# add_mesh_gear.py (c) 2009, 2010 Michel J. Anders (varkenvarken) # # ***** BEGIN GPL LICENSE BLOCK ***** # # # This program is free software; you can redistribute it and/or # modify it under the terms of the GNU General Public License # as published by the Free Software Foundation; either version 2 # of the License, or (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program; if not, write to the Free Software Foundation, # Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. # # ***** END GPL LICENCE BLOCK ***** bl_addon_info = { "name": "Gears", "author": "Michel J. Anders (varkenvarken)", "version": (2,4,1), "blender": (2, 5, 3), "api": 31965, "location": "View3D > Add > Mesh > Gears ", "description": "Adds a mesh Gear to the Add Mesh menu", "warning": "", "wiki_url": "http://wiki.blender.org/index.php/Extensions:2.5/Py/"\ "Scripts/Add_Mesh/Add_Gear", "tracker_url": "https://projects.blender.org/tracker/index.php?"\ "func=detail&aid=21732&group_id=153&atid=469", "category": "Add Mesh"} """ What was needed to port it from 2.49 -> 2.50 alpha 0? The basic functions that calculate the geometry (verts and faces) are mostly unchanged (add_tooth, add_spoke, add_gear) Also, the vertex group API is changed a little bit but the concepts are the same: ========= vertexgroup = ob.vertex_groups.new('NAME_OF_VERTEXGROUP') ob.vertex_groups.assign(vertexgroup_vertex_indices, vertexgroup, weight, 'ADD') ========= Now for some reason the name does not 'stick' and we have to set it this way: vertexgroup.name = 'NAME_OF_VERTEXGROUP' Conversion to 2.50 also meant we could simply do away with our crude user interface. Just definining the appropriate properties in the AddGear() operator will display the properties in the Blender GUI with the added benefit of making it interactive: changing a property will redo the AddGear() operator providing the user with instant feedback. Finally we had to convert/throw away some print statements to print functions as Blender nows uses Python 3.x The code to actually implement the AddGear() function is mostly copied from add_mesh_torus() (distributed with Blender). """ import bpy import mathutils from math import * from bpy.props import * # calculates the matrix for the new object # depending on user pref def align_matrix(context): loc = mathutils.Matrix.Translation(context.scene.cursor_location) obj_align = context.user_preferences.edit.object_align if (context.space_data.type == 'VIEW_3D' and obj_align == 'VIEW'): rot = context.space_data.region_3d.view_matrix.rotation_part().invert().resize4x4() else: rot = mathutils.Matrix() align_matrix = loc * rot return align_matrix # Create a new mesh (object) from verts/edges/faces. # verts/edges/faces ... List of vertices/edges/faces for the # new mesh (as used in from_pydata). # name ... Name of the new mesh (& object). # edit ... Replace existing mesh data. # Note: Using "edit" will destroy/delete existing mesh data. def create_mesh_object(context, verts, edges, faces, name, edit, align_matrix): scene = context.scene obj_act = scene.objects.active # Can't edit anything, unless we have an active obj. if edit and not obj_act: return None # Create new mesh mesh = bpy.data.meshes.new(name) # Make a mesh from a list of verts/edges/faces. mesh.from_pydata(verts, edges, faces) # Update mesh geometry after adding stuff. mesh.update() # Deselect all objects. bpy.ops.object.select_all(action='DESELECT') if edit: # Replace geometry of existing object # Use the active obj and select it. ob_new = obj_act ob_new.select = True if obj_act.mode == 'OBJECT': # Get existing mesh datablock. old_mesh = ob_new.data # Set object data to nothing ob_new.data = None # Clear users of existing mesh datablock. old_mesh.user_clear() # Remove old mesh datablock if no users are left. if (old_mesh.users == 0): bpy.data.meshes.remove(old_mesh) # Assign new mesh datablock. ob_new.data = mesh else: # Create new object ob_new = bpy.data.objects.new(name, mesh) # Link new object to the given scene and select it. scene.objects.link(ob_new) ob_new.select = True # Place the object at the 3D cursor location. # apply viewRotaion ob_new.matrix_world = align_matrix if obj_act and obj_act.mode == 'EDIT': if not edit: # We are in EditMode, switch to ObjectMode. bpy.ops.object.mode_set(mode='OBJECT') # Select the active object as well. obj_act.select = True # Apply location of new object. scene.update() # Join new object into the active. bpy.ops.object.join() # Switching back to EditMode. bpy.ops.object.mode_set(mode='EDIT') ob_new = obj_act else: # We are in ObjectMode. # Make the new object the active one. scene.objects.active = ob_new return ob_new # A very simple "bridge" tool. # Connects two equally long vertex rows with faces. # Returns a list of the new faces (list of lists) # # vertIdx1 ... First vertex list (list of vertex indices). # vertIdx2 ... Second vertex list (list of vertex indices). # closed ... Creates a loop (first & last are closed). # flipped ... Invert the normal of the face(s). # # Note: You can set vertIdx1 to a single vertex index to create # a fan/star of faces. # Note: If both vertex idx list are the same length they have # to have at least 2 vertices. def createFaces(vertIdx1, vertIdx2, closed=False, flipped=False): faces = [] if not vertIdx1 or not vertIdx2: return None if len(vertIdx1) < 2 and len(vertIdx2) < 2: return None fan = False if (len(vertIdx1) != len(vertIdx2)): if (len(vertIdx1) == 1 and len(vertIdx2) > 1): fan = True else: return None total = len(vertIdx2) if closed: # Bridge the start with the end. if flipped: face = [ vertIdx1[0], vertIdx2[0], vertIdx2[total - 1]] if not fan: face.append(vertIdx1[total - 1]) faces.append(face) else: face = [vertIdx2[0], vertIdx1[0]] if not fan: face.append(vertIdx1[total - 1]) face.append(vertIdx2[total - 1]) faces.append(face) # Bridge the rest of the faces. for num in range(total - 1): if flipped: if fan: face = [vertIdx2[num], vertIdx1[0], vertIdx2[num + 1]] else: face = [vertIdx2[num], vertIdx1[num], vertIdx1[num + 1], vertIdx2[num + 1]] faces.append(face) else: if fan: face = [vertIdx1[0], vertIdx2[num], vertIdx2[num + 1]] else: face = [vertIdx1[num], vertIdx2[num], vertIdx2[num + 1], vertIdx1[num + 1]] faces.append(face) return faces # Calculate the vertex coordinates for a single # section of a gear tooth. # Returns 4 lists of vertex coords (list of tuples): # *-*---*---* (1.) verts_inner_base # | | | | # *-*---*---* (2.) verts_outer_base # | | | # *---*---* (3.) verts_middle_tooth # \ | / # *-*-* (4.) verts_tip_tooth # # a # t # d # radius # Ad # De # base # p_angle # rack # crown def add_tooth(a, t, d, radius, Ad, De, base, p_angle, rack=0, crown=0.0): A = [a, a + t / 4, a + t / 2, a + 3 * t / 4] C = [cos(i) for i in A] S = [sin(i) for i in A] Ra = radius + Ad Rd = radius - De Rb = Rd - base # Pressure angle calc O = Ad * tan(p_angle) p_angle = atan(O / Ra) if radius < 0: p_angle = -p_angle if rack: S = [sin(t / 4) * I for I in range(-2, 3)] Sp = [0, sin(-t / 4 + p_angle), 0, sin(t / 4 - p_angle)] verts_inner_base = [(Rb, radius * S[I], d) for I in range(4)] verts_outer_base = [(Rd, radius * S[I], d) for I in range(4)] verts_middle_tooth = [(radius, radius * S[I], d) for I in range(1, 4)] verts_tip_tooth = [(Ra, radius * Sp[I], d) for I in range(1, 4)] else: Cp = [ 0, cos(a + t / 4 + p_angle), cos(a + t / 2), cos(a + 3 * t / 4 - p_angle)] Sp = [0, sin(a + t / 4 + p_angle), sin(a + t / 2), sin(a + 3 * t / 4 - p_angle)] verts_inner_base = [(Rb * C[I], Rb * S[I], d) for I in range(4)] verts_outer_base = [(Rd * C[I], Rd * S[I], d) for I in range(4)] verts_middle_tooth = [(radius * C[I], radius * S[I], d + crown / 3) for I in range(1, 4)] verts_tip_tooth = [(Ra * Cp[I], Ra * Sp[I], d + crown) for I in range(1, 4)] return (verts_inner_base, verts_outer_base, verts_middle_tooth, verts_tip_tooth) # EXPERIMENTAL Calculate the vertex coordinates for a single # section of a gearspoke. # Returns them as a list of tuples. # # a # t # d # radius # De # base # s # w # l # gap # width # # @todo Finish this. def add_spoke(a, t, d, radius, De, base, s, w, l, gap=0, width=19): Rd = radius - De Rb = Rd - base Rl = Rb verts = [] edgefaces = [] edgefaces2 = [] sf = [] if not gap: for N in range(width, 1, -2): edgefaces.append(len(verts)) ts = t / 4 tm = a + 2 * ts te = asin(w / Rb) td = te - ts t4 = ts + td * (width - N) / (width - 3.0) A = [tm + (i - int(N / 2)) * t4 for i in range(N)] C = [cos(i) for i in A] S = [sin(i) for i in A] verts.extend((Rb * I, Rb * J, d) for (I, J) in zip(C, S)) edgefaces2.append(len(verts) - 1) Rb = Rb - s n = 0 for N in range(width, 3, -2): sf.extend([(i + n, i + 1 + n, i + 2 + n, i + N + n) for i in range(0, N - 1, 2)]) sf.extend([(i + 2 + n, i + N + n, i + N + 1 + n, i + N + 2 + n) for i in range(0, N - 3, 2)]) n = n + N return verts, edgefaces, edgefaces2, sf # Create gear geometry. # Returns: # * A list of vertices (list of tuples) # * A list of faces (list of lists) # * A list (group) of vertices of the tip (list of vertex indices). # * A list (group) of vertices of the valley (list of vertex indices). # # teethNum ... Number of teeth on the gear. # radius ... Radius of the gear, negative for crown gear # Ad ... Addendum, extent of tooth above radius. # De ... Dedendum, extent of tooth below radius. # base ... Base, extent of gear below radius. # p_angle ... Pressure angle. Skewness of tooth tip. (radiant) # width ... Width, thickness of gear. # skew ... Skew of teeth. (radiant) # conangle ... Conical angle of gear. (radiant) # rack # crown ... Inward pointing extend of crown teeth. # # inner radius = radius - (De + base) def add_gear(teethNum, radius, Ad, De, base, p_angle, width=1, skew=0, conangle=0, rack=0, crown=0.0): if teethNum < 2: return None, None, None, None t = 2 * pi / teethNum if rack: teethNum = 1 scale = (radius - 2 * width * tan(conangle)) / radius verts = [] faces = [] vgroup_top = [] # Vertex group of top/tip? vertices. vgroup_valley = [] # Vertex group of valley vertices verts_bridge_prev = [] for toothCnt in range(teethNum): a = toothCnt * t verts_bridge_start = [] verts_bridge_end = [] verts_outside_top = [] verts_outside_bottom = [] for (s, d, c, top) \ in [(0, -width, 1, True), \ (skew, width, scale, False)]: verts1, verts2, verts3, verts4 = add_tooth(a + s, t, d, radius * c, Ad * c, De * c, base * c, p_angle, rack, crown) vertsIdx1 = list(range(len(verts), len(verts) + len(verts1))) verts.extend(verts1) vertsIdx2 = list(range(len(verts), len(verts) + len(verts2))) verts.extend(verts2) vertsIdx3 = list(range(len(verts), len(verts) + len(verts3))) verts.extend(verts3) vertsIdx4 = list(range(len(verts), len(verts) + len(verts4))) verts.extend(verts4) verts_outside = [] verts_outside.extend(vertsIdx2[:2]) verts_outside.append(vertsIdx3[0]) verts_outside.extend(vertsIdx4) verts_outside.append(vertsIdx3[-1]) verts_outside.append(vertsIdx2[-1]) if top: #verts_inside_top = vertsIdx1 verts_outside_top = verts_outside verts_bridge_start.append(vertsIdx1[0]) verts_bridge_start.append(vertsIdx2[0]) verts_bridge_end.append(vertsIdx1[-1]) verts_bridge_end.append(vertsIdx2[-1]) else: #verts_inside_bottom = vertsIdx1 verts_outside_bottom = verts_outside verts_bridge_start.append(vertsIdx2[0]) verts_bridge_start.append(vertsIdx1[0]) verts_bridge_end.append(vertsIdx2[-1]) verts_bridge_end.append(vertsIdx1[-1]) # Valley = first 2 vertices of outer base: vgroup_valley.extend(vertsIdx2[:1]) # Top/tip vertices: vgroup_top.extend(vertsIdx4) faces_tooth_middle_top = createFaces(vertsIdx2[1:], vertsIdx3, flipped=top) faces_tooth_outer_top = createFaces(vertsIdx3, vertsIdx4, flipped=top) faces_base_top = createFaces(vertsIdx1, vertsIdx2, flipped=top) faces.extend(faces_base_top) faces.extend(faces_tooth_middle_top) faces.extend(faces_tooth_outer_top) #faces_inside = createFaces(verts_inside_top, verts_inside_bottom) #faces.extend(faces_inside) faces_outside = createFaces(verts_outside_top, verts_outside_bottom, flipped=True) faces.extend(faces_outside) if toothCnt == 0: verts_bridge_first = verts_bridge_start # Bridge one tooth to the next if verts_bridge_prev: faces_bridge = createFaces(verts_bridge_prev, verts_bridge_start) #, closed=True (for "inside" faces) faces.extend(faces_bridge) # Remember "end" vertices for next tooth. verts_bridge_prev = verts_bridge_end # Bridge the first to the last tooth. faces_bridge_f_l = createFaces(verts_bridge_prev, verts_bridge_first) #, closed=True (for "inside" faces) faces.extend(faces_bridge_f_l) return verts, faces, vgroup_top, vgroup_valley # Create spokes geometry. # Returns: # * A list of vertices (list of tuples) # * A list of faces (list of lists) # # teethNum ... Number of teeth on the gear. # radius ... Radius of the gear, negative for crown gear # De ... Dedendum, extent of tooth below radius. # base ... Base, extent of gear below radius. # width ... Width, thickness of gear. # conangle ... Conical angle of gear. (radiant) # rack # spoke # spbevel # spwidth # splength # spresol # # @todo Finish this # @todo Create a function that takes a "Gear" and creates a # matching "Gear Spokes" object. def add_spokes(teethNum, radius, De, base, width=1, conangle=0, rack=0, spoke=3, spbevel=0.1, spwidth=0.2, splength=1.0, spresol=9): if teethNum < 2: return None, None, None, None if spoke < 2: return None, None, None, None t = 2 * pi / teethNum if rack: teethNum = 1 scale = (radius - 2 * width * tan(conangle)) / radius verts = [] faces = [] c = scale # debug fl = len(verts) for toothCnt in range(teethNum): a = toothCnt * t s = 0 # For test if toothCnt % spoke == 0: for d in (-width, width): sv, edgefaces, edgefaces2, sf = add_spoke(a + s, t, d, radius * c, De * c, base * c, spbevel, spwidth, splength, 0, spresol) verts.extend(sv) faces.extend([j + fl for j in i] for i in sf) fl += len(sv) d1 = fl - len(sv) d2 = fl - 2 * len(sv) faces.extend([(i + d2, j + d2, j + d1, i + d1) for (i, j) in zip(edgefaces[:-1], edgefaces[1:])]) faces.extend([(i + d2, j + d2, j + d1, i + d1) for (i, j) in zip(edgefaces2[:-1], edgefaces2[1:])]) else: for d in (-width, width): sv, edgefaces, edgefaces2, sf = add_spoke(a + s, t, d, radius * c, De * c, base * c, spbevel, spwidth, splength, 1, spresol) verts.extend(sv) fl += len(sv) d1 = fl - len(sv) d2 = fl - 2 * len(sv) faces.extend([[i + d2, i + 1 + d2, i + 1 + d1, i + d1] for (i) in range(0, 3)]) faces.extend([[i + d2, i + 1 + d2, i + 1 + d1, i + d1] for (i) in range(5, 8)]) return verts, faces # Create worm geometry. # Returns: # * A list of vertices # * A list of faces # * A list (group) of vertices of the tip # * A list (group) of vertices of the valley # # teethNum ... Number of teeth on the worm # radius ... Radius of the gear, negative for crown gear # Ad ... Addendum, extent of tooth above radius. # De ... Dedendum, extent of tooth below radius. # p_angle ... Pressure angle. Skewness of tooth tip. (radiant) # width ... Width, thickness of gear. # crown ... Inward pointing extend of crown teeth. # # @todo: Fix teethNum. Some numbers are not possible yet. # @todo: Create start & end geoemtry (closing faces) def add_worm(teethNum, rowNum, radius, Ad, De, p_angle, width=1, skew=radians(11.25), crown=0.0): worm = teethNum teethNum = 24 t = 2 * pi / teethNum verts = [] faces = [] vgroup_top = [] # Vertex group of top/tip? vertices. vgroup_valley = [] # Vertex group of valley vertices #width = width / 2.0 edgeloop_prev = [] for Row in range(rowNum): edgeloop = [] for toothCnt in range(teethNum): a = toothCnt * t s = Row * skew d = Row * width c = 1 isTooth = False if toothCnt % (teethNum / worm) != 0: # Flat verts1, verts2, verts3, verts4 = add_tooth(a + s, t, d, radius - De, 0.0, 0.0, 0, p_angle) # Ignore other verts than the "other base". verts1 = verts3 = verts4 = [] else: # Tooth isTooth = True verts1, verts2, verts3, verts4 = add_tooth(a + s, t, d, radius * c, Ad * c, De * c, 0 * c, p_angle, 0, crown) # Remove various unneeded verts (if we are "inside" the tooth) del(verts2[2]) # Central vertex in the base of the tooth. del(verts3[1]) # Central vertex in the middle of the tooth. vertsIdx2 = list(range(len(verts), len(verts) + len(verts2))) verts.extend(verts2) vertsIdx3 = list(range(len(verts), len(verts) + len(verts3))) verts.extend(verts3) vertsIdx4 = list(range(len(verts), len(verts) + len(verts4))) verts.extend(verts4) if isTooth: verts_current = [] verts_current.extend(vertsIdx2[:2]) verts_current.append(vertsIdx3[0]) verts_current.extend(vertsIdx4) verts_current.append(vertsIdx3[-1]) verts_current.append(vertsIdx2[-1]) # Valley = first 2 vertices of outer base: vgroup_valley.extend(vertsIdx2[:1]) # Top/tip vertices: vgroup_top.extend(vertsIdx4) else: # Flat verts_current = vertsIdx2 # Valley - all of them. vgroup_valley.extend(vertsIdx2) edgeloop.extend(verts_current) # Create faces between rings/rows. if edgeloop_prev: faces_row = createFaces(edgeloop, edgeloop_prev, closed=True) faces.extend(faces_row) # Remember last ring/row of vertices for next ring/row iteration. edgeloop_prev = edgeloop return verts, faces, vgroup_top, vgroup_valley class AddGear(bpy.types.Operator): '''Add a gear mesh.''' bl_idname = "mesh.primitive_gear" bl_label = "Add Gear" bl_options = {'REGISTER', 'UNDO'} # edit - Whether to add or update. edit = BoolProperty(name="", description="", default=False, options={'HIDDEN'}) number_of_teeth = IntProperty(name="Number of Teeth", description="Number of teeth on the gear", min=2, max=265, default=12) radius = FloatProperty(name="Radius", description="Radius of the gear, negative for crown gear", min=-100.0, max=100.0, default=1.0) addendum = FloatProperty(name="Addendum", description="Addendum, extent of tooth above radius", min=0.01, max=100.0, default=0.1) dedendum = FloatProperty(name="Dedendum", description="Dedendum, extent of tooth below radius", min=0.0, max=100.0, default=0.1) angle = FloatProperty(name="Pressure Angle", description="Pressure angle, skewness of tooth tip (degrees)", min=0.0, max=45.0, default=20.0) base = FloatProperty(name="Base", description="Base, extent of gear below radius", min=0.0, max=100.0, default=0.2) width = FloatProperty(name="Width", description="Width, thickness of gear", min=0.05, max=100.0, default=0.2) skew = FloatProperty(name="Skewness", description="Skew of teeth (degrees)", min=-90.0, max=90.0, default=0.0) conangle = FloatProperty(name="Conical angle", description="Conical angle of gear (degrees)", min=0.0, max=90.0, default=0.0) crown = FloatProperty(name="Crown", description="Inward pointing extend of crown teeth", min=0.0, max=100.0, default=0.0) align_matrix = mathutils.Matrix() def draw(self, context): layout = self.layout box = layout.box() box.prop(self, 'number_of_teeth') box = layout.box() box.prop(self, 'radius') box.prop(self, 'width') box.prop(self, 'base') box = layout.box() box.prop(self, 'dedendum') box.prop(self, 'addendum') box = layout.box() box.prop(self, 'angle') box.prop(self, 'skew') box.prop(self, 'conangle') box.prop(self, 'crown') def execute(self, context): verts, faces, verts_tip, verts_valley = add_gear( self.number_of_teeth, self.radius, self.addendum, self.dedendum, self.base, radians(self.angle), width=self.width, skew=radians(self.skew), conangle=radians(self.conangle), crown=self.crown) # Actually create the mesh object from this geometry data. obj = create_mesh_object(context, verts, [], faces, "Gear", self.edit, self.align_matrix) # Create vertex groups from stored vertices. tipGroup = obj.vertex_groups.new('Tips') obj.vertex_groups.assign(verts_tip, tipGroup, 1.0, 'ADD') valleyGroup = obj.vertex_groups.new('Valleys') obj.vertex_groups.assign(verts_valley, valleyGroup, 1.0, 'ADD') return {'FINISHED'} def invoke(self, context, event): self.align_matrix = align_matrix(context) self.execute(context) return {'FINISHED'} class AddWormGear(bpy.types.Operator): '''Add a worm gear mesh.''' bl_idname = "mesh.primitive_worm_gear" bl_label = "Add Worm Gear" bl_options = {'REGISTER', 'UNDO'} # edit - Whether to add or update. edit = BoolProperty(name="", description="", default=False, options={'HIDDEN'}) number_of_teeth = IntProperty(name="Number of Teeth", description="Number of teeth on the gear", min=2, max=265, default=12) number_of_rows = IntProperty(name="Number of Rows", description="Number of rows on the worm gear", min=2, max=265, default=32) radius = FloatProperty(name="Radius", description="Radius of the gear, negative for crown gear", min=-100.0, max=100.0, default=1.0) addendum = FloatProperty(name="Addendum", description="Addendum, extent of tooth above radius", min=0.01, max=100.0, default=0.1) dedendum = FloatProperty(name="Dedendum", description="Dedendum, extent of tooth below radius", min=0.0, max=100.0, default=0.1) angle = FloatProperty(name="Pressure Angle", description="Pressure angle, skewness of tooth tip (degrees)", min=0.0, max=45.0, default=20.0) row_height = FloatProperty(name="Row Height", description="Height of each Row", min=0.05, max=100.0, default=0.2) skew = FloatProperty(name="Skewness per Row", description="Skew of each row (degrees)", min=-90.0, max=90.0, default=11.25) crown = FloatProperty(name="Crown", description="Inward pointing extend of crown teeth", min=0.0, max=100.0, default=0.0) align_matrix = mathutils.Matrix() def draw(self, context): layout = self.layout box = layout.box() box.prop(self, 'number_of_teeth') box.prop(self, 'number_of_rows') box.prop(self, 'radius') box.prop(self, 'row_height') box = layout.box() box.prop(self, 'addendum') box.prop(self, 'dedendum') box = layout.box() box.prop(self, 'angle') box.prop(self, 'skew') box.prop(self, 'crown') def execute(self, context): verts, faces, verts_tip, verts_valley = add_worm( self.number_of_teeth, self.number_of_rows, self.radius, self.addendum, self.dedendum, radians(self.angle), width=self.row_height, skew=radians(self.skew), crown=self.crown) # Actually create the mesh object from this geometry data. obj = create_mesh_object(context, verts, [], faces, "Worm Gear", self.edit, self.align_matrix) # Create vertex groups from stored vertices. tipGroup = obj.vertex_groups.new('Tips') obj.vertex_groups.assign(verts_tip, tipGroup, 1.0, 'ADD') valleyGroup = obj.vertex_groups.new('Valleys') obj.vertex_groups.assign(verts_valley, valleyGroup, 1.0, 'ADD') return {'FINISHED'} def invoke(self, context, event): self.align_matrix = align_matrix(context) self.execute(context) return {'FINISHED'} class INFO_MT_mesh_gears_add(bpy.types.Menu): # Define the "Gears" menu bl_idname = "INFO_MT_mesh_gears_add" bl_label = "Gears" def draw(self, context): layout = self.layout layout.operator_context = 'INVOKE_REGION_WIN' layout.operator("mesh.primitive_gear", text="Gear") layout.operator("mesh.primitive_worm_gear", text="Worm") # Define "Gears" menu def menu_func(self, context): self.layout.menu("INFO_MT_mesh_gears_add", icon="PLUGIN") def register(): # Add "Gears" entry to the "Add Mesh" menu. bpy.types.INFO_MT_mesh_add.append(menu_func) def unregister(): # Remove "Gears" entry from the "Add Mesh" menu. bpy.types.INFO_MT_mesh_add.remove(menu_func) if __name__ == "__main__": register()