import numpy as np from numpy import pi import os.path as path import getopt, sys import json import os import copy from scipy.spatial import ConvexHull as sphull def deg2rad(degrees: float) -> float: return degrees * pi / 180 def rad2deg(rad: float) -> float: return rad * 180 / pi ############################################### # EXTREMELY UGLY BUT FUNCTIONAL BOOTSTRAP ############################################### ## IMPORT DEFAULT CONFIG IN CASE NEW PARAMETERS EXIST import generate_configuration as cfg for item in cfg.shape_config: locals()[item] = cfg.shape_config[item] if len(sys.argv) <= 1: print("NO CONFIGURATION SPECIFIED, USING run_config.json") with open(os.path.join(r".", 'run_config.json'), mode='r') as fid: data = json.load(fid) else: ## CHECK FOR CONFIG FILE AND WRITE TO ANY VARIABLES IN FILE. opts, args = getopt.getopt(sys.argv[1:], "", ["config="]) for opt, arg in opts: if opt in ('--config'): with open(os.path.join(r"..", "configs", arg + '.json'), mode='r') as fid: data = json.load(fid) for item in data: locals()[item] = data[item] # Really rough setup. Check for ENGINE, set it not present from configuration. try: print('Found Current Engine in Config = {}'.format(ENGINE)) except Exception: print('Engine Not Found in Config') ENGINE = 'solid' # ENGINE = 'cadquery' print('Setting Current Engine = {}'.format(ENGINE)) if save_dir in ['', None, '.']: save_path = path.join(r"..", "things") parts_path = path.join(r"..", "src", "parts") else: save_path = path.join(r"..", "things", save_dir) parts_path = path.join(r"..", r"..", "src", "parts") ############################################### # END EXTREMELY UGLY BOOTSTRAP ############################################### #################################################### # HELPER FUNCTIONS TO MERGE CADQUERY AND OPENSCAD #################################################### if ENGINE == 'cadquery': from helpers_cadquery import * else: from helpers_solid import * #################################################### # END HELPER FUNCTIONS #################################################### debug_exports = False debug_trace = False def debugprint(info): if debug_trace: print(info) if oled_mount_type is not None and oled_mount_type != "NONE": for item in oled_configurations[oled_mount_type]: locals()[item] = oled_configurations[oled_mount_type][item] if nrows > 5: column_style = column_style_gt5 centerrow = nrows - centerrow_offset lastrow = nrows - 1 if reduced_outer_keys: cornerrow = lastrow - 1 else: cornerrow = lastrow lastcol = ncols - 1 # Derived values if plate_style in ['NUB', 'HS_NUB']: keyswitch_height = nub_keyswitch_height keyswitch_width = nub_keyswitch_width elif plate_style in ['UNDERCUT', 'HS_UNDERCUT', 'NOTCH', 'HS_NOTCH']: keyswitch_height = undercut_keyswitch_height keyswitch_width = undercut_keyswitch_width else: keyswitch_height = hole_keyswitch_height keyswitch_width = hole_keyswitch_width if 'HS_' in plate_style: symmetry = "asymmetric" plate_file = path.join(parts_path, r"hot_swap_plate") plate_offset = 0.0 if (trackball_in_wall or ('TRACKBALL' in thumb_style)) and not ball_side == 'both': symmetry = "asymmetric" mount_width = keyswitch_width + 2 * plate_rim mount_height = keyswitch_height + 2 * plate_rim mount_thickness = plate_thickness if default_1U_cluster and thumb_style=='DEFAULT': double_plate_height = (.7*sa_double_length - mount_height) / 3 elif thumb_style=='DEFAULT': double_plate_height = (.95*sa_double_length - mount_height) / 3 else: double_plate_height = (sa_double_length - mount_height) / 3 if oled_mount_type is not None and oled_mount_type != "NONE": left_wall_x_offset = oled_left_wall_x_offset_override left_wall_z_offset = oled_left_wall_z_offset_override left_wall_lower_y_offset = oled_left_wall_lower_y_offset left_wall_lower_z_offset = oled_left_wall_lower_z_offset cap_top_height = plate_thickness + sa_profile_key_height row_radius = ((mount_height + extra_height) / 2) / (np.sin(alpha / 2)) + cap_top_height column_radius = ( ((mount_width + extra_width) / 2) / (np.sin(beta / 2)) ) + cap_top_height column_x_delta = -1 - column_radius * np.sin(beta) column_base_angle = beta * (centercol - 2) teensy_width = 20 teensy_height = 12 teensy_length = 33 teensy2_length = 53 teensy_pcb_thickness = 2 teensy_offset_height = 5 teensy_holder_top_length = 18 teensy_holder_width = 7 + teensy_pcb_thickness teensy_holder_height = 6 + teensy_width # save_path = path.join("..", "things", save_dir) if not path.isdir(save_path): os.mkdir(save_path) def column_offset(column: int) -> list: return column_offsets[column] # column_style='fixed' def single_plate(cylinder_segments=100, side="right"): if plate_style in ['NUB', 'HS_NUB']: tb_border = (mount_height-keyswitch_height)/2 top_wall = box(mount_width, tb_border, plate_thickness) top_wall = translate(top_wall, (0, (tb_border / 2) + (keyswitch_height / 2), plate_thickness / 2)) lr_border = (mount_width - keyswitch_width) / 2 left_wall = box(lr_border, mount_height, plate_thickness) left_wall = translate(left_wall, ((lr_border / 2) + (keyswitch_width / 2), 0, plate_thickness / 2)) side_nub = cylinder(radius=1, height=2.75) side_nub = rotate(side_nub, (90, 0, 0)) side_nub = translate(side_nub, (keyswitch_width / 2, 0, 1)) nub_cube = box(1.5, 2.75, plate_thickness) nub_cube = translate(nub_cube, ((1.5 / 2) + (keyswitch_width / 2), 0, plate_thickness / 2)) side_nub2 = tess_hull(shapes=(side_nub, nub_cube)) side_nub2 = union([side_nub2, side_nub, nub_cube]) plate_half1 = union([top_wall, left_wall, side_nub2]) plate_half2 = plate_half1 plate_half2 = mirror(plate_half2, 'XZ') plate_half2 = mirror(plate_half2, 'YZ') plate = union([plate_half1, plate_half2]) else: # 'HOLE' or default, square cutout for non-nub designs. plate = box(mount_width, mount_height, mount_thickness) plate = translate(plate, (0.0, 0.0, mount_thickness / 2.0)) shape_cut = box(keyswitch_width, keyswitch_height, mount_thickness * 2 +.02) shape_cut = translate(shape_cut, (0.0, 0.0, mount_thickness-.01)) plate = difference(plate, [shape_cut]) if plate_style in ['UNDERCUT', 'HS_UNDERCUT', 'NOTCH', 'HS_NOTCH']: if plate_style in ['UNDERCUT', 'HS_UNDERCUT']: undercut = box( keyswitch_width + 2 * clip_undercut, keyswitch_height + 2 * clip_undercut, mount_thickness ) if plate_style in ['NOTCH', 'HS_NOTCH']: undercut = box( notch_width, keyswitch_height + 2 * clip_undercut, mount_thickness ) undercut = union([undercut, box( keyswitch_width + 2 * clip_undercut, notch_width, mount_thickness ) ]) undercut = translate(undercut, (0.0, 0.0, -clip_thickness + mount_thickness / 2.0)) if ENGINE=='cadquery' and undercut_transition > 0: undercut = undercut.faces("+Z").chamfer(undercut_transition, clip_undercut) plate = difference(plate, [undercut]) if plate_file is not None: socket = import_file(plate_file) socket = translate(socket, [0, 0, plate_thickness + plate_offset]) plate = union([plate, socket]) if plate_holes: half_width = plate_holes_width/2. half_height = plate_holes_height/2. x_off = plate_holes_xy_offset[0] y_off = plate_holes_xy_offset[1] holes = [ translate( cylinder(radius=plate_holes_diameter/2, height=plate_holes_depth+.01), (x_off+half_width, y_off+half_height, plate_holes_depth/2-.01) ), translate( cylinder(radius=plate_holes_diameter / 2, height=plate_holes_depth+.01), (x_off-half_width, y_off+half_height, plate_holes_depth/2-.01) ), translate( cylinder(radius=plate_holes_diameter / 2, height=plate_holes_depth+.01), (x_off-half_width, y_off-half_height, plate_holes_depth/2-.01) ), translate( cylinder(radius=plate_holes_diameter / 2, height=plate_holes_depth+.01), (x_off+half_width, y_off-half_height, plate_holes_depth/2-.01) ), ] plate = difference(plate, holes) if side == "left": plate = mirror(plate, 'YZ') return plate def plate_pcb_cutout(side="right"): shape = box(*plate_pcb_size) shape = translate(shape, (0, 0, -plate_pcb_size[2]/2)) shape = translate(shape, plate_pcb_offset) if side == "left": shape = mirror(shape, 'YZ') return shape def trackball_cutout(segments=100, side="right"): if trackball_modular: hole_diameter = ball_diameter + 2 * (ball_gap + ball_wall_thickness + trackball_modular_clearance+trackball_modular_lip_width)-.1 shape = cylinder(hole_diameter / 2, trackball_hole_height) else: shape = cylinder(trackball_hole_diameter / 2, trackball_hole_height) return shape def trackball_socket(segments=100, side="right"): if trackball_modular: hole_diameter = ball_diameter + 2 * (ball_gap + ball_wall_thickness + trackball_modular_clearance) ring_diameter = hole_diameter + 2 * trackball_modular_lip_width ring_height = trackball_modular_ring_height ring_z_offset = mount_thickness - trackball_modular_ball_height shape = cylinder(ring_diameter / 2, ring_height) shape = translate(shape, (0, 0, -ring_height / 2 + ring_z_offset)) cutter = cylinder(hole_diameter / 2, ring_height + .2) cutter = translate(cutter, (0, 0, -ring_height / 2 + ring_z_offset)) sensor = None else: tb_file = path.join(parts_path, r"trackball_socket_body_34mm") tbcut_file = path.join(parts_path, r"trackball_socket_cutter_34mm") sens_file = path.join(parts_path, r"trackball_sensor_mount") senscut_file = path.join(parts_path, r"trackball_sensor_cutter") shape = import_file(tb_file) sensor = import_file(sens_file) cutter = import_file(tbcut_file) cutter = union([cutter, import_file(senscut_file)]) # return shape, cutter return shape, cutter, sensor def trackball_ball(segments=100, side="right"): shape = sphere(ball_diameter / 2) return shape ################ ## SA Keycaps ## ################ def sa_cap(Usize=1): # MODIFIED TO NOT HAVE THE ROTATION. NEEDS ROTATION DURING ASSEMBLY # sa_length = 18.25 if Usize == 1: bl2 = 18.5/2 bw2 = 18.5/2 m = 17 / 2 pl2 = 6 pw2 = 6 elif Usize == 2: bl2 = sa_length bw2 = sa_length / 2 m = 0 pl2 = 16 pw2 = 6 elif Usize == 1.5: bl2 = sa_length / 2 bw2 = 27.94 / 2 m = 0 pl2 = 6 pw2 = 11 k1 = polyline([(bw2, bl2), (bw2, -bl2), (-bw2, -bl2), (-bw2, bl2), (bw2, bl2)]) k1 = extrude_poly(outer_poly=k1, height=0.1) k1 = translate(k1, (0, 0, 0.05)) k2 = polyline([(pw2, pl2), (pw2, -pl2), (-pw2, -pl2), (-pw2, pl2), (pw2, pl2)]) k2 = extrude_poly(outer_poly=k2, height=0.1) k2 = translate(k2, (0, 0, 12.0)) if m > 0: m1 = polyline([(m, m), (m, -m), (-m, -m), (-m, m), (m, m)]) m1 = extrude_poly(outer_poly=m1, height=0.1) m1 = translate(m1, (0, 0, 6.0)) key_cap = hull_from_shapes((k1, k2, m1)) else: key_cap = hull_from_shapes((k1, k2)) key_cap = translate(key_cap, (0, 0, 5 + plate_thickness)) if show_pcbs: key_cap = add([key_cap, key_pcb()]) return key_cap def key_pcb(): shape = box(pcb_width, pcb_height, pcb_thickness) shape = translate(shape, (0, 0, -pcb_thickness/2)) hole = cylinder(pcb_hole_diameter/2, pcb_thickness+.2) hole = translate(hole, (0, 0, -(pcb_thickness+.1)/2)) holes = [ translate(hole, (pcb_hole_pattern_width/2, pcb_hole_pattern_height/2, 0)), translate(hole, (-pcb_hole_pattern_width / 2, pcb_hole_pattern_height / 2, 0)), translate(hole, (-pcb_hole_pattern_width / 2, -pcb_hole_pattern_height / 2, 0)), translate(hole, (pcb_hole_pattern_width / 2, -pcb_hole_pattern_height / 2, 0)), ] shape = difference(shape, holes) return shape ######################### ## Placement Functions ## ######################### def rotate_around_x(position, angle): # debugprint('rotate_around_x()') t_matrix = np.array( [ [1, 0, 0], [0, np.cos(angle), -np.sin(angle)], [0, np.sin(angle), np.cos(angle)], ] ) return np.matmul(t_matrix, position) def rotate_around_y(position, angle): # debugprint('rotate_around_y()') t_matrix = np.array( [ [np.cos(angle), 0, np.sin(angle)], [0, 1, 0], [-np.sin(angle), 0, np.cos(angle)], ] ) return np.matmul(t_matrix, position) def apply_key_geometry( shape, translate_fn, rotate_x_fn, rotate_y_fn, column, row, column_style=column_style, ): debugprint('apply_key_geometry()') column_angle = beta * (centercol - column) if column_style == "orthographic": column_z_delta = column_radius * (1 - np.cos(column_angle)) shape = translate_fn(shape, [0, 0, -row_radius]) shape = rotate_x_fn(shape, alpha * (centerrow - row)) shape = translate_fn(shape, [0, 0, row_radius]) shape = rotate_y_fn(shape, column_angle) shape = translate_fn( shape, [-(column - centercol) * column_x_delta, 0, column_z_delta] ) shape = translate_fn(shape, column_offset(column)) elif column_style == "fixed": shape = rotate_y_fn(shape, fixed_angles[column]) shape = translate_fn(shape, [fixed_x[column], 0, fixed_z[column]]) shape = translate_fn(shape, [0, 0, -(row_radius + fixed_z[column])]) shape = rotate_x_fn(shape, alpha * (centerrow - row)) shape = translate_fn(shape, [0, 0, row_radius + fixed_z[column]]) shape = rotate_y_fn(shape, fixed_tenting) shape = translate_fn(shape, [0, column_offset(column)[1], 0]) else: shape = translate_fn(shape, [0, 0, -row_radius]) shape = rotate_x_fn(shape, alpha * (centerrow - row)) shape = translate_fn(shape, [0, 0, row_radius]) shape = translate_fn(shape, [0, 0, -column_radius]) shape = rotate_y_fn(shape, column_angle) shape = translate_fn(shape, [0, 0, column_radius]) shape = translate_fn(shape, column_offset(column)) shape = rotate_y_fn(shape, tenting_angle) shape = translate_fn(shape, [0, 0, keyboard_z_offset]) return shape def x_rot(shape, angle): # debugprint('x_rot()') return rotate(shape, [rad2deg(angle), 0, 0]) def y_rot(shape, angle): # debugprint('y_rot()') return rotate(shape, [0, rad2deg(angle), 0]) def key_place(shape, column, row): debugprint('key_place()') return apply_key_geometry(shape, translate, x_rot, y_rot, column, row) def add_translate(shape, xyz): debugprint('add_translate()') vals = [] for i in range(len(shape)): vals.append(shape[i] + xyz[i]) return vals def key_position(position, column, row): debugprint('key_position()') return apply_key_geometry( position, add_translate, rotate_around_x, rotate_around_y, column, row ) def key_holes(side="right"): debugprint('key_holes()') # hole = single_plate() holes = [] for column in range(ncols): for row in range(nrows): if (column in [2, 3]) or (not row == lastrow) or (not reduced_outer_keys): holes.append(key_place(single_plate(side=side), column, row)) shape = union(holes) return shape def plate_pcb_cutouts(side="right"): debugprint('plate_pcb_cutouts()') # hole = single_plate() cutouts = [] for column in range(ncols): for row in range(nrows): if (column in [2, 3]) or (not row == lastrow): cutouts.append(key_place(plate_pcb_cutout(side=side), column, row)) # cutouts = union(cutouts) return cutouts def caps(): caps = None for column in range(ncols): for row in range(nrows): if (column in [2, 3]) or (not row == lastrow): if caps is None: caps = key_place(sa_cap(), column, row) else: caps = add([caps, key_place(sa_cap(), column, row)]) return caps #################### ## Web Connectors ## #################### def web_post(): debugprint('web_post()') post = box(post_size, post_size, web_thickness) post = translate(post, (0, 0, plate_thickness - (web_thickness / 2))) return post def web_post_tr(wide=False): if wide: w_divide = 1.2 else: w_divide = 2.0 return translate(web_post(), ((mount_width / w_divide) - post_adj, (mount_height / 2) - post_adj, 0)) def web_post_tl(wide=False): if wide: w_divide = 1.2 else: w_divide = 2.0 return translate(web_post(), (-(mount_width / w_divide) + post_adj, (mount_height / 2) - post_adj, 0)) def web_post_bl(wide=False): if wide: w_divide = 1.2 else: w_divide = 2.0 return translate(web_post(), (-(mount_width / w_divide) + post_adj, -(mount_height / 2) + post_adj, 0)) def web_post_br(wide=False): if wide: w_divide = 1.2 else: w_divide = 2.0 return translate(web_post(), ((mount_width / w_divide) - post_adj, -(mount_height / 2) + post_adj, 0)) def connectors(): debugprint('connectors()') hulls = [] for column in range(ncols - 1): if (column in [2]) or (not reduced_outer_keys): iterrows = lastrow+1 else: iterrows = lastrow for row in range(iterrows): # need to consider last_row? # for row in range(nrows): # need to consider last_row? places = [] places.append(key_place(web_post_tl(), column + 1, row)) places.append(key_place(web_post_tr(), column, row)) places.append(key_place(web_post_bl(), column + 1, row)) places.append(key_place(web_post_br(), column, row)) hulls.append(triangle_hulls(places)) for column in range(ncols): if (column in [2, 3]) or (not reduced_outer_keys): iterrows = lastrow else: iterrows = cornerrow for row in range(iterrows): places = [] places.append(key_place(web_post_bl(), column, row)) places.append(key_place(web_post_br(), column, row)) places.append(key_place(web_post_tl(), column, row + 1)) places.append(key_place(web_post_tr(), column, row + 1)) hulls.append(triangle_hulls(places)) for column in range(ncols - 1): if (column in [2]) or (not reduced_outer_keys): iterrows = lastrow else: iterrows = cornerrow for row in range(iterrows): places = [] places.append(key_place(web_post_br(), column, row)) places.append(key_place(web_post_tr(), column, row + 1)) places.append(key_place(web_post_bl(), column + 1, row)) places.append(key_place(web_post_tl(), column + 1, row + 1)) hulls.append(triangle_hulls(places)) if reduced_outer_keys: if column == 1: places = [] places.append(key_place(web_post_bl(), column + 1, iterrows)) places.append(key_place(web_post_br(), column, iterrows)) places.append(key_place(web_post_tl(), column + 1, iterrows + 1)) places.append(key_place(web_post_bl(), column + 1, iterrows + 1)) hulls.append(triangle_hulls(places)) if column == 3: places = [] places.append(key_place(web_post_br(), column, iterrows)) places.append(key_place(web_post_bl(), column + 1, iterrows)) places.append(key_place(web_post_tr(), column, iterrows + 1)) places.append(key_place(web_post_br(), column, iterrows + 1)) hulls.append(triangle_hulls(places)) return union(hulls) #return add(hulls) ############ ## Thumbs ## ############ def thumborigin(): # debugprint('thumborigin()') origin = key_position([mount_width / 2, -(mount_height / 2), 0], 1, cornerrow) for i in range(len(origin)): origin[i] = origin[i] + thumb_offsets[i] if thumb_style == 'MINIDOX': origin[1] = origin[1] - .4*(minidox_Usize-1)*sa_length return origin def default_thumb_tl_place(shape): debugprint('thumb_tl_place()') shape = rotate(shape, [7.5, -18, 10]) shape = translate(shape, thumborigin()) shape = translate(shape, [-32.5, -14.5, -2.5]) return shape def default_thumb_tr_place(shape): debugprint('thumb_tr_place()') shape = rotate(shape, [10, -15, 10]) shape = translate(shape, thumborigin()) shape = translate(shape, [-12, -16, 3]) return shape def default_thumb_mr_place(shape): debugprint('thumb_mr_place()') shape = rotate(shape, [-6, -34, 48]) shape = translate(shape, thumborigin()) shape = translate(shape, [-29, -40, -13]) return shape def default_thumb_ml_place(shape): debugprint('thumb_ml_place()') shape = rotate(shape, [6, -34, 40]) shape = translate(shape, thumborigin()) shape = translate(shape, [-51, -25, -12]) return shape def default_thumb_br_place(shape): debugprint('thumb_br_place()') shape = rotate(shape, [-16, -33, 54]) shape = translate(shape, thumborigin()) shape = translate(shape, [-37.8, -55.3, -25.3]) return shape def default_thumb_bl_place(shape): debugprint('thumb_bl_place()') shape = rotate(shape, [-4, -35, 52]) shape = translate(shape, thumborigin()) shape = translate(shape, [-56.3, -43.3, -23.5]) return shape def default_thumb_1x_layout(shape, cap=False): debugprint('thumb_1x_layout()') if cap: shape_list = [ default_thumb_mr_place(rotate(shape, [0, 0, thumb_plate_mr_rotation])), default_thumb_ml_place(rotate(shape, [0, 0, thumb_plate_ml_rotation])), default_thumb_br_place(rotate(shape, [0, 0, thumb_plate_br_rotation])), default_thumb_bl_place(rotate(shape, [0, 0, thumb_plate_bl_rotation])), ] if default_1U_cluster: shape_list.append(default_thumb_tr_place(rotate(rotate(shape, (0, 0, 90)), [0, 0, thumb_plate_tr_rotation]))) shape_list.append(default_thumb_tr_place(rotate(rotate(shape, (0, 0, 90)), [0, 0, thumb_plate_tr_rotation]))) shape_list.append(default_thumb_tl_place(rotate(shape, [0, 0, thumb_plate_tl_rotation]))) shapes = add(shape_list) else: shape_list = [ default_thumb_mr_place(rotate(shape, [0, 0, thumb_plate_mr_rotation])), default_thumb_ml_place(rotate(shape, [0, 0, thumb_plate_ml_rotation])), default_thumb_br_place(rotate(shape, [0, 0, thumb_plate_br_rotation])), default_thumb_bl_place(rotate(shape, [0, 0, thumb_plate_bl_rotation])), ] if default_1U_cluster: shape_list.append(default_thumb_tr_place(rotate(rotate(shape, (0, 0, 90)), [0, 0, thumb_plate_tr_rotation]))) shapes = union(shape_list) return shapes def default_thumb_pcb_plate_cutouts(side="right"): shape = default_thumb_1x_layout(plate_pcb_cutout(side=side)) shape = union([shape, default_thumb_15x_layout(plate_pcb_cutout(side=side))]) return shape def default_thumb_15x_layout(shape, cap=False, plate=True): debugprint('thumb_15x_layout()') if plate: if cap: shape = rotate(shape, (0, 0, 90)) cap_list = [default_thumb_tl_place(rotate(shape, [0, 0, thumb_plate_tl_rotation]))] cap_list.append(default_thumb_tr_place(rotate(shape, [0, 0, thumb_plate_tr_rotation]))) return add(cap_list) else: shape_list = [default_thumb_tl_place(rotate(shape, [0, 0, thumb_plate_tl_rotation]))] if not default_1U_cluster: shape_list.append(default_thumb_tr_place(rotate(shape, [0, 0, thumb_plate_tr_rotation]))) return union(shape_list) else: if cap: shape = rotate(shape, (0, 0, 90)) shape_list = [ default_thumb_tl_place(shape), ] shape_list.append(default_thumb_tr_place(shape)) return add(shape_list) else: shape_list = [ default_thumb_tl_place(shape), ] if not default_1U_cluster: shape_list.append(default_thumb_tr_place(shape)) return union(shape_list) def adjustable_plate_size(Usize=1.5): return (Usize * sa_length - mount_height) / 2 def usize_dimention(Usize=1.5): return Usize * sa_length def adjustable_plate_half(Usize=1.5): debugprint('double_plate()') adjustable_plate_height = adjustable_plate_size(Usize) top_plate = box(mount_width, adjustable_plate_height, web_thickness) top_plate = translate(top_plate, [0, (adjustable_plate_height + mount_height) / 2, plate_thickness - (web_thickness / 2)] ) return top_plate def adjustable_plate(Usize=1.5): debugprint('double_plate()') top_plate = adjustable_plate_half(Usize) return union((top_plate, mirror(top_plate, 'XZ'))) def adjustable_square_plate(Uwidth=1.5, Uheight=1.5): width = usize_dimention(Usize=Uwidth) height = usize_dimention(Usize=Uheight) print("width: {}, height: {}, thickness:{}".format(width, height, web_thickness)) shape = box(width, height, web_thickness) shape = difference(shape, [box(mount_width-.01, mount_height-.01, 2*web_thickness)]) shape = translate(shape, (0, 0, web_thickness/2)) return shape def double_plate_half(): debugprint('double_plate()') top_plate = box(mount_width, double_plate_height, web_thickness) top_plate = translate(top_plate, [0, (double_plate_height + mount_height) / 2, plate_thickness - (web_thickness / 2)] ) return top_plate def double_plate(): debugprint('double_plate()') top_plate = double_plate_half() return union((top_plate, mirror(top_plate, 'XZ'))) def thumbcaps(side='right', style_override=None): if style_override is None: _thumb_style = thumb_style else: _thumb_style = style_override if _thumb_style == "MINI": return mini_thumbcaps() elif _thumb_style == "MINIDOX": return minidox_thumbcaps() elif _thumb_style == "CARBONFET": return carbonfet_thumbcaps() elif "TRACKBALL" in _thumb_style: if (side == ball_side or ball_side == 'both'): if _thumb_style == "TRACKBALL_ORBYL": return tbjs_thumbcaps() elif _thumb_style == "TRACKBALL_CJ": return tbcj_thumbcaps() else: return thumbcaps(side, style_override=other_thumb) else: return default_thumbcaps() def thumb(side="right", style_override=None): if style_override is None: _thumb_style = thumb_style else: _thumb_style = style_override if _thumb_style == "MINI": return mini_thumb(side) elif _thumb_style == "MINIDOX": return minidox_thumb(side) elif _thumb_style == "CARBONFET": return carbonfet_thumb(side) elif "TRACKBALL" in _thumb_style: if (side == ball_side or ball_side == 'both'): if _thumb_style == "TRACKBALL_ORBYL": return tbjs_thumb(side) elif _thumb_style == "TRACKBALL_CJ": return tbcj_thumb(side) else: return thumb(side, style_override=other_thumb) else: return default_thumb(side) def thumb_connectors(side='right', style_override=None): if style_override is None: _thumb_style = thumb_style else: _thumb_style = style_override if _thumb_style == "MINI": return mini_thumb_connectors() elif _thumb_style == "MINIDOX": return minidox_thumb_connectors() elif _thumb_style == "CARBONFET": return carbonfet_thumb_connectors() elif "TRACKBALL" in _thumb_style: if (side == ball_side or ball_side == 'both'): if _thumb_style == "TRACKBALL_ORBYL": return tbjs_thumb_connectors() elif _thumb_style == "TRACKBALL_CJ": return tbcj_thumb_connectors() else: return thumb_connectors(side, style_override=other_thumb) else: return default_thumb_connectors() def thumb_pcb_plate_cutouts(side='right', style_override=None): if style_override is None: _thumb_style = thumb_style else: _thumb_style = style_override if _thumb_style == "MINI": return mini_thumb_pcb_plate_cutouts(side) elif _thumb_style == "MINIDOX": return minidox_thumb_pcb_plate_cutouts(side) elif _thumb_style == "CARBONFET": return carbonfet_thumb_pcb_plate_cutouts(side) elif "TRACKBALL" in _thumb_style: if (side == ball_side or ball_side == 'both'): if _thumb_style == "TRACKBALL_ORBYL": return tbjs_thumb_pcb_plate_cutouts(side) elif _thumb_style == "TRACKBALL_CJ": return tbcj_thumb_pcb_plate_cutouts(side) else: return thumb_pcb_plate_cutouts(side, style_override=other_thumb) else: return default_thumb_pcb_plate_cutouts(side) def default_thumbcaps(): t1 = default_thumb_1x_layout(sa_cap(1), cap=True) if not default_1U_cluster: t1.add(default_thumb_15x_layout(sa_cap(1.5), cap=True)) return t1 def default_thumb(side="right"): print('thumb()') shape = default_thumb_1x_layout(rotate(single_plate(side=side), (0, 0, -90))) shape = union([shape, default_thumb_15x_layout(rotate(single_plate(side=side), (0, 0, -90)))]) shape = union([shape, default_thumb_15x_layout(double_plate(), plate=False)]) #shape = add([shape, default_thumb_15x_layout(rotate(single_plate(side=side), (0, 0, -90)))]) #shape = add([shape, default_thumb_15x_layout(double_plate(), plate=False)]) # if plate_pcb_clear: # shape = difference(shape, [default_thumb_pcb_plate_cutouts()]) return shape def thumb_post_tr(): debugprint('thumb_post_tr()') return translate(web_post(), [(mount_width / 2) - post_adj, ((mount_height/2) + double_plate_height) - post_adj, 0] ) def thumb_post_tl(): debugprint('thumb_post_tl()') return translate(web_post(), [-(mount_width / 2) + post_adj, ((mount_height/2) + double_plate_height) - post_adj, 0] ) def thumb_post_bl(): debugprint('thumb_post_bl()') return translate(web_post(), [-(mount_width / 2) + post_adj, -((mount_height/2) + double_plate_height) + post_adj, 0] ) def thumb_post_br(): debugprint('thumb_post_br()') return translate(web_post(), [(mount_width / 2) - post_adj, -((mount_height/2) + double_plate_height) + post_adj, 0] ) def default_thumb_connectors(): print('thumb_connectors()') hulls = [] # Top two if default_1U_cluster: hulls.append( triangle_hulls( [ default_thumb_tl_place(thumb_post_tr()), default_thumb_tl_place(thumb_post_br()), default_thumb_tr_place(web_post_tl()), default_thumb_tr_place(web_post_bl()), ] ) ) else: hulls.append( triangle_hulls( [ default_thumb_tl_place(thumb_post_tr()), default_thumb_tl_place(thumb_post_br()), default_thumb_tr_place(thumb_post_tl()), default_thumb_tr_place(thumb_post_bl()), ] ) ) # bottom two on the right hulls.append( triangle_hulls( [ default_thumb_br_place(web_post_tr()), default_thumb_br_place(web_post_br()), default_thumb_mr_place(web_post_tl()), default_thumb_mr_place(web_post_bl()), ] ) ) # bottom two on the left hulls.append( triangle_hulls( [ default_thumb_br_place(web_post_tr()), default_thumb_br_place(web_post_br()), default_thumb_mr_place(web_post_tl()), default_thumb_mr_place(web_post_bl()), ] ) ) # centers of the bottom four hulls.append( triangle_hulls( [ default_thumb_bl_place(web_post_tr()), default_thumb_bl_place(web_post_br()), default_thumb_ml_place(web_post_tl()), default_thumb_ml_place(web_post_bl()), ] ) ) # top two to the middle two, starting on the left hulls.append( triangle_hulls( [ default_thumb_br_place(web_post_tl()), default_thumb_bl_place(web_post_bl()), default_thumb_br_place(web_post_tr()), default_thumb_bl_place(web_post_br()), default_thumb_mr_place(web_post_tl()), default_thumb_ml_place(web_post_bl()), default_thumb_mr_place(web_post_tr()), default_thumb_ml_place(web_post_br()), ] ) ) if default_1U_cluster: hulls.append( triangle_hulls( [ default_thumb_tl_place(thumb_post_tl()), default_thumb_ml_place(web_post_tr()), default_thumb_tl_place(thumb_post_bl()), default_thumb_ml_place(web_post_br()), default_thumb_tl_place(thumb_post_br()), default_thumb_mr_place(web_post_tr()), default_thumb_tr_place(web_post_bl()), default_thumb_mr_place(web_post_br()), default_thumb_tr_place(web_post_br()), ] ) ) else: # top two to the main keyboard, starting on the left hulls.append( triangle_hulls( [ default_thumb_tl_place(thumb_post_tl()), default_thumb_ml_place(web_post_tr()), default_thumb_tl_place(thumb_post_bl()), default_thumb_ml_place(web_post_br()), default_thumb_tl_place(thumb_post_br()), default_thumb_mr_place(web_post_tr()), default_thumb_tr_place(thumb_post_bl()), default_thumb_mr_place(web_post_br()), default_thumb_tr_place(thumb_post_br()), ] ) ) if default_1U_cluster: hulls.append( triangle_hulls( [ default_thumb_tl_place(thumb_post_tl()), key_place(web_post_bl(), 0, cornerrow), default_thumb_tl_place(thumb_post_tr()), key_place(web_post_br(), 0, cornerrow), default_thumb_tr_place(web_post_tl()), key_place(web_post_bl(), 1, cornerrow), default_thumb_tr_place(web_post_tr()), key_place(web_post_br(), 1, cornerrow), key_place(web_post_bl(), 2, lastrow), default_thumb_tr_place(web_post_tr()), key_place(web_post_bl(), 2, lastrow), default_thumb_tr_place(web_post_br()), key_place(web_post_br(), 2, lastrow), key_place(web_post_bl(), 3, lastrow), ] ) ) else: hulls.append( triangle_hulls( [ default_thumb_tl_place(thumb_post_tl()), key_place(web_post_bl(), 0, cornerrow), default_thumb_tl_place(thumb_post_tr()), key_place(web_post_br(), 0, cornerrow), default_thumb_tr_place(thumb_post_tl()), key_place(web_post_bl(), 1, cornerrow), default_thumb_tr_place(thumb_post_tr()), key_place(web_post_br(), 1, cornerrow), key_place(web_post_tl(), 2, lastrow), key_place(web_post_bl(), 2, lastrow), default_thumb_tr_place(thumb_post_tr()), key_place(web_post_bl(), 2, lastrow), default_thumb_tr_place(thumb_post_br()), key_place(web_post_br(), 2, lastrow), key_place(web_post_bl(), 3, lastrow), ] ) ) #return add(hulls) return union(hulls) ############################ # MINI THUMB CLUSTER ############################ def mini_thumb_tr_place(shape): shape = rotate(shape, [14, -15, 10]) shape = translate(shape, thumborigin()) shape = translate(shape, [-15, -10, 5]) return shape def mini_thumb_tl_place(shape): shape = rotate(shape, [10, -23, 25]) shape = translate(shape, thumborigin()) shape = translate(shape, [-35, -16, -2]) return shape def mini_thumb_mr_place(shape): shape = rotate(shape, [10, -23, 25]) shape = translate(shape, thumborigin()) shape = translate(shape, [-23, -34, -6]) return shape def mini_thumb_br_place(shape): shape = rotate(shape, [6, -34, 35]) shape = translate(shape, thumborigin()) shape = translate(shape, [-39, -43, -16]) return shape def mini_thumb_bl_place(shape): shape = rotate(shape, [6, -32, 35]) shape = translate(shape, thumborigin()) shape = translate(shape, [-51, -25, -11.5]) return shape def mini_thumb_1x_layout(shape): return union([ #return add([ mini_thumb_mr_place(rotate(shape, [0, 0, thumb_plate_mr_rotation])), mini_thumb_br_place(rotate(shape, [0, 0, thumb_plate_br_rotation])), mini_thumb_tl_place(rotate(shape, [0, 0, thumb_plate_tl_rotation])), mini_thumb_bl_place(rotate(shape, [0, 0, thumb_plate_bl_rotation])), ]) def mini_thumb_15x_layout(shape): return union([mini_thumb_tr_place(rotate(shape, [0, 0, thumb_plate_tr_rotation]))]) #return add([mini_thumb_tr_place(rotate(shape, [0, 0, thumb_plate_tr_rotation]))]) def mini_thumbcaps(): t1 = mini_thumb_1x_layout(sa_cap(1)) t15 = mini_thumb_15x_layout(rotate(sa_cap(1), [0, 0, rad2deg(pi / 2)])) return t1.add(t15) def mini_thumb(side="right"): shape = mini_thumb_1x_layout(single_plate(side=side)) shape = union([shape, mini_thumb_15x_layout(single_plate(side=side))]) #shape = add([shape, mini_thumb_15x_layout(single_plate(side=side))]) return shape def mini_thumb_pcb_plate_cutouts(side="right"): shape = mini_thumb_1x_layout(plate_pcb_cutout(side=side)) shape = union([shape, mini_thumb_15x_layout(plate_pcb_cutout(side=side))]) #shape = add([shape, mini_thumb_15x_layout(plate_pcb_cutout(side=side))]) return shape def mini_thumb_post_tr(): return translate(web_post(), [(mount_width / 2) - post_adj, (mount_height / 2) - post_adj, 0] ) def mini_thumb_post_tl(): return translate(web_post(), [-(mount_width / 2) + post_adj, (mount_height / 2) - post_adj, 0] ) def mini_thumb_post_bl(): return translate(web_post(), [-(mount_width / 2) + post_adj, -(mount_height / 2) + post_adj, 0] ) def mini_thumb_post_br(): return translate(web_post(), [(mount_width / 2) - post_adj, -(mount_height / 2) + post_adj, 0] ) def mini_thumb_connectors(): hulls = [] # Top two hulls.append( triangle_hulls( [ mini_thumb_tl_place(web_post_tr()), mini_thumb_tl_place(web_post_br()), mini_thumb_tr_place(mini_thumb_post_tl()), mini_thumb_tr_place(mini_thumb_post_bl()), ] ) ) # bottom two on the right hulls.append( triangle_hulls( [ mini_thumb_br_place(web_post_tr()), mini_thumb_br_place(web_post_br()), mini_thumb_mr_place(web_post_tl()), mini_thumb_mr_place(web_post_bl()), ] ) ) # bottom two on the left hulls.append( triangle_hulls( [ mini_thumb_mr_place(web_post_tr()), mini_thumb_mr_place(web_post_br()), mini_thumb_tr_place(mini_thumb_post_br()), ] ) ) # between top and bottom row hulls.append( triangle_hulls( [ mini_thumb_br_place(web_post_tl()), mini_thumb_bl_place(web_post_bl()), mini_thumb_br_place(web_post_tr()), mini_thumb_bl_place(web_post_br()), mini_thumb_mr_place(web_post_tl()), mini_thumb_tl_place(web_post_bl()), mini_thumb_mr_place(web_post_tr()), mini_thumb_tl_place(web_post_br()), mini_thumb_tr_place(web_post_bl()), mini_thumb_mr_place(web_post_tr()), mini_thumb_tr_place(web_post_br()), ] ) ) # top two to the main keyboard, starting on the left hulls.append( triangle_hulls( [ mini_thumb_tl_place(web_post_tl()), mini_thumb_bl_place(web_post_tr()), mini_thumb_tl_place(web_post_bl()), mini_thumb_bl_place(web_post_br()), mini_thumb_mr_place(web_post_tr()), mini_thumb_tl_place(web_post_bl()), mini_thumb_tl_place(web_post_br()), mini_thumb_mr_place(web_post_tr()), ] ) ) # top two to the main keyboard, starting on the left hulls.append( triangle_hulls( [ mini_thumb_tl_place(web_post_tl()), key_place(web_post_bl(), 0, cornerrow), mini_thumb_tl_place(web_post_tr()), key_place(web_post_br(), 0, cornerrow), mini_thumb_tr_place(mini_thumb_post_tl()), key_place(web_post_bl(), 1, cornerrow), mini_thumb_tr_place(mini_thumb_post_tr()), key_place(web_post_br(), 1, cornerrow), # key_place(web_post_tl(), 2, lastrow), key_place(web_post_bl(), 2, lastrow), mini_thumb_tr_place(mini_thumb_post_tr()), key_place(web_post_bl(), 2, lastrow), mini_thumb_tr_place(mini_thumb_post_br()), key_place(web_post_br(), 2, lastrow), key_place(web_post_bl(), 3, lastrow), ] ) ) return union(hulls) #return add(hulls) ############################ # MINIDOX (3-key) THUMB CLUSTER ############################ def minidox_thumb_tl_place(shape): shape = rotate(shape, [10, -23, 25]) shape = translate(shape, thumborigin()) shape = translate(shape, [-35, -16, -2]) return shape def minidox_thumb_tr_place(shape): shape = rotate(shape, [14, -15, 10]) shape = translate(shape, thumborigin()) shape = translate(shape, [-15, -10, 5]) return shape def minidox_thumb_ml_place(shape): shape = rotate(shape, [6, -34, 40]) shape = translate(shape, thumborigin()) shape = translate(shape, [-53, -26, -12]) return shape def minidox_thumb_1x_layout(shape): return union([ #return add([ minidox_thumb_tr_place(rotate(shape, [0, 0, thumb_plate_tr_rotation])), minidox_thumb_tl_place(rotate(shape, [0, 0, thumb_plate_tl_rotation])), minidox_thumb_ml_place(rotate(shape, [0, 0, thumb_plate_ml_rotation])), ]) def minidox_thumb_fx_layout(shape): return union([ #return add([ minidox_thumb_tr_place(rotate(shape, [0, 0, thumb_plate_tr_rotation])), minidox_thumb_tl_place(rotate(shape, [0, 0, thumb_plate_tl_rotation])), minidox_thumb_ml_place(rotate(shape, [0, 0, thumb_plate_ml_rotation])), ]) def minidox_thumbcaps(): t1 = minidox_thumb_1x_layout(sa_cap(1)) # t1.add(minidox_thumb_15x_layout(rotate(sa_cap(1), [0, 0, rad2deg(pi / 2)]))) return t1 def minidox_thumb(side="right"): shape = minidox_thumb_fx_layout(rotate(single_plate(side=side), [0.0, 0.0, -90])) shape = union([shape, minidox_thumb_fx_layout(adjustable_plate(minidox_Usize))]) #shape = add([shape, minidox_thumb_fx_layout(adjustable_plate(minidox_Usize))]) # shape = minidox_thumb_1x_layout(single_plate(side=side)) return shape def minidox_thumb_pcb_plate_cutouts(side="right"): shape = minidox_thumb_fx_layout(plate_pcb_cutout(side=side)) shape = union([shape, minidox_thumb_fx_layout(plate_pcb_cutout())]) #shape = add([shape, minidox_thumb_fx_layout(plate_pcb_cutout())]) return shape def minidox_thumb_post_tr(): debugprint('thumb_post_tr()') return translate(web_post(), [(mount_width / 2) - post_adj, ((mount_height/2) + adjustable_plate_size(minidox_Usize)) - post_adj, 0] ) def minidox_thumb_post_tl(): debugprint('thumb_post_tl()') return translate(web_post(), [-(mount_width / 2) + post_adj, ((mount_height/2) + adjustable_plate_size(minidox_Usize)) - post_adj, 0] ) def minidox_thumb_post_bl(): debugprint('thumb_post_bl()') return translate(web_post(), [-(mount_width / 2) + post_adj, -((mount_height/2) + adjustable_plate_size(minidox_Usize)) + post_adj, 0] ) def minidox_thumb_post_br(): debugprint('thumb_post_br()') return translate(web_post(), [(mount_width / 2) - post_adj, -((mount_height/2) + adjustable_plate_size(minidox_Usize)) + post_adj, 0] ) def minidox_thumb_connectors(): hulls = [] # Top two hulls.append( triangle_hulls( [ minidox_thumb_tl_place(minidox_thumb_post_tr()), minidox_thumb_tl_place(minidox_thumb_post_br()), minidox_thumb_tr_place(minidox_thumb_post_tl()), minidox_thumb_tr_place(minidox_thumb_post_bl()), ] ) ) # bottom two on the right hulls.append( triangle_hulls( [ minidox_thumb_tl_place(minidox_thumb_post_tl()), minidox_thumb_tl_place(minidox_thumb_post_bl()), minidox_thumb_ml_place(minidox_thumb_post_tr()), minidox_thumb_ml_place(minidox_thumb_post_br()), ] ) ) # top two to the main keyboard, starting on the left hulls.append( triangle_hulls( [ minidox_thumb_tl_place(minidox_thumb_post_tl()), key_place(web_post_bl(), 0, cornerrow), minidox_thumb_tl_place(minidox_thumb_post_tr()), key_place(web_post_br(), 0, cornerrow), minidox_thumb_tr_place(minidox_thumb_post_tl()), key_place(web_post_bl(), 1, cornerrow), minidox_thumb_tr_place(minidox_thumb_post_tr()), key_place(web_post_br(), 1, cornerrow), key_place(web_post_bl(), 2, lastrow), minidox_thumb_tr_place(minidox_thumb_post_tr()), key_place(web_post_bl(), 2, lastrow), minidox_thumb_tr_place(minidox_thumb_post_br()), key_place(web_post_br(), 2, lastrow), key_place(web_post_bl(), 3, lastrow), ] ) ) return union(hulls) #return add(hulls) ############################ # Carbonfet THUMB CLUSTER ############################ def carbonfet_thumb_tl_place(shape): shape = rotate(shape, [10, -24, 10]) shape = translate(shape, thumborigin()) shape = translate(shape, [-13, -9.8, 4]) return shape def carbonfet_thumb_tr_place(shape): shape = rotate(shape, [6, -25, 10]) shape = translate(shape, thumborigin()) shape = translate(shape, [-7.5, -29.5, 0]) return shape def carbonfet_thumb_ml_place(shape): shape = rotate(shape, [8, -31, 14]) shape = translate(shape, thumborigin()) shape = translate(shape, [-30.5, -17, -6]) return shape def carbonfet_thumb_mr_place(shape): shape = rotate(shape, [4, -31, 14]) shape = translate(shape, thumborigin()) shape = translate(shape, [-22.2, -41, -10.3]) return shape def carbonfet_thumb_br_place(shape): shape = rotate(shape, [2, -37, 18]) shape = translate(shape, thumborigin()) shape = translate(shape, [-37, -46.4, -22]) return shape def carbonfet_thumb_bl_place(shape): shape = rotate(shape, [6, -37, 18]) shape = translate(shape, thumborigin()) shape = translate(shape, [-47, -23, -19]) return shape def carbonfet_thumb_1x_layout(shape): return union([ #return add([ carbonfet_thumb_tr_place(rotate(shape, [0, 0, thumb_plate_tr_rotation])), carbonfet_thumb_mr_place(rotate(shape, [0, 0, thumb_plate_mr_rotation])), carbonfet_thumb_br_place(rotate(shape, [0, 0, thumb_plate_br_rotation])), carbonfet_thumb_tl_place(rotate(shape, [0, 0, thumb_plate_tl_rotation])), ]) def carbonfet_thumb_15x_layout(shape, plate=True): if plate: return union([ #return add([ carbonfet_thumb_bl_place(rotate(shape, [0, 0, thumb_plate_bl_rotation])), carbonfet_thumb_ml_place(rotate(shape, [0, 0, thumb_plate_ml_rotation])) ]) else: return union([ #return add([ carbonfet_thumb_bl_place(shape), carbonfet_thumb_ml_place(shape) ]) def carbonfet_thumbcaps(): t1 = carbonfet_thumb_1x_layout(sa_cap(1)) t15 = carbonfet_thumb_15x_layout(rotate(sa_cap(1.5), [0, 0, rad2deg(pi / 2)])) return t1.add(t15) def carbonfet_thumb(side="right"): shape = carbonfet_thumb_1x_layout(single_plate(side=side)) shape = union([shape, carbonfet_thumb_15x_layout(double_plate_half(), plate=False)]) shape = union([shape, carbonfet_thumb_15x_layout(single_plate(side=side))]) #shape = add([shape, carbonfet_thumb_15x_layout(double_plate_half(), plate=False)]) #shape = add([shape, carbonfet_thumb_15x_layout(single_plate(side=side))]) return shape def carbonfet_thumb_pcb_plate_cutouts(side="right"): shape = carbonfet_thumb_1x_layout(plate_pcb_cutout(side=side)) shape = union([shape, carbonfet_thumb_15x_layout(plate_pcb_cutout())]) #shape = add([shape, carbonfet_thumb_15x_layout(plate_pcb_cutout())]) return shape def carbonfet_thumb_post_tr(): return translate(web_post(), [(mount_width / 2) - post_adj, (mount_height / 1.15) - post_adj, 0] ) def carbonfet_thumb_post_tl(): return translate(web_post(), [-(mount_width / 2) + post_adj, (mount_height / 1.15) - post_adj, 0] ) def carbonfet_thumb_post_bl(): return translate(web_post(), [-(mount_width / 2) + post_adj, -(mount_height / 1.15) + post_adj, 0] ) def carbonfet_thumb_post_br(): return translate(web_post(), [(mount_width / 2) - post_adj, -(mount_height / 2) + post_adj, 0] ) def carbonfet_thumb_connectors(): hulls = [] # Top two hulls.append( triangle_hulls( [ carbonfet_thumb_tl_place(web_post_tl()), carbonfet_thumb_tl_place(web_post_bl()), carbonfet_thumb_ml_place(carbonfet_thumb_post_tr()), carbonfet_thumb_ml_place(web_post_br()), ] ) ) hulls.append( triangle_hulls( [ carbonfet_thumb_ml_place(carbonfet_thumb_post_tl()), carbonfet_thumb_ml_place(web_post_bl()), carbonfet_thumb_bl_place(carbonfet_thumb_post_tr()), carbonfet_thumb_bl_place(web_post_br()), ] ) ) # bottom two on the right hulls.append( triangle_hulls( [ carbonfet_thumb_br_place(web_post_tr()), carbonfet_thumb_br_place(web_post_br()), carbonfet_thumb_mr_place(web_post_tl()), carbonfet_thumb_mr_place(web_post_bl()), ] ) ) # bottom two on the left hulls.append( triangle_hulls( [ carbonfet_thumb_mr_place(web_post_tr()), carbonfet_thumb_mr_place(web_post_br()), carbonfet_thumb_tr_place(web_post_tl()), carbonfet_thumb_tr_place(web_post_bl()), ] ) ) hulls.append( triangle_hulls( [ carbonfet_thumb_tr_place(web_post_br()), carbonfet_thumb_tr_place(web_post_bl()), carbonfet_thumb_mr_place(web_post_br()), ] ) ) # between top and bottom row hulls.append( triangle_hulls( [ carbonfet_thumb_br_place(web_post_tl()), carbonfet_thumb_bl_place(web_post_bl()), carbonfet_thumb_br_place(web_post_tr()), carbonfet_thumb_bl_place(web_post_br()), carbonfet_thumb_mr_place(web_post_tl()), carbonfet_thumb_ml_place(web_post_bl()), carbonfet_thumb_mr_place(web_post_tr()), carbonfet_thumb_ml_place(web_post_br()), carbonfet_thumb_tr_place(web_post_tl()), carbonfet_thumb_tl_place(web_post_bl()), carbonfet_thumb_tr_place(web_post_tr()), carbonfet_thumb_tl_place(web_post_br()), ] ) ) # top two to the main keyboard, starting on the left hulls.append( triangle_hulls( [ carbonfet_thumb_ml_place(carbonfet_thumb_post_tl()), key_place(web_post_bl(), 0, cornerrow), carbonfet_thumb_ml_place(carbonfet_thumb_post_tr()), key_place(web_post_br(), 0, cornerrow), carbonfet_thumb_tl_place(web_post_tl()), key_place(web_post_bl(), 1, cornerrow), carbonfet_thumb_tl_place(web_post_tr()), key_place(web_post_br(), 1, cornerrow), key_place(web_post_bl(), 2, lastrow), carbonfet_thumb_tl_place(web_post_tr()), key_place(web_post_bl(), 2, lastrow), carbonfet_thumb_tl_place(web_post_br()), key_place(web_post_br(), 2, lastrow), key_place(web_post_bl(), 3, lastrow), carbonfet_thumb_tl_place(web_post_br()), carbonfet_thumb_tr_place(web_post_tr()), ] ) ) hulls.append( triangle_hulls( [ carbonfet_thumb_tr_place(web_post_br()), carbonfet_thumb_tr_place(web_post_tr()), key_place(web_post_bl(), 3, lastrow), ] ) ) return union(hulls) #return add(hulls) ############################ # Trackball (Ball + 4-key) THUMB CLUSTER ############################ def tbjs_thumb_position_rotation(): rot = [10, -15, 5] pos = thumborigin() # Changes size based on key diameter around ball, shifting off of the top left cluster key. shift = [-.9*tbjs_key_diameter/2+27-42, -.1*tbjs_key_diameter/2+3-25, -5] for i in range(len(pos)): pos[i] = pos[i] + shift[i] + tbjs_translation_offset[i] for i in range(len(rot)): rot[i] = rot[i] + tbjs_rotation_offset[i] return pos, rot def tbjs_place(shape): pos, rot = tbjs_thumb_position_rotation() shape = rotate(shape, rot) shape = translate(shape, pos) return shape def tbjs_thumb_tl_place(shape): debugprint('thumb_tr_place()') # Modifying to make a "ring" of keys shape = rotate(shape, [0, 0, 0]) t_off = tbjs_key_translation_offsets[0] shape = rotate(shape, tbjs_key_rotation_offsets[0]) shape = translate(shape, (t_off[0], t_off[1]+tbjs_key_diameter/2, t_off[2])) shape = rotate(shape, [0,0,-80]) shape = tbjs_place(shape) return shape def tbjs_thumb_mr_place(shape): debugprint('thumb_mr_place()') shape = rotate(shape, [0, 0, 0]) shape = rotate(shape, tbjs_key_rotation_offsets[1]) t_off = tbjs_key_translation_offsets[1] shape = translate(shape, (t_off[0], t_off[1]+tbjs_key_diameter/2, t_off[2])) shape = rotate(shape, [0,0,-130]) shape = tbjs_place(shape) return shape def tbjs_thumb_br_place(shape): debugprint('thumb_br_place()') shape = rotate(shape, [0, 0, 180]) shape = rotate(shape, tbjs_key_rotation_offsets[2]) t_off = tbjs_key_translation_offsets[2] shape = translate(shape, (t_off[0], t_off[1]+tbjs_key_diameter/2, t_off[2])) shape = rotate(shape, [0,0,-180]) shape = tbjs_place(shape) return shape def tbjs_thumb_bl_place(shape): debugprint('thumb_bl_place()') shape = rotate(shape, [0, 0, 180]) shape = rotate(shape, tbjs_key_rotation_offsets[3]) t_off = tbjs_key_translation_offsets[3] shape = translate(shape, (t_off[0], t_off[1]+tbjs_key_diameter/2, t_off[2])) shape = rotate(shape, [0,0,-230]) shape = tbjs_place(shape) return shape def tbjs_thumb_1x_layout(shape): return union([ #return add([ tbjs_thumb_tl_place(rotate(shape, [0, 0, thumb_plate_tr_rotation])), tbjs_thumb_mr_place(rotate(shape, [0, 0, thumb_plate_mr_rotation])), tbjs_thumb_bl_place(rotate(shape, [0, 0, thumb_plate_bl_rotation])), tbjs_thumb_br_place(rotate(shape, [0, 0, thumb_plate_br_rotation])), ]) def tbjs_thumb_pcb_plate_cutouts(side="right"): return tbjs_thumb_1x_layout(plate_pcb_cutout(side=side)) def tbjs_thumb_fx_layout(shape): return [ tbjs_thumb_tl_place(rotate(shape, [0, 0, thumb_plate_tr_rotation])), tbjs_thumb_mr_place(rotate(shape, [0, 0, thumb_plate_mr_rotation])), tbjs_thumb_bl_place(rotate(shape, [0, 0, thumb_plate_bl_rotation])), tbjs_thumb_br_place(rotate(shape, [0, 0, thumb_plate_br_rotation])), ] def trackball_layout(shape): return union([ #return add([ tbjs_place(shape), ]) def tbjs_thumbcaps(): t1 = tbjs_thumb_1x_layout(sa_cap(1)) # t1 = tbjs_thumb_fx_layout(sa_cap(1)) # t1.add(tbjs_thumb_15x_layout(rotate(sa_cap(1), [0, 0, rad2deg(pi / 2)]))) return t1 def tbjs_thumb(side="right"): # shape = tbjs_thumb_fx_layout(rotate(single_plate(side=side), [0.0, 0.0, -90])) shape = tbjs_thumb_1x_layout(single_plate(side=side)) # shape = tbjs_thumb_fx_layout(adjustable_square_plate(Uwidth=tbjs_Uwidth, Uheight=tbjs_Uheight)) shape = union([shape, *tbjs_thumb_fx_layout(adjustable_square_plate(Uwidth=tbjs_Uwidth, Uheight=tbjs_Uheight))]) #shape = add([shape, *tbjs_thumb_fx_layout(adjustable_square_plate(Uwidth=tbjs_Uwidth, Uheight=tbjs_Uheight))]) # shape = union([shape, trackball_layout(trackball_socket())]) # shape = tbjs_thumb_1x_layout(single_plate(side=side)) return shape def tbjs_thumb_post_tr(): debugprint('thumb_post_tr()') return translate(web_post(), [(mount_width / 2) + adjustable_plate_size(tbjs_Uwidth) - post_adj, ((mount_height/2) + adjustable_plate_size(tbjs_Uheight)) - post_adj, 0] ) def tbjs_thumb_post_tl(): debugprint('thumb_post_tl()') return translate(web_post(), [-(mount_width / 2) - adjustable_plate_size(tbjs_Uwidth) + post_adj, ((mount_height/2) + adjustable_plate_size(tbjs_Uheight)) - post_adj, 0] ) def tbjs_thumb_post_bl(): debugprint('thumb_post_bl()') return translate(web_post(), [-(mount_width / 2) - adjustable_plate_size(tbjs_Uwidth) + post_adj, -((mount_height/2) + adjustable_plate_size(tbjs_Uheight)) + post_adj, 0] ) def tbjs_thumb_post_br(): debugprint('thumb_post_br()') return translate(web_post(), [(mount_width / 2) + adjustable_plate_size(tbjs_Uwidth) - post_adj, - ((mount_height/2) + adjustable_plate_size(tbjs_Uheight)) + post_adj, 0] ) def tbjs_post_r(): debugprint('tbjs_post_r()') radius = ball_diameter/2 + ball_wall_thickness + ball_gap return translate(web_post(), [1.0*(radius - post_adj), 0.0*(radius - post_adj), 0] ) def tbjs_post_tr(): debugprint('tbjs_post_tr()') radius = ball_diameter/2+ball_wall_thickness + ball_gap return translate(web_post(), [0.5*(radius - post_adj), 0.866*(radius - post_adj), 0] ) def tbjs_post_tl(): debugprint('tbjs_post_tl()') radius = ball_diameter/2+ball_wall_thickness + ball_gap return translate(web_post(), [-0.5*(radius - post_adj), 0.866*(radius - post_adj), 0] ) def tbjs_post_l(): debugprint('tbjs_post_l()') radius = ball_diameter/2+ball_wall_thickness + ball_gap return translate(web_post(), [-1.0*(radius - post_adj), 0.0*(radius - post_adj), 0] ) def tbjs_post_bl(): debugprint('tbjs_post_bl()') radius = ball_diameter/2+ball_wall_thickness + ball_gap return translate(web_post(), [-0.5*(radius - post_adj), -0.866*(radius - post_adj), 0] ) def tbjs_post_br(): debugprint('tbjs_post_br()') radius = ball_diameter/2+ball_wall_thickness + ball_gap return translate(web_post(), [0.5*(radius - post_adj), -0.866*(radius - post_adj), 0] ) def tbjs_thumb_connectors(): print('thumb_connectors()') hulls = [] # bottom 2 to tb hulls.append( triangle_hulls( [ tbjs_place(tbjs_post_l()), tbjs_thumb_bl_place(tbjs_thumb_post_tl()), tbjs_place(tbjs_post_bl()), tbjs_thumb_bl_place(tbjs_thumb_post_tr()), tbjs_thumb_br_place(tbjs_thumb_post_tl()), tbjs_place(tbjs_post_bl()), tbjs_thumb_br_place(tbjs_thumb_post_tr()), tbjs_place(tbjs_post_br()), tbjs_thumb_br_place(tbjs_thumb_post_tr()), tbjs_place(tbjs_post_br()), tbjs_thumb_mr_place(tbjs_thumb_post_br()), tbjs_place(tbjs_post_r()), tbjs_thumb_mr_place(tbjs_thumb_post_bl()), tbjs_thumb_tl_place(tbjs_thumb_post_br()), tbjs_place(tbjs_post_r()), tbjs_thumb_tl_place(tbjs_thumb_post_bl()), tbjs_place(tbjs_post_tr()), key_place(web_post_bl(), 0, cornerrow), tbjs_place(tbjs_post_tl()), ] ) ) # bottom left hulls.append( triangle_hulls( [ tbjs_thumb_bl_place(tbjs_thumb_post_tr()), tbjs_thumb_br_place(tbjs_thumb_post_tl()), tbjs_thumb_bl_place(tbjs_thumb_post_br()), tbjs_thumb_br_place(tbjs_thumb_post_bl()), ] ) ) # bottom right hulls.append( triangle_hulls( [ tbjs_thumb_br_place(tbjs_thumb_post_tr()), tbjs_thumb_mr_place(tbjs_thumb_post_br()), tbjs_thumb_br_place(tbjs_thumb_post_br()), tbjs_thumb_mr_place(tbjs_thumb_post_tr()), ] ) ) # top right hulls.append( triangle_hulls( [ tbjs_thumb_mr_place(tbjs_thumb_post_bl()), tbjs_thumb_tl_place(tbjs_thumb_post_br()), tbjs_thumb_mr_place(tbjs_thumb_post_tl()), tbjs_thumb_tl_place(tbjs_thumb_post_tr()), ] ) ) return union(hulls) #return add(hulls) ############################ # TRACKBALL THUMB CLUSTER ############################ # single_plate = the switch shape def tbcj_thumb_tr_place(shape): shape = rotate(shape, [10, -15, 10]) shape = translate(shape, thumborigin()) shape = translate(shape, [-12, -16, 3]) return shape def tbcj_thumb_tl_place(shape): shape = rotate(shape, [7.5, -18, 10]) shape = translate(shape, thumborigin()) shape = translate(shape, [-32.5, -14.5, -2.5]) return shape def tbcj_thumb_ml_place(shape): shape = rotate(shape, [6, -34, 40]) shape = translate(shape, thumborigin()) shape = translate(shape, [-51, -25, -12]) return shape def tbcj_thumb_bl_place(shape): shape = rotate(shape, [-4, -35, 52]) shape = translate(shape, thumborigin()) shape = translate(shape, [-56.3, -43.3, -23.5]) return shape def tbcj_thumb_layout(shape): return union([ #return add([ tbcj_thumb_tr_place(rotate(shape, [0, 0, thumb_plate_tr_rotation])), tbcj_thumb_tl_place(rotate(shape, [0, 0, thumb_plate_tl_rotation])), tbcj_thumb_ml_place(rotate(shape, [0, 0, thumb_plate_ml_rotation])), tbcj_thumb_bl_place(rotate(shape, [0, 0, thumb_plate_bl_rotation])), ]) #def oct_corner(i, radius, shape): # i = (i+1)%8 # # points_x = [1, 2, 2, 1, -1, -2, -2, -1] # points_y = [2, 1, -1, -2, -2, -1, 1, 2] # # return translate(shape, (points_x[i] * radius / 2, points_y[i] * radius / 2, 0)) import math def oct_corner(i, diameter, shape): radius = diameter / 2 i = (i+1)%8 r = radius m = radius * math.tan(math.pi / 8) points_x = [m, r, r, m, -m, -r, -r, -m] points_y = [r, m, -m, -r, -r, -m, m, r] return translate(shape, (points_x[i], points_y[i], 0)) def tbcj_edge_post(i): shape = box(post_size, post_size, tbcj_thickness) shape = oct_corner(i, tbcj_outer_diameter, shape) return shape def tbcj_web_post(i): shape = box(post_size, post_size, tbcj_thickness) shape = oct_corner(i, tbcj_outer_diameter, shape) return shape def tbcj_holder(): center = box(post_size, post_size, tbcj_thickness) shape = [] for i in range(8): shape_ = hull_from_shapes([ center, tbcj_edge_post(i), tbcj_edge_post(i + 1), ]) shape.append(shape_) shape = union(shape) shape = difference( shape, [cylinder(tbcj_inner_diameter/2, tbcj_thickness + 0.1)] ) return shape def tbcj_thumb_position_rotation(): pos = np.array([-15, -60, -12]) + thumborigin() rot = (0, 0, 0) return pos, rot def tbcj_place(shape): loc = np.array([-15, -60, -12]) + thumborigin() shape = translate(shape, loc) shape = rotate(shape, (0, 0, 0)) return shape def tbcj_thumb(side="right"): t = tbcj_thumb_layout(single_plate(side=side)) tb = tbcj_place(tbcj_holder()) return union([t, tb]) #return add([t, tb]) def tbcj_thumb_pcb_plate_cutouts(side="right"): t = tbcj_thumb_layout(plate_pcb_cutout(side=side)) return t def tbcj_thumbcaps(): t = tbcj_thumb_layout(sa_cap(1)) return t # TODO: VERIFY THEY CAN BE DELETED. THEY LOOK LIKE REPLICATES. # def thumb_post_tr(): # return translate(web_post(), # [(mount_width / 2) - post_adj, ((mount_height/2) + double_plate_height) - post_adj, 0] # ) # # # def thumb_post_tl(): # return translate(web_post(), # [-(mount_width / 2) + post_adj, ((mount_height/2) + double_plate_height) - post_adj, 0] # ) # # # def thumb_post_bl(): # return translate(web_post(), # [-(mount_width / 2) + post_adj, -((mount_height/2) + double_plate_height) + post_adj, 0] # ) # # # def thumb_post_br(): # return translate(web_post(), # [(mount_width / 2) - post_adj, -((mount_height/2) + double_plate_height) + post_adj, 0] # ) def tbcj_thumb_connectors(): hulls = [] # Top two hulls.append( triangle_hulls( [ tbcj_thumb_tl_place(web_post_tr()), tbcj_thumb_tl_place(web_post_br()), tbcj_thumb_tr_place(web_post_tl()), tbcj_thumb_tr_place(web_post_bl()), ] ) ) # centers of the bottom four hulls.append( triangle_hulls( [ tbcj_thumb_bl_place(web_post_tr()), tbcj_thumb_bl_place(web_post_br()), tbcj_thumb_ml_place(web_post_tl()), tbcj_thumb_ml_place(web_post_bl()), ] ) ) # top two to the middle two, starting on the left hulls.append( triangle_hulls( [ tbcj_thumb_tl_place(web_post_tl()), tbcj_thumb_ml_place(web_post_tr()), tbcj_thumb_tl_place(web_post_bl()), tbcj_thumb_ml_place(web_post_br()), tbcj_thumb_tl_place(web_post_br()), tbcj_thumb_tr_place(web_post_bl()), tbcj_thumb_tr_place(web_post_br()), ] ) ) hulls.append( triangle_hulls( [ tbcj_thumb_tl_place(web_post_tl()), key_place(web_post_bl(), 0, cornerrow), tbcj_thumb_tl_place(web_post_tr()), key_place(web_post_br(), 0, cornerrow), tbcj_thumb_tr_place(web_post_tl()), key_place(web_post_bl(), 1, cornerrow), tbcj_thumb_tr_place(web_post_tr()), key_place(web_post_br(), 1, cornerrow), key_place(web_post_bl(), 2, lastrow), tbcj_thumb_tr_place(web_post_tr()), key_place(web_post_bl(), 2, lastrow), tbcj_thumb_tr_place(web_post_br()), key_place(web_post_br(), 2, lastrow), key_place(web_post_bl(), 3, lastrow), ] ) ) hulls.append( triangle_hulls( [ tbcj_place(tbcj_web_post(4)), tbcj_thumb_bl_place(web_post_bl()), tbcj_place(tbcj_web_post(5)), tbcj_thumb_bl_place(web_post_br()), tbcj_place(tbcj_web_post(6)), ] ) ) hulls.append( triangle_hulls( [ tbcj_thumb_bl_place(web_post_br()), tbcj_place(tbcj_web_post(6)), tbcj_thumb_ml_place(web_post_bl()), ] ) ) hulls.append( triangle_hulls( [ tbcj_thumb_ml_place(web_post_bl()), tbcj_place(tbcj_web_post(6)), tbcj_thumb_ml_place(web_post_br()), tbcj_thumb_tr_place(web_post_bl()), ] ) ) hulls.append( triangle_hulls( [ tbcj_place(tbcj_web_post(6)), tbcj_thumb_tr_place(web_post_bl()), tbcj_place(tbcj_web_post(7)), tbcj_thumb_tr_place(web_post_br()), tbcj_place(tbcj_web_post(0)), tbcj_thumb_tr_place(web_post_br()), key_place(web_post_bl(), 3, lastrow), ] ) ) return union(hulls) #return add(hulls) ########## ## Case ## ########## def left_key_position(row, direction, low_corner=False, side='right'): debugprint("left_key_position()") pos = np.array( key_position([-mount_width * 0.5, direction * mount_height * 0.5, 0], 0, row) ) if trackball_in_wall and (side == ball_side or ball_side == 'both'): if low_corner: x_offset = tbiw_left_wall_lower_x_offset y_offset = tbiw_left_wall_lower_y_offset z_offset = tbiw_left_wall_lower_z_offset else: x_offset = 0.0 y_offset = 0.0 z_offset = 0.0 return list(pos - np.array([ tbiw_left_wall_x_offset_override - x_offset, -y_offset, tbiw_left_wall_z_offset_override + z_offset ])) if low_corner: x_offset = left_wall_lower_x_offset y_offset = left_wall_lower_y_offset z_offset = left_wall_lower_z_offset else: x_offset = 0.0 y_offset = 0.0 z_offset = 0.0 return list(pos - np.array([left_wall_x_offset - x_offset, -y_offset, left_wall_z_offset + z_offset])) def left_key_place(shape, row, direction, low_corner=False, side='right'): debugprint("left_key_place()") pos = left_key_position(row, direction, low_corner=low_corner, side=side) return translate(shape, pos) def wall_locate1(dx, dy): debugprint("wall_locate1()") return [dx * wall_thickness, dy * wall_thickness, -1] def wall_locate2(dx, dy): debugprint("wall_locate2()") return [dx * wall_x_offset, dy * wall_y_offset, -wall_z_offset] def wall_locate3(dx, dy, back=False): debugprint("wall_locate3()") if back: return [ dx * (wall_x_offset + wall_base_x_thickness), dy * (wall_y_offset + wall_base_back_thickness), -wall_z_offset, ] else: return [ dx * (wall_x_offset + wall_base_x_thickness), dy * (wall_y_offset + wall_base_y_thickness), -wall_z_offset, ] def wall_brace(place1, dx1, dy1, post1, place2, dx2, dy2, post2, back=False, skeleton=False, skel_bottom=False): debugprint("wall_brace()") hulls = [] hulls.append(place1(post1)) if not skeleton: hulls.append(place1(translate(post1, wall_locate1(dx1, dy1)))) hulls.append(place1(translate(post1, wall_locate2(dx1, dy1)))) if not skeleton or skel_bottom: hulls.append(place1(translate(post1, wall_locate3(dx1, dy1, back)))) hulls.append(place2(post2)) if not skeleton: hulls.append(place2(translate(post2, wall_locate1(dx2, dy2)))) hulls.append(place2(translate(post2, wall_locate2(dx2, dy2)))) if not skeleton or skel_bottom: hulls.append(place2(translate(post2, wall_locate3(dx2, dy2, back)))) shape1 = hull_from_shapes(hulls) hulls = [] if not skeleton: hulls.append(place1(translate(post1, wall_locate2(dx1, dy1)))) if not skeleton or skel_bottom: hulls.append(place1(translate(post1, wall_locate3(dx1, dy1, back)))) if not skeleton: hulls.append(place2(translate(post2, wall_locate2(dx2, dy2)))) if not skeleton or skel_bottom: hulls.append(place2(translate(post2, wall_locate3(dx2, dy2, back)))) if len(hulls)>0: shape2 = bottom_hull(hulls) shape1 = union([shape1, shape2]) #shape1 = add([shape1, shape2]) return shape1 def key_wall_brace(x1, y1, dx1, dy1, post1, x2, y2, dx2, dy2, post2, back=False, skeleton=False, skel_bottom=False): debugprint("key_wall_brace()") return wall_brace( (lambda shape: key_place(shape, x1, y1)), dx1, dy1, post1, (lambda shape: key_place(shape, x2, y2)), dx2, dy2, post2, back, skeleton=skeleton, skel_bottom=False, ) def back_wall(skeleton=False): print("back_wall()") x = 0 shape = None shape = union([shape, key_wall_brace( x, 0, 0, 1, web_post_tl(), x, 0, 0, 1, web_post_tr(), back=True, )]) for i in range(ncols - 1): x = i + 1 shape = union([shape, key_wall_brace( x, 0, 0, 1, web_post_tl(), x, 0, 0, 1, web_post_tr(), back=True, )]) skelly = skeleton and not x==1 shape = union([shape, key_wall_brace( x, 0, 0, 1, web_post_tl(), x - 1, 0, 0, 1, web_post_tr(), back=True, skeleton=skelly, skel_bottom=True, )]) shape = union([shape, key_wall_brace( lastcol, 0, 0, 1, web_post_tr(), lastcol, 0, 1, 0, web_post_tr(), back=True, skeleton=skeleton, skel_bottom=True, )]) if not skeleton: shape = union([shape, key_wall_brace( lastcol, 0, 0, 1, web_post_tr(), lastcol, 0, 1, 0, web_post_tr() ) ]) return shape def right_wall(skeleton=False): print("right_wall()") y = 0 shape = None shape = union([shape, key_wall_brace( lastcol, y, 1, 0, web_post_tr(), lastcol, y, 1, 0, web_post_br(), skeleton=skeleton, )]) for i in range(cornerrow): y = i + 1 shape = union([shape, key_wall_brace( lastcol, y - 1, 1, 0, web_post_br(), lastcol, y, 1, 0, web_post_tr(), skeleton=skeleton, )]) shape = union([shape, key_wall_brace( lastcol, y, 1, 0, web_post_tr(), lastcol, y, 1, 0, web_post_br(), skeleton=skeleton, )]) #STRANGE PARTIAL OFFSET shape = union([ shape, key_wall_brace( lastcol, cornerrow, 0, -1, web_post_br(), lastcol, cornerrow, 1, 0, web_post_br(), skeleton=skeleton ), ]) return shape def left_wall(side='right', skeleton=False): print('left_wall()') shape = union([wall_brace( (lambda sh: key_place(sh, 0, 0)), 0, 1, web_post_tl(), (lambda sh: left_key_place(sh, 0, 1, side=side)), 0, 1, web_post(), )]) shape = union([shape, wall_brace( (lambda sh: left_key_place(sh, 0, 1, side=side)), 0, 1, web_post(), (lambda sh: left_key_place(sh, 0, 1, side=side)), -1, 0, web_post(), skeleton=skeleton, )]) # for i in range(lastrow): for i in range(cornerrow+1): y = i low = (y == (cornerrow)) temp_shape1 = wall_brace( (lambda sh: left_key_place(sh, y, 1, side=side)), -1, 0, web_post(), (lambda sh: left_key_place(sh, y, -1, low_corner=low, side=side)), -1, 0, web_post(), skeleton=skeleton and (y < (cornerrow)), ) shape = union([shape, temp_shape1]) temp_shape2 = hull_from_shapes(( key_place(web_post_tl(), 0, y), key_place(web_post_bl(), 0, y), left_key_place(web_post(), y, 1, side=side), left_key_place(web_post(), y, -1, low_corner=low, side=side), )) shape = union([shape, temp_shape2]) for i in range(cornerrow): y = i + 1 low = (y == (cornerrow)) temp_shape1 = wall_brace( (lambda sh: left_key_place(sh, y - 1, -1, side=side)), -1, 0, web_post(), (lambda sh: left_key_place(sh, y, 1, side=side)), -1, 0, web_post(), skeleton=skeleton and (y < (cornerrow)), ) shape = union([shape, temp_shape1]) temp_shape2 = hull_from_shapes(( key_place(web_post_tl(), 0, y), key_place(web_post_bl(), 0, y - 1), left_key_place(web_post(), y, 1, side=side), left_key_place(web_post(), y - 1, -1, side=side), )) shape = union([shape, temp_shape2]) return shape def front_wall(skeleton=False): print('front_wall()') shape = None shape = union([shape,key_wall_brace( 3, lastrow, 0, -1, web_post_bl(), 3, lastrow, 0.5, -1, web_post_br() )]) shape = union([shape,key_wall_brace( 3, lastrow, 0.5, -1, web_post_br(), 4, cornerrow, .5, -1, web_post_bl() )]) shape = union([shape,key_wall_brace( 4, cornerrow, .5, -1, web_post_bl(), 4, cornerrow, 0, -1, web_post_br() )]) for i in range(ncols - 5): x = i + 5 shape = union([shape,key_wall_brace( x, cornerrow, 0, -1, web_post_bl(), x, cornerrow, 0, -1, web_post_br() )]) shape = union([shape, key_wall_brace( x, cornerrow, 0, -1, web_post_bl(), x - 1, cornerrow, 0, -1, web_post_br() )]) return shape def thumb_walls(side='right', style_override=None, skeleton=False): if style_override is None: _thumb_style = thumb_style else: _thumb_style = style_override if _thumb_style == "MINI": return mini_thumb_walls(skeleton=skeleton) elif _thumb_style == "MINIDOX": return minidox_thumb_walls(skeleton=skeleton) elif _thumb_style == "CARBONFET": return carbonfet_thumb_walls(skeleton=skeleton) elif "TRACKBALL" in _thumb_style: if (side == ball_side or ball_side == 'both'): if _thumb_style == "TRACKBALL_ORBYL": return tbjs_thumb_walls(skeleton=skeleton) elif thumb_style == "TRACKBALL_CJ": return tbcj_thumb_walls(skeleton=skeleton) else: return thumb_walls(side, style_override=other_thumb, skeleton=skeleton) else: return default_thumb_walls(skeleton=skeleton) def thumb_connection(side='right', style_override=None, skeleton=False): if style_override is None: _thumb_style = thumb_style else: _thumb_style = style_override if _thumb_style == "MINI": return mini_thumb_connection(side=side, skeleton=skeleton) elif _thumb_style == "MINIDOX": return minidox_thumb_connection(side=side, skeleton=skeleton) elif _thumb_style == "CARBONFET": return carbonfet_thumb_connection(side=side, skeleton=skeleton) elif "TRACKBALL" in _thumb_style: if (side == ball_side or ball_side == 'both'): if _thumb_style == "TRACKBALL_ORBYL": return tbjs_thumb_connection(side=side, skeleton=skeleton) elif thumb_style == "TRACKBALL_CJ": return tbcj_thumb_connection(side=side, skeleton=skeleton) else: return thumb_connection(side, style_override=other_thumb, skeleton=skeleton) else: return default_thumb_connection(side=side, skeleton=skeleton) def default_thumb_walls(skeleton=False): print('thumb_walls()') # thumb, walls if default_1U_cluster: shape = union([wall_brace(default_thumb_mr_place, 0, -1, web_post_br(), default_thumb_tr_place, 0, -1, web_post_br())]) else: shape = union([wall_brace(default_thumb_mr_place, 0, -1, web_post_br(), default_thumb_tr_place, 0, -1, thumb_post_br())]) shape = union([shape, wall_brace(default_thumb_mr_place, 0, -1, web_post_br(), default_thumb_mr_place, 0, -1, web_post_bl())]) shape = union([shape, wall_brace(default_thumb_br_place, 0, -1, web_post_br(), default_thumb_br_place, 0, -1, web_post_bl())]) shape = union([shape, wall_brace(default_thumb_ml_place, -0.3, 1, web_post_tr(), default_thumb_ml_place, 0, 1, web_post_tl())]) shape = union([shape, wall_brace(default_thumb_bl_place, 0, 1, web_post_tr(), default_thumb_bl_place, 0, 1, web_post_tl())]) shape = union([shape, wall_brace(default_thumb_br_place, -1, 0, web_post_tl(), default_thumb_br_place, -1, 0, web_post_bl())]) shape = union([shape, wall_brace(default_thumb_bl_place, -1, 0, web_post_tl(), default_thumb_bl_place, -1, 0, web_post_bl())]) # thumb, corners shape = union([shape, wall_brace(default_thumb_br_place, -1, 0, web_post_bl(), default_thumb_br_place, 0, -1, web_post_bl())]) shape = union([shape, wall_brace(default_thumb_bl_place, -1, 0, web_post_tl(), default_thumb_bl_place, 0, 1, web_post_tl())]) # thumb, tweeners shape = union([shape, wall_brace(default_thumb_mr_place, 0, -1, web_post_bl(), default_thumb_br_place, 0, -1, web_post_br())]) shape = union([shape, wall_brace(default_thumb_ml_place, 0, 1, web_post_tl(), default_thumb_bl_place, 0, 1, web_post_tr())]) shape = union([shape, wall_brace(default_thumb_bl_place, -1, 0, web_post_bl(), default_thumb_br_place, -1, 0, web_post_tl())]) if default_1U_cluster: shape = union([shape, wall_brace(default_thumb_tr_place, 0, -1, web_post_br(), (lambda sh: key_place(sh, 3, lastrow)), 0, -1, web_post_bl())]) else: shape = union([shape, wall_brace(default_thumb_tr_place, 0, -1, thumb_post_br(), (lambda sh: key_place(sh, 3, lastrow)), 0, -1, web_post_bl())]) return shape def default_thumb_connection(side='right', skeleton=False): print('thumb_connection()') # clunky bit on the top left thumb connection (normal connectors don't work well) shape = None shape = union([shape, bottom_hull( [ left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), default_thumb_ml_place(translate(web_post_tr(), wall_locate2(-0.3, 1))), default_thumb_ml_place(translate(web_post_tr(), wall_locate3(-0.3, 1))), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), default_thumb_ml_place(translate(web_post_tr(), wall_locate2(-0.3, 1))), default_thumb_ml_place(translate(web_post_tr(), wall_locate3(-0.3, 1))), default_thumb_tl_place(thumb_post_tl()), ] ) ]) # ) shape = union([shape, hull_from_shapes( [ left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), default_thumb_tl_place(thumb_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(web_post(), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True, side=side), key_place(web_post_bl(), 0, cornerrow), default_thumb_tl_place(thumb_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ default_thumb_ml_place(web_post_tr()), default_thumb_ml_place(translate(web_post_tr(), wall_locate1(-0.3, 1))), default_thumb_ml_place(translate(web_post_tr(), wall_locate2(-0.3, 1))), default_thumb_ml_place(translate(web_post_tr(), wall_locate3(-0.3, 1))), default_thumb_tl_place(thumb_post_tl()), ] )]) return shape def tbjs_thumb_connection(side='right', skeleton=False): print('thumb_connection()') # clunky bit on the top left thumb connection (normal connectors don't work well) hulls = [] hulls.append( triangle_hulls( [ key_place(web_post_bl(), 0, cornerrow), left_key_place(web_post(), cornerrow, -1, side=side, low_corner=True), # left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True), tbjs_place(tbjs_post_tl()), ] ) ) hulls.append( triangle_hulls( [ key_place(web_post_bl(), 0, cornerrow), tbjs_thumb_tl_place(tbjs_thumb_post_bl()), key_place(web_post_br(), 0, cornerrow), tbjs_thumb_tl_place(tbjs_thumb_post_tl()), key_place(web_post_bl(), 1, cornerrow), tbjs_thumb_tl_place(tbjs_thumb_post_tl()), key_place(web_post_br(), 1, cornerrow), tbjs_thumb_tl_place(tbjs_thumb_post_tr()), key_place(web_post_bl(), 2, lastrow), tbjs_thumb_tl_place(tbjs_thumb_post_tr()), key_place(web_post_bl(), 2, lastrow), tbjs_thumb_mr_place(tbjs_thumb_post_tl()), key_place(web_post_br(), 2, lastrow), key_place(web_post_bl(), 3, lastrow), tbjs_thumb_mr_place(tbjs_thumb_post_tr()), tbjs_thumb_mr_place(tbjs_thumb_post_tl()), key_place(web_post_br(), 2, lastrow), ] ) ) shape = union(hulls) return shape def tbjs_thumb_walls(skeleton=False): print('thumb_walls()') # thumb, walls shape = wall_brace( tbjs_thumb_mr_place, .5, 1, tbjs_thumb_post_tr(), (lambda sh: key_place(sh, 3, lastrow)), 0, -1, web_post_bl(), ) shape = union([shape, wall_brace( tbjs_thumb_mr_place, .5, 1, tbjs_thumb_post_tr(), tbjs_thumb_br_place, 0, -1, tbjs_thumb_post_br(), )]) shape = union([shape, wall_brace( tbjs_thumb_br_place, 0, -1, tbjs_thumb_post_br(), tbjs_thumb_br_place, 0, -1, tbjs_thumb_post_bl(), )]) shape = union([shape, wall_brace( tbjs_thumb_br_place, 0, -1, tbjs_thumb_post_bl(), tbjs_thumb_bl_place, 0, -1, tbjs_thumb_post_br(), )]) shape = union([shape, wall_brace( tbjs_thumb_bl_place, 0, -1, tbjs_thumb_post_br(), tbjs_thumb_bl_place, -1, -1, tbjs_thumb_post_bl(), )]) shape = union([shape, wall_brace( tbjs_place, -1.5, 0, tbjs_post_tl(), (lambda sh: left_key_place(sh, cornerrow, -1, side=ball_side, low_corner=True)), -1, 0, web_post(), )]) shape = union([shape, wall_brace( tbjs_place, -1.5, 0, tbjs_post_tl(), tbjs_place, -1, 0, tbjs_post_l(), )]) shape = union([shape, wall_brace( tbjs_place, -1, 0, tbjs_post_l(), tbjs_thumb_bl_place, -1, 0, tbjs_thumb_post_tl(), )]) shape = union([shape, wall_brace( tbjs_thumb_bl_place, -1, 0, tbjs_thumb_post_tl(), tbjs_thumb_bl_place, -1, -1, tbjs_thumb_post_bl(), )]) return shape def tbcj_thumb_connection(side='right', skeleton=False): # clunky bit on the top left thumb connection (normal connectors don't work well) shape = union([bottom_hull( [ left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), default_thumb_ml_place(translate(web_post_tr(), wall_locate2(-0.3, 1))), default_thumb_ml_place(translate(web_post_tr(), wall_locate3(-0.3, 1))), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), default_thumb_ml_place(translate(web_post_tr(), wall_locate2(-0.3, 1))), default_thumb_ml_place(translate(web_post_tr(), wall_locate3(-0.3, 1))), default_thumb_tl_place(web_post_tl()), ] ) ]) # ) shape = union([shape, hull_from_shapes( [ left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), default_thumb_tl_place(web_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(web_post(), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True, side=side), key_place(web_post_bl(), 0, cornerrow), default_thumb_tl_place(web_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ default_thumb_ml_place(web_post_tr()), default_thumb_ml_place(translate(web_post_tr(), wall_locate1(-0.3, 1))), default_thumb_ml_place(translate(web_post_tr(), wall_locate2(-0.3, 1))), default_thumb_ml_place(translate(web_post_tr(), wall_locate3(-0.3, 1))), default_thumb_tl_place(web_post_tl()), ] )]) return shape def tbcj_thumb_walls(skeleton=False): shape = union([wall_brace(tbcj_thumb_ml_place, -0.3, 1, web_post_tr(), tbcj_thumb_ml_place, 0, 1, web_post_tl())]) shape = union([shape, wall_brace(tbcj_thumb_bl_place, 0, 1, web_post_tr(), tbcj_thumb_bl_place, 0, 1, web_post_tl())]) shape = union([shape, wall_brace(tbcj_thumb_bl_place, -1, 0, web_post_tl(), tbcj_thumb_bl_place, -1, 0, web_post_bl())]) shape = union([shape, wall_brace(tbcj_thumb_bl_place, -1, 0, web_post_tl(), tbcj_thumb_bl_place, 0, 1, web_post_tl())]) shape = union([shape, wall_brace(tbcj_thumb_ml_place, 0, 1, web_post_tl(), tbcj_thumb_bl_place, 0, 1, web_post_tr())]) corner = box(1,1,tbcj_thickness) points = [ (tbcj_thumb_bl_place, -1, 0, web_post_bl()), (tbcj_place, 0, -1, tbcj_web_post(4)), (tbcj_place, 0, -1, tbcj_web_post(3)), (tbcj_place, 0, -1, tbcj_web_post(2)), (tbcj_place, 1, -1, tbcj_web_post(1)), (tbcj_place, 1, 0, tbcj_web_post(0)), ((lambda sh: key_place(sh, 3, lastrow)), 0, -1, web_post_bl()), ] for i,_ in enumerate(points[:-1]): (pa, dxa, dya, sa) = points[i] (pb, dxb, dyb, sb) = points[i + 1] shape = union([shape, wall_brace(pa, dxa, dya, sa, pb, dxb, dyb, sb)]) return shape def mini_thumb_walls(skeleton=False): # thumb, walls shape = union([wall_brace(mini_thumb_mr_place, 0, -1, web_post_br(), mini_thumb_tr_place, 0, -1, mini_thumb_post_br())]) shape = union([shape, wall_brace(mini_thumb_mr_place, 0, -1, web_post_br(), mini_thumb_mr_place, 0, -1, web_post_bl())]) shape = union([shape, wall_brace(mini_thumb_br_place, 0, -1, web_post_br(), mini_thumb_br_place, 0, -1, web_post_bl())]) shape = union([shape, wall_brace(mini_thumb_bl_place, 0, 1, web_post_tr(), mini_thumb_bl_place, 0, 1, web_post_tl())]) shape = union([shape, wall_brace(mini_thumb_br_place, -1, 0, web_post_tl(), mini_thumb_br_place, -1, 0, web_post_bl())]) shape = union([shape, wall_brace(mini_thumb_bl_place, -1, 0, web_post_tl(), mini_thumb_bl_place, -1, 0, web_post_bl())]) # thumb, corners shape = union([shape, wall_brace(mini_thumb_br_place, -1, 0, web_post_bl(), mini_thumb_br_place, 0, -1, web_post_bl())]) shape = union([shape, wall_brace(mini_thumb_bl_place, -1, 0, web_post_tl(), mini_thumb_bl_place, 0, 1, web_post_tl())]) # thumb, tweeners shape = union([shape, wall_brace(mini_thumb_mr_place, 0, -1, web_post_bl(), mini_thumb_br_place, 0, -1, web_post_br())]) shape = union([shape, wall_brace(mini_thumb_bl_place, -1, 0, web_post_bl(), mini_thumb_br_place, -1, 0, web_post_tl())]) shape = union([shape, wall_brace(mini_thumb_tr_place, 0, -1, mini_thumb_post_br(), (lambda sh: key_place(sh, 3, lastrow)), 0, -1, web_post_bl())]) return shape def mini_thumb_connection(side='right', skeleton=False): # clunky bit on the top left thumb connection (normal connectors don't work well) shape = union([bottom_hull( [ left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), mini_thumb_bl_place(translate(web_post_tr(), wall_locate2(-0.3, 1))), mini_thumb_bl_place(translate(web_post_tr(), wall_locate3(-0.3, 1))), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), mini_thumb_bl_place(translate(web_post_tr(), wall_locate2(-0.3, 1))), mini_thumb_bl_place(translate(web_post_tr(), wall_locate3(-0.3, 1))), mini_thumb_tl_place(web_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(web_post(), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), mini_thumb_tl_place(web_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(web_post(), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True, side=side), key_place(web_post_bl(), 0, cornerrow), mini_thumb_tl_place(web_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ mini_thumb_bl_place(web_post_tr()), mini_thumb_bl_place(translate(web_post_tr(), wall_locate1(-0.3, 1))), mini_thumb_bl_place(translate(web_post_tr(), wall_locate2(-0.3, 1))), mini_thumb_bl_place(translate(web_post_tr(), wall_locate3(-0.3, 1))), mini_thumb_tl_place(web_post_tl()), ] )]) return shape def minidox_thumb_walls(skeleton=False): # thumb, walls shape = union([wall_brace(minidox_thumb_tr_place, 0, -1, minidox_thumb_post_br(), minidox_thumb_tr_place, 0, -1, minidox_thumb_post_bl())]) shape = union([shape, wall_brace(minidox_thumb_tr_place, 0, -1, minidox_thumb_post_bl(), minidox_thumb_tl_place, 0, -1, minidox_thumb_post_br())]) shape = union([shape, wall_brace(minidox_thumb_tl_place, 0, -1, minidox_thumb_post_br(), minidox_thumb_tl_place, 0, -1, minidox_thumb_post_bl())]) shape = union([shape, wall_brace(minidox_thumb_tl_place, 0, -1, minidox_thumb_post_bl(), minidox_thumb_ml_place, -1, -1, minidox_thumb_post_br())]) shape = union([shape, wall_brace(minidox_thumb_ml_place, -1, -1, minidox_thumb_post_br(), minidox_thumb_ml_place, 0, -1, minidox_thumb_post_bl())]) shape = union([shape, wall_brace(minidox_thumb_ml_place, 0, -1, minidox_thumb_post_bl(), minidox_thumb_ml_place, -1, 0, minidox_thumb_post_bl())]) # thumb, corners shape = union([shape, wall_brace(minidox_thumb_ml_place, -1, 0, minidox_thumb_post_bl(), minidox_thumb_ml_place, -1, 0, minidox_thumb_post_tl())]) shape = union([shape, wall_brace(minidox_thumb_ml_place, -1, 0, minidox_thumb_post_tl(), minidox_thumb_ml_place, 0, 1, minidox_thumb_post_tl())]) # thumb, tweeners shape = union([shape, wall_brace(minidox_thumb_ml_place, 0, 1, minidox_thumb_post_tr(), minidox_thumb_ml_place, 0, 1, minidox_thumb_post_tl())]) shape = union([shape, wall_brace(minidox_thumb_tr_place, 0, -1, minidox_thumb_post_br(), (lambda sh: key_place(sh, 3, lastrow)), 0, -1, web_post_bl())]) return shape def minidox_thumb_connection(side='right', skeleton=False): # clunky bit on the top left thumb connection (normal connectors don't work well) shape = union([bottom_hull( [ left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), minidox_thumb_ml_place(translate(minidox_thumb_post_tr(), wall_locate2(-0.3, 1))), minidox_thumb_ml_place(translate(minidox_thumb_post_tr(), wall_locate3(-0.3, 1))), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), minidox_thumb_ml_place(translate(minidox_thumb_post_tr(), wall_locate2(-0.3, 1))), minidox_thumb_ml_place(translate(minidox_thumb_post_tr(), wall_locate3(-0.3, 1))), minidox_thumb_tl_place(minidox_thumb_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(web_post(), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), minidox_thumb_tl_place(minidox_thumb_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(web_post(), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True, side=side), key_place(web_post_bl(), 0, cornerrow), minidox_thumb_tl_place(minidox_thumb_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ minidox_thumb_ml_place(minidox_thumb_post_tr()), minidox_thumb_ml_place(translate(minidox_thumb_post_tr(), wall_locate1(0, 1))), minidox_thumb_ml_place(translate(minidox_thumb_post_tr(), wall_locate2(0, 1))), minidox_thumb_ml_place(translate(minidox_thumb_post_tr(), wall_locate3(0, 1))), minidox_thumb_tl_place(minidox_thumb_post_tl()), ] )]) return shape def carbonfet_thumb_walls(skeleton=False): # thumb, walls shape = union([wall_brace(carbonfet_thumb_mr_place, 0, -1, web_post_br(), carbonfet_thumb_tr_place, 0, -1, web_post_br())]) shape = union([shape, wall_brace(carbonfet_thumb_mr_place, 0, -1, web_post_br(), carbonfet_thumb_mr_place, 0, -1.15, web_post_bl())]) shape = union([shape, wall_brace(carbonfet_thumb_br_place, 0, -1, web_post_br(), carbonfet_thumb_br_place, 0, -1, web_post_bl())]) shape = union([shape, wall_brace(carbonfet_thumb_bl_place, -.3, 1, thumb_post_tr(), carbonfet_thumb_bl_place, 0, 1, thumb_post_tl())]) shape = union([shape, wall_brace(carbonfet_thumb_br_place, -1, 0, web_post_tl(), carbonfet_thumb_br_place, -1, 0, web_post_bl())]) shape = union([shape, wall_brace(carbonfet_thumb_bl_place, -1, 0, thumb_post_tl(), carbonfet_thumb_bl_place, -1, 0, web_post_bl())]) # thumb, corners shape = union([shape, wall_brace(carbonfet_thumb_br_place, -1, 0, web_post_bl(), carbonfet_thumb_br_place, 0, -1, web_post_bl())]) shape = union([shape, wall_brace(carbonfet_thumb_bl_place, -1, 0, thumb_post_tl(), carbonfet_thumb_bl_place, 0, 1, thumb_post_tl())]) # thumb, tweeners shape = union([shape, wall_brace(carbonfet_thumb_mr_place, 0, -1.15, web_post_bl(), carbonfet_thumb_br_place, 0, -1, web_post_br())]) shape = union([shape, wall_brace(carbonfet_thumb_bl_place, -1, 0, web_post_bl(), carbonfet_thumb_br_place, -1, 0, web_post_tl())]) shape = union([shape, wall_brace(carbonfet_thumb_tr_place, 0, -1, web_post_br(), (lambda sh: key_place(sh, 3, lastrow)), 0, -1, web_post_bl())]) return shape def carbonfet_thumb_connection(side='right', skeleton=False): # clunky bit on the top left thumb connection (normal connectors don't work well) shape = bottom_hull( [ left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), carbonfet_thumb_bl_place(translate(thumb_post_tr(), wall_locate2(-0.3, 1))), carbonfet_thumb_bl_place(translate(thumb_post_tr(), wall_locate3(-0.3, 1))), ] ) shape = union([shape, hull_from_shapes( [ left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), carbonfet_thumb_bl_place(translate(thumb_post_tr(), wall_locate2(-0.3, 1))), carbonfet_thumb_bl_place(translate(thumb_post_tr(), wall_locate3(-0.3, 1))), carbonfet_thumb_ml_place(thumb_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(web_post(), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate2(-1, 0)), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate3(-1, 0)), cornerrow, -1, low_corner=True, side=side), carbonfet_thumb_ml_place(thumb_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ left_key_place(web_post(), cornerrow, -1, low_corner=True, side=side), left_key_place(translate(web_post(), wall_locate1(-1, 0)), cornerrow, -1, low_corner=True, side=side), key_place(web_post_bl(), 0, cornerrow), carbonfet_thumb_ml_place(thumb_post_tl()), ] )]) shape = union([shape, hull_from_shapes( [ carbonfet_thumb_bl_place(thumb_post_tr()), carbonfet_thumb_bl_place(translate(thumb_post_tr(), wall_locate1(-0.3, 1))), carbonfet_thumb_bl_place(translate(thumb_post_tr(), wall_locate2(-0.3, 1))), carbonfet_thumb_bl_place(translate(thumb_post_tr(), wall_locate3(-0.3, 1))), carbonfet_thumb_ml_place(thumb_post_tl()), ] )]) return shape def case_walls(side='right', skeleton=False): print('case_walls()') return ( union([ back_wall(skeleton=skeleton), left_wall(side=side, skeleton=skeleton), right_wall(skeleton=skeleton), front_wall(skeleton=skeleton), # thumb_walls(side=side), # thumb_connection(side=side), ]) ) rj9_start = list( np.array([0, -3, 0]) + np.array( key_position( list(np.array(wall_locate3(0, 1)) + np.array([0, (mount_height / 2), 0])), 0, 0, ) ) ) rj9_position = (rj9_start[0], rj9_start[1], 11) def rj9_cube(): debugprint('rj9_cube()') shape = box(14.78, 13, 22.38) return shape def rj9_space(): debugprint('rj9_space()') return translate(rj9_cube(), rj9_position) def rj9_holder(): print('rj9_holder()') shape = union([translate(box(10.78, 9, 18.38), (0, 2, 0)), translate(box(10.78, 13, 5), (0, 0, 5))]) shape = difference(rj9_cube(), [shape]) shape = translate(shape, rj9_position) return shape usb_holder_position = key_position( list(np.array(wall_locate2(0, 1)) + np.array([0, (mount_height / 2), 0])), 1, 0 ) usb_holder_size = [6.5, 10.0, 13.6] usb_holder_thickness = 4 def usb_holder(): print('usb_holder()') shape = box( usb_holder_size[0] + usb_holder_thickness, usb_holder_size[1], usb_holder_size[2] + usb_holder_thickness, ) shape = translate(shape, ( usb_holder_position[0], usb_holder_position[1], (usb_holder_size[2] + usb_holder_thickness) / 2, ) ) return shape def usb_holder_hole(): debugprint('usb_holder_hole()') shape = box(*usb_holder_size) shape = translate(shape, ( usb_holder_position[0], usb_holder_position[1], (usb_holder_size[2] + usb_holder_thickness) / 2, ) ) return shape external_start = list( # np.array([0, -3, 0]) np.array([external_holder_width / 2, 0, 0]) + np.array( key_position( list(np.array(wall_locate3(0, 1)) + np.array([0, (mount_height / 2), 0])), 0, 0, ) ) ) def external_mount_hole(): print('external_mount_hole()') shape = box(external_holder_width, 20.0, external_holder_height+.1) undercut = box(external_holder_width+8, 10.0, external_holder_height+8+.1) shape = union([shape, translate(undercut,(0, -5, 0))]) shape = translate(shape, ( external_start[0] + external_holder_xoffset, external_start[1] + external_holder_yoffset, external_holder_height / 2-.05, ) ) return shape pcb_mount_ref_position = key_position( #TRRS POSITION IS REFERENCE BY CONVENIENCE list(np.array(wall_locate3(0, 1)) + np.array([0, (mount_height / 2), 0])), 0, 0 ) pcb_mount_ref_position[0] = pcb_mount_ref_position[0] + pcb_mount_ref_offset[0] pcb_mount_ref_position[1] = pcb_mount_ref_position[1] + pcb_mount_ref_offset[1] pcb_mount_ref_position[2] = 0.0 + pcb_mount_ref_offset[2] def pcb_usb_hole(): debugprint('pcb_holder()') pcb_usb_position = copy.deepcopy(pcb_mount_ref_position) pcb_usb_position[0] = pcb_usb_position[0] + pcb_usb_hole_offset[0] pcb_usb_position[1] = pcb_usb_position[1] + pcb_usb_hole_offset[1] pcb_usb_position[2] = pcb_usb_position[2] + pcb_usb_hole_offset[2] shape = box(*pcb_usb_hole_size) shape = translate(shape, ( pcb_usb_position[0], pcb_usb_position[1], pcb_usb_hole_size[2] / 2 + usb_holder_thickness, ) ) return shape pcb_holder_position = copy.deepcopy(pcb_mount_ref_position) pcb_holder_position[0] = pcb_holder_position[0] + pcb_holder_offset[0] pcb_holder_position[1] = pcb_holder_position[1] + pcb_holder_offset[1] pcb_holder_position[2] = pcb_holder_position[2] + pcb_holder_offset[2] pcb_holder_thickness = pcb_holder_size[2] def pcb_holder(): debugprint('pcb_holder()') shape = box(*pcb_holder_size) shape = translate(shape, ( pcb_holder_position[0], pcb_holder_position[1] - pcb_holder_size[1] / 2, pcb_holder_thickness / 2, ) ) return shape def wall_thinner(): debugprint('wall_thinner()') shape = box(*wall_thinner_size) shape = translate(shape, ( pcb_holder_position[0], pcb_holder_position[1] - wall_thinner_size[1]/2, wall_thinner_size[2]/2 + pcb_holder_thickness, ) ) return shape def trrs_hole(): debugprint('trrs_hole()') trrs_position = copy.deepcopy(pcb_mount_ref_position) trrs_position[0] = trrs_position[0] + trrs_offset[0] trrs_position[1] = trrs_position[1] + trrs_offset[1] trrs_position[2] = trrs_position[2] + trrs_offset[2] trrs_hole_size = [3, 20] shape = cylinder(*trrs_hole_size) shape = rotate(shape, [0, 90, 90]) shape = translate(shape, ( trrs_position[0], trrs_position[1], trrs_hole_size[0] + pcb_holder_thickness, ) ) return shape pcb_screw_position = copy.deepcopy(pcb_mount_ref_position) pcb_screw_position[1] = pcb_screw_position[1] + pcb_screw_y_offset def pcb_screw_hole(): debugprint('pcb_screw_hole()') holes = [] hole = cylinder(*pcb_screw_hole_size) hole = translate(hole, pcb_screw_position) hole = translate(hole, (0, 0, pcb_screw_hole_size[1]/2-.1)) for offset in pcb_screw_x_offsets: holes.append(translate(hole, (offset, 0, 0))) return holes if oled_center_row is not None: base_pt1 = key_position( list(np.array([-mount_width/2, 0, 0]) + np.array([0, (mount_height / 2), 0])), 0, oled_center_row-1 ) base_pt2 = key_position( list(np.array([-mount_width/2, 0, 0]) + np.array([0, (mount_height / 2), 0])), 0, oled_center_row+1 ) base_pt0 = key_position( list(np.array([-mount_width / 2, 0, 0]) + np.array([0, (mount_height / 2), 0])), 0, oled_center_row ) oled_mount_location_xyz = (np.array(base_pt1)+np.array(base_pt2))/2. + np.array(((-left_wall_x_offset/2), 0, 0)) + np.array(oled_translation_offset) oled_mount_location_xyz[2] = (oled_mount_location_xyz[2] + base_pt0[2])/2 angle_x = np.arctan2(base_pt1[2] - base_pt2[2], base_pt1[1] - base_pt2[1]) angle_z = np.arctan2(base_pt1[0] - base_pt2[0], base_pt1[1] - base_pt2[1]) oled_mount_rotation_xyz = (rad2deg(angle_x), 0, -rad2deg(angle_z)) + np.array(oled_rotation_offset) def generate_trackball(pos, rot): precut = trackball_cutout() precut = rotate(precut, tb_socket_rotation_offset) precut = translate(precut, tb_socket_translation_offset) precut = rotate(precut, rot) precut = translate(precut, pos) shape, cutout, sensor = trackball_socket() shape = rotate(shape, tb_socket_rotation_offset) shape = translate(shape, tb_socket_translation_offset) shape = rotate(shape, rot) shape = translate(shape, pos) cutout = rotate(cutout, tb_socket_rotation_offset) cutout = translate(cutout, tb_socket_translation_offset) # cutout = rotate(cutout, tb_sensor_translation_offset) # cutout = translate(cutout, tb_sensor_rotation_offset) cutout = rotate(cutout, rot) cutout = translate(cutout, pos) # Small adjustment due to line to line surface / minute numerical error issues # Creates small overlap to assist engines in union function later sensor = rotate(sensor, tb_socket_rotation_offset) sensor = translate(sensor, tb_socket_translation_offset) # sensor = rotate(sensor, tb_sensor_translation_offset) # sensor = translate(sensor, tb_sensor_rotation_offset) sensor = translate(sensor, (0, 0, .001)) sensor = rotate(sensor, rot) sensor = translate(sensor, pos) ball = trackball_ball() ball = rotate(ball, tb_socket_rotation_offset) ball = translate(ball, tb_socket_translation_offset) ball = rotate(ball, rot) ball = translate(ball, pos) # return precut, shape, cutout, ball return precut, shape, cutout, sensor, ball def generate_trackball_in_cluster(): if thumb_style == 'TRACKBALL_ORBYL': pos, rot = tbjs_thumb_position_rotation() elif thumb_style == 'TRACKBALL_CJ': pos, rot = tbcj_thumb_position_rotation() return generate_trackball(pos, rot) def tbiw_position_rotation(): base_pt1 = key_position( list(np.array([-mount_width/2, 0, 0]) + np.array([0, (mount_height / 2), 0])), 0, cornerrow - tbiw_ball_center_row - 1 ) base_pt2 = key_position( list(np.array([-mount_width/2, 0, 0]) + np.array([0, (mount_height / 2), 0])), 0, cornerrow - tbiw_ball_center_row + 1 ) base_pt0 = key_position( list(np.array([-mount_width / 2, 0, 0]) + np.array([0, (mount_height / 2), 0])), 0, cornerrow - tbiw_ball_center_row ) left_wall_x_offset = tbiw_left_wall_x_offset_override tbiw_mount_location_xyz = ( (np.array(base_pt1)+np.array(base_pt2))/2. + np.array(((-left_wall_x_offset/2), 0, 0)) + np.array(tbiw_translational_offset) ) # tbiw_mount_location_xyz[2] = (oled_translation_offset[2] + base_pt0[2])/2 angle_x = np.arctan2(base_pt1[2] - base_pt2[2], base_pt1[1] - base_pt2[1]) angle_z = np.arctan2(base_pt1[0] - base_pt2[0], base_pt1[1] - base_pt2[1]) tbiw_mount_rotation_xyz = (rad2deg(angle_x), 0, rad2deg(angle_z)) + np.array(tbiw_rotation_offset) return tbiw_mount_location_xyz, tbiw_mount_rotation_xyz def generate_trackball_in_wall(): pos, rot = tbiw_position_rotation() return generate_trackball(pos, rot) def oled_position_rotation(side='right'): _oled_center_row = None if trackball_in_wall and (side == ball_side or ball_side == 'both'): _oled_center_row = tbiw_oled_center_row _oled_translation_offset = tbiw_oled_translation_offset _oled_rotation_offset = tbiw_oled_rotation_offset elif oled_center_row is not None: _oled_center_row = oled_center_row _oled_translation_offset = oled_translation_offset _oled_rotation_offset = oled_rotation_offset if _oled_center_row is not None: base_pt1 = key_position( list(np.array([-mount_width/2, 0, 0]) + np.array([0, (mount_height / 2), 0])), 0, _oled_center_row-1 ) base_pt2 = key_position( list(np.array([-mount_width/2, 0, 0]) + np.array([0, (mount_height / 2), 0])), 0, _oled_center_row+1 ) base_pt0 = key_position( list(np.array([-mount_width / 2, 0, 0]) + np.array([0, (mount_height / 2), 0])), 0, _oled_center_row ) if trackball_in_wall and (side == ball_side or ball_side == 'both'): _left_wall_x_offset = tbiw_left_wall_x_offset_override else: _left_wall_x_offset = left_wall_x_offset oled_mount_location_xyz = (np.array(base_pt1)+np.array(base_pt2))/2. + np.array(((-_left_wall_x_offset/2), 0, 0)) + np.array(_oled_translation_offset) oled_mount_location_xyz[2] = (oled_mount_location_xyz[2] + base_pt0[2])/2 angle_x = np.arctan2(base_pt1[2] - base_pt2[2], base_pt1[1] - base_pt2[1]) angle_z = np.arctan2(base_pt1[0] - base_pt2[0], base_pt1[1] - base_pt2[1]) if trackball_in_wall and (side == ball_side or ball_side == 'both'): # oled_mount_rotation_xyz = (0, rad2deg(angle_x), -rad2deg(angle_z)-90) + np.array(oled_rotation_offset) # oled_mount_rotation_xyz = (rad2deg(angle_x)*.707, rad2deg(angle_x)*.707, -45) + np.array(oled_rotation_offset) oled_mount_rotation_xyz = (0, rad2deg(angle_x), -90) + np.array(_oled_rotation_offset) else: oled_mount_rotation_xyz = (rad2deg(angle_x), 0, -rad2deg(angle_z)) + np.array(_oled_rotation_offset) return oled_mount_location_xyz, oled_mount_rotation_xyz def oled_sliding_mount_frame(side='right'): mount_ext_width = oled_mount_width + 2 * oled_mount_rim mount_ext_height = ( oled_mount_height + 2 * oled_edge_overlap_end + oled_edge_overlap_connector + oled_edge_overlap_clearance + 2 * oled_mount_rim ) mount_ext_up_height = oled_mount_height + 2 * oled_mount_rim top_hole_start = -mount_ext_height / 2.0 + oled_mount_rim + oled_edge_overlap_end + oled_edge_overlap_connector top_hole_length = oled_mount_height hole = box(mount_ext_width, mount_ext_up_height, oled_mount_cut_depth + .01) hole = translate(hole, (0., top_hole_start + top_hole_length / 2, 0.)) hole_down = box(mount_ext_width, mount_ext_height, oled_mount_depth + oled_mount_cut_depth / 2) hole_down = translate(hole_down, (0., 0., -oled_mount_cut_depth / 4)) hole = union([hole, hole_down]) shape = box(mount_ext_width, mount_ext_height, oled_mount_depth) conn_hole_start = -mount_ext_height / 2.0 + oled_mount_rim conn_hole_length = ( oled_edge_overlap_end + oled_edge_overlap_connector + oled_edge_overlap_clearance + oled_thickness ) conn_hole = box(oled_mount_width, conn_hole_length + .01, oled_mount_depth) conn_hole = translate(conn_hole, ( 0, conn_hole_start + conn_hole_length / 2, -oled_edge_overlap_thickness )) end_hole_length = ( oled_edge_overlap_end + oled_edge_overlap_clearance ) end_hole_start = mount_ext_height / 2.0 - oled_mount_rim - end_hole_length end_hole = box(oled_mount_width, end_hole_length + .01, oled_mount_depth) end_hole = translate(end_hole, ( 0, end_hole_start + end_hole_length / 2, -oled_edge_overlap_thickness )) top_hole_start = -mount_ext_height / 2.0 + oled_mount_rim + oled_edge_overlap_end + oled_edge_overlap_connector top_hole_length = oled_mount_height top_hole = box(oled_mount_width, top_hole_length, oled_edge_overlap_thickness + oled_thickness - oled_edge_chamfer) top_hole = translate(top_hole, ( 0, top_hole_start + top_hole_length / 2, (oled_mount_depth - oled_edge_overlap_thickness - oled_thickness - oled_edge_chamfer) / 2.0 )) top_chamfer_1 = box( oled_mount_width, top_hole_length, 0.01 ) top_chamfer_2 = box( oled_mount_width + 2 * oled_edge_chamfer, top_hole_length + 2 * oled_edge_chamfer, 0.01 ) top_chamfer_1 = translate(top_chamfer_1, (0, 0, -oled_edge_chamfer - .05)) top_chamfer_1 = hull_from_shapes([top_chamfer_1, top_chamfer_2]) top_chamfer_1 = translate(top_chamfer_1, ( 0, top_hole_start + top_hole_length / 2, oled_mount_depth / 2.0 + .05 )) top_hole = union([top_hole, top_chamfer_1]) shape = difference(shape, [conn_hole, top_hole, end_hole]) oled_mount_location_xyz, oled_mount_rotation_xyz = oled_position_rotation(side=side) shape = rotate(shape, oled_mount_rotation_xyz) shape = translate(shape, ( oled_mount_location_xyz[0], oled_mount_location_xyz[1], oled_mount_location_xyz[2], ) ) hole = rotate(hole, oled_mount_rotation_xyz) hole = translate(hole, ( oled_mount_location_xyz[0], oled_mount_location_xyz[1], oled_mount_location_xyz[2], ) ) return hole, shape def oled_clip_mount_frame(side='right'): mount_ext_width = oled_mount_width + 2 * oled_mount_rim mount_ext_height = ( oled_mount_height + 2 * oled_clip_thickness + 2 * oled_clip_undercut + 2 * oled_clip_overhang + 2 * oled_mount_rim ) hole = box(mount_ext_width, mount_ext_height, oled_mount_cut_depth + .01) shape = box(mount_ext_width, mount_ext_height, oled_mount_depth) shape = difference(shape, [box(oled_mount_width, oled_mount_height, oled_mount_depth + .1)]) clip_slot = box( oled_clip_width + 2 * oled_clip_width_clearance, oled_mount_height + 2 * oled_clip_thickness + 2 * oled_clip_overhang, oled_mount_depth + .1 ) shape = difference(shape, [clip_slot]) clip_undercut = box( oled_clip_width + 2 * oled_clip_width_clearance, oled_mount_height + 2 * oled_clip_thickness + 2 * oled_clip_overhang + 2 * oled_clip_undercut, oled_mount_depth + .1 ) clip_undercut = translate(clip_undercut, (0., 0., oled_clip_undercut_thickness)) shape = difference(shape, [clip_undercut]) plate = box( oled_mount_width + .1, oled_mount_height - 2 * oled_mount_connector_hole, oled_mount_depth - oled_thickness ) plate = translate(plate, (0., 0., -oled_thickness / 2.0)) shape = union([shape, plate]) oled_mount_location_xyz, oled_mount_rotation_xyz = oled_position_rotation(side=side) shape = rotate(shape, oled_mount_rotation_xyz) shape = translate(shape, ( oled_mount_location_xyz[0], oled_mount_location_xyz[1], oled_mount_location_xyz[2], ) ) hole = rotate(hole, oled_mount_rotation_xyz) hole = translate(hole, ( oled_mount_location_xyz[0], oled_mount_location_xyz[1], oled_mount_location_xyz[2], ) ) return hole, shape def oled_clip(): mount_ext_width = oled_mount_width + 2 * oled_mount_rim mount_ext_height = ( oled_mount_height + 2 * oled_clip_thickness + 2 * oled_clip_overhang + 2 * oled_clip_undercut + 2 * oled_mount_rim ) oled_leg_depth = oled_mount_depth + oled_clip_z_gap shape = box(mount_ext_width - .1, mount_ext_height - .1, oled_mount_bezel_thickness) shape = translate(shape, (0., 0., oled_mount_bezel_thickness / 2.)) hole_1 = box( oled_screen_width + 2 * oled_mount_bezel_chamfer, oled_screen_length + 2 * oled_mount_bezel_chamfer, .01 ) hole_2 = box(oled_screen_width, oled_screen_length, 2.05 * oled_mount_bezel_thickness) hole = hull_from_shapes([hole_1, hole_2]) shape = difference(shape, [translate(hole, (0., 0., oled_mount_bezel_thickness))]) clip_leg = box(oled_clip_width, oled_clip_thickness, oled_leg_depth) clip_leg = translate(clip_leg, ( 0., 0., # (oled_mount_height+2*oled_clip_overhang+oled_clip_thickness)/2, -oled_leg_depth / 2. )) latch_1 = box( oled_clip_width, oled_clip_overhang + oled_clip_thickness, .01 ) latch_2 = box( oled_clip_width, oled_clip_thickness / 2, oled_clip_extension ) latch_2 = translate(latch_2, ( 0., -(-oled_clip_thickness / 2 + oled_clip_thickness + oled_clip_overhang) / 2, -oled_clip_extension / 2 )) latch = hull_from_shapes([latch_1, latch_2]) latch = translate(latch, ( 0., oled_clip_overhang / 2, -oled_leg_depth )) clip_leg = union([clip_leg, latch]) clip_leg = translate(clip_leg, ( 0., (oled_mount_height + 2 * oled_clip_overhang + oled_clip_thickness) / 2 - oled_clip_y_gap, 0. )) shape = union([shape, clip_leg, mirror(clip_leg, 'XZ')]) return shape def oled_undercut_mount_frame(side='right'): mount_ext_width = oled_mount_width + 2 * oled_mount_rim mount_ext_height = oled_mount_height + 2 * oled_mount_rim hole = box(mount_ext_width, mount_ext_height, oled_mount_cut_depth + .01) shape = box(mount_ext_width, mount_ext_height, oled_mount_depth) shape = difference(shape, [box(oled_mount_width, oled_mount_height, oled_mount_depth + .1)]) undercut = box( oled_mount_width + 2 * oled_mount_undercut, oled_mount_height + 2 * oled_mount_undercut, oled_mount_depth) undercut = translate(undercut, (0., 0., -oled_mount_undercut_thickness)) shape = difference(shape, [undercut]) oled_mount_location_xyz, oled_mount_rotation_xyz = oled_position_rotation(side=side) shape = rotate(shape, oled_mount_rotation_xyz) shape = translate(shape, ( oled_mount_location_xyz[0], oled_mount_location_xyz[1], oled_mount_location_xyz[2], ) ) hole = rotate(hole, oled_mount_rotation_xyz) hole = translate(hole, ( oled_mount_location_xyz[0], oled_mount_location_xyz[1], oled_mount_location_xyz[2], ) ) return hole, shape def teensy_holder(): print('teensy_holder()') teensy_top_xy = key_position(wall_locate3(-1, 0), 0, centerrow - 1) teensy_bot_xy = key_position(wall_locate3(-1, 0), 0, centerrow + 1) teensy_holder_length = teensy_top_xy[1] - teensy_bot_xy[1] teensy_holder_offset = -teensy_holder_length / 2 teensy_holder_top_offset = (teensy_holder_top_length / 2) - teensy_holder_length s1 = box(3, teensy_holder_length, 6 + teensy_width) s1 = translate(s1, [1.5, teensy_holder_offset, 0]) s2 = box(teensy_pcb_thickness, teensy_holder_length, 3) s2 = translate(s2, ( (teensy_pcb_thickness / 2) + 3, teensy_holder_offset, -1.5 - (teensy_width / 2), ) ) s3 = box(teensy_pcb_thickness, teensy_holder_top_length, 3) s3 = translate(s3, [ (teensy_pcb_thickness / 2) + 3, teensy_holder_top_offset, 1.5 + (teensy_width / 2), ] ) s4 = box(4, teensy_holder_top_length, 4) s4 = translate(s4, [teensy_pcb_thickness + 5, teensy_holder_top_offset, 1 + (teensy_width / 2)] ) shape = union((s1, s2, s3, s4)) shape = translate(shape, [-teensy_holder_width, 0, 0]) shape = translate(shape, [-1.4, 0, 0]) shape = translate(shape, [teensy_top_xy[0], teensy_top_xy[1] - 1, (6 + teensy_width) / 2] ) return shape def screw_insert_shape(bottom_radius, top_radius, height): debugprint('screw_insert_shape()') if bottom_radius == top_radius: base = cylinder(radius=bottom_radius, height=height) else: base = translate(cone(r1=bottom_radius, r2=top_radius, height=height), (0, 0, -height / 2)) shape = union(( base, translate(sphere(top_radius), (0, 0, height / 2)), )) return shape def screw_insert(column, row, bottom_radius, top_radius, height, side='right'): debugprint('screw_insert()') shift_right = column == lastcol shift_left = column == 0 shift_up = (not (shift_right or shift_left)) and (row == 0) shift_down = (not (shift_right or shift_left)) and (row >= lastrow) if screws_offset == 'INSIDE': # debugprint('Shift Inside') shift_left_adjust = wall_base_x_thickness shift_right_adjust = -wall_base_x_thickness/2 shift_down_adjust = -wall_base_y_thickness/2 shift_up_adjust = -wall_base_y_thickness/3 elif screws_offset == 'OUTSIDE': debugprint('Shift Outside') shift_left_adjust = 0 shift_right_adjust = wall_base_x_thickness/2 shift_down_adjust = wall_base_y_thickness*2/3 shift_up_adjust = wall_base_y_thickness*2/3 else: # debugprint('Shift Origin') shift_left_adjust = 0 shift_right_adjust = 0 shift_down_adjust = 0 shift_up_adjust = 0 if shift_up: position = key_position( list(np.array(wall_locate2(0, 1)) + np.array([0, (mount_height / 2) + shift_up_adjust, 0])), column, row, ) elif shift_down: position = key_position( list(np.array(wall_locate2(0, -1)) - np.array([0, (mount_height / 2) + shift_down_adjust, 0])), column, row, ) elif shift_left: position = list( np.array(left_key_position(row, 0, side=side)) + np.array(wall_locate3(-1, 0)) + np.array((shift_left_adjust,0,0)) ) else: position = key_position( list(np.array(wall_locate2(1, 0)) + np.array([(mount_height / 2), 0, 0]) + np.array((shift_right_adjust,0,0)) ), column, row, ) shape = screw_insert_shape(bottom_radius, top_radius, height) shape = translate(shape, [position[0], position[1], height / 2]) return shape def thumb_screw_insert(bottom_radius, top_radius, height, offset=None, side='right'): shape = screw_insert_shape(bottom_radius, top_radius, height) shapes = [] if offset is None: offset = 0.0 origin = thumborigin() if ('TRACKBALL' in thumb_style) and not (side == ball_side or ball_side == 'both'): _thumb_style = other_thumb else: _thumb_style = thumb_style if _thumb_style == 'MINI': if separable_thumb: xypositions = copy.deepcopy(mini_separable_thumb_screw_xy_locations) else: xypositions = copy.deepcopy(mini_thumb_screw_xy_locations) elif _thumb_style == 'MINIDOX': if separable_thumb: xypositions = copy.deepcopy(minidox_separable_thumb_screw_xy_locations) else: xypositions = copy.deepcopy(minidox_thumb_screw_xy_locations) xypositions[0][1] = xypositions[0][1] - .4 * (minidox_Usize - 1) * sa_length elif _thumb_style == 'CARBONFET': if separable_thumb: xypositions = copy.deepcopy(carbonfet_separable_thumb_screw_xy_locations) else: xypositions = copy.deepcopy(carbonfet_thumb_screw_xy_locations) elif _thumb_style == 'TRACKBALL_ORBYL': if separable_thumb: xypositions = copy.deepcopy(orbyl_separable_thumb_screw_xy_locations) else: xypositions = copy.deepcopy(orbyl_thumb_screw_xy_locations) elif _thumb_style == 'TRACKBALL_CJ': if separable_thumb: xypositions = copy.deepcopy(tbcj_separable_thumb_screw_xy_locations) else: xypositions = copy.deepcopy(tbcj_thumb_screw_xy_locations) else: if separable_thumb: xypositions = copy.deepcopy(default_separable_thumb_screw_xy_locations) else: xypositions = copy.deepcopy(default_thumb_screw_xy_locations) for xyposition in xypositions: position = list(np.array(origin) + np.array([*xyposition, -origin[2]])) shapes.append(translate(shape, [position[0], position[1], height / 2 + offset])) return shapes def screw_insert_all_shapes(bottom_radius, top_radius, height, offset=0, side='right'): print('screw_insert_all_shapes()') shape = ( translate(screw_insert(0, 0, bottom_radius, top_radius, height, side=side), (0, 0, offset)), translate(screw_insert(0, cornerrow, bottom_radius, top_radius, height, side=side), (0, left_wall_lower_y_offset, offset)), translate(screw_insert(3, lastrow, bottom_radius, top_radius, height, side=side), (0, 0, offset)), translate(screw_insert(3, 0, bottom_radius, top_radius, height, side=side), (0,0, offset)), translate(screw_insert(lastcol, 0, bottom_radius, top_radius, height, side=side), (0, 0, offset)), translate(screw_insert(lastcol, cornerrow, bottom_radius, top_radius, height, side=side), (0, 0, offset)), # translate(screw_insert_thumb(bottom_radius, top_radius, height), (0, 0, offset)), ) return shape def thumb_screw_insert_holes(side='right'): return thumb_screw_insert( screw_insert_bottom_radius, screw_insert_top_radius, screw_insert_height+.02, offset=-.01, side=side ) def thumb_screw_insert_outers(offset=0.0, side='right'): # screw_insert_bottom_radius + screw_insert_wall # screw_insert_top_radius + screw_insert_wall bottom_radius = screw_insert_outer_radius top_radius = screw_insert_outer_radius height = screw_insert_height + 1.5 return thumb_screw_insert(bottom_radius, top_radius, height, offset=offset, side=side) def screw_insert_holes(side='right'): return screw_insert_all_shapes( screw_insert_bottom_radius, screw_insert_top_radius, screw_insert_height+.02, offset=-.01, side=side ) def screw_insert_outers(offset=0.0, side='right'): # screw_insert_bottom_radius + screw_insert_wall # screw_insert_top_radius + screw_insert_wall bottom_radius = screw_insert_outer_radius top_radius = screw_insert_outer_radius height = screw_insert_height + 1.5 return screw_insert_all_shapes(bottom_radius, top_radius, height, offset=offset, side=side) def screw_insert_screw_holes(side='right'): return screw_insert_all_shapes(1.7, 1.7, 350, side=side) def wire_post(direction, offset): debugprint('wire_post()') s1 = box( wire_post_diameter, wire_post_diameter, wire_post_height ) s1 = translate(s1, [0, -wire_post_diameter * 0.5 * direction, 0]) s2 = box( wire_post_diameter, wire_post_overhang, wire_post_diameter ) s2 = translate(s2, [0, -wire_post_overhang * 0.5 * direction, -wire_post_height / 2] ) shape = union((s1, s2)) shape = translate(shape, [0, -offset, (-wire_post_height / 2) + 3]) shape = rotate(shape, [-alpha / 2, 0, 0]) shape = translate(shape, (3, -mount_height / 2, 0)) return shape def wire_posts(): debugprint('wire_posts()') shape = default_thumb_ml_place(wire_post(1, 0).translate([-5, 0, -2])) shape = union([shape, default_thumb_ml_place(wire_post(-1, 6).translate([0, 0, -2.5]))]) shape = union([shape, default_thumb_ml_place(wire_post(1, 0).translate([5, 0, -2]))]) for column in range(lastcol): for row in range(cornerrow): shape = union([ shape, key_place(wire_post(1, 0).translate([-5, 0, 0]), column, row), key_place(wire_post(-1, 6).translate([0, 0, 0]), column, row), key_place(wire_post(1, 0).translate([5, 0, 0]), column, row), ]) return shape def model_side(side="right"): print('model_right()') #shape = add([key_holes(side=side)]) shape = union([key_holes(side=side)]) if debug_exports: export_file(shape=shape, fname=path.join(r"..", "things", r"debug_key_plates")) connector_shape = connectors() shape = union([shape, connector_shape]) if debug_exports: export_file(shape=shape, fname=path.join(r"..", "things", r"debug_connector_shape")) walls_shape = case_walls(side=side, skeleton=skeletal) if debug_exports: export_file(shape=walls_shape, fname=path.join(r"..", "things", r"debug_walls_shape")) s2 = union([walls_shape]) s2 = union([s2, *screw_insert_outers(side=side)]) if controller_mount_type in ['RJ9_USB_TEENSY', 'USB_TEENSY']: s2 = union([s2, teensy_holder()]) if controller_mount_type in ['RJ9_USB_TEENSY', 'RJ9_USB_WALL', 'USB_WALL', 'USB_TEENSY']: s2 = union([s2, usb_holder()]) s2 = difference(s2, [usb_holder_hole()]) if controller_mount_type in ['RJ9_USB_TEENSY', 'RJ9_USB_WALL']: s2 = difference(s2, [rj9_space()]) if controller_mount_type in ['EXTERNAL']: s2 = difference(s2, [external_mount_hole()]) if controller_mount_type in ['PCB_MOUNT']: s2 = difference(s2, [pcb_usb_hole()]) s2 = difference(s2, [trrs_hole()]) s2 = union([s2, pcb_holder()]) s2 = difference(s2, [wall_thinner()]) s2 = difference(s2, pcb_screw_hole()) if controller_mount_type in [None, 'None']: 0 # do nothing, only here to expressly state inaction. s2 = difference(s2, [union(screw_insert_holes(side=side))]) shape = union([shape, s2]) if controller_mount_type in ['RJ9_USB_TEENSY', 'RJ9_USB_WALL']: shape = union([shape, rj9_holder()]) if oled_mount_type == "UNDERCUT": hole, frame = oled_undercut_mount_frame(side=side) shape = difference(shape, [hole]) shape = union([shape, frame]) elif oled_mount_type == "SLIDING": hole, frame = oled_sliding_mount_frame(side=side) shape = difference(shape, [hole]) shape = union([shape, frame]) elif oled_mount_type == "CLIP": hole, frame = oled_clip_mount_frame(side=side) shape = difference(shape, [hole]) shape = union([shape, frame]) if trackball_in_wall and (side == ball_side or ball_side == 'both') and separable_thumb: tbprecut, tb, tbcutout, sensor, ball = generate_trackball_in_wall() shape = difference(shape, [tbprecut]) # export_file(shape=shape, fname=path.join(save_path, config_name + r"_test_1")) shape = union([shape, tb]) # export_file(shape=shape, fname=path.join(save_path, config_name + r"_test_2")) shape = difference(shape, [tbcutout]) # export_file(shape=shape, fname=path.join(save_path, config_name + r"_test_3a")) # export_file(shape=add([shape, sensor]), fname=path.join(save_path, config_name + r"_test_3b")) shape = union([shape, sensor]) if show_caps: shape = add([shape, ball]) if plate_pcb_clear: shape = difference(shape, [plate_pcb_cutouts(side=side)]) main_shape = shape #BUILD THUMB thumb_shape = thumb(side=side) if debug_exports: export_file(shape=thumb_shape, fname=path.join(r"..", "things", r"debug_thumb_shape")) thumb_connector_shape = thumb_connectors(side=side) if debug_exports: export_file(shape=thumb_connector_shape, fname=path.join(r"..", "things", r"debug_thumb_connector_shape")) thumb_wall_shape = thumb_walls(side=side, skeleton=skeletal) thumb_wall_shape = union([thumb_wall_shape, *thumb_screw_insert_outers(side=side)]) thumb_connection_shape = thumb_connection(side=side, skeleton=skeletal) if debug_exports: thumb_test = union([thumb_shape, thumb_connector_shape, thumb_wall_shape, thumb_connection_shape]) export_file(shape=thumb_test, fname=path.join(r"..", "things", r"debug_thumb_test_{}_shape".format(side))) thumb_section = union([thumb_shape, thumb_connector_shape, thumb_wall_shape, thumb_connection_shape]) thumb_section = difference(thumb_section, [union(thumb_screw_insert_holes(side=side))]) has_trackball = False if ('TRACKBALL' in thumb_style) and (side == ball_side or ball_side == 'both'): print("Has Trackball") tbprecut, tb, tbcutout, sensor, ball = generate_trackball_in_cluster() has_trackball = True thumb_section = difference(thumb_section, [tbprecut]) if debug_exports: export_file(shape=thumb_section, fname=path.join(r"..", "things", r"debug_thumb_test_1_shape".format(side))) thumb_section = union([thumb_section, tb]) if debug_exports: export_file(shape=thumb_section, fname=path.join(r"..", "things", r"debug_thumb_test_2_shape".format(side))) thumb_section = difference(thumb_section, [tbcutout]) if debug_exports: export_file(shape=thumb_section, fname=path.join(r"..", "things", r"debug_thumb_test_3_shape".format(side))) thumb_section = union([thumb_section, sensor]) if debug_exports: export_file(shape=thumb_section, fname=path.join(r"..", "things", r"debug_thumb_test_4_shape".format(side))) if plate_pcb_clear: thumb_section = difference(thumb_section, [thumb_pcb_plate_cutouts(side=side)]) block = box(350, 350, 40) block = translate(block, (0, 0, -20)) main_shape = difference(main_shape, [block]) thumb_section = difference(thumb_section, [block]) if debug_exports: export_file(shape=thumb_section, fname=path.join(r"..", "things", r"debug_thumb_test_5_shape".format(side))) if separable_thumb: thumb_section = difference(thumb_section, [main_shape]) if show_caps: thumb_section = add([thumb_section, thumbcaps(side=side)]) if has_trackball: thumb_section = add([thumb_section, ball]) else: main_shape = union([main_shape, thumb_section]) if debug_exports: export_file(shape=main_shape, fname=path.join(r"..", "things", r"debug_thumb_test_6_shape".format(side))) if show_caps: main_shape = add([main_shape, thumbcaps(side=side)]) if has_trackball: main_shape = add([main_shape, ball]) if trackball_in_wall and (side == ball_side or ball_side == 'both') and not separable_thumb: tbprecut, tb, tbcutout, sensor, ball = generate_trackball_in_wall() main_shape = difference(main_shape, [tbprecut]) # export_file(shape=shape, fname=path.join(save_path, config_name + r"_test_1")) main_shape = union([main_shape, tb]) # export_file(shape=shape, fname=path.join(save_path, config_name + r"_test_2")) main_shape = difference(main_shape, [tbcutout]) # export_file(shape=shape, fname=path.join(save_path, config_name + r"_test_3a")) # export_file(shape=add([shape, sensor]), fname=path.join(save_path, config_name + r"_test_3b")) main_shape = union([main_shape, sensor]) if show_caps: main_shape = add([main_shape, ball]) if show_caps: main_shape = add([main_shape, caps()]) if side == "left": main_shape = mirror(main_shape, 'YZ') thumb_section = mirror(thumb_section, 'YZ') return main_shape, thumb_section # NEEDS TO BE SPECIAL FOR CADQUERY #def baseplate(main_shape, base_shape, wedge_angle=None, side='right'): def baseplate(wedge_angle=None, side='right'): if ENGINE == 'cadquery': # shape = mod_r thumb_shape = thumb(side=side) thumb_wall_shape = thumb_walls(side=side, skeleton=skeletal) thumb_wall_shape = union([thumb_wall_shape, *thumb_screw_insert_outers(side=side)]) thumb_connector_shape = thumb_connectors(side=side) thumb_connection_shape = thumb_connection(side=side, skeleton=skeletal) thumb_section = union([thumb_shape, thumb_connector_shape, thumb_wall_shape, thumb_connection_shape]) thumb_section = difference(thumb_section, [union(thumb_screw_insert_holes(side=side))]) shape = union([ case_walls(side=side), *screw_insert_outers(side=side), thumb_section ]) tool = screw_insert_all_shapes(screw_hole_diameter/2., screw_hole_diameter/2., 350, side=side) for item in tool: item = translate(item, [0, 0, -10]) shape = difference(shape, [item]) tool = thumb_screw_insert(screw_hole_diameter/2., screw_hole_diameter/2., 350, side=side) for item in tool: item = translate(item, [0, 0, -10]) shape = difference(shape, [item]) #shape = union([main_shape, thumb_shape]) shape = translate(shape, (0, 0, -0.0001)) square = cq.Workplane('XY').rect(1000, 1000) for wire in square.wires().objects: plane = cq.Workplane('XY').add(cq.Face.makeFromWires(wire)) shape = intersect(shape, plane) outside = shape.vertices(cq.DirectionMinMaxSelector(cq.Vector(1, 0, 0), True)).objects[0] sizes = [] max_val = 0 inner_index = 0 base_wires = shape.wires().objects for i_wire, wire in enumerate(base_wires): is_outside = False for vert in wire.Vertices(): if vert.toTuple() == outside.toTuple(): outer_wire = wire outer_index = i_wire is_outside = True sizes.append(0) if not is_outside: sizes.append(len(wire.Vertices())) if sizes[-1]>max_val: inner_index = i_wire max_val = sizes[-1] debugprint(sizes) inner_wire = base_wires[inner_index] # inner_plate = cq.Workplane('XY').add(cq.Face.makeFromWires(inner_wire)) if wedge_angle is not None: cq.Workplane('XY').add(cq.Solid.revolve(outerWire, innerWires, angleDegrees, axisStart, axisEnd)) else: inner_shape = cq.Workplane('XY').add(cq.Solid.extrudeLinear(outerWire=inner_wire, innerWires=[], vecNormal=cq.Vector(0, 0, base_thickness))) inner_shape = translate(inner_shape, (0, 0, -base_rim_thickness)) holes = [] for i in range(len(base_wires)): if i not in [inner_index, outer_index]: holes.append(base_wires[i]) cutout = [*holes, inner_wire] shape = cq.Workplane('XY').add(cq.Solid.extrudeLinear(outer_wire, cutout, cq.Vector(0, 0, base_rim_thickness))) hole_shapes=[] for hole in holes: loc = hole.Center() hole_shapes.append( translate( cylinder(screw_cbore_diameter/2.0, screw_cbore_depth), (loc.x, loc.y, 0) # (loc.x, loc.y, screw_cbore_depth/2) ) ) shape = difference(shape, hole_shapes) shape = translate(shape, (0, 0, -base_rim_thickness)) shape = union([shape, inner_shape]) return shape else: shape = union([ case_walls(side=side), *screw_insert_outers(side=side), thumb_walls(side=side), *thumb_screw_insert_outers(side=side), ]) tool = translate(union(screw_insert_screw_holes(side=side)), [0, 0, -10]) base = box(1000, 1000, .01) shape = shape - tool shape = intersect(shape, base) shape = translate(shape, [0, 0, -0.001]) return sl.projection(cut=True)(shape) def run(): mod_r, tmb_r = model_side(side="right") export_file(shape=mod_r, fname=path.join(save_path, config_name + r"_right")) export_file(shape=tmb_r, fname=path.join(save_path, config_name + r"_thumb_right")) #base = baseplate(mod_r, tmb_r, side='right') base = baseplate(side='right') export_file(shape=base, fname=path.join(save_path, config_name + r"_right_plate")) export_dxf(shape=base, fname=path.join(save_path, config_name + r"_right_plate")) if symmetry == "asymmetric": mod_l, tmb_l = model_side(side="left") export_file(shape=mod_l, fname=path.join(save_path, config_name + r"_left")) export_file(shape=tmb_l, fname=path.join(save_path, config_name + r"_thumb_left")) #base_l = mirror(baseplate(mod_l, tmb_l, side='left'), 'YZ') base_l = mirror(baseplate(side='left'), 'YZ') export_file(shape=base_l, fname=path.join(save_path, config_name + r"_left_plate")) export_dxf(shape=base_l, fname=path.join(save_path, config_name + r"_left_plate")) else: export_file(shape=mirror(mod_r, 'YZ'), fname=path.join(save_path, config_name + r"_left")) lbase = mirror(base, 'YZ') export_file(shape=lbase, fname=path.join(save_path, config_name + r"_left_plate")) export_dxf(shape=lbase, fname=path.join(save_path, config_name + r"_left_plate")) if oled_mount_type == 'UNDERCUT': export_file(shape=oled_undercut_mount_frame()[1], fname=path.join(save_path, config_name + r"_oled_undercut_test")) if oled_mount_type == 'SLIDING': export_file(shape=oled_sliding_mount_frame()[1], fname=path.join(save_path, config_name + r"_oled_sliding_test")) if oled_mount_type == 'CLIP': oled_mount_location_xyz = (0.0, 0.0, -oled_mount_depth / 2) oled_mount_rotation_xyz = (0.0, 0.0, 0.0) export_file(shape=oled_clip(), fname=path.join(save_path, config_name + r"_oled_clip")) export_file(shape=oled_clip_mount_frame()[1], fname=path.join(save_path, config_name + r"_oled_clip_test")) export_file(shape=union((oled_clip_mount_frame()[1], oled_clip())), fname=path.join(save_path, config_name + r"_oled_clip_assy_test")) # base = baseplate() # export_file(shape=base, fname=path.join(save_path, config_name + r"_plate")) if __name__ == '__main__': run()