34

For an image processing class, I am doing point operations on monochrome images. Pixels are uint8 [0,255].

numpy uint8 will wrap. For example, 235+30 = 9. I need the pixels to saturate (max=255) or truncate (min=0) instead of wrapping.

My solution uses int32 pixels for the point math then converts to uint8 to save the image.

Is this the best way? Or is there a faster way?

#!/usr/bin/python

import sys
import numpy as np
import Image

def to_uint8( data ) :
    # maximum pixel
    latch = np.zeros_like( data )
    latch[:] = 255
    # minimum pixel
    zeros = np.zeros_like( data )

    # unrolled to illustrate steps
    d = np.maximum( zeros, data )
    d = np.minimum( latch, d )

    # cast to uint8
    return np.asarray( d, dtype="uint8" )

infilename=sys.argv[1]
img = Image.open(infilename)
data32 = np.asarray( img, dtype="int32")
data32 += 30
data_u8 = to_uint8( data32 )
outimg = Image.fromarray( data_u8, "L" )
outimg.save( "out.png" )

Input image:
Riemann

Output image:
Output

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1
  • While working with the MNIST dataset my resulting .png images showed weird square artifacts instead of the actual handwritten number. The issue was also the dtype int32. After using the accepted answer with numpy.clip and the astype() conversion everything worked.
    – JohnDizzle
    May 21, 2020 at 8:42

3 Answers 3

Reset to default
39

Use numpy.clip:

import numpy as np
np.clip(data32, 0, 255, out=data32)
data_u8 = data32.astype('uint8')

Note that you can also brighten images without numpy this way:

import ImageEnhance
enhancer = ImageEnhance.Brightness(img)
outimg = enhancer.enhance(1.2)
outimg.save('out.png')
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1
  • 1
    np.clip() is exactly what I've been needing. Thanks! I'll also read up on ImageEnhance. The homework was about doing point ops ourselves but will be good to learn other ways.
    – David Poole
    Sep 25, 2011 at 19:57
6

You can use OpenCV add or subtract functions (additional explanation here).

>>> import numpy as np
>>> import cv2
>>> arr = np.array([100, 250, 255], dtype=np.uint8)
>>> arr
Out[1]: array([100, 250, 255], dtype=uint8)
>>> cv2.add(arr, 10, arr)  # Inplace
Out[2]: array([110, 255, 255], dtype=uint8)  # Saturated!
>>> cv2.subtract(arr, 150, arr)
Out[3]: array([  0, 105, 105], dtype=uint8)  # Truncated!

Unfortunately it's impossible to use indexes for output array, so inplace calculations for each image channel may be performed in this, less efficient, way:

arr[..., channel] = cv2.add(arr[..., channel], 40)
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1

Basically, it comes down to checking before you add. For instance, you could define a function like this:

def clip_add(arr, amt):
    if amt > 0:
        cutoff = 255 - amt
        arr[arr > cutoff] = 255
        arr[arr <= cutoff] += amt
    else:
        cutoff = -amt
        arr[arr < cutoff] = 0
        arr[arr >= cutoff] += amt
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