# How to find the dominant/most common color in an image?

I'm looking for a way to find the most dominant color/tone in an image using python. Either the average shade or the most common out of RGB will do. I've looked at the Python Imaging library, and could not find anything relating to what I was looking for in their manual, and also briefly at VTK.

I did however find a PHP script which does what I need, here (login required to download). The script seems to resize the image to 150*150, to bring out the dominant colors. However, after that, I am fairly lost. I did consider writing something that would resize the image to a small size then check every other pixel or so for it's image, though I imagine this would be very inefficient (though implementing this idea as a C python module might be an idea).

However, after all of that, I am still stumped. Is there an easy, efficient way to find the dominant color in an image?

• I'm guessing it resizes the picture to let the rescaling algorithm do some of the averaging for you. Commented Jul 13, 2010 at 22:09

Here's code making use of Pillow and Scipy's cluster package.

For simplicity I've hardcoded the filename as "image.jpg". Resizing the image is for speed: if you don't mind the wait, comment out the resize call. When run on this sample image,

it usually says the dominant colour is #d8c865, which corresponds roughly to the bright yellowish area to the lower left of the two peppers. I say "usually" because the clustering algorithm used has a degree of randomness to it. There are various ways you could change this, but for your purposes it may suit well. (Check out the options on the kmeans2() variant if you need deterministic results.)

``````from __future__ import print_function
import binascii
import struct
from PIL import Image
import numpy as np
import scipy
import scipy.misc
import scipy.cluster

NUM_CLUSTERS = 5

im = Image.open('image.jpg')
im = im.resize((150, 150))      # optional, to reduce time
ar = np.asarray(im)
shape = ar.shape
ar = ar.reshape(scipy.product(shape[:2]), shape[2]).astype(float)

print('finding clusters')
codes, dist = scipy.cluster.vq.kmeans(ar, NUM_CLUSTERS)
print('cluster centres:\n', codes)

vecs, dist = scipy.cluster.vq.vq(ar, codes)         # assign codes
counts, bins = scipy.histogram(vecs, len(codes))    # count occurrences

index_max = scipy.argmax(counts)                    # find most frequent
peak = codes[index_max]
colour = binascii.hexlify(bytearray(int(c) for c in peak)).decode('ascii')
print('most frequent is %s (#%s)' % (peak, colour))
``````

Note: when I expand the number of clusters to find from 5 to 10 or 15, it frequently gave results that were greenish or bluish. Given the input image, those are reasonable results too... I can't tell which colour is really dominant in that image either, so I don't fault the algorithm!

Also a small bonus: save the reduced-size image with only the N most-frequent colours:

``````# bonus: save image using only the N most common colours
import imageio
c = ar.copy()
for i, code in enumerate(codes):
c[scipy.r_[scipy.where(vecs==i)],:] = code
imageio.imwrite('clusters.png', c.reshape(*shape).astype(np.uint8))
print('saved clustered image')
``````
• Wow. That's great. Almost exactly what I was looking for. I did look at scipy, and had a feeling the answer was somewhere in there :P Thank you for your answer. Commented Jul 14, 2010 at 11:38
• I've edited/updated your code. Thanks for this compact and well working solution! Commented Dec 3, 2017 at 18:04
• @SimonSteinberger Thanks for the edit, and I'm happy to hear it's still able to run and help someone 7 years later! It was a fun problem to work on. Commented Dec 3, 2017 at 18:15
• this has multiple issues with python 3.x. For example, (1) `.encode('hex')` is no longer valid syntax, and (2) `from PIL import Image` source Commented May 5, 2019 at 12:12
• Thanks @philshem. I believe I've modified it to support 3.x as well now. Some changes done at the same time resolved deprecations and warnings that were reported on either 2.7 or 3.7 (but not necessarily both). Commented May 6, 2019 at 14:18

Try `Color Thief`, installable via PyPI. The only requirement is `Pillow`.

### Installation

``````pip install colorthief
``````

### Usage

``````from colorthief import ColorThief

color_thief = ColorThief('/path/to/imagefile')
``````

#### Get the dominant color

``````dominant_color = color_thief.get_color(quality=1)
``````

The output is a tuple `(r, g, b)`.

NB: The parameter `quality` is optional and allows to trade quality for speed. 1 gives the highest quality. The larger the number, the faster a color will be returned but the greater the likelihood that it is not the visually most dominant color.

#### Build a color palette

``````palette = color_thief.get_palette(color_count=6, quality=1)
``````

The output is a list of tuples `(r, g, b)`.

The parameter `color_count` is the size of the palette, i.e. the maximal number of colors.

NB: The parameter `quality` is optional and allows to trade quality for speed. 1 gives the highest quality. The larger the number, the faster the palette generation, but the greater the likelihood that colors are missed.

• Fantastic module Commented Jan 13, 2020 at 21:26
• I am wondering if there is a difference in the correcness of the methods in Top voted, accepeted answer and this? I understand the other answer is old and hence might have more votes. Commented Jan 29, 2022 at 11:44
• This method doesn't give me accurate result. I used PIL resize from the other answer and it worked great. Commented Jun 11 at 16:36
• @Soyal7 stackoverflow is dead after the AI development, no need to use this outdated tech lmao Commented Jun 14 at 13:35

You can do this in many different ways. And you don't really need scipy and k-means since internally Pillow already does that for you when you either resize the image or reduce the image to a certain palette.

Solution 1: resize image down to 1 pixel.

``````def get_dominant_color(pil_img):
img = pil_img.copy()
img = img.convert("RGBA")
img = img.resize((1, 1), resample=0)
dominant_color = img.getpixel((0, 0))
return dominant_color

``````

Solution 2: reduce image colors to a palette.

``````def get_dominant_color(pil_img, palette_size=16):
# Resize image to speed up processing
img = pil_img.copy()
img.thumbnail((100, 100))

# Reduce colors (uses k-means internally)
paletted = img.convert('P', palette=Image.ADAPTIVE, colors=palette_size)

# Find the color that occurs most often
palette = paletted.getpalette()
color_counts = sorted(paletted.getcolors(), reverse=True)
palette_index = color_counts[0][1]
dominant_color = palette[palette_index*3:palette_index*3+3]

return dominant_color
``````

Both solutions give similar results. The latter solution gives you probably more accuracy since we keep the aspect ratio when resizing the image. Also, you get more control since you can tweak the `palette_size`.

Addendum: retrieve a list of the top dominant colors.

``````def get_dominant_colors(pil_img, palette_size=16, num_colors=10):
# Resize image to speed up processing
img = pil_img.copy()
img.thumbnail((100, 100))

# Reduce colors (uses k-means internally)
paletted = img.convert('P', palette=Image.ADAPTIVE, colors=palette_size)

# Find the color that occurs most often
palette = paletted.getpalette()
color_counts = sorted(paletted.getcolors(), reverse=True)

dominant_colors = []
for i in range(num_colors):
palette_index = color_counts[i][1]
dominant_colors.append(palette[palette_index*3:palette_index*3+3])

return dominant_colors
``````
• This is also leaps and bounds faster than any of the scikit-learn/scipy images above. Commented May 15, 2020 at 2:38
• Works like a charm, and doesn't require any additional modules. Thank you so much! Commented Feb 4, 2021 at 14:53
• Thanks for the piece of code, also could you explain how to know what colour is this (Red, blue...). It would be great if you can provide some piece of code. Commented Apr 4, 2022 at 12:56
• This could be made faster with `topk`, at the price of adding another dependency, such as `torch.`
– Wok
Commented Dec 27, 2023 at 20:45

Python Imaging Library has method getcolors on Image objects:

im.getcolors() => a list of (count, color) tuples or None

I guess you can still try resizing the image before that and see if it performs any better.

## My solution

Here's my adaptation based on Peter Hansen's solution.

``````import scipy.cluster
import sklearn.cluster
import numpy
from PIL import Image

def dominant_colors(image):  # PIL image input

image = image.resize((150, 150))      # optional, to reduce time
ar = numpy.asarray(image)
shape = ar.shape
ar = ar.reshape(numpy.product(shape[:2]), shape[2]).astype(float)

kmeans = sklearn.cluster.MiniBatchKMeans(
n_clusters=10,
init="k-means++",
max_iter=20,
random_state=1000
).fit(ar)
codes = kmeans.cluster_centers_

vecs, _dist = scipy.cluster.vq.vq(ar, codes)         # assign codes
counts, _bins = numpy.histogram(vecs, len(codes))    # count occurrences

colors = []
for index in numpy.argsort(counts)[::-1]:
colors.append(tuple([int(code) for code in codes[index]]))
return colors                    # returns colors in order of dominance
``````

## What are the differences/improvements?

### It's (subjectively) more accurate

It's using the kmeans++ to pick initial cluster centers which gives better results. (kmeans++ may not be the fastest way to pick cluster centers though)

### It's faster

Using `sklearn.cluster.MiniBatchKMeans` is significantly faster and gives very similar colors to the default KMeans algorithm. You can always try the slower `sklearn.cluster.KMeans` and compare the results and decide whether the tradeoff is worth it.

### It's deterministic

I am using a random_state to get consistent ouput (I believe the original `scipy.cluster.vq.kmeans` also has a `seed` parameter). Before adding a random state I found that certain inputs could have significantly different outputs.

### Benchmarks

I decided to very crudely benchmark a few solutions.

Method Time (100 iterations)
Peter Hansen (kmeans) 58.85
Artem Bernatskyi (Color Thief) 61.29
Artem Bernatskyi (Color Thief palette) 15.69
Pithikos (PIL resize) 0.11
Pithikos (palette) 1.68
Mine (mini batch kmeans) 6.31
• Thanks for adding to the solution Jacob! It's gratifying to see this fun question still helping people out. :) Commented Jan 6, 2022 at 22:47

It's not necessary to use k-means to find the dominant color as Peter suggests. This overcomplicates a simple problem. You're also restricting yourself by the amount of clusters you select, so basically you need an idea of what you're looking at.

As you mentioned and as suggested by zvone, a quick solution to find the most common/dominant color is by using the Pillow library. We just need to sort the pixels by their count number.

``````from PIL import Image

def find_dominant_color(filename):
#Resizing parameters
width, height = 150, 150
image = Image.open(filename)
image = image.resize((width, height), resample = 0)
#Get colors from image object
pixels = image.getcolors(width * height)
#Sort them by count number(first element of tuple)
sorted_pixels = sorted(pixels, key=lambda t: t[0])
#Get the most frequent color
dominant_color = sorted_pixels[-1][1]
return dominant_color
``````

The only problem is that the method `getcolors()` returns None when the amount of colors is more than 256. You can deal with it by resizing the original image.

In all, it might not be the most precise solution, but it gets the job done.

• This is not very reliable. (1) you should use `thumbnail` instead of resize to avoid crop or stretch, (2) if you have an image with 2 white pixels and 100 different levels of blackish pixels, you will still get white. Commented May 11, 2020 at 11:27
• Agreed but I wanted to avoid the caveat of reducing the granularity when using predefined clusters or a palette. Depending on the use case this might not be desirable. Commented Jul 10, 2020 at 15:51
• The resampling filter you use might be the cheapest, but the result can be very surprising to users if the picture has really high resolution and is a bit noisy.
– Wolf
Commented Feb 6, 2023 at 10:26

If you're still looking for an answer, here's what worked for me, albeit not terribly efficient:

``````from PIL import Image

def compute_average_image_color(img):
width, height = img.size

r_total = 0
g_total = 0
b_total = 0

count = 0
for x in range(0, width):
for y in range(0, height):
r, g, b = img.getpixel((x,y))
r_total += r
g_total += g
b_total += b
count += 1

return (r_total/count, g_total/count, b_total/count)

img = Image.open('image.png')
#img = img.resize((50,50))  # Small optimization
average_color = compute_average_image_color(img)
print(average_color)
``````
• For png, you need to tweak this slightly to handle the fact that img.getpixel returns r,g,b,a (four values instead of three). Or it did for me anyway. Commented Sep 26, 2016 at 15:28
• This weighs pixels unevenly. The final pixel touched contributes half the total value. The pixel before contributes half of that. Only the last 8 pixels will affect the average at all, in fact. Commented Jan 22, 2017 at 13:52
• You're right - silly mistake. Just edited the answer - let me know if that works. Commented Jan 23, 2017 at 19:00
• This is not an answer to this question. Average color is not the dominant color in an image. Commented Aug 15, 2019 at 13:12

You could use PIL to repeatedly resize the image down by a factor of 2 in each dimension until it reaches 1x1. I don't know what algorithm PIL uses for downscaling by large factors, so going directly to 1x1 in a single resize might lose information. It might not be the most efficient, but it will give you the "average" color of the image.

To add to Peter's answer, if PIL is giving you an image with mode "P" or pretty much any mode that isn't "RGBA", then you need to apply an alpha mask to convert it to RGBA. You can do that pretty easily with:

``````if im.mode == 'P':
im.putalpha(0)
``````

Below is a c++ Qt based example to guess the predominant image color. You can use PyQt and translate the same to Python equivalent.

``````#include <Qt/QtGui>
#include <Qt/QtCore>
#include <QtGui/QApplication>

int main(int argc, char** argv)
{
QApplication app(argc, argv);
QPixmap pixmap("logo.png");
QImage image = pixmap.toImage();
QRgb col;
QMap<QRgb,int> rgbcount;
QRgb greatest = 0;

int width = pixmap.width();
int height = pixmap.height();

int count = 0;
for (int i = 0; i < width; ++i)
{
for (int j = 0; j < height; ++j)
{
col = image.pixel(i, j);
if (rgbcount.contains(col)) {
rgbcount[col] = rgbcount[col] + 1;
}
else  {
rgbcount[col] = 1;
}

if (rgbcount[col] > count)  {
greatest = col;
count = rgbcount[col];
}

}
}
qDebug() << count << greatest;
return app.exec();
}
``````

This is a complete script with a function compute_average_image_color().

Just copy and past it, and change the path of your image.

My image is img_path='./dir/image001.png'

``````#AVERANGE COLOR, MIN, MAX, STANDARD DEVIATION
#SELECT ONLY NOT TRANSPARENT COLOR

from PIL import Image
import sys
import os
import os.path
from os import path
import numpy as np
import math

def compute_average_image_color(img_path):

if not os.path.isfile(img_path):
print(path_inp_image, 'DONT EXISTS, EXIT')
sys.exit()

img = Image.open(img_path).convert('RGBA')
img = img.resize((50,50))  # Small optimization

#DEFINE SOME VARIABLES
width, height = img.size
r_total = 0
g_total = 0
b_total = 0
count = 0
red_list=[]
green_list=[]
blue_list=[]

#READ AND CHECK PIXEL BY PIXEL
for x in range(0, width):
for y in range(0, height):
r, g, b, alpha = img.getpixel((x,y))

if alpha !=0:
red_list.append(r)
green_list.append(g)
blue_list.append(b)

r_total += r
g_total += g
b_total += b
count += 1

#CALCULATE THE AVRANGE COLOR, MIN, MAX, ETC
average_color=(round(r_total/count), round(g_total/count), round(b_total/count))
print(average_color)

red_list.sort()
green_list.sort()
blue_list.sort()

red_min_max=[]
green_min_max=[]
blue_min_max=[]

red_min_max.append(min(red_list))
red_min_max.append(max(red_list))
green_min_max.append(min(green_list))
green_min_max.append(max(red_list))
blue_min_max.append(min(blue_list))
blue_min_max.append(max(blue_list))

print('red_min_max: ', red_min_max)
print('green_min_max: ', green_min_max)
print('blue_min_max: ', blue_min_max)

#variance and standard devietion
red_stddev=round(math.sqrt(np.var(red_list)))
green_stddev=round(math.sqrt(np.var(green_list)))
blue_stddev=round(math.sqrt(np.var(blue_list)))

print('red_stddev: ', red_stddev)
print('green_stddev: ', green_stddev)
print('blue_stddev: ', blue_stddev)

img_path='./dir/image001.png'
compute_average_image_color(img_path)

``````
• Can you explain your code a little bit? (What libraries or modules you used if any and why). It would be nice for others to understand your research, the downsides and upsides of your code and alternatives. It's always better to add some explanation in order to provide context to readers. Commented Jul 1, 2021 at 21:11
• Look better. This is a complete python script. There are 7-8 IMPORT instructions. And every line of code is commented. This is a script, so the user can copy and paste it. You have just change the name of the input image image001.png Commented Jul 1, 2021 at 21:31
• The question is not about getting the average color, but about getting the dominant one, this script can return a color that doesn't exist at all in the original image (for a simple example, think of the image of a random country flag, and what it'll return, for France it'll be a clear purple, while the dominant color should be one of red, white and blue, as they are equally present). Commented Apr 5, 2023 at 17:39
• @Tshirtman. Read the script code. #CALCULATE THE AVRANGE COLOR, MIN, MAX, ETC rtman Commented Apr 6, 2023 at 9:16
• I did read the code, did you read the question? Commented Apr 6, 2023 at 22:56