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https://github.com/pmret/papermario.git
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ae66312d8c
* Add Python linter to github actions * wip * Add back splat_ext * Format files * C++ -> C * format 2 files * split workflow into separate file, line length 120, fix excludes * -l 120 in ci * update black locally and apply formatting changes * pyproject.toject --------- Co-authored-by: Ethan Roseman <ethteck@gmail.com>
265 lines
9.3 KiB
Python
Executable File
265 lines
9.3 KiB
Python
Executable File
#!/usr/bin/env python3
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from sys import argv, stderr
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from math import floor, ceil
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from glob import glob
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import png # type: ignore
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def unpack_color(s):
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r = (s >> 11) & 0x1F
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g = (s >> 6) & 0x1F
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b = (s >> 1) & 0x1F
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a = (s & 1) * 0xFF
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r = ceil(0xFF * (r / 31))
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g = ceil(0xFF * (g / 31))
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b = ceil(0xFF * (b / 31))
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return r, g, b, a
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def pack_color(r, g, b, a):
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r = r >> 3
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g = g >> 3
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b = b >> 3
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a = a >> 7
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return (r << 11) | (g << 6) | (b << 1) | a
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def rgb_to_intensity(r, g, b):
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return round(r * 0.2126 + g * 0.7152 + 0.0722 * b)
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def iter_in_groups(iterable, n, fillvalue=None):
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from itertools import zip_longest
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args = [iter(iterable)] * n
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return zip_longest(*args, fillvalue=fillvalue)
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def reversed_if(iterator, cond):
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if cond:
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return reversed(list(iterator))
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else:
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return iterator
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class Converter:
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def __init__(self, mode, infile, flip_x: bool = False, flip_y: bool = False):
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self.mode = mode
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self.infile = infile
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self.flip_x = flip_x
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self.flip_y = flip_y
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assert self.flip_x == False, "flip_x is not supported"
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self.warned = False
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def warn(self, msg):
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if not self.warned:
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self.warned = True
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print(self.infile + ": warning: " + msg, file=stderr)
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def convert(self):
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out_bytes = bytearray()
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out_width = 0
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out_height = 0
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img = png.Reader(self.infile)
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if self.mode == "rgba32":
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(out_width, out_height, data, info) = img.asRGBA()
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for row in reversed_if(data, self.flip_y):
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out_bytes += row
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elif self.mode == "rgba16":
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(out_width, out_height, data, info) = img.asRGBA()
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for row in reversed_if(data, self.flip_y):
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for rgba in iter_in_groups(row, 4):
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if rgba[3] not in (0, 0xFF):
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self.warn("alpha mask mode but translucent pixels used")
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color = pack_color(*rgba)
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out_bytes += color.to_bytes(2, byteorder="big")
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elif self.mode == "ci8":
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(out_width, out_height, data, info) = img.read()
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for row in reversed_if(data, self.flip_y):
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out_bytes += row
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elif self.mode == "ci4":
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(out_width, out_height, data, info) = img.read()
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for row in reversed_if(data, self.flip_y):
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for a, b in iter_in_groups(row, 2):
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byte = (a << 4) | b
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byte = byte & 0xFF
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out_bytes += byte.to_bytes(1, byteorder="big")
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elif self.mode == "palette":
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img.preamble(True)
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palette = img.palette(alpha="force")
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for rgba in palette:
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if rgba[3] not in (0, 0xFF):
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self.warn("alpha mask mode but translucent pixels used")
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color = pack_color(*rgba)
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out_bytes += color.to_bytes(2, byteorder="big")
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elif self.mode == "ia4":
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(out_width, out_height, data, info) = img.asRGBA()
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for row in reversed_if(data, self.flip_y):
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for c1, c2 in iter_in_groups(iter_in_groups(row, 4), 2):
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i1 = rgb_to_intensity(*c1[:3])
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a1 = c1[3]
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i2 = rgb_to_intensity(*c2[:3])
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a2 = c2[3]
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i1 = i1 >> 5
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i2 = i2 >> 5
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if a1 not in (0, 0xFF) or a2 not in (0, 0xFF):
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self.warn("alpha mask mode but translucent pixels used")
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if c1[0] != c1[1] != c1[2]:
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self.warn("grayscale mode but image is not")
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if c2[0] != c2[1] != c2[2]:
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self.warn("grayscale mode but image is not")
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a1 = 1 if a1 > 128 else 0
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a2 = 1 if a2 > 128 else 0
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h = (i1 << 1) | a1
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l = (i2 << 1) | a2
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byte = (h << 4) | l
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out_bytes += byte.to_bytes(1, byteorder="big")
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elif self.mode == "ia8":
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(out_width, out_height, data, info) = img.asRGBA()
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for row in reversed_if(data, self.flip_y):
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for rgba in iter_in_groups(row, 4):
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i = rgb_to_intensity(*rgba[:3])
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a = rgba[3]
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i = floor(15 * (i / 0xFF))
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a = floor(15 * (a / 0xFF))
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if rgba[0] != rgba[1] != rgba[2]:
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self.warn("grayscale mode but image is not")
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byte = (i << 4) | a
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out_bytes += byte.to_bytes(1, byteorder="big")
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elif self.mode == "ia16":
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(out_width, out_height, data, info) = img.asRGBA()
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for row in reversed_if(data, self.flip_y):
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for rgba in iter_in_groups(row, 4):
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i = rgb_to_intensity(*rgba[:3])
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a = rgba[3]
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if rgba[0] != rgba[1] != rgba[2]:
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self.warn("grayscale mode but image is not")
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out_bytes += bytes((i, a))
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elif self.mode == "i4":
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(out_width, out_height, data, info) = img.asRGBA()
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for row in reversed_if(data, self.flip_y):
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for c1, c2 in iter_in_groups(iter_in_groups(row, 4), 2):
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if c1[3] != 0xFF or c2[3] != 0xFF:
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self.warn("discarding alpha channel")
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i1 = rgb_to_intensity(*c1[:3])
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i2 = rgb_to_intensity(*c2[:3])
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i1 = floor(15 * (i1 / 0xFF))
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i2 = floor(15 * (i2 / 0xFF))
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if c1[0] != c1[1] != c1[2]:
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self.warn("grayscale mode but image is not")
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if c2[0] != c2[1] != c2[2]:
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self.warn("grayscale mode but image is not")
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byte = (i1 << 4) | i2
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out_bytes += byte.to_bytes(1, byteorder="big")
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elif self.mode == "i8":
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(out_width, out_height, data, info) = img.asRGBA()
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for row in reversed_if(data, self.flip_y):
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for rgba in iter_in_groups(row, 4):
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if rgba[3] != 0xFF or rgba[3] != 0xFF:
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self.warn("discarding alpha channel")
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if rgba[0] != rgba[1] != rgba[2]:
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self.warn("grayscale mode but image is not")
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i = rgb_to_intensity(*rgba[:3])
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out_bytes += i.to_bytes(1, byteorder="big")
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elif self.mode == "party":
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(out_width, out_height, data, info) = img.read()
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img.preamble(True)
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palette = img.palette(alpha="force")
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# palette
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for rgba in palette:
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if rgba[3] not in (0, 0xFF):
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self.warn("alpha mask mode but translucent pixels used")
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color = pack_color(*rgba)
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out_bytes += color.to_bytes(2, byteorder="big")
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# ci 8
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for row in reversed_if(data, self.flip_y):
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out_bytes += row
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out_bytes += b"\0\0\0\0\0\0\0\0\0\0" # padding
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elif self.mode == "bg":
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(out_width, out_height, data, info) = img.read()
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img.preamble(True)
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palettes = [img.palette(alpha="force")]
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for palettepath in glob(self.infile.split(".")[0] + ".*.png"):
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pal = png.Reader(palettepath)
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pal.preamble(True)
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palettes.append(pal.palette(alpha="force"))
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baseaddr = 0x80200000 # gBackgroundImage
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headers_len = 0x10 * len(palettes)
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palettes_len = 0x200 * len(palettes)
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# header (struct BackgroundHeader)
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for i, palette in enumerate(palettes):
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out_bytes += (baseaddr + palettes_len + headers_len).to_bytes(4, byteorder="big") # raster offset
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out_bytes += (baseaddr + headers_len + 0x200 * i).to_bytes(4, byteorder="big") # palette offset
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out_bytes += (12).to_bytes(2, byteorder="big") # startX
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out_bytes += (20).to_bytes(2, byteorder="big") # startY
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out_bytes += (out_width).to_bytes(2, byteorder="big") # width
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out_bytes += (out_height).to_bytes(2, byteorder="big") # height
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for palette in palettes:
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# palette
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for rgba in palette:
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if rgba[3] not in (0, 0xFF):
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self.warn("alpha mask mode but translucent pixels used")
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color = pack_color(*rgba)
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out_bytes += color.to_bytes(2, byteorder="big")
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# ci 8
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for row in reversed_if(data, self.flip_y):
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out_bytes += row
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else:
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print("unsupported mode", file=stderr)
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exit(1)
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return (out_bytes, out_width, out_height)
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if __name__ == "__main__":
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if len(argv) < 4:
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print("usage: build.py MODE INFILE OUTFILE [--flip-x] [--flip-y]")
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exit(1)
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mode = argv[1]
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infile = argv[2]
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outfile = argv[3]
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flip_x = "--flip-x" in argv
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flip_y = "--flip-y" in argv
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(out_bytes, out_width, out_height) = Converter(mode, infile, flip_x, flip_y).convert()
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with open(argv[3], "wb") as f:
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f.write(out_bytes)
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