Here is a pixelwise way of doing it, which can work for any number of colors in the image (although it can get slow for many colours and large images). It also will work for paletted images (it converts them).
im = im.convert('RGB')
colors = im.getcolors()
width, height = im.size
colors_dict = dict((val,Image.new('RGB', (width, height), (0,0,0)))
for val in colors)
pix = im.load()
for i in xrange(width):
for j in xrange(height):
im = Image.open("colorwheel.tiff")
colors_dict = color_separator(im)
#show the images:
im.getcolors() returns a list of all the colors in the image and the number of times they occur, as a tuple, unless the number of colors exceeds a max value (which you can specify, and defaults to 256).
- We then build a dictionary
colors_dict, keyed by the colors in the image, and with corresponding values of empty images.
- We then iterate over the image for all pixels, updating the appropriate dictionary entry for each pixel. Doing it like this means we only need to read through the image once. We use
load() to make pixel access faster as we read through the image.
color_separator() returns a dictionary of images, keyed by every unique colour in the image.
To make it faster you could use
load() for every image in
colors_dict, but you may need to be a little careful as it could consume a lot of memory if the images have many colours and are large. If this isn't an issue then add (after the creation of
fast_colors = dict((key, value.load()) for key, value in colors_dict.items())
fast_colors[pix[j,i]][j,i] = pix[j,i]
22 color image:
22 color isolated images: