# Convert 16bit colour to 32bit

I've got an 16bit bitmap image with each colour represented as a single short (2 bytes), I need to display this in a 32bit bitmap context. How can I convert a 2 byte colour to a 4 byte colour in C++?

The input format contains each colour in a single short (2 bytes).

The output format is 32bit RGB. This means each pixel has 3 bytes I believe?

I need to convert the short value into RGB colours.

Excuse my lack of knowledge of colours, this is my first adventure into the world of graphics programming.

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What are you doing with C++ on iOS? Just use UIImage, or cocos2d. –  Richard J. Ross III Dec 20 '11 at 17:22
You mentioned three different source formats: 16bits per pixel, 2 bytes per color, and "single byte colour". Which is it? –  interjay Dec 20 '11 at 17:26
Depends on the bitwise format... 565/555/556/655 etc –  tenfour Dec 20 '11 at 17:30

Common formats include BGR0, RGB0, 0RGB, 0BGR. In the code below I have assumed 0RGB. Changing this is easy, just modify the shift amounts in the last line.

unsigned long rgb16_to_rgb32(unsigned short a)
{
/* 1. Extract the red, green and blue values */

/* from rrrr rggg gggb bbbb */
unsigned long r = (a & 0xF800) >11;
unsigned long g = (a & 0x07E0) >5;
unsigned long b = (a & 0x001F);

/* 2. Convert them to 0-255 range:
There is more than one way. You can just shift them left:
to 00000000 rrrrr000 gggggg00 bbbbb000
r <<= 3;
g <<= 2;
b <<= 3;
But that means your image will be slightly dark and
off-colour as white 0xFFFF will convert to F8,FC,F8
So instead you can scale by multiply and divide: */

r = r * 255 / 31;
g = g * 255 / 63;
b = b * 255 / 31;
/* This ensures 31/31 converts to 255/255 */

/* 3. Construct your 32-bit format (this is 0RGB): */
return (r << 16) | (g << 8) | b;

/* Or for BGR0:
return (r << 8) | (g << 16) | (b << 24);
*/
}
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Normally a 16-bit pixel is 5 bits of red, 6 bits of green, and 5 bits of blue data. The minimum-error solution (that is, for which the output color is guaranteed to be as close a match to the input colour) is:

red8bit   = (red5bit << 3) | (red5bit >> 2);
green8bit = (green6bit << 2) | (green6bit >> 4);
blue8bit  = (blue5bit << 3) | (blue5bit >> 2);

To see why this solution works, let's look at at a red pixel. Our 5-bit red is some fraction fivebit/31. We want to translate that into a new fraction eightbit/255. Some simple arithmetic:

fivebit   eightbit
------- = --------
31        255

Yields:

eightbit = fivebit * 8.226

Or closely (note the squiggly ≈):

eightbit ≈ (fivebit * 8) + (fivebit * 0.25)

That operation is a multiply by 8 and a divide by 4. Owch - both operations that might take forever on your hardware. Lucky thing they're both powers of two and can be converted to shift operations:

eightbit = (fivebit << 3) | (fivebit >> 2);

The same steps work for green, which has six bits per pixel, but you get an accordingly different answer, of course! The quick way to remember the solution is that you're taking the top bits off of the "short" pixel and adding them on at the bottom to make the "long" pixel. This method works equally well for any data set you need to map up into a higher resolution space. A couple of quick examples:

five bit space         eight bit space        error
00000                  00000000                 0%
11111                  11111111                 0%
10101                  10101010                0.02%
00111                  00111001               -1.01%
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Multiply the three (four, when you have an alpha layer) values by 16 - that's it :)

You have a 16-bit color and want to make it a 32-bit color. This gives you four times four bits, which you want to convert to four times eight bits. You're adding four bits, but you should add them to the right side of the values. To do this, shift them by four bits (multiply by 16). Additionally you could compensate a bit for inaccuracy by adding 8 (you're adding 4 bits, which has the value of 0-15, and you can take the average of 8 to compensate)

Update This only applies to colors that use 4 bits for each channel and have an alpha channel.

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This solution is a bit naive - it will leave black black, but whites will turn gray. –  Carl Norum Dec 20 '11 at 17:39
@CarlNorum As I mentioned you're always making up data. There's no perfect solution. –  Tom van der Woerdt Dec 20 '11 at 17:41
You can always try to make up good information. In this case, as a matter of fact, there is a guaranteed minimum error solution - see my answer. –  Carl Norum Dec 20 '11 at 17:47

There some questions about the model like is it HSV, RGB? If you wanna ready, fire, aim I'd try this first.

#include <stdint.h>

uint32_t convert(uint16_t _pixel)
{
uint32_t pixel;
pixel = (uint32_t)_pixel;
return ((pixel & 0xF000) << 16)
| ((pixel & 0x0F00) << 12)
| ((pixel & 0x00F0) << 8)
| ((pixel & 0x000F) << 4);
}

This maps 0xRGBA -> 0xRRGGBBAA, or possibly 0xHSVA -> 0xHHSSVVAA, but it won't do 0xHSVA -> 0xRRGGBBAA.

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Actually, it maps 0xRGBA onto oxR0G0B0A0, which is probably not what you want. –  Carl Norum Dec 20 '11 at 17:57
You're gonna have to fabricate those other 16 bits somehow. :) –  zap Dec 20 '11 at 17:58
but you might as well fabricate them with good information instead of just zeroes. –  Carl Norum Dec 20 '11 at 18:00
tronche.com/gui/x/xlib/graphics/images.html#XImage msdn.microsoft.com/en-us/library/dd183370(v=vs.85).aspx It really depends on what the situation is. –  zap Dec 20 '11 at 18:13
Didn't see the iphone tag. Carl is probably right. –  zap Dec 20 '11 at 18:17