I'm using PIL to convert a transparent PNG image uploaded with Django to a JPG file. The output looks broken.

Source file

transparent source file


Image.open(object.logo.path).save('/tmp/output.jpg', 'JPEG')




Both ways, the resulting image looks like this:

resulting file

Is there a way to fix this? I'd like to have white background where the transparent background used to be.


Thanks to the great answers, I've come up with the following function collection:

import Image
import numpy as np

def alpha_to_color(image, color=(255, 255, 255)):
    """Set all fully transparent pixels of an RGBA image to the specified color.
    This is a very simple solution that might leave over some ugly edges, due
    to semi-transparent areas. You should use alpha_composite_with color instead.

    Source: http://stackoverflow.com/a/9166671/284318

    Keyword Arguments:
    image -- PIL RGBA Image object
    color -- Tuple r, g, b (default 255, 255, 255)

    x = np.array(image)
    r, g, b, a = np.rollaxis(x, axis=-1)
    r[a == 0] = color[0]
    g[a == 0] = color[1]
    b[a == 0] = color[2] 
    x = np.dstack([r, g, b, a])
    return Image.fromarray(x, 'RGBA')

def alpha_composite(front, back):
    """Alpha composite two RGBA images.

    Source: http://stackoverflow.com/a/9166671/284318

    Keyword Arguments:
    front -- PIL RGBA Image object
    back -- PIL RGBA Image object

    front = np.asarray(front)
    back = np.asarray(back)
    result = np.empty(front.shape, dtype='float')
    alpha = np.index_exp[:, :, 3:]
    rgb = np.index_exp[:, :, :3]
    falpha = front[alpha] / 255.0
    balpha = back[alpha] / 255.0
    result[alpha] = falpha + balpha * (1 - falpha)
    old_setting = np.seterr(invalid='ignore')
    result[rgb] = (front[rgb] * falpha + back[rgb] * balpha * (1 - falpha)) / result[alpha]
    result[alpha] *= 255
    np.clip(result, 0, 255)
    # astype('uint8') maps np.nan and np.inf to 0
    result = result.astype('uint8')
    result = Image.fromarray(result, 'RGBA')
    return result

def alpha_composite_with_color(image, color=(255, 255, 255)):
    """Alpha composite an RGBA image with a single color image of the
    specified color and the same size as the original image.

    Keyword Arguments:
    image -- PIL RGBA Image object
    color -- Tuple r, g, b (default 255, 255, 255)

    back = Image.new('RGBA', size=image.size, color=color + (255,))
    return alpha_composite(image, back)

def pure_pil_alpha_to_color_v1(image, color=(255, 255, 255)):
    """Alpha composite an RGBA Image with a specified color.

    NOTE: This version is much slower than the
    alpha_composite_with_color solution. Use it only if
    numpy is not available.

    Source: http://stackoverflow.com/a/9168169/284318

    Keyword Arguments:
    image -- PIL RGBA Image object
    color -- Tuple r, g, b (default 255, 255, 255)

    def blend_value(back, front, a):
        return (front * a + back * (255 - a)) / 255

    def blend_rgba(back, front):
        result = [blend_value(back[i], front[i], front[3]) for i in (0, 1, 2)]
        return tuple(result + [255])

    im = image.copy()  # don't edit the reference directly
    p = im.load()  # load pixel array
    for y in range(im.size[1]):
        for x in range(im.size[0]):
            p[x, y] = blend_rgba(color + (255,), p[x, y])

    return im

def pure_pil_alpha_to_color_v2(image, color=(255, 255, 255)):
    """Alpha composite an RGBA Image with a specified color.

    Simpler, faster version than the solutions above.

    Source: http://stackoverflow.com/a/9459208/284318

    Keyword Arguments:
    image -- PIL RGBA Image object
    color -- Tuple r, g, b (default 255, 255, 255)

    image.load()  # needed for split()
    background = Image.new('RGB', image.size, color)
    background.paste(image, mask=image.split()[3])  # 3 is the alpha channel
    return background


The simple non-compositing alpha_to_color function is the fastest solution, but leaves behind ugly borders because it does not handle semi transparent areas.

Both the pure PIL and the numpy compositing solutions give great results, but alpha_composite_with_color is much faster (8.93 msec) than pure_pil_alpha_to_color (79.6 msec). If numpy is available on your system, that's the way to go. (Update: The new pure PIL version is the fastest of all mentioned solutions.)

$ python -m timeit "import Image; from apps.front import utils; i = Image.open(u'logo.png'); i2 = utils.alpha_to_color(i)"
10 loops, best of 3: 4.67 msec per loop
$ python -m timeit "import Image; from apps.front import utils; i = Image.open(u'logo.png'); i2 = utils.alpha_composite_with_color(i)"
10 loops, best of 3: 8.93 msec per loop
$ python -m timeit "import Image; from apps.front import utils; i = Image.open(u'logo.png'); i2 = utils.pure_pil_alpha_to_color(i)"
10 loops, best of 3: 79.6 msec per loop
$ python -m timeit "import Image; from apps.front import utils; i = Image.open(u'logo.png'); i2 = utils.pure_pil_alpha_to_color_v2(i)"
10 loops, best of 3: 1.1 msec per loop
  • For a bit more speed, I believe im = image.copy() can be removed from pure_pil_alpha_to_color_v2 without changing the result. (After changing subsequent instances of im to image, of course.)
    – unutbu
    Commented Feb 27, 2012 at 19:16

9 Answers 9


Here's a version that's much simpler - not sure how performant it is. Heavily based on some django snippet I found while building RGBA -> JPG + BG support for sorl thumbnails.

from PIL import Image

png = Image.open(object.logo.path)
png.load() # required for png.split()

background = Image.new("RGB", png.size, (255, 255, 255))
background.paste(png, mask=png.split()[3]) # 3 is the alpha channel

background.save('foo.jpg', 'JPEG', quality=80)

Result @80%

enter image description here

Result @ 50%
enter image description here

  • 1
    Looks like your version is the fastest: pastebin.com/mC4Wgqzv Thanks! Two things about your post though: The png.load() command seems to be unnecessary, and line 4 should be background = Image.new("RGB", png.size, (255, 255, 255)). Commented Feb 27, 2012 at 14:39
  • 3
    Congratulations on figuring out how to make paste do a proper blend. Commented Feb 27, 2012 at 15:41
  • @DaniloBargen, ah! Indeed it was missing size, but the load method is required for the split method. And that's awesome to hear it's actually fast /and/ simple! Commented Feb 27, 2012 at 18:16
  • 16
    This code was causing a error for me: tuple index out of range. I fixed this by following another question(stackoverflow.com/questions/1962795/…). I had to convert the PNG to RGBA first and then slice it: alpha = img.split()[-1] then use that on the background mask.
    – joehand
    Commented Nov 2, 2012 at 0:56
  • 1
    background.paste(image, mask=image.getchannel('A')) -- is a bit better with the pixel range issue. And likely would work for some other modes like LA
    – Tatarize
    Commented Aug 27, 2020 at 20:59

By using Image.alpha_composite, the solution by Yuji 'Tomita' Tomita become simpler. This code can avoid a tuple index out of range error if png has no alpha channel.

from PIL import Image

png = Image.open(img_path).convert('RGBA')
background = Image.new('RGBA', png.size, (255, 255, 255))

alpha_composite = Image.alpha_composite(background, png)
alpha_composite.save('foo.jpg', 'JPEG', quality=80)
  • This is the best solution to me because all of my images do not have alpha channel.
    – lenhhoxung
    Commented Oct 11, 2016 at 8:42
  • 3
    When I use this code the mode of the png object is still 'RGBA'
    – logic1976
    Commented Jul 30, 2019 at 3:05
  • 5
    @logic1976 just throw in a .convert("RGB") before saving it
    – josch
    Commented Jun 10, 2020 at 10:46

The transparent parts mostly have RGBA value (0,0,0,0). Since the JPG has no transparency, the jpeg value is set to (0,0,0), which is black.

Around the circular icon, there are pixels with nonzero RGB values where A = 0. So they look transparent in the PNG, but funny-colored in the JPG.

You can set all pixels where A == 0 to have R = G = B = 255 using numpy like this:

import Image
import numpy as np

FNAME = 'logo.png'
img = Image.open(FNAME).convert('RGBA')
x = np.array(img)
r, g, b, a = np.rollaxis(x, axis = -1)
r[a == 0] = 255
g[a == 0] = 255
b[a == 0] = 255
x = np.dstack([r, g, b, a])
img = Image.fromarray(x, 'RGBA')

enter image description here

Note that the logo also has some semi-transparent pixels used to smooth the edges around the words and icon. Saving to jpeg ignores the semi-transparency, making the resultant jpeg look quite jagged.

A better quality result could be made using imagemagick's convert command:

convert logo.png -background white -flatten /tmp/out.jpg

enter image description here

To make a nicer quality blend using numpy, you could use alpha compositing:

import Image
import numpy as np

def alpha_composite(src, dst):
    Return the alpha composite of src and dst.

    src -- PIL RGBA Image object
    dst -- PIL RGBA Image object

    The algorithm comes from http://en.wikipedia.org/wiki/Alpha_compositing
    # http://stackoverflow.com/a/3375291/190597
    # http://stackoverflow.com/a/9166671/190597
    src = np.asarray(src)
    dst = np.asarray(dst)
    out = np.empty(src.shape, dtype = 'float')
    alpha = np.index_exp[:, :, 3:]
    rgb = np.index_exp[:, :, :3]
    src_a = src[alpha]/255.0
    dst_a = dst[alpha]/255.0
    out[alpha] = src_a+dst_a*(1-src_a)
    old_setting = np.seterr(invalid = 'ignore')
    out[rgb] = (src[rgb]*src_a + dst[rgb]*dst_a*(1-src_a))/out[alpha]
    out[alpha] *= 255
    # astype('uint8') maps np.nan (and np.inf) to 0
    out = out.astype('uint8')
    out = Image.fromarray(out, 'RGBA')
    return out            

FNAME = 'logo.png'
img = Image.open(FNAME).convert('RGBA')
white = Image.new('RGBA', size = img.size, color = (255, 255, 255, 255))
img = alpha_composite(img, white)

enter image description here

  • Thank you, that explanation makes a whole lot of sense :) Commented Feb 6, 2012 at 20:24
  • @DaniloBargen, did you notice that the quality of the conversion is poor? This solution doesn't account for partial transparency. Commented Feb 6, 2012 at 20:30
  • @MarkRansom: True. Do you know how to fix that?
    – unutbu
    Commented Feb 6, 2012 at 20:32
  • It requires a full blend (with white) based on the alpha value. I've been searching PIL for a natural way to do it and I've come up empty. Commented Feb 6, 2012 at 20:35
  • 1
    Awesome question mate + awesome answer. Thank you i really learned a lot. Commented Feb 6, 2012 at 21:36

Here's a solution in pure PIL.

def blend_value(under, over, a):
    return (over*a + under*(255-a)) / 255

def blend_rgba(under, over):
    return tuple([blend_value(under[i], over[i], over[3]) for i in (0,1,2)] + [255])

white = (255, 255, 255, 255)

im = Image.open(object.logo.path)
p = im.load()
for y in range(im.size[1]):
    for x in range(im.size[0]):
        p[x,y] = blend_rgba(white, p[x,y])
  • Thanks, this works well. But the numpy solution appears to be much faster: pastebin.com/rv4zcpAV (numpy: 8.92ms, pil: 79.7ms) Commented Feb 7, 2012 at 10:42
  • Seems like there is another, faster version with pure PIL. See new answer. Commented Feb 27, 2012 at 14:46
  • 2
    @DaniloBargen, thanks - I appreciate seeing the better answer and I wouldn't have if you hadn't brought it to my attention. Commented Feb 27, 2012 at 15:44

It's not broken. It's doing exactly what you told it to; those pixels are black with full transparency. You will need to iterate across all pixels and convert ones with full transparency to white.

  • Thanks. But around the blue circle there are blue areas. Are those semi-transparent areas? Is there a way I can fix those too? Commented Feb 6, 2012 at 20:06
import numpy as np
import PIL

def convert_image(image_file):
    image = Image.open(image_file) # this could be a 4D array PNG (RGBA)
    original_width, original_height = image.size

    np_image = np.array(image)
    new_image = np.zeros((np_image.shape[0], np_image.shape[1], 3)) 
    # create 3D array

    for each_channel in range(3):
        new_image[:,:,each_channel] = np_image[:,:,each_channel]  
        # only copy first 3 channels.

    # flushing
    np_image = []
    return new_image

The best answer has been given already:

from PIL import Image
img = Image.open("image.png")
bg = Image.new("RGBA",img.size,(255,255,255))
img = Image.alpha_composite(bg,img) # puts our image on top of white background

But here's how i did it myself before seeing these solutions. I'm sharing it just since it's the simplest to understand how it works. (how each pixel is blended)

from PIL import Image
import numpy

data = numpy.array(Image.open("image.png"))
h,w = data.shape[:2]

def lerp(a,b,f): return [round(a[i]+(b[i]-a[i])*f) for i in (0,1,2)]

for x in range(w):
    for y in range(h):
        r,g,b,a = data[y][x]
        r,g,b = lerp((255,255,255),(r,g,b),a/255) # blend ontop of white based on alpha amount
        data[y][x] = (r,g,b,255)


All we're doing is interpolating between white (alpha=0) and the existing pixel. (alpha=255)

Both solutions create the exact same image you'd get if you re-saved an image with Paint. (you can check with (data1==data2).all()) The round() is needed in the lerp() function to be exact. I saved the pixels to a float array to see what we get compared to the pixels in a re-saved image and saw how pixels should be rounded. (i.e. 180 vs 180.3 and 214 vs 213.7) And it makes sense to round to be what it's nearest to.

Now i just need to know how to resize exactly how Paint resizes.

from PIL import Image
def fig2img ( fig ):
    @brief Convert a Matplotlib figure to a PIL Image in RGBA format and return it
    @param fig a matplotlib figure
    @return a Python Imaging Library ( PIL ) image
    # put the figure pixmap into a numpy array
    buf = fig2data ( fig )
    w, h, d = buf.shape
    return Image.frombytes( "RGBA", ( w ,h ), buf.tostring( ) )

def fig2data ( fig ):
    @brief Convert a Matplotlib figure to a 4D numpy array with RGBA channels and return it
    @param fig a matplotlib figure
    @return a numpy 3D array of RGBA values
    # draw the renderer
    fig.canvas.draw ( )
    # Get the RGBA buffer from the figure
    w,h = fig.canvas.get_width_height()
    buf = np.fromstring ( fig.canvas.tostring_argb(), dtype=np.uint8 )
    buf.shape = ( w, h, 4 )
    # canvas.tostring_argb give pixmap in ARGB mode. Roll the ALPHA channel to have it in RGBA mode
    buf = np.roll ( buf, 3, axis = 2 )
    return buf

def rgba2rgb(img, c=(0, 0, 0), path='foo.jpg', is_already_saved=False, if_load=True):
    if not is_already_saved:
        background = Image.new("RGB", img.size, c)
        background.paste(img, mask=img.split()[3]) # 3 is the alpha channel

        background.save(path, 'JPEG', quality=100)   
        is_already_saved = True
    if if_load:
        if is_already_saved:
            im = Image.open(path)
            return np.array(im)
            raise ValueError('No image to load.')

Based on above examples:

It takes in an RGBA image and returns an RGB image with alpha channel converted to white color.

from PIL import Image

def imageAlphaToWhite(image):
    background = Image.new("RGBA", image.size, "WHITE")
    alphaComposite = Image.alpha_composite(background, image)
    return alphaComposite
  • Downvoted, because it does not add any value to existing answers, besides that the Python variable convention is snake_case not camelCase.
    – jpoppe
    Commented Jan 19 at 8:27

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