By reading HSL/HSV color theory, I get the impression that hue component is a cyclical attribute that repeats every 360 degrees and can be changed independently of saturation and lightness/value. Correct me if I am wrong, but these statements logically follow the previous definition:

  1. Rotating hue by 360 degrees yields the same color
  2. Rotating hue by 180 degrees twice yields the original color
  3. Rotating hue by 180 degrees followed by -180 degrees yields the original color

However, only the option 1 is correct. Rotating hue 4 times by +90 degrees yields a color that isn't even remotely similar to the original.

Furthermore, using -webkit-filter and SVG's

<filter><feColorMatrix in="SourceGraphic" type="hueRotate" values="..." /></filter>

don't produce the same result for the same rotation. On the other hand, colors produced by SVG filters are consistent across browsers.

Is there any "hidden" property of hue rotation that makes the operation not associative?

Examples of both webkit filters and SVGs can be found here: http://jsfiddle.net/maros_urbanec/ARsjb/5/

  • Numbers 2 and 3 are absolutely true if you've correctly implemented your HLS or HSV conversions. Is it possible that the feColorMatrix filter uses radians instead of degrees? Oct 5, 2013 at 2:13
  • 2
    No, since rotating feColorMatrix by 360 indeed yields the original color. Rotating twice by 180 doesn't, as shown in the example. The difference is much larger than a simple rounding error, in both webkit-filters and SVG filters Oct 5, 2013 at 6:53
  • So I took the image made by your code into an image manipulation program, and what I'm seeing is that the hue is correct on all the color swatches, but the saturation and value (or luminance if you prefer) are not correct. In order to get them to match, I had to turn the saturation up from 1 (meaning no change) to 3, and the value down to about 0.6. Then the swatches mostly matched. So it looks like the issue isn't the hue, but the other two channels, from what I can tell. Oct 5, 2013 at 14:04

3 Answers 3


In both CSS and SVG filters, there is no conversion into HSV or HSL - the hueRotation shorthands are using a linear matrix approximation in RGB space to perform the hue rotation. This doesn't conserve saturation or brightness very well for small rotations and highly saturated colors - as you're seeing.

A true hue rotation, would first convert the input RGB color to HSL, adjust the H and then convert back to RGB. Filters don't do this. And this conversion can't be accurately approximated with a linear matrix, so while the hue is accurately changed(mostly), the saturation and brightness goes all over the place. These effects are non-linear, so adding smaller ops together results in different colors vs. doing one big operation.

(The difference between huerotation in SVG and CSS filters could be due to using different color spaces (sRGB vs. linearRGB) - these should be the same.)

Update: I got interested enough to go and do a manual comparison. As you can see, filters do a terrible job of hue rotating pure colors in the 0 to 180 degree range. This image compares a manual hue rotation done by plugging in hsl colors manually (outer ring) vs. a filter hue rotation on the base color (inner ring)

Explicit HSL Hue Rotation vs. CSS Filter Hue Rotation

But, they do a better job at less pure colors like hsl(0,50%,75%) as you can see. hue rotation with mid HSL

codepen link in case you want to play: http://codepen.io/mullany/pen/fwHrd

  • 1
    I expended your example with the SVG filters: jsfiddle.net/PhilQ/tx70as92. SVG's feColorMatrix's type hueRotate in sRGB mode yields the same colors as CSS's hue-rotate
    – Philip
    Sep 23, 2021 at 2:24
  • The result of hue-rotate() is even worse on linear-gradients: see here
    – Philip
    Sep 23, 2021 at 7:05

Michael's answer is awesome, and I wish I had seen it before; but since I need to not only understand they're damn wierd but also in which way (I want to work around their logic so I need the maths), I've coded a hue-rotate implementation in Javascript (which was mostly taken from reading Firefox's source code), which emulates the hue-rotate that Webkit/Blink/Gecko use.

Again, the whole point here is just to understand what results it produces.

function calculate() {
    // Get the RGB and angle to work with.
    var color = document.getElementById('color').value;
    if (! /^[0-9A-F]{6}$/i.test(color)) return alert('Bad color!');
    var angle = document.getElementById('angle').value;
    if (! /^-?[0-9]+$/i.test(angle)) return alert('Bad angle!');
    var r = parseInt(color.substr(0, 2), 16);
    var g = parseInt(color.substr(2, 2), 16);
    var b = parseInt(color.substr(4, 2), 16);
    var angle = (parseInt(angle) % 360 + 360) % 360;
    // Hold your breath because what follows isn't flowers.
    var matrix = [ // Just remember this is the identity matrix for
        1, 0, 0,   // Reds
        0, 1, 0,   // Greens
        0, 0, 1    // Blues
    // Luminance coefficients.
    var lumR = 0.2126;
    var lumG = 0.7152;
    var lumB = 0.0722;
    // Hue rotate coefficients.
    var hueRotateR = 0.143;
    var hueRotateG = 0.140;
    var hueRotateB = 0.283;
    var cos = Math.cos(angle * Math.PI / 180);
    var sin = Math.sin(angle * Math.PI / 180);
    matrix[0] = lumR + (1 - lumR) * cos - lumR * sin;
    matrix[1] = lumG - lumG * cos - lumG * sin;
    matrix[2] = lumB - lumB * cos + (1 - lumB) * sin;
    matrix[3] = lumR - lumR * cos + hueRotateR * sin;
    matrix[4] = lumG + (1 - lumG) * cos + hueRotateG * sin;
    matrix[5] = lumB - lumB * cos - hueRotateB * sin;
    matrix[6] = lumR - lumR * cos - (1 - lumR) * sin;
    matrix[7] = lumG - lumG * cos + lumG * sin;
    matrix[8] = lumB + (1 - lumB) * cos + lumB * sin;
    function clamp(num) {
        return Math.round(Math.max(0, Math.min(255, num)));
    var R = clamp(matrix[0] * r + matrix[1] * g + matrix[2] * b);
    var G = clamp(matrix[3] * r + matrix[4] * g + matrix[5] * b);
    var B = clamp(matrix[6] * r + matrix[7] * g + matrix[8] * b);
    // Output the result
    var result = 'The original color, rgb(' + [r,g,b] + '), '
               + 'when rotated by ' + angle + ' degrees '
               + 'by the devil\'s logic, gives you '
               + 'rgb(' + [R,G,B] + '). If I got it right.';
    document.getElementById('result').innerText = result;
// Listen for Enter key press.
['color', 'angle'].forEach(function(i) {
    document.getElementById(i).onkeypress = function(event) {
        var e = event || window.event, c = e.which || e.keyCode;
        if (c == '13') return calculate();
body {
    font: 14px sans-serif;
    padding: 6px 8px;

input {
    width: 64px;
    This algorithm emulates the wierd, nonsensical and completely 
    idiotic <code>hue-rotate</code> CSS filter. I wanted to know
    how it worked, because it is out of touch with any definition
    of "hue" I've ever seen; the results it produces are stupid
    and I believe it was coded under extreme influence of meth,
    alcohol and caffeine, by a scientologist listening to Death Metal.
<input type="text" id="color" placeholder="RRGGBB">
<input type="text" id="angle" placeholder="degrees">
<button onclick="calculate()">Calculate</button>
<p id="result"></p>

The snippet was taken from this answer.

  • 1
    "I believe it was coded under extreme influence of meth, alcohol and caffeine, by a scientologist listening to Death Metal..." made me chuckle :) Great answer to understand the hue-filter btw!
    – supersan
    Nov 5, 2020 at 8:35

tl;dr Error from converting colors from floats (inside the filter) to bytes (everywhere else).

So it's a bit more complicated than that, the spec provides a good formula for hue rotation matrices, for instance the one for 180 degrees is (excluding alpha and shifts):

-0.5747  1.4304   0.1444
 0.4252  0.4304   0.1444
 0.4252  1.4304  -0.8556

Note, if you multiply that by itself you get (to four decimal places):

 0.9999  0.0001   0.0000
 0.0000  1.0      0.0
 0.0000  0.0000   1.0

which is very close to the identity matrix, or a null transformation.

That would be perfect, except that the browser is converting back to RGB between each filter. Look what happens when we hue-rotate bright red:

-0.5747  1.4304   0.1444     1     -0.5747
 0.4252  0.4304   0.1444  *  0  =   0.4252
 0.4252  1.4304  -0.8556     0      0.4252

We get a color that's impossible to represent in RGB with values from 0 to 255. So it gets bound and rounded to 0 0.4235 0.4235 during the RGB conversion, and when it's rotated again we end up with a dark desaturated red, 0.6667 0.2431 0.2431 instead of the bright pure red we started with.

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