Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I wrote the two methods below to automatically select N distinct colors. It works by defining a piecewise linear function on the RGB cube. The benefit of this is you can also get a progressive scale if that's what you want, but when N gets large the colors can start to look similar. I can also imagine evenly subdividing the RGB cube into a lattice and then drawing points. Does anyone know any other methods? I'm ruling out defining a list and then just cycling through it. I should also say I don't generally care if they clash or don't look nice, they just have to be visually distinct.

public static List<Color> pick(int num) {
	List<Color> colors = new ArrayList<Color>();
	if (num < 2)
		return colors;
	float dx = 1.0f / (float) (num - 1);
	for (int i = 0; i < num; i++) {
		colors.add(get(i * dx));
	return colors;

public static Color get(float x) {
	float r = 0.0f;
	float g = 0.0f;
	float b = 1.0f;
	if (x >= 0.0f && x < 0.2f) {
		x = x / 0.2f;
		r = 0.0f;
		g = x;
		b = 1.0f;
	} else if (x >= 0.2f && x < 0.4f) {
		x = (x - 0.2f) / 0.2f;
		r = 0.0f;
		g = 1.0f;
		b = 1.0f - x;
	} else if (x >= 0.4f && x < 0.6f) {
		x = (x - 0.4f) / 0.2f;
		r = x;
		g = 1.0f;
		b = 0.0f;
	} else if (x >= 0.6f && x < 0.8f) {
		x = (x - 0.6f) / 0.2f;
		r = 1.0f;
		g = 1.0f - x;
		b = 0.0f;
	} else if (x >= 0.8f && x <= 1.0f) {
		x = (x - 0.8f) / 0.2f;
		r = 1.0f;
		g = 0.0f;
		b = x;
	return new Color(r, g, b);
share|improve this question
Strongly relevant Programmers question with interesting answers: "Color schemes generation - theory and algorithms." –  Alexey Popkov Sep 13 '11 at 11:13
Human color perception is not linear, unfortunately. You may also need to account for Bezold–Brücke shift if you are using varying intensities. There is also good information here: vis4.net/blog/posts/avoid-equidistant-hsv-colors –  spex Apr 14 at 16:13
add comment

8 Answers

up vote 40 down vote accepted

You can use the HSL color model to create your colors.

If all you want is differing hues (likely), and slight variations on lightness or saturation, you can distribute the hues like so:

// assumes hue [0, 360), saturation [0, 100), lightness [0, 100)

for(i = 0; i < 360; i += 360 / num_colors) {
    HSLColor c;
    c.hue = i;
    c.saturation = 90 + randf() * 10;
    c.lightness = 50 + randf() * 10;

share|improve this answer
This technique is smart. I bet it'll get more aesthetic results than mine. –  mquander Jan 22 '09 at 20:51
This assumes that equally-spaced hue values are equally perceptually different. Even discounting various forms of colorblindness, this is not true for most people: the difference between 120° (green) and 135° (very slightly mint green) is imperceptible, while the difference between 30° (orange) and 45° (peach) is quite obvious. You need a non-linear spacing along the hue for best results. –  Phrogz Feb 21 '12 at 17:05
@mquander - It's not smart at all. There's nothing to prevent this algorithm from accidentally picking two almost identical colours. My answer is better, and ohadsc's answer is much better. –  Rocketmagnet Jun 1 '12 at 17:51
This is wrong for the reasons already mentioned, but also because you are not picking uniformly. –  Sam Hocevar Dec 30 '12 at 22:12
@Phrogz: Which function do you suggest? I'll accept any continuous function in my answer. –  Janus Troelsen Apr 18 '13 at 17:04
show 2 more comments

This questions appears in quite a few SO discussions:

Different solutions are proposed, but none are optimal. Luckily, science comes to the rescue

Arbitrary N

The last 2 will be free via most university libraries / proxies.

N is finite and relatively small

In this case, one could go for a list solution. A very interesting article in the subject is freely available:

There are several color lists to consider:

  • Boynton's list of 11 colors that are almost never confused (available in the first paper of the previous section)
  • Kelly's 22 colors of maximum contrast (available in the paper above)

I also ran into this Palette by an MIT student. Lastly, The following links may be useful in converting between different color systems / coordinates (some colors in the articles are not specified in RGB, for instance):

For Kelly's and Boynton's list, I've already made the conversion to RGB. Some C# code:

public static ReadOnlyCollection<Color> KellysMaxContrastSet
    get { return _kellysMaxContrastSet.AsReadOnly(); }

private static readonly List<Color> _kellysMaxContrastSet = new List<Color>
    UIntToColor(0xFFFFB300), //Vivid Yellow
    UIntToColor(0xFF803E75), //Strong Purple
    UIntToColor(0xFFFF6800), //Vivid Orange
    UIntToColor(0xFFA6BDD7), //Very Light Blue
    UIntToColor(0xFFC10020), //Vivid Red
    UIntToColor(0xFFCEA262), //Grayish Yellow
    UIntToColor(0xFF817066), //Medium Gray

    //The following will not be good for people with defective color vision
    UIntToColor(0xFF007D34), //Vivid Green
    UIntToColor(0xFFF6768E), //Strong Purplish Pink
    UIntToColor(0xFF00538A), //Strong Blue
    UIntToColor(0xFFFF7A5C), //Strong Yellowish Pink
    UIntToColor(0xFF53377A), //Strong Violet
    UIntToColor(0xFFFF8E00), //Vivid Orange Yellow
    UIntToColor(0xFFB32851), //Strong Purplish Red
    UIntToColor(0xFFF4C800), //Vivid Greenish Yellow
    UIntToColor(0xFF7F180D), //Strong Reddish Brown
    UIntToColor(0xFF93AA00), //Vivid Yellowish Green
    UIntToColor(0xFF593315), //Deep Yellowish Brown
    UIntToColor(0xFFF13A13), //Vivid Reddish Orange
    UIntToColor(0xFF232C16), //Dark Olive Green

public static ReadOnlyCollection<Color> BoyntonOptimized
    get { return _boyntonOptimized.AsReadOnly(); }

private static readonly List<Color> _boyntonOptimized = new List<Color>
    Color.FromArgb(0, 0, 255),      //Blue
    Color.FromArgb(255, 0, 0),      //Red
    Color.FromArgb(0, 255, 0),      //Green
    Color.FromArgb(255, 255, 0),    //Yellow
    Color.FromArgb(255, 0, 255),    //Magenta
    Color.FromArgb(255, 128, 128),  //Pink
    Color.FromArgb(128, 128, 128),  //Gray
    Color.FromArgb(128, 0, 0),      //Brown
    Color.FromArgb(255, 128, 0),    //Orange

static public Color UIntToColor(uint color)
    var a = (byte)(color >> 24);
    var r = (byte)(color >> 16);
    var g = (byte)(color >> 8);
    var b = (byte)(color >> 0);
    return Color.FromArgb(a, r, g, b);
share|improve this answer
+1 Thank you very much for this great answer! BTW the link colour-journal.org/2010/5/10 is dead, this article is still available at web.archive.org. –  Alexey Popkov Sep 13 '11 at 17:54
Thanks Alexey, I fixed the broken link –  Ohad Schneider Sep 14 '11 at 16:44
Great answer, thanks! I've taken the liberty of turning these two colors sets into a convenient jsfiddle where you can see the colors in action. –  David Mills Oct 24 '11 at 2:05
Just noticed there are only 20 and 9 colors in those lists, respectively. I'm guessing it's because white and black are omitted. –  David Mills Oct 24 '11 at 2:25
show 7 more comments

Here's an idea. Imagine an HSV cylinder

Define the upper and lower limits you want for the Brightness and Saturation. This defines a square cross section ring within the space.

Now, scatter N points randomly within this space.

Then apply an iterative repulsion algorithm on them, either for a fixed number of iterations, or until the points stabilise.

Now you should have N points representing N colours that are about as different as possible within the colour space you're interested in.


share|improve this answer
add comment

Like Uri Cohen's answer, but is a generator instead. Will start by using colors far apart. Deterministic.

Sample, left colors first: sample

#!/usr/bin/env python3.3
import colorsys
import itertools
from fractions import Fraction

def zenos_dichotomy():
    for k in itertools.count():
        yield Fraction(1,2**k)

def getfracs():
    [Fraction(0, 1), Fraction(1, 2), Fraction(1, 4), Fraction(3, 4), Fraction(1, 8), Fraction(3, 8), Fraction(5, 8), Fraction(7, 8), Fraction(1, 16), Fraction(3, 16), ...]
    [0.0, 0.5, 0.25, 0.75, 0.125, 0.375, 0.625, 0.875, 0.0625, 0.1875, ...]
    yield 0
    for k in zenos_dichotomy():
        i = k.denominator # [1,2,4,8,16,...]
        for j in range(1,i,2):
            yield Fraction(j,i)

bias = lambda x: (math.sqrt(x/3)/Fraction(2,3)+Fraction(1,3))/Fraction(6,5) # can be used for the v in hsv to map linear values 0..1 to something that looks equidistant

def genhsv(h):
    for s in [Fraction(6,10)]: # optionally use range
        for v in [Fraction(8,10),Fraction(5,10)]: # could use range too
            yield (h, s, v) # use bias for v here if you use range

genrgb = lambda x: colorsys.hsv_to_rgb(*x)

flatten = itertools.chain.from_iterable

gethsvs = lambda: flatten(map(genhsv,getfracs()))

getrgbs = lambda: map(genrgb, gethsvs())

def genhtml(x):
    uint8tuple = map(lambda y: int(y*255), x)
    return "rgb({},{},{})".format(*uint8tuple)

gethtmlcolors = lambda: map(genhtml, getrgbs())

if __name__ == "__main__":
    print(list(itertools.islice(gethtmlcolors(), 100)))
share|improve this answer
add comment

For the sake of generations to come I add here the accepted answer in Python.

import numpy as np
import colorsys

def _get_colors(num_colors):
    for i in np.arange(0., 360., 360. / num_colors):
        hue = i/360.
        lightness = (50 + np.random.rand() * 10)/100.
        saturation = (90 + np.random.rand() * 10)/100.
        colors.append(colorsys.hls_to_rgb(hue, lightness, saturation))
    return colors
share|improve this answer
add comment

Here's a solution to managed your "distinct" issue, which is entirely overblown:

Create a unit sphere and drop points on it with repelling charges. Run a particle system until they no longer move (or the delta is "small enough"). At this point, each of the points are as far away from each other as possible. Convert (x, y, z) to rgb.

I mention it because for certain classes of problems, this type of solution can work better than brute force.

I originally saw this approach here for tesselating a sphere.

Again, the most obvious solutions of traversing HSL space or RGB space will probably work just fine.

share|improve this answer
That's a good idea, but it probably makes sense to use a cube, rather than a sphere. –  Rocketmagnet Jan 22 '09 at 23:21
add comment

If N is big enough, you're going to get some similar-looking colors. There's only so many of them in the world.

Why not just evenly distribute them through the spectrum, like so:

IEnumerable<Color> CreateUniqueColors(int nColors)
    int subdivision = (int)Math.Floor(Math.Pow(nColors, 1/3d));
    for(int r = 0; r < 255; r += subdivision)
        for(int g = 0; g < 255; g += subdivision)
            for(int b = 0; b < 255; b += subdivision)
                yield return Color.FromArgb(r, g, b);

If you want to mix up the sequence so that similar colors aren't next to each other, you could maybe shuffle the resulting list.

Am I underthinking this?

share|improve this answer
-1. You are generating shades of gray. –  Boris Yankov May 22 '13 at 0:20
Yes, you're under-thinking this. Human color perception is not linear, unfortunately. You may also need to account for Bezold–Brücke shift if you are using varying intensities. There is also good information here: vis4.net/blog/posts/avoid-equidistant-hsv-colors –  spex Apr 14 at 16:13
add comment

I would try to fix saturation and lumination to maximum and focus on hue only. As I see it, H can go from 0 to 255 and then wraps around. Now if you wanted two contrasting colours you would take the opposite sides of this ring, i.e. 0 and 128. If you wanted 4 colours, you would take some separated by 1/4 of the 256 length of the circle, i.e. 0, 64,128,192. And of course, as others suggested when you need N colours, you could just separate them by 256/N.

What I would add to this idea is to use a reversed representation of a binary number to form this sequence. Look at this:

0 = 00000000  after reversal is 00000000 = 0
1 = 00000001  after reversal is 10000000 = 128
2 = 00000010  after reversal is 01000000 = 64
3 = 00000011  after reversal is 11000000 = 192

... this way if you need N different colours you could just take first N numbers, reverse them, and you get as much distant points as possible (for N being power of two) while at the same time preserving that each prefix of the sequence differs a lot.

This was an important goal in my use case, as I had a chart where colors were sorted by area covered by this colour. I wanted the largest areas of the chart to have large contrast, and I was ok with some small areas to have colours similar to those from top 10, as it was obvious for the reader which one is which one by just observing the area.

share|improve this answer
This is what I did in my answer, although a bit more "mathematical". See the function getfracs. But your approach is fast and "simple" in low-level languages: bit reversing in C. –  Janus Troelsen Apr 18 '13 at 16:56
Just noticed Ridiculous Fish did it too –  Janus Troelsen Apr 18 '13 at 18:49
add comment

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.