Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I've got 3x3D arrays which are the red, green and blue channels of a 3D rgb image. What is an elegant way in numpy to to create a histogram volume of the input channels?

The operation would be equivalent to

""" assume R, G and B are 3D arrays and output is a 3D array filled with zeros """
for x in x_dim:
     for y in y_dim:
          for z in z_dim:
               output[ R[x][y][z] ][ G[x][y][z] ][ B[x][y][z] ] += 1

This code too slow for large images. Can numpy improve the efficiency of the above algorithm?

share|improve this question
up vote 4 down vote accepted

You can do it using numpy.histogramdd but, as you say, the method proposed by @jozzas won't work. What you have to do is flatten each of your three 3D arrays and then combine them into a 2-d array of dimensions (x_dim*y_dim*z_dim, 3), which you pass to histogramdd. The fact that your original data are 3D is a red herring, since the spatial information is irrelevant to calculating the histogram.

Here is an example using random data in the channel cubes:

import numpy 

n = 400  # approximate largest cube size that works on my laptop
# Fill channel cubes with random 8-bit integers
r = numpy.random.randint(256, size=(n,n,n)).astype(numpy.uint8)
g = numpy.random.randint(256, size=(n,n,n)).astype(numpy.uint8)
b = numpy.random.randint(256, size=(n,n,n)).astype(numpy.uint8)

# reorder data into for suitable for histogramming
data = numpy.vstack((r.flat, g.flat, b.flat)).astype(numpy.uint8).T

# Destroy originals to save space
del(r); del(g); del(b)

m = 256                                  # size of 3d histogram cube
hist, edges = numpy.histogramdd(
    data, bins=m, range=((-0.5,255.5),(-0.5,255.5),(-0.5,255.5))

# Check that it worked
assert hist.sum() == n**3, 'Failed to conserve pixels'

This does use a lot more memory than you would expect because histogramdd seems to be using 64-bit floats to do its work, even though we are sending it 8-bit integers.

share|improve this answer
What will the output of such a procedure yield? I'm imagining output where output[x,y,z] is the count of R[:]==x and G[:]==y and B[:]==z. Is it something at all like this? – ajwood Sep 15 '11 at 15:22
Yes, that is exactly right. I get the impression that your input channel arrays are integers, in which case you can specify bins=N and range=((0,N-1),(0,N-1),(0,N-1)), where N is the number of discrete pixel values (e.g., N=256 for 8 bits per channel). However, unless x_dim, etc are much larger than N, then I imagine this will give you a rather sparse and noisy histogram. So you might want to set the bins parameter to a smaller value. For more details, see the docs for histogramdd – deprecated Sep 15 '11 at 15:36
This works, except only on input arrays smaller than 40x40x40... any idea why that might be? – ajwood Sep 16 '11 at 1:57
I have edited my answer to include example code. I can get it to work on arrays up to 400x400x400 on a machine with very little free memory. This took 30 sec of CPU time and the python process seemed to max out at about 1.5GB memory usage. How big are your arrays? – deprecated Sep 16 '11 at 5:12

Assuming 8-bit channels, the 3-tuple of integers (R,G,B) can be thought of as a single number in base 256: R*256**2 + G*256 + B. Thus we can convert the 3 arrays R,G,B into a single array of "color values" and use np.bincount to produce the desired histogram.

import numpy as np

def using_bincount(r,g,b):
    return output

def using_histogramdd(r,g,b):
    data = np.vstack((r.flat, g.flat, b.flat)).astype(np.uint8).T
    del(r); del(g); del(b)
    hist, edges = np.histogramdd(
        data, bins=base, range=([0,base],[0,base],[0,base])
    return hist

n = 200
base = 256
r = np.random.randint(base, size=(n,n,n)).astype(np.uint8)
g = np.random.randint(base, size=(n,n,n)).astype(np.uint8)
b = np.random.randint(base, size=(n,n,n)).astype(np.uint8)

if __name__=='__main__':
    assert np.allclose(bhist,hhist)

These timeit results suggest using_bincount is faster than using_histogramdd, perhaps because histogramdd is built for handling floats and bins which are ranges, while bincount is solely for counting integers.

% python -mtimeit -s'import test' 'test.using_bincount(test.r,test.g,test.b)'
10 loops, best of 3: 1.07 sec per loop
% python -mtimeit -s'import test' 'test.using_histogramdd(test.r,test.g,test.b)'
10 loops, best of 3: 8.42 sec per loop
share|improve this answer

You can use numpy's histogramdd to compute the histogram of an n-dimensional array. If you don't want a histogram for each 2d slice, be sure to set the bins for that dimension to 1.

To get the overall histogram, you could compute them individually for the R, G and B channels and then take the maximum value of the three for each position.

share|improve this answer
I like the idea of using histogramdd and just setting the bins to 1 for a dimension you don't need to use. I don't know where, but I'm going to use that. +1 – Carl F. Sep 15 '11 at 0:14
The information that needs to come out is the values of each inputs at corresponding indices. I don't understand how you can compute the histograms for each channel individually and keep any notion of, for example, (1,1,1) aligning on each input. – ajwood Sep 15 '11 at 13:06

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.