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All right, so I have been very frustrated trying to convert a 12-bit buffer to an 8-bit one. The image source is a 12-bit GrayScale (decompressed from JPEG2000) whose color range goes from 0-4095. Now I have to reduce that to 0-255. Common sense tells me that I should simply divide each pixel value like this. But when I try this, the image comes out too light.

    unsigned char * charArray,
    unsigned char * shortArray,
    const int num )

    short shortValue  = 0; //Will contain the two bytes in the shortArray.
    double doubleValue  = 0; //Will contain intermediary calculations.

    for( int i = 0, j =0; i < num; i++, j +=2 )
        // Bitwise manipulations to fit two chars onto one short.
        shortValue = (shortArray[j]<<8);
        shortValue += (shortArray[j+1]);

        charArray[i] = (( unsigned char)(shortValue/16));

Now I can tell that there needs to be some contrast adjustments. Any ideas anyone?

Many Thanks in advance

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Why is shortArray declared as unsigned char * instead of the more convenient unsigned* type? – DarenW Oct 13 '10 at 4:11
You might experiement with gamma correction: something like pow(double(pixel)/16, gamma)/pow(255,gamma) - gamma of say 1.1 and vary to taste. – Tony D Oct 13 '10 at 4:21
@DarenW : Because whatever reader I use reads one byte at a time, like most. However, it contains twice as much space as the charBuffer because it must hold twice the amount of bytes. – Sir Wellington Oct 13 '10 at 5:09
@Tony: Yes I think that is something quite similar to what I ended up doing. I will definitely give it a try to see where it takes me. – Sir Wellington Oct 13 '10 at 5:10

5 Answers 5

In actuality, it was merely some simple Contrast adjustments that needed to be made. I realized this as soon as I loaded up the result image in Photoshop and did auto-contrast....the image result would very closely resemble the expected output image. I found out an algorithm that does the contrast and will post it here for other's convenience:

#include <math.h>

 short shortValue  = 0; //Will contain the two bytes in the shortBuffer.
 double doubleValue  = 0; //Will contain intermediary calculations.

 //Contrast adjustment necessary when converting
 //setting 50 as the contrast seems to be real sweetspot.
 double contrast = pow( ((100.0f + 50.0f) / 100.0f), 2); 

 for ( int i = 0, j =0; i < num; i++, j += 2 )

  //Bitwise manipulations to fit two chars onto one short.
  shortValue = (shortBuffer[j]<<8);
  shortValue += (shortBuffer[j+1]);

  doubleValue = (double)shortValue;

  //Divide by 16 to bring down to 0-255 from 0-4095 (12 to 8 bits)
  doubleValue /= 16;

  //Flatten it out from 0-1
  doubleValue /= 255;
  //Center pixel values at 0, so that the range is -0.5 to 0.5
  doubleValue -= 0.5f;
  //Multiply and just by the contrast ratio, this distances the color
  //distributing right at the center....see histogram for further details
  doubleValue *= contrast;

  //change back to a 0-1 range
  doubleValue += 0.5f;
  //and back to 0-255
  doubleValue *= 255;

  //If the pixel values clip a little, equalize them.
  if (doubleValue >255)
   doubleValue = 255;
  else if (doubleValue<0)
   doubleValue = 0;

  //Finally, put back into the char buffer.
  charBuffer[i] = (( unsigned char)(doubleValue));

share|improve this answer
Nice and simple :-). Gives you a linearly stretched contrast enhancement, whereas the gamma thing is exponential. Linear's clearly easier to calculate quickly. Both have some issues with rescaling to avoid blowing highlights / loss in shadows if your image was already spanning the full dynamic range. – Tony D Oct 13 '10 at 5:16
@Tony: You have no idea how worried I was that I would have to implement something as ghastly as fast fourier transform or some other complex algorithm. This is indeed a linear method, but it sounds like the exponential ones might spread out the concentrated pixel values a little better, but because we are dealing with a tight spectrum here, 0-255, it may not be as noticeable. Thanks a lot for all your help! Really appreciated! – Sir Wellington Oct 13 '10 at 5:26
it's a tricky space - to get really good results you often need manual tuning - in Photoshop I tend to use multi-point curves adjustments: they do create a smooth curve through the control points you've added and I'm sure the maths is much more involved. Basically, for everywhere you want to increase contrast, you have to accept that you're reducing contrast in some other part of the intensity levels. Having 12 bit input you'll get less obvious banding, but the differences in output intensities are still just as real. But, if what you've got's good enough for your purposes, great! – Tony D Oct 13 '10 at 6:06

The main problem, as I understand, is to convert a 12-bit value to a 8-bit one.

Range of 12-bit value = 0 - 4095 (4096 values)
Range of  8-bit value = 0 -  255 ( 256 values)

I would try to convert a 12-bit value x to a 8-bit value y

  1. First, scale down first to the range 0-1, and
  2. Then, scale up to the range 0-256.

Some C-ish code:

uint16_t x = some_value; 
uint8_t  y = (uint8_t) ((double) x/4096 ) * 256;


Thanks to Kriss's comment, I realized that I disregarded the speed issue. The above solution, due to floating operations, might be slower than pure integer operations.

Then I started considering another solution. How about constructing y with the 8 most significant bits of x? In other words, by trimming off the 4 least significant bits.

y = x >> 4;

Will this work?

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I think you are close to or right on the money with this one. – Sir Wellington Oct 13 '10 at 4:59
The original code is already doing something like that in a much more efficient manner and without losing more precision than necessary by rounding (but maybe with an endianness problem ?). Your suggestion have no benefit at all except making the code 10 times slower or worse by performing a floating point division. – kriss Oct 13 '10 at 4:59
@Juan: Thanks, but I am not sure if that was a encouragement or sarcasm :-). @kriss: Thanks for pointing out the shortcoming. I posted an update, let me know if you have further comments. @Anonymous down voter: I am trying to learn by trying to solve. It will be helpful for me if you provide your comments as @kriss did. – Arun Oct 13 '10 at 5:33
@ArunSaha: No sarcasm, I felt you touched something when you said to scale the value to the 0-1 range. The rest was redundant but your first statement struck a cord. – Sir Wellington Oct 13 '10 at 5:45
@Juan: Thank you. Does my (updated) answer make sense though? – Arun Oct 13 '10 at 5:56

if you just want to drop the bottom 4 least significant bits you can do the following:

unsigned int start_value = SOMEVALUE; // starting value
value = (value & 0xFF0 );             // drop bits 
unsigned char final_value =(uint8_t)value >> 4; //bit shift to 8 bits

Note the "unsigned". You don't want the signed bit mucking with your values.

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Like this:

// Image is stored in 'data'
unsigned short* I = (unsigned short*)data;

for(int i=0; i<imageSize; i++) {
// 'color' is the 8-bit value  
   char color = (char)((double)(255*I[i])/(double)(1<<12));
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Wild guess: your code assumes a big-endian machine (most significant byte first). A Windows PC is little-endian. So perhaps try

  shortValue = (shortArray[j+1]<<8);
  shortValue += (shortArray[j]);

If indeed endiasness is the problem then the code you presented would just shave off the 4 most significant bits of every value, and expand the rest to the intensity range. Hm, EDIT, 2 secs later: no, that was a thinko. But try it anyway?

Cheers & hth.,

– Alf

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