# Explanation required for BITCOUNT macro

Can someone explain how this works?

``````#define  BX_(x)         ((x) - (((x)>>1)&0x77777777)                    \
- (((x)>>2)&0x33333333)                    \
- (((x)>>3)&0x11111111))

#define BITCOUNT(x)     (((BX_(x)+(BX_(x)>>4)) & 0x0F0F0F0F) % 255)
``````

## Clarification:

Ideally, the answer will start something along the lines of:

The macro: "BX_" subtracts three values from the passed in number.

These three values represent:

1. XXXXX
2. YYYYY
3. ZZZZZ

This allows the BITCOUNT() to work as follows...

Cheers,

David

-
Have you picked your favorite 8-digit hex number and run the macro by hand to see what comes out? If not, try that. –  John Jan 5 '10 at 22:36
If you're using GCC, the best thing to do is `#define BITCOUNT __builtin_popcount`, which should ideally choose the best implementation for your target platform. –  ephemient Jan 5 '10 at 23:06
No - I'd rather the question I ask answered, not have the answerer make assumptions on what's best for me. –  user227479 Jan 5 '10 at 23:36
What's best for you is to have a better grasp on understanding problems, not be intellectually lazy and never learn more than how to ask someone else. –  GManNickG Jan 5 '10 at 23:39
@GMan: no need to be a jerk about it, though. If I ask, "how does an optical mouse work?" do you talk about light scattering off the surface of my desk, or do you tell me to stop being so lazy, dismantle my mouse and figure it out for myself? –  Steve Jessop Jan 6 '10 at 1:11

The output of BX_(x) is the number of on bits in each hex digit. So

`BX_(0x0123457F) = 0x01121234`

The following:

`((BX_(x)+(BX_(x)>>4)) & 0x0F0F0F0F)`

shuffles the counts into bytes:

`((BX_(0x0123457F)+(BX_(0x0123457F)>>4)) & 0x0F0F0F0F) = 0x01030307`

Taking this result modulo 255 adds up the individual bytes to arrive at the correct answer 14. To see that this works, consider just a two-byte integer, 256*X + Y. This is just 255*X + X + Y, and 255*X % 255 is always zero, so

`(256*X + Y) % 255 = (X + Y) % 255.`

This extends to four-byte integers:

256^3*V + 256^2*W + 256*X + Y

Just replace each 256 with (255+1) to see that

`(256^3*V + 256^2*W + 256*X + Y) % 255 = (V + W + X + Y) % 255.`

The final observation (which I swept under the rug with the 2-digit example) is that `V + W + X + Y` is always less than 255, so

`(V + W + X + Y) % 255 = V + W + X + Y.`
-
Thanks - I get it. –  user227479 Jan 5 '10 at 23:35

As quoted by Johannes from that splendid Bit Twiddling Hacks page, there's an excellent and detailed description of that algorithm in Software Optimization Guide for AMD Athlon™ 64 and Opteron™ Processors from AMD on page numbers 179 and 180 - corresponding to pages 195 and 196 of the PDF.

Also describing the same idea and some alternative solutions and their relative performance: this page.

-