Colour
Converts and manipulates common color representation (RGB, HSL, web, ...)
Feature
- Damn simple and pythonic way to manipulate color representation (see examples below)
- Full conversion between RGB, HSL, 6-digit hex, 3-digit hex, human color
- One object (
Color
) or bunch of single purpose function (rgb2hex
,hsl2rgb
...) web
format that use the smallest representation between 6-digit (e.g.#fa3b2c
), 3-digit (e.g.#fbb
), fully spelled color (e.g.white
), following W3C color naming for compatible CSS or HTML color specifications.- smooth intuitive color scale generation choosing N color gradients.
- can pick colors for you to identify objects of your application.
Installation
You don't need to download the GIT version of the code as colour
is
available on the PyPI. So you should be able to run:
pip install colour
If you have downloaded the GIT sources, then you could add the colour.py
directly to one of your site-packages
(thanks to a symlink). Or install
the current version via traditional:
python setup.py install
And if you don't have the GIT sources but would like to get the latest master or branch from github, you could also:
pip install git+https://github.com/vaab/colour
Or even select a specific revision (branch/tag/commit):
pip install git+https://github.com/vaab/colour@master
Usage
To get complete demo of each function, please read the source code which is heavily documented and provide a lot of examples in doctest format.
Here is a reduced sample of a common usage scenario:
Instantiation
Let's create blue color:
>>> from colour import Color >>> c = Color("blue") >>> c <Color blue>
Please note that all of these are equivalent examples to create the red color:
Color("red") ## human, web compatible representation Color(red=1) ## default amount of blue and green is 0.0 Color("blue", hue=0) ## hue of blue is 0.66, hue of red is 0.0 Color("#f00") ## standard 3 hex digit web compatible representation Color("#ff0000") ## standard 6 hex digit web compatible representation Color(hue=0, saturation=1, luminance=0.5) Color(hsl=(0, 1, 0.5)) ## full 3-uple HSL specification Color(rgb=(1, 0, 0)) ## full 3-uple RGB specification Color(Color("red")) ## recursion doesn't break object
Reading values
Several representations are accessible:
>>> c.hex '#00f' >>> c.hsl # doctest: +ELLIPSIS (0.66..., 1.0, 0.5) >>> c.rgb (0.0, 0.0, 1.0)
And their different parts are also independently accessible, as the different amount of red, blue, green, in the RGB format:
>>> c.red 0.0 >>> c.blue 1.0 >>> c.green 0.0
Or the hue, saturation and luminance of the HSL representation:
>>> c.hue # doctest: +ELLIPSIS 0.66... >>> c.saturation 1.0 >>> c.luminance 0.5
A note on the .hex
property, it'll return the smallest valid value
when possible. If you are only interested by the long value, use
.hex_l
:
>>> c.hex_l '#0000ff'
Modifying color objects
All of these properties are read/write, so let's add some red to this color:
>>> c.red = 1 >>> c <Color magenta>
We might want to de-saturate this color:
>>> c.saturation = 0.5 >>> c <Color #bf40bf>
And of course, the string conversion will give the web representation which is human, or 3-digit, or 6-digit hex representation depending which is usable:
>>> "%s" % c '#bf40bf' >>> c.luminance = 1 >>> "%s" % c 'white'
Ranges of colors
You can get some color scale of variation between two Color
objects quite
easily. Here, is the color scale of the rainbow between red and blue:
>>> red = Color("red") >>> blue = Color("blue") >>> list(red.range_to(blue, 5)) [<Color red>, <Color yellow>, <Color lime>, <Color cyan>, <Color blue>]
Or the different amount of gray between black and white:
>>> black = Color("black") >>> white = Color("white") >>> list(black.range_to(white, 6)) [<Color black>, <Color #333>, <Color #666>, <Color #999>, <Color #ccc>, <Color white>]
If you have to create graphical representation with color scale between red and green ('lime' color is full green):
>>> lime = Color("lime") >>> list(red.range_to(lime, 5)) [<Color red>, <Color #ff7f00>, <Color yellow>, <Color chartreuse>, <Color lime>]
Notice how naturally, the yellow is displayed in human format and in the middle of the scale. And that the quite unusual (but compatible) 'chartreuse' color specification has been used in place of the hexadecimal representation.
Color comparison
Sane default
Color comparison is a vast subject. However, it might seem quite straightforward for
you. Colour
uses a configurable default way of comparing color that might suit
your needs:
>>> Color("red") == Color("#f00") == Color("blue", hue=0) True
The default comparison algorithm focuses only on the "web" representation which is equivalent to comparing the long hex representation (e.g. #FF0000) or to be more specific, it is equivalent to compare the amount of red, green, and blue composition of the RGB representation, each of these value being quantized to a 256 value scale.
This default comparison is a practical and convenient way to measure the actual color equivalence on your screen, or in your video card memory.
But this comparison wouldn't make the difference between a black red, and a black blue, which both are black:
>>> black_red = Color("red", luminance=0) >>> black_blue = Color("blue", luminance=0) >>> black_red == black_blue True
Customization
But, this is not the sole way to compare two colors. As I'm quite lazy, I'm providing you a way to customize it to your needs. Thus:
>>> from colour import RGB_equivalence, HSL_equivalence >>> black_red = Color("red", luminance=0, equality=HSL_equivalence) >>> black_blue = Color("blue", luminance=0, equality=HSL_equivalence) >>> black_red == black_blue False
As you might have already guessed, the sane default is RGB_equivalence
, so:
>>> black_red = Color("red", luminance=0, equality=RGB_equivalence) >>> black_blue = Color("blue", luminance=0, equality=RGB_equivalence) >>> black_red == black_blue True
Here's how you could implement your unique comparison function:
>>> saturation_equivalence = lambda c1, c2: c1.saturation == c2.saturation >>> red = Color("red", equality=saturation_equivalence) >>> blue = Color("blue", equality=saturation_equivalence) >>> white = Color("white", equality=saturation_equivalence) >>> red == blue True >>> white == red False
Note: When comparing 2 colors, only the equality function of the first color will be used. Thus:
>>> black_red = Color("red", luminance=0, equality=RGB_equivalence) >>> black_blue = Color("blue", luminance=0, equality=HSL_equivalence) >>> black_red == black_blue True
But reverse operation is not equivalent !:
>>> black_blue == black_red False
Equality to non-Colour objects
As a side note, whatever your custom equality function is, it won't be
used if you compare to anything else than a Colour
instance:
>>> red = Color("red", equality=lambda c1, c2: True) >>> blue = Color("blue", equality=lambda c1, c2: True)
Note that these instances would compare as equal to any other color:
>>> red == blue True
But on another non-Colour object:
>>> red == None False >>> red != None True
Actually, Colour
instances will, politely enough, leave
the other side of the equality have a chance to decide of the output,
(by executing its own __eq__
), so:
>>> class OtherColorImplem(object): ... def __init__(self, color): ... self.color = color ... def __eq__(self, other): ... return self.color == other.web >>> alien_red = OtherColorImplem("red") >>> red == alien_red True >>> blue == alien_red False
And inequality (using __ne__
) are also polite:
>>> class AnotherColorImplem(OtherColorImplem): ... def __ne__(self, other): ... return self.color != other.web >>> new_alien_red = AnotherColorImplem("red") >>> red != new_alien_red False >>> blue != new_alien_red True
Picking arbitrary color for a python object
Basic Usage
Sometimes, you just want to pick a color for an object in your application often to visually identify this object. Thus, the picked color should be the same for same objects, and different for different object:
>>> foo = object() >>> bar = object() >>> Color(pick_for=foo) # doctest: +ELLIPSIS <Color ...> >>> Color(pick_for=foo) == Color(pick_for=foo) True >>> Color(pick_for=foo) == Color(pick_for=bar) False
Of course, although there's a tiny probability that different strings yield the same color, most of the time, different inputs will produce different colors.
Advanced Usage
You can customize your color picking algorithm by providing a picker
. A
picker
is a callable that takes an object, and returns something that can
be instantiated as a color by Color
:
>>> my_picker = lambda obj: "red" if isinstance(obj, int) else "blue" >>> Color(pick_for=3, picker=my_picker, pick_key=None) <Color red> >>> Color(pick_for="foo", picker=my_picker, pick_key=None) <Color blue>
You might want to use a particular picker, but enforce how the picker will
identify two object as the same (or not). So there's a pick_key
attribute
that is provided and defaults as equivalent of hash
method and if hash is
not supported by your object, it'll default to the str
of your object salted
with the class name.
Thus:
>>> class MyObj(str): pass >>> my_obj_color = Color(pick_for=MyObj("foo")) >>> my_str_color = Color(pick_for="foo") >>> my_obj_color == my_str_color False
Please make sure your object is hashable or "stringable" before using the
RGB_color_picker
picking mechanism or provide another color picker. Nearly
all python object are hashable by default so this shouldn't be an issue (e.g.
instances of object
and subclasses are hashable).
Neither hash
nor str
are perfect solution. So feel free to use
pick_key
at Color
instantiation time to set your way to identify
objects, for instance:
>>> a = object() >>> b = object() >>> Color(pick_for=a, pick_key=id) == Color(pick_for=b, pick_key=id) False
When choosing a pick key, you should closely consider if you want your color to be consistent between runs (this is NOT the case with the last example), or consistent with the content of your object if it is a mutable object.
Default value of pick_key
and picker
ensures that the same color will
be attributed to same object between different run on different computer for
most python object.
Color factory
As you might have noticed, there are few attributes that you might want to see
attached to all of your colors as equality
for equality comparison support,
or picker
, pick_key
to configure your object color picker.
You can create a customized Color
factory thanks to the make_color_factory
:
>>> from colour import make_color_factory, HSL_equivalence, RGB_color_picker >>> get_color = make_color_factory( ... equality=HSL_equivalence, ... picker=RGB_color_picker, ... pick_key=str, ... )
All color created thanks to CustomColor
class instead of the default one
would get the specified attributes by default:
>>> black_red = get_color("red", luminance=0) >>> black_blue = get_color("blue", luminance=0)
Of course, these are always instances of Color
class:
>>> isinstance(black_red, Color) True
Equality was changed from normal defaults, so:
>>> black_red == black_blue False
This because the default equivalence of Color
was set to
HSL_equivalence
.
Contributing
Any suggestion or issue is welcome. Push request are very welcome, please check out the guidelines.
Push Request Guidelines
You can send any code. I'll look at it and will integrate it myself in the code base and leave you as the author. This process can take time and it'll take less time if you follow the following guidelines:
- check your code with PEP8 or pylint. Try to stick to 80 columns wide.
- separate your commits per smallest concern.
- each commit should pass the tests (to allow easy bisect)
- each functionality/bugfix commit should contain the code, tests, and doc.
- prior minor commit with typographic or code cosmetic changes are
very welcome. These should be tagged in their commit summary with
!minor
. - the commit message should follow gitchangelog rules (check the git log to get examples)
- if the commit fixes an issue or finished the implementation of a feature, please mention it in the summary.
If you have some questions about guidelines which is not answered here,
please check the current git log
, you might find previous commit that
would show you how to deal with your issue.
License
Copyright (c) 2012-2017 Valentin Lab.
Licensed under the BSD License.