2016-12-23 03:42:21 +00:00
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import argparse
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import math
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import PIL.Image
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import PIL.ImageDraw
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import sys
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def choose_guideline_style(guideline_mod):
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if guideline_mod % 16 == 0:
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return ('#1f32ff', 3)
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if guideline_mod % 8 == 0:
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return ('#80f783', 2)
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if guideline_mod % 4 == 0:
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return ('#f4bffb', 1)
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2017-11-19 19:01:41 +00:00
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def in_ellipsoid(x, y, z, rad_x, rad_y, rad_z, center_x=None, center_y=None, center_z=None):
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'''
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Given a point (x, y, z), return whether that point lies inside the
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ellipsoid defined by (x/a)^2 + (y/b)^2 + (z/c)^2 = 1
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'''
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if center_x is None: center_x = rad_x
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if center_y is None: center_y = rad_y
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if center_z is None: center_z = rad_z
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#print(x, y, z, rad_x, rad_y, rad_z, center_x, center_y, center_z)
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x = ((x - center_x) / rad_x) ** 2
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y = ((y - center_y) / rad_y) ** 2
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z = ((z - center_z) / rad_z) ** 2
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distance = x + y + z
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#print(distance)
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return distance < 1
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def voxelspheregenerator(WIDTH, HEIGH, DEPTH, WALL_THICKNESS=None, specific=None):
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2016-12-23 03:42:21 +00:00
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ODD_W = WIDTH % 2 == 1
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ODD_H = HEIGH % 2 == 1
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ODD_D = DEPTH % 2 == 1
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RAD_X = WIDTH / 2
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RAD_Y = HEIGH / 2
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RAD_Z = DEPTH / 2
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if WALL_THICKNESS:
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INNER_RAD_X = RAD_X - WALL_THICKNESS
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INNER_RAD_Y = RAD_Y - WALL_THICKNESS
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INNER_RAD_Z = RAD_Z - WALL_THICKNESS
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X_CENTER = {WIDTH // 2} if ODD_W else {WIDTH // 2, (WIDTH // 2) - 1}
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Y_CENTER = {HEIGH // 2} if ODD_H else {HEIGH // 2, (HEIGH // 2) - 1}
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Z_CENTER = {DEPTH // 2} if ODD_D else {DEPTH // 2, (DEPTH // 2) - 1}
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layer_digits = len(str(DEPTH))
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filename_form = '{w}x{h}x{d}w{wall}-{{layer:0{digits}}}.png'
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filename_form = filename_form.format(
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w=WIDTH,
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h=HEIGH,
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d=DEPTH,
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wall=WALL_THICKNESS if WALL_THICKNESS else 0,
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digits=layer_digits,
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)
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dot_highlight = PIL.Image.open('dot_highlight.png')
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dot_normal = PIL.Image.open('dot_normal.png')
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dot_corner = PIL.Image.open('dot_corner.png')
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pixel_scale = dot_highlight.size[0]
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# Space between each pixel
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PIXEL_MARGIN = 7
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# Space between the pixel area and the canvas
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2017-11-19 19:01:41 +00:00
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PIXELSPACE_MARGIN = 2
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2016-12-23 03:42:21 +00:00
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# Space between the canvas area and the image edge
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2017-11-19 19:01:41 +00:00
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CANVAS_MARGIN = 2
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2016-12-23 03:42:21 +00:00
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LABEL_HEIGH = 20
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FINAL_IMAGE_SCALE = 1
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PIXELSPACE_WIDTH = (WIDTH * pixel_scale) + ((WIDTH - 1) * PIXEL_MARGIN)
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PIXELSPACE_HEIGH = (HEIGH * pixel_scale) + ((HEIGH - 1) * PIXEL_MARGIN)
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2017-11-19 19:01:41 +00:00
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CANVAS_WIDTH = PIXELSPACE_WIDTH + (2 * PIXELSPACE_MARGIN * pixel_scale)
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CANVAS_HEIGH = PIXELSPACE_HEIGH + (2 * PIXELSPACE_MARGIN * pixel_scale)
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2016-12-23 03:42:21 +00:00
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2017-11-19 19:01:41 +00:00
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IMAGE_WIDTH = CANVAS_WIDTH + (2 * CANVAS_MARGIN * pixel_scale)
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IMAGE_HEIGH = CANVAS_HEIGH + (2 * CANVAS_MARGIN * pixel_scale) + LABEL_HEIGH
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2016-12-23 03:42:21 +00:00
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2017-11-19 19:01:41 +00:00
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CANVAS_START_X = CANVAS_MARGIN * pixel_scale
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CANVAS_START_Y = CANVAS_MARGIN * pixel_scale
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2016-12-23 03:42:21 +00:00
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CANVAS_END_X = CANVAS_START_X + CANVAS_WIDTH
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CANVAS_END_Y = CANVAS_START_Y + CANVAS_HEIGH
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2017-11-19 19:01:41 +00:00
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PIXELSPACE_START_X = CANVAS_START_X + (PIXELSPACE_MARGIN * pixel_scale)
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PIXELSPACE_START_Y = CANVAS_START_Y + (PIXELSPACE_MARGIN * pixel_scale)
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2016-12-23 03:42:21 +00:00
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PIXELSPACE_END_X = PIXELSPACE_START_X + PIXELSPACE_WIDTH
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PIXELSPACE_END_Y = PIXELSPACE_START_Y + PIXELSPACE_HEIGH
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GUIDELINE_MOD_X = math.ceil(RAD_X)
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GUIDELINE_MOD_Y = math.ceil(RAD_Y)
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def pixel_coord(x, y):
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x = PIXELSPACE_START_X + (x * pixel_scale) + (x * PIXEL_MARGIN)
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y = PIXELSPACE_START_Y + (y * pixel_scale) + (y * PIXEL_MARGIN)
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return (x, y)
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def make_layer_matrix(z):
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layer_matrix = [[None for y in range(math.ceil(RAD_Y))] for x in range(math.ceil(RAD_X))]
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# Generate the upper left corner.
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furthest_x = RAD_X
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furthest_y = RAD_Y
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for y in range(math.ceil(RAD_Y)):
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for x in range(math.ceil(RAD_X)):
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ux = x + 0.5
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uy = y + 0.5
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uz = z + 0.5
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within = in_ellipsoid(ux, uy, uz, RAD_X, RAD_Y, RAD_Z)
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if WALL_THICKNESS:
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in_hole = in_ellipsoid(
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ux, uy, uz,
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INNER_RAD_X, INNER_RAD_Y, INNER_RAD_Z,
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RAD_X, RAD_Y, RAD_Z
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)
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within = within and not in_hole
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if within:
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if x in X_CENTER or y in Y_CENTER:
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if z in Z_CENTER:
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dot = dot_normal
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else:
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dot = dot_highlight
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else:
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if z in Z_CENTER:
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dot = dot_highlight
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else:
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dot = dot_normal
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layer_matrix[x][y] = dot
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furthest_x = min(x, furthest_x)
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furthest_y = min(y, furthest_y)
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#layer_image.paste(dot, box=(pixel_coord_x, pixel_coord_y))
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# Mark the corner pieces
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2019-06-12 05:29:25 +00:00
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furthest_y = math.floor(furthest_y)
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2016-12-23 03:42:21 +00:00
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for y in range(furthest_y, math.ceil(RAD_Y-1)):
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for x in range(furthest_x, math.ceil(RAD_X-1)):
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is_corner = (
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layer_matrix[x][y] is not None and
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layer_matrix[x-1][y+1] is not None and
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layer_matrix[x+1][y-1] is not None and
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(
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# Outer corners
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(layer_matrix[x][y-1] is None and layer_matrix[x-1][y] is None) or
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# Inner corners, if hollow
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(layer_matrix[x][y+1] is None and layer_matrix[x+1][y] is None)
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)
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)
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if is_corner:
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layer_matrix[x][y] = dot_corner
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return layer_matrix
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def make_layer_image(layer_matrix):
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layer_image = PIL.Image.new('RGBA', size=(IMAGE_WIDTH, IMAGE_HEIGH), color=(0, 0, 0, 0))
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draw = PIL.ImageDraw.ImageDraw(layer_image)
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# Plot.
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2017-11-19 19:01:41 +00:00
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LABEL_Y = (2 * math.ceil(RAD_Y))
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2016-12-23 03:42:21 +00:00
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for y in range(math.ceil(RAD_Y)):
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2017-11-19 19:01:41 +00:00
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bottom_y = (HEIGH - 1) - y
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2016-12-23 03:42:21 +00:00
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for x in range(math.ceil(RAD_X)):
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right_x = (WIDTH - 1) - x
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if layer_matrix[x][y] is not None:
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layer_image.paste(layer_matrix[x][y], box=pixel_coord(x, y))
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layer_image.paste(layer_matrix[x][y], box=pixel_coord(right_x, y))
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layer_image.paste(layer_matrix[x][y], box=pixel_coord(x, bottom_y))
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layer_image.paste(layer_matrix[x][y], box=pixel_coord(right_x, bottom_y))
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2017-11-19 19:01:41 +00:00
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# Draw the counting helpers along the bottom.
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# Start at the center top of the circle and walk along the edge.
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# Every time the walker 'falls' down, mark the distance.
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def put_counterhelper(start_x, end_x, y):
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2019-06-12 05:29:25 +00:00
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if start_x > end_x:
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2017-11-19 19:01:41 +00:00
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return
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y = (HEIGH + 1) - y
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span = end_x - start_x
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center = start_x + 1
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draw.text(pixel_coord(center, y), str(span), fill='#000')
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y = 0
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x = math.floor(RAD_X) - 1
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end_x = x
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start_y = None
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while x >= y and y < RAD_Y:
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2019-06-12 05:29:25 +00:00
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#print(x, y, start_y)
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2017-11-19 19:01:41 +00:00
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pixel = layer_matrix[x][y]
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if pixel is None:
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y += 1
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if x != end_x:
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put_counterhelper(x, end_x, y)
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if start_y is None:
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start_y = y
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else:
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put_counterhelper(x, end_x, start_y)
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end_x = x
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continue
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x -= 1
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y += 1
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put_counterhelper(x, end_x, y)
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2016-12-23 03:42:21 +00:00
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# To draw the guidelines, start from
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for x in range(GUIDELINE_MOD_X % 4, WIDTH + 4, 4):
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# Vertical guideline
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as_if = GUIDELINE_MOD_X - x
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#print(x, as_if)
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line_x = PIXELSPACE_START_X + (x * pixel_scale) + (x * PIXEL_MARGIN)
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line_x = line_x - PIXEL_MARGIN + (PIXEL_MARGIN // 2)
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if line_x >= PIXELSPACE_END_X:
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continue
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(color, width) = choose_guideline_style(as_if)
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draw.line((line_x, CANVAS_START_Y, line_x, CANVAS_END_Y - 1), fill=color, width=width)
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draw.text((line_x, CANVAS_END_X), str(x), fill='#000')
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for y in range(GUIDELINE_MOD_Y % 4, HEIGH + 4, 4):
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# Horizontal guideline
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as_if = GUIDELINE_MOD_Y - y
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#print(y, as_if)
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line_y = PIXELSPACE_START_Y + (y * pixel_scale) + (y * PIXEL_MARGIN)
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line_y = line_y - PIXEL_MARGIN + (PIXEL_MARGIN // 2)
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if line_y >= PIXELSPACE_END_Y:
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continue
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(color, width) = choose_guideline_style(as_if)
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draw.line((CANVAS_START_X, line_y, CANVAS_END_X - 1, line_y), fill=color, width=width)
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draw.text((CANVAS_END_X, line_y), str(y), fill='#000')
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draw.rectangle((CANVAS_START_X, CANVAS_START_Y, CANVAS_END_X - 1, CANVAS_END_Y - 1), outline='#000')
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draw.text((CANVAS_START_X, IMAGE_HEIGH - LABEL_HEIGH), layer_filename, fill='#000')
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print(layer_filename)
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if FINAL_IMAGE_SCALE != 1:
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layer_image = layer_image.resize((FINAL_IMAGE_SCALE * IMAGE_WIDTH, FINAL_IMAGE_SCALE * IMAGE_HEIGH))
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return layer_image
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2017-11-19 19:01:41 +00:00
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if specific is None:
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zrange = range(DEPTH)
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elif isinstance(specific, int):
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zrange = [specific]
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else:
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zrange = specific
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2016-12-23 03:42:21 +00:00
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layer_matrices = []
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2017-11-19 19:01:41 +00:00
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for z in zrange:
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2016-12-23 03:42:21 +00:00
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if z < math.ceil(RAD_Z):
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layer_matrix = make_layer_matrix(z)
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layer_matrices.append(layer_matrix)
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else:
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layer_matrix = layer_matrices[(DEPTH - 1) - z]
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layer_filename = filename_form.format(layer=z)
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layer_image = make_layer_image(layer_matrix)
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layer_image.save(layer_filename)
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def voxelsphere_argparse(args):
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height_depth_match = bool(args.height) == bool(args.depth)
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if not height_depth_match:
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raise ValueError('Must provide both or neither of height+depth. Not just one.')
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if (args.height is args.depth is None):
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args.height = args.width
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args.depth = args.width
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2017-11-19 19:01:41 +00:00
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wall_thickness = int(args.wall_thickness) if args.wall_thickness else None
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specific = int(args.specific) if args.specific else None
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2016-12-23 03:42:21 +00:00
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voxelspheregenerator(
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2017-11-19 19:01:41 +00:00
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WIDTH=int(args.width),
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HEIGH=int(args.height),
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DEPTH=int(args.depth),
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WALL_THICKNESS=wall_thickness,
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specific=specific,
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2016-12-23 03:42:21 +00:00
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)
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def main(argv):
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parser = argparse.ArgumentParser()
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parser.add_argument('width')
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parser.add_argument('height', nargs='?', default=None)
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parser.add_argument('depth', nargs='?', default=None)
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parser.add_argument('--wall', dest='wall_thickness', default=None)
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2017-11-19 19:01:41 +00:00
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parser.add_argument('--specific', dest='specific', default=None)
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2016-12-23 03:42:21 +00:00
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parser.set_defaults(func=voxelsphere_argparse)
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args = parser.parse_args(argv)
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args.func(args)
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if __name__ == '__main__':
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main(sys.argv[1:])
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