# How does the algorithm to color the song list in iTunes 11 work? [closed]

The new iTunes 11 has a very nice view for the song list of an album, picking the colors for the fonts and background in function of album cover. How does the algorithm work?

• The w3c color contrast formula might be part of the answer. My own empircal tests show that this formula is used by MS Word to decide it's auto-color font. Search for "Color brightness is determined by the following formula" [w3c color contrast formula][1] [1]: w3.org/TR/AERT#color-contrast Commented Nov 30, 2012 at 3:25
• @bluedog , i think you are right. I tried a lot of my album covers and always the font has enough contrast with the background to watch it clearly. Commented Nov 30, 2012 at 3:48
• Something else to note is that it seems to differ between Mac OS and Windows: twitter.com/grimfrog/status/275187988374380546 Commented Dec 2, 2012 at 16:10
• I could imagine that maybe not only the quantity of the colors, but also their saturation values are part of the calculation: My experiments led me to the conclusions, that highlight colors are often being picked as background color although they occur in few areas of the image. That's why I believe looking at the histogram of the cover image and its peaks could be useful, and based on some finely tuned parameters, the color is chosen. Commented Dec 2, 2012 at 20:14
• See another answer at panic.com/blog/2012/12/itunes-11-and-colors Commented Dec 11, 2012 at 19:31

I approximated the iTunes 11 color algorithm in Mathematica given the album cover as input:

## How I did it

Through trial and error, I came up with an algorithm that works on ~80% of the albums with which I've tested it.

### Color Differences

The bulk of the algorithm deals with finding the dominant color of an image. A prerequisite to finding dominant colors, however, is calculating a quantifiable difference between two colors. One way to calculate the difference between two colors is to calculate their Euclidean distance in the RGB color space. However, human color perception doesn't match up very well with distance in the RGB color space.

Therefore, I wrote a function to convert RGB colors (in the form `{1,1,1}`) to YUV, a color space which is much better at approximating color perception:

(EDIT: @cormullion and @Drake pointed out that Mathematica's built-in CIELAB and CIELUV color spaces would be just as suitable... looks like I reinvented the wheel a bit here)

``````convertToYUV[rawRGB_] :=
Module[{yuv},
yuv = {{0.299, 0.587, 0.114}, {-0.14713, -0.28886, 0.436},
{0.615, -0.51499, -0.10001}};
yuv . rawRGB
]
``````

Next, I wrote a function to calculate color distance with the above conversion:

``````ColorDistance[rawRGB1_, rawRGB2_] :=
EuclideanDistance[convertToYUV @ rawRGB1, convertToYUV @ rawRGB2]
``````

### Dominant Colors

I quickly discovered that the built-in Mathematica function `DominantColors` doesn't allow enough fine-grained control to approximate the algorithm that iTunes uses. I wrote my own function instead...

A simple method to calculate the dominant color in a group of pixels is to collect all pixels into buckets of similar colors and then find the largest bucket.

``````DominantColorSimple[pixelArray_] :=
Module[{buckets},
buckets = Gather[pixelArray, ColorDistance[#1,#2] < .1 &];
buckets = Sort[buckets, Length[#1] > Length[#2] &];
RGBColor @@ Mean @ First @ buckets
]
``````

Note that `.1` is the tolerance for how different colors must be to be considered separate. Also note that although the input is an array of pixels in raw triplet form (`{{1,1,1},{0,0,0}}`), I return a Mathematica `RGBColor` element to better approximate the built-in `DominantColors` function.

My actual function `DominantColorsNew` adds the option of returning up to `n` dominant colors after filtering out a given other color. It also exposes tolerances for each color comparison:

``````DominantColorsNew[pixelArray_, threshold_: .1, n_: 1,
numThreshold_: .2, filterColor_: 0, filterThreshold_: .5] :=
Module[
{buckets, color, previous, output},
buckets = Gather[pixelArray, ColorDistance[#1, #2] < threshold &];
If[filterColor =!= 0,
buckets =
Select[buckets,
ColorDistance[ Mean[#1], filterColor] > filterThreshold &]];
buckets = Sort[buckets, Length[#1] > Length[#2] &];
If[Length @ buckets == 0, Return[{}]];
color = Mean @ First @ buckets;
buckets = Drop[buckets, 1];
output = List[RGBColor @@ color];
previous = color;
Do[
If[Length @ buckets == 0, Return[output]];
While[
ColorDistance[(color = Mean @ First @ buckets), previous] <
numThreshold,
If[Length @ buckets != 0, buckets = Drop[buckets, 1],
Return[output]]
];
output = Append[output, RGBColor @@ color];
previous = color,
{i, n - 1}
];
output
]
``````

### The Rest of the Algorithm

First I resized the album cover (`36px`, `36px`) & reduced detail with a bilateral filter

``````image = Import["http://i.imgur.com/z2t8y.jpg"]
thumb = ImageResize[ image, 36, Resampling -> "Nearest"];
thumb = BilateralFilter[thumb, 1, .2, MaxIterations -> 2];
``````

iTunes picks the background color by finding the dominant color along the edges of the album. However, it ignores narrow album cover borders by cropping the image.

``````thumb = ImageCrop[thumb, 34];
``````

Next, I found the dominant color (with the new function above) along the outermost edge of the image with a default tolerance of `.1`.

``````border = Flatten[
Join[ImageData[thumb][[1 ;; 34 ;; 33]] ,
Transpose @ ImageData[thumb][[All, 1 ;; 34 ;; 33]]], 1];
background = DominantColorsNew[border][[1]];
``````

Lastly, I returned 2 dominant colors in the image as a whole, telling the function to filter out the background color as well.

``````highlights = DominantColorsNew[Flatten[ImageData[thumb], 1], .1, 2, .2,
List @@ background, .5];
title = highlights[[1]];
songs = highlights[[2]];
``````

The tolerance values above are as follows: `.1` is the minimum difference between "separate" colors; `.2` is the minimum difference between numerous dominant colors (A lower value might return black and dark gray, while a higher value ensures more diversity in the dominant colors); `.5` is the minimum difference between dominant colors and the background (A higher value will yield higher-contrast color combinations)

Voila!

``````Graphics[{background, Disk[]}]
Graphics[{title, Disk[]}]
Graphics[{songs, Disk[]}]
``````

### Notes

The algorithm can be applied very generally. I tweaked the above settings and tolerance values to the point where they work to produce generally correct colors for ~80% of the album covers I tested. A few edge cases occur when `DominantColorsNew` doesn't find two colors to return for the highlights (i.e. when the album cover is monochrome). My algorithm doesn't address these cases, but it would be trivial to duplicate iTunes' functionality: when the album yields less than two highlights, the title becomes white or black depending on the best contrast with the background. Then the songs become the one highlight color if there is one, or the title color faded into the background a bit.

## More Examples

• OK @Seth Thompson, it seems very promising. I'm going to try it my self, it will take me a couple of days, please be patient. Commented Dec 3, 2012 at 1:50
• Pretty awesome solution. Now need a port from Mathematica to Objective-C, that is a hard struggle. Commented Dec 3, 2012 at 20:29
• +1 for this very detailed answer! Commented Dec 7, 2012 at 0:41
• @cormullion LUV (and LAB) both aim for perceptual uniformity. However, I didn't find any explicit references to using euclidean distances in either color space. My guess is that if nothing else, they would both be better than RGB. Commented Dec 9, 2012 at 18:22
• This is what I like to call a "Chuck Norris Answer" Commented Jul 3, 2013 at 15:04

With the answer of Seth Thompson and the comment of bluedog, I build a little Objective-C (Cocoa Touch) project to generate color schemes in function of an image.

You can check the project at:

https://github.com/luisespinoza/LEColorPicker

For now, LEColorPicker is doing:

1. Image is scaled to 36x36 px (this reduce the compute time).
2. It generates a pixel array from the image.
3. Converts the pixel array to YUV space.
4. Gather colors as Seth Thompson's code does it.
5. The color's sets are sorted by count.
6. The algorithm select the three most dominant colors.
7. The most dominant is assigned as Background.
8. The second and third most dominants are tested using the W3C color contrast formula, to check if the colors has enough contrast with the background.
9. If one of the text colors don't pass the test, then is assigned to white or black, depending of the Y component.

That is for now, I will be checking the ColorTunes project and the Wade Cosgrove project for new features. Also I have some new ideas for improve the color scheme result.

• +1 - Very cool stuff, and a great example of how algorithm development and application development can both be very interesting in their own right Commented Jul 3, 2013 at 7:23
• +1 for checking the contrast. Commented Oct 13, 2014 at 16:39
• Yeah cool but how are you rounding the hash values for each color? I think I could break this algorithm easily, by simply adding a little black and white "Explicit" logo in the bottom right, you are really adding a focus for black and white. Anyways, this algorithm would work better for clip-art based images, but if you have the image at 36x36 those fail cases will be made more rare by the anti-aliasing Commented Nov 12, 2014 at 5:16
• One word: FANTASTIC! Commented Aug 28, 2015 at 13:15

Wade Cosgrove of Panic wrote a nice blog post describing his implementation of an algorithm that approximates the one in iTunes. It includes a sample implementation in Objective-C.

You might also checkout ColorTunes which is a HTML implementation of the Itunes album view which is using the MMCQ (median cut color quantization) algorithm.

• yes I already check it. Sadly seems barely documented. Commented Dec 9, 2012 at 22:41
• The important comment in ColorTunes is the reference to the (median cut quantization algorithm)[leptonica.com/papers/mediancut.pdf]. I just implemented this in python in about 2 hours just form the description in the paper, and prefer it to my implementation of Seth's algorithm above. I like the results a bit better, but most importantly it is quite a bit faster (of course, I could have implemented Seth's algorithm incorrectly). Commented Oct 13, 2014 at 16:42
• @sh1ftst0rm do you have your python implementation on github or somewhere? cheers Commented Apr 3, 2015 at 19:27
• @Anentropic Sorry, I don't. It was part of a private project I was working on, and I haven't extracted it out at all. If I get a chance to, I'll try to post it somewhere, but it probably won't be anytime soon. Commented Apr 4, 2015 at 1:10

I just wrote a JavaScript library implementing roughly the same algorithm that the one described by @Seth. It is freely available on github.com/arcanis/colibrijs, and on NPM as `colibrijs`.

With Seth Thompson's answer, I implemented the algorithm to get the dominant color in the two lateral borders of a picture using PHP and ImageMagick.

https://gist.github.com/felipecrv/5688064#file-simpleimage-php-L81

I asked the same question in a different context and was pointed over to Using Python and k-means to find the dominant colors in images for a learning algorithm (k-means) that roughly does the same thing using random starting points in the image. That way, the algorithm finds dominant colors by itself.