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Trying to solve a problem of preventing duplicate images to be uploaded.

I have two JPGs. Looking at them I can see that they are in fact identical. But for some reason they have different file size (one is pulled from a backup, the other is another upload) and so they have a different md5 checksum.

How can I efficiently and confidently compare two images in the same sense as a human would be able to see that they are clearly identical?

Example: and


I wrote this script:

import math, operator
from PIL import Image
def compare(file1, file2):
    image1 =
    image2 =
    h1 = image1.histogram()
    h2 = image2.histogram()
    rms = math.sqrt(reduce(operator.add,
                           map(lambda a,b: (a-b)**2, h1, h2))/len(h1))
    return rms

if __name__=='__main__':
    import sys
    file1, file2 = sys.argv[1:]
    print compare(file1, file2)

Then I downloaded the two visually identical images and ran the script. Output:


Can anybody tell me what a suitable cutoff should be?

Update II

The difference between a.jpg and b.jpg is that the second one has been saved with PIL:'a.jpg')'b.jpg','wb'))

This apparently applies some very very light quality modifications. I've now solved my problem by applying the same PIL save to the file being uploaded without doing anything with it and it now works!

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As far as I can neither of them have exif data. – Peter Bengtsson Dec 18 '09 at 11:28
reduce(operator.add(...)) -> sum(...). – J.F. Sebastian Dec 18 '09 at 13:49
For what it's worth (mainly in references to background info) this is like a simplified version of this question: – Peter Hansen Dec 18 '09 at 13:57
The links for your images have gone bad. Note that stackoverflow now has an image hosting service. – ThomasW Nov 17 '11 at 0:51
@J.F.Sebastian if I get it right statistics.pstdev comes remarkably close, but it operates on a single sequence and uses a constant mu instead of items from another sequence. too bad. rewritten as rms = math.sqrt(sum((a-b)**2 for a,b in zip(h1, h2))/len(h1)) – n611x007 Aug 8 '14 at 16:21

7 Answers 7

up vote 17 down vote accepted

There is a OSS project that uses WebDriver to take screen shots and then compares the images to see if there are any issues ( It does it by openning the file into a stream and then comparing every bit.

You may be able to do something similar with PIL.


After more research I found

h1 ="image1").histogram()
h2 ="image2").histogram()

rms = math.sqrt(reduce(operator.add,
    map(lambda a,b: (a-b)**2, h1, h2))/len(h1))

on and

share|improve this answer
I applied that technique but for the two images I linked to above, the RMS is 58.9. If I compare a.jpg with a.jpg I get 0.0 which is expected. I changed one in gimp by drawing some crap on it and the RMS came to 675.6 – Peter Bengtsson Dec 18 '09 at 12:47
This code finds the RMS error between the images’ histograms, NOT between the images themselves. Consider that two images could have identical histograms but be completely different, for example if you “scrambled” the pixels. – musicinmybrain Dec 18 '09 at 12:47
It should be noted that if you replace the map + reduce call with the equivalent list comprehension, you'll get a very nice speed boost (about 80% faster on my Mac). Use the following code instead (apologies for the poor formatting): diff_squares = [(h1[i] - h2[i]) ** 2 for i in xrange(len(h1))]; rms = math.sqrt(sum(diff_squares) / len(h1));. This is on Python 2.7.3 and I've replicated the results on OS X and Linux. YMMV, but the difference is large enough to warrant investigation. – CadentOrange Oct 4 '12 at 13:31
the actual source seems to be from 1997 from – n611x007 Aug 8 '14 at 16:33
That histogram method is even more wrong than @musicinmybrain already noted. See…. E.g. a 100x50 image that's half red half blue has the same histogram as a 50x100 image that's half magenta half black. – mercator Dec 15 '14 at 16:43

From here

The quickest way to determine if two images have exactly the same contents is to get the difference between the two images, and then calculate the bounding box of the non-zero regions in this image. If the images are identical, all pixels in the difference image are zero, and the bounding box function returns None.

import ImageChops

def equal(im1, im2):
    return ImageChops.difference(im1, im2).getbbox() is None
share|improve this answer

Using ImageMagick, you can simply use in your shell [or call via the OS library from within a program]

compare image1 image2 output

This will create an output image with the differences marked

compare -metric AE -fuzz 5% image1 image2 output

Will give you a fuzziness factor of 5% to ignore minor pixel differences. More information can be procured from here

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Is there a way that you can programmatically determine if the resulting output is blank? – Flimm Dec 28 '12 at 17:26

I guess you should decode the images and do a pixel by pixel comparison to see if they're reasonably similar.

With PIL and Numpy you can do it quite easily:

import Image
import numpy
import sys

def main():
    img1 =[1])
    img2 =[2])

    if img1.size != img2.size or img1.getbands() != img2.getbands():
        return -1

    s = 0
    for band_index, band in enumerate(img1.getbands()):
        m1 = numpy.array([p[band_index] for p in img1.getdata()]).reshape(*img1.size)
        m2 = numpy.array([p[band_index] for p in img2.getdata()]).reshape(*img2.size)
        s += numpy.sum(numpy.abs(m1-m2))
    print s

if __name__ == "__main__":

This will give you a numeric value that should be very close to 0 if the images are quite the same.

Note that images that are shifted/rotated will be reported as very different, as the pixels won't match one by one.

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Normalized color histograms (in the OP's question) aren't affected by shifts/rotations. You can reduce your algorithm's sensitivity to small rotations/shift by downsampling before diffing, e.g. sum 10x10 boxes pixels and diff those 100x fewer "pixels". – hobs Dec 30 '13 at 4:12

the problem of knowing what makes some features of the image more important than other is a whole scientific program. I would suggest some alternatives depending on the solution you want:

  • if your problem is to see if there is a flipping of bits in your JPEGs, then try to image the difference image (there was perhaps a minor edit locally?),

  • to see if images are globally the same, use the Kullback Leibler distance to compare your histograms,

  • to see if you have some qualittative change, before applying other answers, filter your image using the functions below to raise the importance of high-level frequencies:


def FTfilter(image,FTfilter):
    from scipy.fftpack import fft2, fftshift, ifft2, ifftshift
    from scipy import real
    FTimage = fftshift(fft2(image)) * FTfilter
    return real(ifft2(ifftshift(FTimage)))
    #return real(ifft2(fft2(image)* FTfilter))

#### whitening
def olshausen_whitening_filt(size, f_0 = .78, alpha = 4., N = 0.01):
    Returns the whitening filter used by (Olshausen, 98)

    f_0 = 200 / 512

    /!\ you will have some problems at dewhitening without a low-pass

    from scipy import mgrid, absolute
    fx, fy = mgrid[-1:1:1j*size[0],-1:1:1j*size[1]]
    rho = numpy.sqrt(fx**2+fy**2)
    K_ols = (N**2 + rho**2)**.5 * low_pass(size, f_0 = f_0, alpha = alpha)
    K_ols /= numpy.max(K_ols)

    return  K_ols

def low_pass(size, f_0, alpha):
    Returns the low_pass filter used by (Olshausen, 98)

    parameters from Atick (p.240)
    f_0 = 22 c/deg in primates: the full image is approx 45 deg
    alpha makes the aspect change (1=diamond on the vert and hor, 2 = anisotropic)


    from scipy import mgrid, absolute
    fx, fy = mgrid[-1:1:1j*size[0],-1:1:1j*size[1]]
    rho = numpy.sqrt(fx**2+fy**2)
    low_pass = numpy.exp(-(rho/f_0)**alpha)

    return  low_pass

(shameless copy from )

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would you mind formatting your code? – tgray Dec 18 '09 at 15:58

First, I should note they’re not identical; b has been recompressed and lost quality. You can see this if you look carefully on a good monitor.

To determine that they are subjectively “the same,” you would have to do something like what fortran suggested, although you will have to arbitrarily establish a threshold for “sameness.” To make s independent of image size, and to handle channels a little more sensibly, I would consider doing the RMS (root mean square) Euclidean distance in colorspace between the pixels of the two images. I don’t have time to write out the code right now, but basically for each pixel, you compute

(R_2 - R_1) ** 2 + (G_2 - G_1) ** 2 + (B_2 - B_1) ** 2

, adding in an

(A_2 - A_1) ** 2

term if the image has an alpha channel, etc. The result is the square of the colorspace distance between the two images. Find the mean (average) across all pixels, then take the square root of the resulting scalar. Then decide a reasonable threshold for this value.

Or, you might just decide that copies of the same original image with different lossy compression are not truly “the same” and stick with the file hash.

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You can either compare it using PIL (iterate through pixels / segments of the picture and compare) or if you're looking for a complete identical copy comparison, try comparing the MD5 hash of both files.

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