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Say I have the binary number 0b00110101.

Is there a set of trivial arithmetic operations that will produce 0b0000111100110011, where every bit of the first word is repeated twice?

Does such a trivial function exist to repeat bits 3, 4, or N times?

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Short of a lookup table, I think the answer is: no. Whether implicitly or explicitly, you need to unpack the bits in the input word. –  Oliver Charlesworth Jan 14 '13 at 0:19
2  
@Nate It's just one way to write a binary number and mark it as such (similar to people usually using 0x0000 for hexadecimal numbers. –  Mario Jan 14 '13 at 0:22
1  
@Nate: that's a binary literal, which I believe c++ supports. –  Eric Jan 14 '13 at 0:23
1  
@Mario oh ok thanks I'm not familiar with that my bad. –  Nate-Wilkins Jan 14 '13 at 0:28
1  
Write your program in INTERCAL and use the INTERLEAVE operator. –  Adam Rosenfield Jan 14 '13 at 2:28

4 Answers 4

up vote 9 down vote accepted

Have a look at this document:

http://www-graphics.stanford.edu/~seander/bithacks.html#InterleaveBMN

It describes interleaving two 16-bit numbers, and it's fairly trivial to extend it to 32-bit numbers (this creating a 64-bit number). You just continue the pattern for one extra cycle. Like this:

static const unsigned long long B[] = {
    0x5555555555555555,
    0x3333333333333333,
    0x0F0F0F0F0F0F0F0F,
    0x00FF00FF00FF00FF,
    0x0000FFFF0000FFFF
};
static const unsigned int S[] = {1, 2, 4, 8, 16};

unsigned long long x; // x must initially fit inside 32 bits
unsigned long long z; // z gets the result of x interleaved with itself

x = (x | (x << S[4])) & B[4];
x = (x | (x << S[3])) & B[3];
x = (x | (x << S[2])) & B[2];
x = (x | (x << S[1])) & B[1];
x = (x | (x << S[0])) & B[0];

z = x | (x << 1);
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I forgot to answer the second part of your question, regarding triplicate etc... I believe the same thing applies but using different magic numbers in B. There's an existing question about 3-value Morton Numbers on SO that might help: stackoverflow.com/questions/1024754/… –  paddy Jan 14 '13 at 4:47
    
This was the kind of solution I suspected existed. Thanks! –  Eric Jan 14 '13 at 8:37

I would make a table - it's PROBABLY the quickest way.

You could of course do this:

 int doublebits(int x)
 {
     int y = 0;
     int bit = 0;
     while(x)
     {
        if (x & 1)
            y |= 3 << bit;
        bit += 2;
        x >>= 1;
     }
     return y;
 }

For an 8-bit number, you'll do at most 8 shifts down, and 8 shifts to the right to make the new number.

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I don't think you need to use an if inside the loop, it should be possible with just logical shifts and or, at least it would in Assembler. –  Peter Wooster Jan 14 '13 at 0:26
    
I wrote it so that's reasonably readable. If you want speed, use that function to generate a table. [I don't expect a modern compiler, at least gcc and MS to generate a branch anyways]. –  Mats Petersson Jan 14 '13 at 0:44
3  
x >> 1 is a dangling statement. What did you mean for it to do? –  0x499602D2 Jan 14 '13 at 0:47
    
Fixed.. Thanks for spotting [and the missing space!] –  Mats Petersson Jan 14 '13 at 0:48
    
Readable and clever don't need to go together. I agree the table solution is faster, but seriously ugly. Something done with bit manipulation only would appeal to the Assembler geeks. –  Peter Wooster Jan 14 '13 at 0:52

Ok, this time I believe to have found the correct sequence:

http://oeis.org/search?q=3%2C12%2C15%2C48&sort=&language=&go=Search

One way they suggest producing it is recursively:

a(2n) = 4a(n), a(2n+1) = 4a(n) + 3.

which is anything but trivial.

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Looking here, it seems that the techniques either require LUTs or loops. So, I think the most elegant way will be to use the "Obvious way" (linked) while setting y = x prior to the calculation.

unsigned short x;   // Interleave bits of x and y, so that all of the
unsigned short y;   // bits of x are in the even positions and y in the odd;
unsigned int z = 0; // z gets the resulting Morton Number.

x = INPUT_PATTERN;
y = x;

for (int i = 0; i < sizeof(x) * CHAR_BIT; i++) // unroll for more speed...
{
  z |= (x & 1U << i) << i | (y & 1U << i) << (i + 1);
}

Yes, I am aware it is not necessarily the "clever" solution that the OP asks for, but the other answers so far include loops/recursion as well, so why not give it a try...

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