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Description:

acrylic 0.3.1

Have you ever wanted a simple and intuitive way to work with colors in python? Then this library is for you! acrylic is a python package that you can use to manage colors, convert between different color formats, and work with color schemes and palettes.
Currently supported color formats are:
rgb, hsl, hsv, ryb, hex, name
Small example:
from acrylic import Color, RANDOM

# Define a color using rgb values
orange = Color(rgb=[247, 177, 79])

# Use saturation from that color to create a new random color with hsv
random_color = Color(hsv=[RANDOM, orange.hsv.s, 98])

# Print the random color's value in hex
print(random_color.hex) # Output: '#50FAF0'

check out more examples
below.
acrylic also has support for color
schemes, support for more
color schemes and functions to generate color palettes will be added in the
future.
complementary = cyan.scheme(Schemes.COMPLEMENTARY)
shades = cyan.scheme(Schemes.SHADES)
color_palette = [cyan, *complementary, *shades]

More about color schemes here
How to Install
acrylic can be installed using pip:
pip install acrylic

It has no dependencies and works with Python >=3.6
Documentation
Defining Colors
You can create a new color like this:
from acrylic import Color
cyan = Color(rgb=[83, 237, 229])

The same syntax can be used to give input in any of the supported color formats. Currently supported formats are rgb, hsv, hsl, hex and ryb. Example:
color = Color(rgb=[127, 255, 212])
color = Color(hsl=[160, 100, 75])
color = Color(hsv=[160, 50, 100])
color = Color(hex='#7fffd4')
color = Color(name='aquamarine')
color = Color(ryb=[0, 77, 128])

All values for rgb and ryb should be between 0 - 255
The value of hue for hsv and hsl should be between 0.0 - 360.0 and the other two components should be between 0.0 - 100.0.
Values for hex should be a string representing 6-digit hex number
Values for name should be a string representing a valid CSS3 color name

Converting between color formats
Any instance of Color() is automatically converted to every supported color format when its created, so there is no need to manually convert from one format to another. For any color, no matter how it was created, you can get its value in any format like this:
cyan = Color(rgb=[83, 237, 229])
print(cyan.rgb)
print(cyan.hsv)
print(cyan.hsl)
print(cyan.hex)
print(cyan.name)
print(cyan.ryb)

This makes converting from say rgb to hsl as easy as doing:
hsl_values = Color(rgb=[83, 237, 229]).hsl

Accessing values of colors
When accessing these attributes for a color, it returns the values back as a namedtuple instance. This behaves exactly as a normal tuple would, but has an added benefit that its values can be accessed directly via the dot notation. Example:
>>> cyan = Color(rgb=[83, 237, 229])
>>> cyan.rgb # returns a namedtuple containing the values
Rgb(r=83, g=237, b=229)
>>> [x for x in cyan.rgb] # can be iterated over like a normal tuple
[83, 237, 229]
>>> cyan.rgb[1] # items can be accessed via index
237
>>> r, g, b = cyan.rgb # items can be unpacked
>>> cyan.rgb.r, cyan.rgb.g # items can also be accessed via their name
(83, 237)

Additional ways to define a color
In addition to the default way to create a color, Color() offers additional methods that would enhance your ability to create colors.
For example, to create a random color:
from acrylic import Color, RANDOM
random_color = Color(rgb=RANDOM)

Creating a color with a random hue, but fixed saturation and value:
random_hue = Color(hsv=[RANDOM, 65, 95])

(for aesthetically pleasing random colors, check example 2 below)
Any of the components can be given as a list of 2 values like [a, b] instead of a single value. When given a range, a value a <= value <= b will randomly be picked for that component. For example to create a cyan color where saturation is randomly picked between 30 to 70:
random_cyan = Color(hsv=[176, (30, 70), 95])

Giving both values for a range isn't required, you can use this to just set the upper or lower limit by setting the other half to RANDOM:
random_cyan = Color(hsv=[176, (RANDOM, 70), 95])
random_cyan = Color(hsv=[176, (30, RANDOM), 95])

Note: Immutability and Hashibility

All instances of colors are immutable, meaning their values can't be changed once they are defined. This means that each instance of Color() represents a specific color and will always represent that color. If you feel the need to modify a color, this can easily be done as:
old_color = Color(rgb=[83, 237, 229])
# change hue, but not saturation or value
new_color = Color(hsv=[230, old_color.hsv.s, old_color.hsv.v])

All instances of colors are also hashable. They can be safely used as keys for dict()s and can be added to set() to efficiently find unique colors or to test membership.
>>> colors = {Color(hex='#7fffd4'): 'Can be used in dict() keys!'}
>>> Color(name='aquamarine') in colors
True
>>> colors[Color(rgb=[127, 255, 212])]
'Can be used in dict() keys!'

As a result of colors being immutable and hashable, colors that represent the same RGB values will always be unambiguously equal to each other. This prevents a lot of bugs that can randomly appear when working with float hsv/hsl values and removes the inconsistencies in the conversion algorithm that converts between rgb and hsv/hsl. An example that demonstrates this:
>>> Color(hsl=[236.94, 9.29, 84.54]) == Color(hsl=[240.0, 8.86, 84.51])
True

This results in True because both of these hsl values map to the same rgb value (212, 212, 219) and thus represent the same color.

Color schemes
The Color() class also provides some convenience functions to work with color schemes. In the future, these would also be used to build color palettes. For now, the corresponding colors from a color scheme for a specific color can be generated like this:
from acrylic import Color, Schemes
cyan = Color(rgb=[83, 237, 229])

complementary_color = cyan.scheme(Schemes.COMPLEMENTARY)
cyan_triads = cyan.scheme(Schemes.TRIADIC)
cyan_shades = cyan.scheme(Schemes.SHADES)

Taking inspiration from traditional art where most of these color schemes originated from, these are calculated using the ryb(red-yellow-blue) color wheel by default. To use the rgb(red-green-blue) color wheel instead you can pass in_rgb=True to the .scheme() function.
For a list of all the available color schemes and their explanations, check this page.
Example Usecases

Create a color using RGB, use its saturation to create a new color, and print its value as a hex string:
orange = Color(rgb=[247, 177, 79])
cyan = Color(hsv=[176.5, orange.hsv.s, 98])
print(cyan.hex) # Output: '#50FAF0'

Generating random aesthetically pleasing colors, which for example can be used to color the default profile pictures for users of an app
def aesthetic_color():
return Color(hsl=[RANDOM, (65, RANDOM), (60, 75)])

(If you have ever tried generating random colors by randomizing rgb values, you would know how badly that works)

Finding unique colors:
test_set = set([
Color(rgb=[61, 245, 245]), Color(hex='#3DF5F5'),
Color(hsl=[180, 89.8, 60]), Color(hsl=[179.8, 90.2, 60.1])
])
print(test_set) # Output: {Color(rgb=(61, 245, 245))}

The set contains only one color as all those colors map to the same rgb values.

Sorting all the pixels in an image horizontally by hue:
from acrylic import Color
from PIL import Image

orignal_image = Image.open('test.jpg')
sorted_img = orignal_image.copy()
pixels = orignal_image.load()

for y in range(sorted_image.height):
row = [Color(rgb=pixels[n, y]) for n in range(sorted_image.width)]
sorted_row = sorted(row, key=lambda c: c.hsl.h)
for x, c in enumerate(sorted_row):
sorted_image.putpixel((x, y), c.rgb)

This example also illustrates how easy it is to integrate acrylic with other libraries and seamlessly switch between rgb and hsl

Contributions
All contributions to acrylic are welcome and appreciated! Ways in which you can contribute are:

Report an issue (here)
Raise a pull request (here)
Request new features
Spread the word about acrylic!

License
MIT License: Copyright (c) 2020 - 2022 Arsh
License.txt