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160 lines
5.7 KiB
Python
160 lines
5.7 KiB
Python
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"""
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The RGB color model is an additive color model in which red, green, and blue light
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are added together in various ways to reproduce a broad array of colors. The name
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of the model comes from the initials of the three additive primary colors, red,
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green, and blue. Meanwhile, the HSV representation models how colors appear under
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light. In it, colors are represented using three components: hue, saturation and
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(brightness-)value. This file provides functions for converting colors from one
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representation to the other.
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(description adapted from https://en.wikipedia.org/wiki/RGB_color_model and
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https://en.wikipedia.org/wiki/HSL_and_HSV).
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"""
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def hsv_to_rgb(hue: float, saturation: float, value: float) -> list[int]:
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"""
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Conversion from the HSV-representation to the RGB-representation.
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Expected RGB-values taken from
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https://www.rapidtables.com/convert/color/hsv-to-rgb.html
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>>> hsv_to_rgb(0, 0, 0)
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[0, 0, 0]
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>>> hsv_to_rgb(0, 0, 1)
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[255, 255, 255]
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>>> hsv_to_rgb(0, 1, 1)
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[255, 0, 0]
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>>> hsv_to_rgb(60, 1, 1)
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[255, 255, 0]
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>>> hsv_to_rgb(120, 1, 1)
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[0, 255, 0]
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>>> hsv_to_rgb(240, 1, 1)
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[0, 0, 255]
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>>> hsv_to_rgb(300, 1, 1)
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[255, 0, 255]
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>>> hsv_to_rgb(180, 0.5, 0.5)
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[64, 128, 128]
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>>> hsv_to_rgb(234, 0.14, 0.88)
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[193, 196, 224]
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>>> hsv_to_rgb(330, 0.75, 0.5)
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[128, 32, 80]
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"""
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if hue < 0 or hue > 360:
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raise Exception("hue should be between 0 and 360")
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if saturation < 0 or saturation > 1:
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raise Exception("saturation should be between 0 and 1")
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if value < 0 or value > 1:
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raise Exception("value should be between 0 and 1")
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chroma = value * saturation
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hue_section = hue / 60
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second_largest_component = chroma * (1 - abs(hue_section % 2 - 1))
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match_value = value - chroma
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if hue_section >= 0 and hue_section <= 1:
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red = round(255 * (chroma + match_value))
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green = round(255 * (second_largest_component + match_value))
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blue = round(255 * (match_value))
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elif hue_section > 1 and hue_section <= 2:
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red = round(255 * (second_largest_component + match_value))
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green = round(255 * (chroma + match_value))
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blue = round(255 * (match_value))
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elif hue_section > 2 and hue_section <= 3:
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red = round(255 * (match_value))
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green = round(255 * (chroma + match_value))
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blue = round(255 * (second_largest_component + match_value))
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elif hue_section > 3 and hue_section <= 4:
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red = round(255 * (match_value))
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green = round(255 * (second_largest_component + match_value))
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blue = round(255 * (chroma + match_value))
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elif hue_section > 4 and hue_section <= 5:
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red = round(255 * (second_largest_component + match_value))
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green = round(255 * (match_value))
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blue = round(255 * (chroma + match_value))
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else:
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red = round(255 * (chroma + match_value))
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green = round(255 * (match_value))
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blue = round(255 * (second_largest_component + match_value))
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return [red, green, blue]
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def rgb_to_hsv(red: int, green: int, blue: int) -> list[float]:
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"""
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Conversion from the RGB-representation to the HSV-representation.
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The tested values are the reverse values from the hsv_to_rgb-doctests.
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Function "approximately_equal_hsv" is needed because of small deviations due to
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rounding for the RGB-values.
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>>> approximately_equal_hsv(rgb_to_hsv(0, 0, 0), [0, 0, 0])
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True
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>>> approximately_equal_hsv(rgb_to_hsv(255, 255, 255), [0, 0, 1])
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True
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>>> approximately_equal_hsv(rgb_to_hsv(255, 0, 0), [0, 1, 1])
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True
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>>> approximately_equal_hsv(rgb_to_hsv(255, 255, 0), [60, 1, 1])
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True
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>>> approximately_equal_hsv(rgb_to_hsv(0, 255, 0), [120, 1, 1])
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True
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>>> approximately_equal_hsv(rgb_to_hsv(0, 0, 255), [240, 1, 1])
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True
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>>> approximately_equal_hsv(rgb_to_hsv(255, 0, 255), [300, 1, 1])
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True
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>>> approximately_equal_hsv(rgb_to_hsv(64, 128, 128), [180, 0.5, 0.5])
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True
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>>> approximately_equal_hsv(rgb_to_hsv(193, 196, 224), [234, 0.14, 0.88])
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True
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>>> approximately_equal_hsv(rgb_to_hsv(128, 32, 80), [330, 0.75, 0.5])
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True
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"""
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if red < 0 or red > 255:
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raise Exception("red should be between 0 and 255")
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if green < 0 or green > 255:
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raise Exception("green should be between 0 and 255")
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if blue < 0 or blue > 255:
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raise Exception("blue should be between 0 and 255")
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float_red = red / 255
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float_green = green / 255
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float_blue = blue / 255
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value = max(max(float_red, float_green), float_blue)
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chroma = value - min(min(float_red, float_green), float_blue)
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saturation = 0 if value == 0 else chroma / value
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if chroma == 0:
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hue = 0.0
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elif value == float_red:
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hue = 60 * (0 + (float_green - float_blue) / chroma)
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elif value == float_green:
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hue = 60 * (2 + (float_blue - float_red) / chroma)
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else:
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hue = 60 * (4 + (float_red - float_green) / chroma)
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hue = (hue + 360) % 360
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return [hue, saturation, value]
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def approximately_equal_hsv(hsv_1: list[float], hsv_2: list[float]) -> bool:
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"""
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Utility-function to check that two hsv-colors are approximately equal
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>>> approximately_equal_hsv([0, 0, 0], [0, 0, 0])
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True
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>>> approximately_equal_hsv([180, 0.5, 0.3], [179.9999, 0.500001, 0.30001])
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True
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>>> approximately_equal_hsv([0, 0, 0], [1, 0, 0])
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False
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>>> approximately_equal_hsv([180, 0.5, 0.3], [179.9999, 0.6, 0.30001])
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False
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"""
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check_hue = abs(hsv_1[0] - hsv_2[0]) < 0.2
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check_saturation = abs(hsv_1[1] - hsv_2[1]) < 0.002
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check_value = abs(hsv_1[2] - hsv_2[2]) < 0.002
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return check_hue and check_saturation and check_value
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