# RGB to closest predefined color

Edit:

With the answer given I made this function

``````function grabclosestcolor(\$r, \$g, \$b){
\$colors = array(array(124,12,12),array(7,7,11),array(110,224,219),array(123,123,123),array(124,177,74),array(130,86,53),array(77,77,77),array(164,124,68),array(204,196,132),array(164,148,147),array(163,123,67),array(26,122,26), array(195,195,50),array(193,193,193),array(255,248,73),array(243,243,243));
\$differencearray = array();
foreach (\$colors as \$value) {
\$difference = sqrt(pow(\$r-\$value,2)+pow(\$g-\$value,2)+pow(\$b-\$value,2));
array_push(\$differencearray, \$difference);
\$smallest = min(\$differencearray);
\$key = array_search(\$smallest, \$differencearray);
return \$colors[\$key];
}
}
``````

My goal is this. I grab a picture and loop through each pixel and grab its x,y, and rgb.

Instead of just grabbing the rgb, I have a predefined array and I'm looking for the closest match from the color I grabbed to the predefined array. The goal here is to only use colors from the predefined array. Here is my array of colors.

``````\$colors = array(array(124,12,12),array(7,7,11),array(110,224,219),array(123,123,123),array(124,177,74),array(130,86,53),array(77,77,77),array(164,124,68),array(204,196,132),array(164,148,147),array(163,123,67),array(26,122,26), array(195,195,50),array(193,193,193),array(255,248,73),array(243,243,243));
``````

and here is my existing code that loops through it all.

``````\$int = imagesx(\$im) - 1;
\$int2 = imagesy(\$im) - 1;
\$start2 = 0;
do{
\$start = 0;
do{
\$rgb = imagecolorat(\$im, \$start, \$start2);
\$r = (\$rgb >> 16) & 0xFF;
\$g = (\$rgb >> 8) & 0xFF;
\$b = \$rgb & 0xFF;
\$value = rgb2hex(\$r,\$g,\$b).":\$start:\$start2";
array_push(\$colorsofimage, \$value);
} while(\$int > \$start++);
} while(\$int2 > \$start2++);
``````

rgb2hex is a User Defined Function, but what I want to accomplish is to change that function with the function to grab the closest color.

\$colorsofimage contains an array of each pixels info with hex:x:y what i want it to be is rgb2hex(NEWFUNCTION(\$r,\$g,\$b)); So that the new hex is the 1 out of the predefined array.

I hope you understood, because I have no clue how to do it because I don't know the algorithm of a color.

You have to calculate the distance to each color, and pick the smallest.

There are a few ways to do this. A simple method would be to calculate the distance would be:

``````sqrt((r-r1)^2+(g-g1)^2+(b-b1)^2)
``````

A better method might be to incorporate the weighted values to calculate a distance, for instance the values used when converting RGB->YUV:

``````Y = 0.299 * R + 0.587 * G + 0.114 * B
``````

in that case you would use

``````sqrt(((r - r1) * .299)^2 + ((g - g1) * .587)^2 + ((b - b1) * .114)^2)
``````

Of course, since you don't need the exact distances, just a comparison, you can and probably should just skip the square root, making the last calculation:

``````((r - r1) * .299)^2 + ((g - g1) * .587)^2 + ((b - b1) * .114)^2
``````
• Thanks for this, im going to edit the OP and put the function I made. – Ugleh Dec 19 '10 at 22:39
• Random thought: Strictly speaking you don't need to take the square root and can just find the smallest square if performance is a concern. – Kevin Stricker Dec 19 '10 at 22:40
• @mootinator Why do we need to square the values at all? Why not just shortest distance? – Albert Renshaw Jun 23 '13 at 19:53
• @mootinator Are we squaring to eliminate negative values? Does anyone know if the absolute value function is faster than squaring? Or simply converting to a string and stripping the negative then converting back to a number, or maybe just multiplying itself by negative 1 if it's negative? – Albert Renshaw Jun 23 '13 at 19:55
• @Albert Renshaw We're squaring to find the euclidean distance between two points. We're skipping taking the square root of the distance because that step doesn't affect the sort order of the distances. – Kevin Stricker Jun 24 '13 at 14:36

The RGB colour-space is simply a cube. In 24-bit colour each side has a length of 256, allowing values from 0 to 255. In order to find the closest colour in within this cube, you need a distance function. The simplest and most intuitive is the Euclidean distance: if you have colour (r1, g1, b1) and another colour (r2, g2, b2) the distance would be `sqrt((r2-r1)^2 + (g2-g1)^2 + (b2-b1)^2)`.

The challenge for you is then to find the best match across all the values in your predefined array. I suggest that you start simply by iterating over all your values and check the distance for each in turn. Note that for this purpose you do not need to perform the `sqrt`, simply comparing on the sum of the squares would be sufficient, and would have the benefit of being all based in integer maths. My PHP isn't great, but roughly you would do:

``````function dist(\$col1,\$col2) {
\$delta_r = \$col1 - \$col2;
\$delta_g = \$col1 - \$col2;
\$delta_b = \$col1 - \$col2;
return \$delta_r * \$delta_r + \$delta_g * \$delta_g + \$delta_b * \$delta_b;
}

\$closest=\$colors;
\$mindist=dist(\$rgb,\$colors);
\$ncolors=sizeof(\$colors);
for(\$i = 1; \$i < \$ncolors; ++\$i)
{
\$currdist = dist(\$rgb,\$colors[\$i]);
if(\$currdist<\$mindist) {
\$mindist=\$currdist;
\$closest=\$colors[\$i];
}
}
``````

There are more complicated distance functions (for instance, taking better account of psychovisual interpretation of colour differences (look into Delta E) but I suspect this is more than you need.

• It's not necessarily a cube, even if it's commonly done so. It's primarily a vector space, and could as well be a paralleloid. – user502515 Dec 20 '10 at 2:12
• @user502515: It could be, but it's unlikely. All the RGB colour spaces I've encountered (most obviously sRGB) tend to be bounded in the range 0 to 1 or 0 to 255. Other colour spaces, such as CIE Lab, do indeed have different bounds, but they are not RGB. – beldaz Dec 20 '10 at 3:40
• @beldaz why are we squaring the distance as well? Why not just take the sum of the distance of each color? – Albert Renshaw Jun 23 '13 at 19:40
• Is it to eliminate negative values? Are there quicker ways of doing this? – Albert Renshaw Jun 23 '13 at 19:55
• @Albert the sum of distances would be like walking around a square rather than walking directly across it: the distances are different (FWIW your approach is sometimes referred to as a Manhattan Distance). – beldaz Jul 2 '13 at 6:52

Since this question is displayed in the top ten of goolge search results, here is a more complex function I wrote some years ago, which produced better results than the existing PHP functions.

``````/*
* Die Funktion gibt den Array-Schlüssel der Farbe (\$palette),
* die am ehesten der Farbe \$givenColor entspricht.
*
* Returns the index of the palette-color which is most similar
* to \$givenColor.
*
* \$givenColor und die Einträge in \$palette können entweder
* Strings im Format (#)rrggbb
* (z. B. "ff0000", "4da4f3" oder auch "#b5d7f3")
* oder Arrays mit je einem Wert für Rot, Grün und Blau
* (z. B. \$givenColor = array( 0xff, 0x00, 0x00 ) )
* sein.
*
* \$givenColor and the colors in \$palette should be either
* formatted as (#)rrggbb
* (e. g. "ff0000", "4da4f3" or "#b5d7f3")
* or arrays with values for red, green and blue
* (e. g. \$givenColor = array( 0xff, 0x00, 0x00 ) )
*
* Referenzen/References:
* function rgb2lab
*   - http://www.f4.fhtw-berlin.de/~barthel/ImageJ/ColorInspector//HTMLHilfe/farbraumJava.htm
*   - http://www.brucelindbloom.com/index.html?Eqn_RGB_to_XYZ.html
*   - http://www.brucelindbloom.com/index.html?Eqn_XYZ_to_Lab.html
*
* function deltaE
*   - http://www.brucelindbloom.com/index.html?Eqn_DeltaE_CMC.html
*/
function getNearestColor( \$givenColor,
\$palette = array('blue' => '0000ff','red' => 'ff0000','green' => '00ff00','yellow' => 'ffff00','black' => '000000','white' => 'ffffff','orange' => 'ff8800','purple' => 'ff00ff', 'teal' => '00ffff')
)
{
if(!function_exists('rgb2lab'))
{
function rgb2lab(\$rgb) {
\$eps = 216/24389; \$k = 24389/27;
// reference white D50
\$xr = 0.964221; \$yr = 1.0; \$zr = 0.825211;
// reference white D65
#\$xr = 0.95047; \$yr = 1.0; \$zr = 1.08883;

// RGB to XYZ
\$rgb = \$rgb/255; //R 0..1
\$rgb = \$rgb/255; //G 0..1
\$rgb = \$rgb/255; //B 0..1

// assuming sRGB (D65)
\$rgb = (\$rgb <= 0.04045)?(\$rgb/12.92):pow((\$rgb+0.055)/1.055,2.4);
\$rgb = (\$rgb <= 0.04045)?(\$rgb/12.92):pow((\$rgb+0.055)/1.055,2.4);
\$rgb = (\$rgb <= 0.04045)?(\$rgb/12.92):pow((\$rgb+0.055)/1.055,2.4);

// sRGB D50
\$x =  0.4360747*\$rgb + 0.3850649*\$rgb + 0.1430804*\$rgb;
\$y =  0.2225045*\$rgb + 0.7168786*\$rgb + 0.0606169*\$rgb;
\$z =  0.0139322*\$rgb + 0.0971045*\$rgb + 0.7141733*\$rgb;
// sRGB D65
/*\$x =  0.412453*\$rgb + 0.357580*\$rgb + 0.180423*\$rgb;
\$y =  0.212671*\$rgb + 0.715160*\$rgb + 0.072169*\$rgb;
\$z =  0.019334*\$rgb + 0.119193*\$rgb + 0.950227*\$rgb;*/

// XYZ to Lab
\$xr = \$x/\$xr; \$yr = \$y/\$yr; \$zr = \$z/\$zr;

\$fx = (\$xr > \$eps)?pow(\$xr, 1/3):(\$fx = (\$k * \$xr + 16) / 116); \$fy = (\$yr > \$eps)?pow(\$yr, 1/3):(\$fy = (\$k * \$yr + 16) / 116); \$fz = (\$zr > \$eps)?pow(\$zr, 1/3):(\$fz = (\$k * \$zr + 16) / 116);

\$lab = array();
\$lab[] = round(( 116 * \$fy ) - 16); \$lab[] = round(500*(\$fx-\$fy)); \$lab[] = round(200*(\$fy-\$fz));
return \$lab;
} // function rgb2lab
}

if(!function_exists('deltaE'))
{
function deltaE(\$lab1, \$lab2)
{
// CMC 1:1
\$l = 1; \$c = 1;

\$c1 = sqrt(\$lab1*\$lab1+\$lab1*\$lab1); \$c2 = sqrt(\$lab2*\$lab2+\$lab2*\$lab2);

\$h1 = (((180000000/M_PI) * atan2(\$lab1,\$lab1) + 360000000) % 360000000)/1000000;

\$t = (164 <= \$h1 AND \$h1 <= 345)?(0.56 + abs(0.2 * cos(\$h1+168))):(0.36 + abs(0.4 * cos(\$h1+35)));
\$f = sqrt(pow(\$c1,4)/(pow(\$c1,4) + 1900));

\$sl = (\$lab1 < 16)?(0.511):((0.040975*\$lab1)/(1 + 0.01765*\$lab1));
\$sc = (0.0638 * \$c1)/(1 + 0.0131 * \$c1) + 0.638;
\$sh = \$sc * (\$f * \$t + 1 -\$f);

return sqrt( pow((\$lab1-\$lab2)/(\$l * \$sl),2) + pow((\$c1-\$c2)/(\$c * \$sc),2) + pow(sqrt((\$lab1-\$lab2)*(\$lab1-\$lab2) + (\$lab1-\$lab2)*(\$lab1-\$lab2) + (\$c1-\$c2)*(\$c1-\$c2))/\$sh,2) );
} // function deltaE
}

if(!function_exists('colorDistance'))
{
function colorDistance(\$lab1,\$lab2)
{
return sqrt((\$lab1-\$lab2)*(\$lab1-\$lab2)+(\$lab1-\$lab2)*(\$lab1-\$lab2)+(\$lab1-\$lab2)*(\$lab1-\$lab2));
}
}

if(!function_exists('str2rgb'))
{
function str2rgb(\$str)
{
\$str = preg_replace('~[^0-9a-f]~','',\$str);
\$rgb = str_split(\$str,2);
for(\$i=0;\$i<3;\$i++)
\$rgb[\$i] = intval(\$rgb[\$i],16);

return \$rgb;
} // function str2rgb
}

// split into RGB, if not already done
\$givenColorRGB = is_array(\$givenColor)?\$givenColor:str2rgb(\$givenColor);
\$min = 0xffff;
\$return = NULL;

foreach(\$palette as \$key => \$color)
{
// split into RGB
\$color = is_array(\$color)?\$color:str2rgb(\$color);
// deltaE
#if(\$min >= (\$deltaE = deltaE(rgb2lab(\$color),rgb2lab(\$givenColorRGB))))
// euclidean distance
if(\$min >= (\$deltaE = colorDistance(rgb2lab(\$color),rgb2lab(\$givenColorRGB))))
{
\$min = \$deltaE;
\$return = \$key;
}
}

return \$return;
}
``````
• for me this is the only proper answer! – Andreas Linden Jun 22 '16 at 12:02
• Be aware that meanwhile there are replacements for the Delta E algorithm I used in the above code. Nevertheless, if I were to implement a new color distance function today, I would use the DIN99c or DIN99d color spaces since they are easier and faster to calculate than CIE94 or CIEDE2000 while serving a similar quality. – xong Mar 12 '17 at 10:14
• Some explanation is in order. What does this do? Why is it better? – Raphael Apr 1 '17 at 7:26
• This function uses a color space in which the distances between the colors are similar to the human color perception. This allows for a certain color to get the best matching color from a given palette. But as I wrote: Today I would use an implementation of DIN99 to achieve this. The above function was written over 10 years ago. – xong Apr 8 '17 at 9:27

Calculate the distance from the input color to all possible candidates of your palette, and then pick the one with the smallest distance as the one to replace it with.

Distance can be defined in any way you like; Euclidean distance seems workable for RGB cubes, cylinders or HSL/HSV cones.

There is no point in taking the square root. Finding the shortest distance is the same as finding the shortest squared distance. `sqrt` is an expensive operation, so just skip it.

Whether it really matters, of course, depends of how often your program will make this calculation, but it's still pointless to have it.