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Im trying to find the most efficient algorithm to count "edges" in a bit-pattern. An edge meaning a change from 0 to 1 or 1 to 0. I am sampling each bit every 250 us and shifting it into a 32 bit unsigned variable.

This is my algorithm so far

void CountEdges(void)
{
    uint_least32_t feedback_samples_copy = feedback_samples;
    signal_edges = 0;

    while (feedback_samples_copy > 0)
    {
        uint_least8_t flank_information = (feedback_samples_copy & 0x03);

        if (flank_information == 0x01 || flank_information == 0x02)
        {
            signal_edges++;
        }

        feedback_samples_copy >>= 1;
    }
}

It needs to be at least 2 or 3 times as fast.

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You should be able to bitwise XOR them together to get a bit pattern representing the flipped bits. Then use one of the bit counting tricks on this page: http://graphics.stanford.edu/~seander/bithacks.html to count how many 1's there are in the result.

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Another link for this solution : tekpool.wordpress.com/category/bit-count – Guillaume Oct 27 '09 at 13:36
    
I don't think it'll measure up against lookuptables though. For extreme memory constraint devices it might be the solution though. Although I would not expect someone to code C in that case but turn to assembly instead – Toad Oct 27 '09 at 13:38
    
Forgive me my ignorance, but how does XOR give "edges"? You can count the set bits, but the way I understand this, you need 00011101011 to be 5 (or 7 if you count the borders) and 1111100001111 to be 3. – Abel Oct 27 '09 at 13:40
1  
he means by xoring the same value shifted by 1: edges = value ^ (value>>1).... it then is a matter of counting the 1's in the edges variable – Toad Oct 27 '09 at 13:41
1  
ah yes, of course, simple but effective, nice 1 :) – Abel Oct 27 '09 at 13:45

One thing that may help is to precompute the edge count for all possible 8-bit value (a 512 entry lookup table, since you have to include the bit the precedes each value) and then sum up the count 1 byte at a time.

// prevBit is the last bit of the previous 32-bit word
// edgeLut is a 512 entry precomputed edge count table
// Some of the shifts and & are extraneous, but there for clarity
edgeCount = 
    edgeLut[(prevBit << 8) | (feedback_samples >> 24) & 0xFF] + 
    edgeLut[(feedback_samples >> 16) & 0x1FF] + 
    edgeLut[(feedback_samples >>  8) & 0x1FF] + 
    edgeLut[(feedback_samples >>  0) & 0x1FF];

prevBit = feedback_samples & 0x1;
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why & with 0x1f? you are ignoring 3 bits per byte this way – Toad Oct 27 '09 at 13:40
    
I must have edited it while you were reading ;-] – Daniel LeCheminant Oct 27 '09 at 13:42
    
I comment faster than my shadow apparently ;^) – Toad Oct 27 '09 at 13:44
    
(prevBit << 4) should be (prevBit << 8) ;^) – Toad Oct 27 '09 at 13:44
    
Shoot, this time you commented while I was editing :-P Good to have another bit twiddler watching my back :-] – Daniel LeCheminant Oct 27 '09 at 13:46

My suggestion:

  • copy your input value to a temp variable, left shifted by one
  • copy the LSB of your input to yout temp variable
  • XOR the two values. Every bit set in the result value represents one edge.
  • use this algorithm to count the number of bits set.

This might be the code for the first 3 steps:

uint32 input; //some value
uint32 temp = (input << 1) | (input & 0x00000001);
uint32 result = input ^ temp;

//continue to count the bits set in result
//...
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+1. I was about to write something similar. My first thought was temp = (intput >> 1) ^ (input & 0x7FFFFFFFu); return countBits(temp);, though. – sellibitze Oct 27 '09 at 14:39

Create a look-up table so you can get the transitions within a byte or 16-bit value in one shot - then all you need to do is look at the differences in the 'edge' bits between bytes (or 16-bit values).

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Argh, double-ninja'd. – David Seiler Oct 27 '09 at 13:34

You are looking at only 2 bits during every iteration.
The fastest algorithm would probably be to build a hash table for all possibles values. Since there are 2^32 values that is not the best idea.
But why don't you look at 3, 4, 5 ... bits in one step? You can for instance precalculate for all 4 bit combinations your edgecount. Just take care of possible edges between the pieces.

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you could always use a lookup table for say 8 bits at a time this way you get a speed improvement of around 8 times

don't forget to check for bits in between those 8 bits though. These then have to be checked 'manually'

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