_point(radius=self.sphere_radius, hide=self.hide_endpoints) end1.name = "Arc endpoint" end2 = new_point(radius=self.sphere_radius, hide=self.hide_endpoints) end2.name = "Arc endpoint" position_on_curve(end1, arc_neo, position=0) position_on_curve(end2, arc_neo, position=1) add_driver( obj=end1.constraints[-1], prop='offset_factor', vars_def={ 'bev': ("datapath", arc_neo, "data.bevel_factor_start"), }, expr="bev" ) add_driver( obj=end2.constraints[-1], prop='offset_factor', vars_def={ 'bev': ("datapath", arc_neo, "data.bevel_factor_end"), }, expr="bev" ) if self.display_sides: side1 = new_line() add_abs_bevel(side1, self.bevel_depth) side2 = new_line() add_abs_bevel(side2, self.bevel_depth) ray(side1, A, end1) ray(side2, A, end2) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-4:] others.remove(A) (O_test, L_test, R_test) = others if 'Sphere' in O_test.data.name: O = O_test if 'Sphere' in L_test.data.name: O = L_test if 'Sphere' in R_test.data.name: O = R_test others.remove(O) (L_test, R_test) = others if 'Line' in L_test.data.name: L = L_test R = R_test if 'Line' in R_test.data.name: L = R_test R = L_test # A: object to transform, O: origin, L: line, R: circle if not (isinstance(A.data, bpy.types.Curve)): new = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius) new.name = "Homothetic object" if 'Line' in A.data.name: new = new_line() new.name = "Homothetic object" add_abs_bevel(new, self.bevel_depth) if 'Circle' in A.data.name: new = new_circle() new.name = "Homothetic object" add_abs_bevel(new, self.bevel_depth) copy_rotation(new, A) add_driver(obj=new, prop='location', fields='XYZ', vars_def={ 's': ('transform', L, 'scale', 'X'), 'r': ('transform', R, 'scale', 'X'), 'b1': ('transform', O, 'location', '-'), 'a1': ('transform', A, 'location', '-'), }, expr="b1 + (s/r)*(a1-b1)") if 'Circle' in A.data.name: add_driver(obj=new, prop='scale', fields='XYZ', vars_def={ 's': ('transform', L, 'scale', 'X'), 'r': ('transform', R, 'scale', 'X'), 's1': ('transform', A, 'scale', 'X'), }, expr="(s/r)*s1") if self.display_center: center = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius) copy_location(center, new) copy_rotation(center, new) if 'Line' in A.data.name: add_driver(obj=new, prop='scale', fields='XYZ', vars_def={ 's': ('transform', L, 'scale', 'X'), 'r': ('transform', R, 'scale', 'X'), 's1': ('transform', A, 'scale', 'X'), }, expr="(s/r)*s1") end1 = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius) end2 = new_point(use_spheres=self.use_spheres, radius=self.sphere_radius) line_ends(end1, end2, new) return {'FINISHED'}
def execute(self, context): A = context.active_object others = context.selected_objects[-3:] others.remove(A) B, C = others arc = new_arc(angle=360, sides=64, hide=self.hide_arc) if self.display_sides: side1 = new_line() add_abs_bevel(side1, self.bevel_depth) side2 = new_line() add_abs_bevel(side2, self.bevel_depth) ray(side1, A, B) ray(side2, A, C) uniform_scale(arc, self.radius) add_abs_bevel(arc, self.bevel_depth) align_to_plane_of(arc, A, B, C) if self.other_angle: B, C = C, B add_driver( obj=arc.data, prop='bevel_factor_start', vars_def={ 'ax': ('transform', A, 'location', 'X'), 'ay': ('transform', A, 'location', 'Y'), 'az': ('transform', A, 'location', 'Z'), 'bx': ('transform', B, 'location', 'X'), 'by': ('transform', B, 'location', 'Y'), 'bz': ('transform', B, 'location', 'Z'), 'cx': ('transform', C, 'location', 'X'), 'cy': ('transform', C, 'location', 'Y'), 'cz': ('transform', C, 'location', 'Z'), }, expr='gb_drive_angle_bevel(True,ax,ay,az,bx,by,bz,cx,cy,cz)') add_driver( obj=arc.data, prop='bevel_factor_end', vars_def={ 'ax': ('transform', A, 'location', 'X'), 'ay': ('transform', A, 'location', 'Y'), 'az': ('transform', A, 'location', 'Z'), 'bx': ('transform', B, 'location', 'X'), 'by': ('transform', B, 'location', 'Y'), 'bz': ('transform', B, 'location', 'Z'), 'cx': ('transform', C, 'location', 'X'), 'cy': ('transform', C, 'location', 'Y'), 'cz': ('transform', C, 'location', 'Z'), }, expr='gb_drive_angle_bevel(False,ax,ay,az,bx,by,bz,cx,cy,cz)') end1 = new_point(radius=self.sphere_radius, hide=self.hide_endpoints) end1.name = "Arc endpoint" end2 = new_point(radius=self.sphere_radius, hide=self.hide_endpoints) end2.name = "Arc endpoint" position_on_curve(end1, arc, position=0) position_on_curve(end2, arc, position=1) add_driver(obj=end1.constraints[-1], prop='offset_factor', vars_def={ 'bev': ("datapath", arc, "data.bevel_factor_start"), }, expr="bev") add_driver(obj=end2.constraints[-1], prop='offset_factor', vars_def={ 'bev': ("datapath", arc, "data.bevel_factor_end"), }, expr="bev") return {'FINISHED'}