254 lines
8.1 KiB
Python
254 lines
8.1 KiB
Python
import tempfile
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import pathlib
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import os
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import subprocess
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import PIL.Image
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import math
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def tiles_to_equirectangular_blender(back, right, front, left, top, bottom,
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rx=0, ry=0, rz=0, tmp=None, height=1920, width=3840, keep=False):
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'''
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Use Blender to convert the images into an equirectangular format. This
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requires both Blender and cube2sphere to be installed and in $PATH.
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Will create a temporary directory to store files in if no working directory
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is passed (tmp). The function will return a PIL.Image object containing the
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final equirectangular image.
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:param back: PIL.Image containing the "back" part of the cube map
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:param right: PIL.Image containing the "right" part of the cube map
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:param front: PIL.Image containing the "front" part of the cube map
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:param left: PIL.Image containting the "left" part of the cube map
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:param top: PIL.Image containing the "top" part of the cube map
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:param bottom: PIL.Image containing the "bottom" part of the cube map
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:param rx: Rotation in degrees (integer) to apply on the x axis
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:param ry: Rotation in degrees (integer) to apply on the y axis
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:param rz: Rotation in degrees (integer) to apply on the z axis
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:param tmp: Temporary directory to use. Will create one if None is passed
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:param height: Target height of the output image
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:param width: Target width of the output image
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:param keep: Will not clean up temporary directory if True
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:return: PIL.Image object containing the equirectangular image
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'''
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tmpdir = tempfile.TemporaryDirectory()
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if tmp and not keep:
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tmpdir.name = tmp
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if not tmp:
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tmp = tmpdir.name
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'''Blender needs actual files rather than PIL objects, so create a folder
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for those.'''
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try:
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pathlib.Path(tmp).mkdir(parents=True, exist_ok=True)
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except:
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print("Failed to create temporary directory.")
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print(tmp)
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raise
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'''If no resolution is passed, assume the original resolution for output.'''
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if not height and not width:
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height = height or left.size[0] * 2
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width = width or left.size[0] * 4
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'''Move to temporary directory and create files for Blender to work with.'''
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pre = os.getcwd()
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os.chdir(tmp)
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left.save("left.png")
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front.save("front.png")
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right.save("right.png")
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back.save("back.png")
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bottom.save("bottom.png")
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top.save("top.png")
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try:
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process = subprocess.Popen(
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['cube2sphere',
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'front.png',
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'back.png',
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'right.png',
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'left.png',
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'top.png',
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'bottom.png',
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'-R', str(rx), str(ry), str(rz), # rotation on x/y/z axes
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'-o', 'out',
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'-f', 'png',
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"-r", str(width), str(height)]
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)
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process.wait()
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outimg = PIL.Image.open("%s/out0001.png" % tmp) # Read new image to PIL
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os.chdir(pre) # Move back to previous working directory
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if not keep:
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tmpdir.cleanup() # Delete temporary directory to free space
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except:
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os.chdir(pre)
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print("Something went wrong trying to convert to equirectangular.")
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raise
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def tiles_to_equirectangular(back, right, front, left, top, bottom):
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'''
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Use Blender to convert the images into an equirectangular format. This does
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not require Blender to be installed, instead using a custom algorithm. This
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is not tested thoroughly and will probably not work at this point.
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The function will return a PIL.Image object containing the final
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equirectangular image.
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:param back: PIL.Image containing the "back" part of the cube map
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:param right: PIL.Image containing the "right" part of the cube map
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:param front: PIL.Image containing the "front" part of the cube map
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:param left: PIL.Image containting the "left" part of the cube map
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:param top: PIL.Image containing the "top" part of the cube map
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:param bottom: PIL.Image containing the "bottom" part of the cube map
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:return: PIL.Image object containing the equirectangular image
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'''
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dim = left.size[0]
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raw = []
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t_width = dim * 4
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t_height = dim * 2
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for y in range(t_height):
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v = 1.0 - (float(y) / t_height)
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phi = v * math.pi
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for x in range(t_width):
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u = float(x) / t_width
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theta = u * math.pi * 2
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x = math.cos(theta) * math.sin(phi)
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y = math.sin(theta) * math.sin(phi)
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z = math.cos(phi)
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a = max(abs(x), abs(y), abs(z))
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xx = x / a
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yy = y / a
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zz = z / a
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if yy == -1:
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currx = int(((-1 * math.tan(math.atan(x / y)) + 1.0) / 2.0) * dim)
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ystore = int(((-1 * math.tan(math.atan(z / y)) + 1.0) / 2.0) * (dim - 1))
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part = left
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elif xx == 1:
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currx = int(((math.tan(math.atan(y / x)) + 1.0) / 2.0) * dim)
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ystore = int(((math.tan(math.atan(z / x)) + 1.0) / 2.0) * dim)
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part = front
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elif yy == 1:
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currx = int(((-1 * math.tan(math.atan(x / y)) + 1.0) / 2.0) * dim)
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ystore = int(((math.tan(math.atan(z / y)) + 1.0) / 2.0) * (dim - 1))
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part = right
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elif xx == -1:
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currx = int(((math.tan(math.atan(y / x)) + 1.0) / 2.0) * dim)
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ystore = int(((-1 * math.tan(math.atan(z / x)) + 1.0) / 2.0) * (dim - 1))
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part = back
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elif zz == 1:
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currx = int(((math.tan(math.atan(y / z)) + 1.0) / 2.0) * dim)
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ystore = int(((-1 * math.tan(math.atan(x / z)) + 1.0) / 2.0) * (dim - 1))
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part = bottom
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else:
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currx = int(((-1 * math.tan(math.atan(y / z)) + 1.0) / 2.0) * dim)
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ystore = int(((-1 * math.tan(math.atan(x / z)) + 1.0) / 2.0) * (dim - 1))
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part = top
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curry = (dim - 1) if ystore > (dim - 1) else ystore
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if curry > (dim - 1):
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curry = dim - 1
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if currx > (dim - 1):
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currx = dim - 1
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raw.append(part.getpixel((currx, curry)))
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output = PIL.Image.new("RGB", (t_width, t_height))
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output.putdata(raw)
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return output
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def multistitch(tiles):
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'''
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Takes a list of lists of lists containing PIL Image objects and stitches
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them into one. Each box tile (first-order lists), line (second-order) and
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column (third-order) must be equal in height and width.
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:param faces: list of lists of lists containing PIL.Image objects
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:return: list of stitched PIL.Image objects
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'''
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output = []
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for tile in tiles:
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output.append(stitch(tile))
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return output
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def stitch(images):
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'''
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Takes a list of lists containing PIL Image objects and stitches them into
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one. Each line (first-order lists) and column (second-order) must be equal
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in height and width.
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:param images: list of lists containing PIL.Image objects
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:return: stitched PIL.Image object
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'''
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t_height = 0 # Total height of resulting image
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t_width = 0 # Total width of resulting image
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'''Calculate height of final image by adding up heights of the first images
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of each row.'''
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for row in images:
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w, h = row[0].size
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t_height += h
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'''Calculate width of final image by adding up widths of the images in the
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first row.'''
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for image in images[0]:
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w, h = image.size
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t_width += w
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'''Generate output Image object using calculated height and width.'''
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output = PIL.Image.new("RGB", (t_width, t_height))
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curry = 0 # Current y position (top = 0)
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for row in images:
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currx = 0 # Current x position (left = 0)
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y_offset = 0 # How far down we have to go for the next line
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for image in row:
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'''Paste line of images into the output image.'''
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output.paste(im=image, box=(currx, curry))
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w, h = image.size
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currx += w
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if not y_offset:
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y_offset = h
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curry += y_offset
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return output
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