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I have a requirement to compute k as the smallest power of 2 which is >= an integer value, n (n is always > 0)

currently I am using:

#define log2(x) log(x)/log(2)
#define round(x) (int)(x+0.5)

k = round(pow(2,(ceil(log2(n)))));

this is in a performance critical function

Is there a more computationally efficient way of calculating k?

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If you are using GCC, you can use 1 << CHAR_BIT * sizeof x - __builtin_clz(x), provided x has type unsigned int or, on normal systems, int. There is also __builtin_clzl for unsigned long. Some non-GCC compilers also support this extension. This will be faster than any of the other answers so far on processors that have a “find first bit set” instruction. – Eric Postpischil Mar 20 '13 at 14:12
note edit from '> an integer value' to '>= an integer value' – bph Mar 20 '13 at 14:34
Now everybody has to change their answers again. :-) – Eric Postpischil Mar 20 '13 at 14:37
demand a stack overflow 'undo' button... – bph Mar 20 '13 at 14:38
Unrelated to an answer, but worth mentioning to anyone who comes upon this and doesn't know better: it's wise to ditch the +0.5 and (int) cast, and instead use the floor() or ceiling() functions in calculations like this. Of course, logarithms are still slow. – DarenW Mar 28 '13 at 7:32
up vote 2 down vote accepted
int calculate_least_covering_power_of_two(int x)
  int k = 1;
  while( k < x ) k = k << 1;
  return k;
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thanks for last edit, answer is now correct – bph Mar 20 '13 at 15:18
benchmark this with the branch-free version, I suspect you'll find this isn't the most efficient way to do it. But, it will work. – Randy Howard Mar 20 '13 at 16:27
@RandyHoward i've done that and theres no discernible difference (for my application) so I think I'll stick with this answer as its simpler – bph Mar 20 '13 at 17:40
@Randy: this naive method is very easy to understand and must not be ported to 64- (128-, ...)bit machines. It is also helpful to understand it first, then move on to the branch-free version. The branch-free version will surely be more efficient for uniformly distributed 32-bit-integers., but may be a bit slower for small integers. Also, I've given a "+1" to your post, and it was a nice surprise that my post was accepted ) – Alex Shesterov Mar 20 '13 at 17:42
@alex-shesterov could you explain the problem with porting your function to a 64-bit machine? – bph Mar 20 '13 at 18:32
/* returns greatest power of 2 less than or equal to x, branch-free */
/* Source: Hacker's Delight, First Edition. */
flp2(int x)
    x = x | (x>>1);
    x = x | (x>>2);
    x = x | (x>>4);
    x = x | (x>>8);
    x = x | (x>>16);
    return x - (x>>1);

It's entertaining to study it and see how it works. I think the only way for you to know for sure which of the solutions you see will be optimal for your situation is to use all of them in a text fixture and profile it and see which is most efficient for your purpose.

Being branch-free, this one is likely to be quite good performance-wise relative to some others, but you should test it directly to be sure.

If you want the least power of two greater than or equal to X, you can use a slightly different solution:

clp2(unsigned x)
    x = x -1;
    x = x | (x >> 1);
    x = x | (x >> 2);
    x = x | (x >> 4);
    x = x | (x >> 8);
    x = x | (x >> 16);
    return x + 1;
share|improve this answer
This is nice, since the 'left most' 1 is the answer the goal is to 0 all other bits, this does it nicely. You will need an extra line for 64 bit numbers. – dingrite Mar 20 '13 at 14:16
Ah yes, you wanted something else, let me post it. – dingrite Mar 20 '13 at 14:19
If you use the x |= x >>1; ... form, you can get rid of the parentheses, since the assignment operators have very low precedence. – wildplasser Mar 20 '13 at 14:21
Yes. Moving the end result up or down by one power of 2, (depending on the actual intent) is pretty straightforward. Hopefully Hiett will be able to use the information for the specific needs of his program. – Randy Howard Mar 20 '13 at 14:33
@Hiett since right shifting 0 is still 0 you can add the extra line if you need to cater for both 32-bit and 64-bit. the result for 32 bit will still be correct and only waste a few instructions – Rune FS Apr 4 '13 at 15:50
lim = 123;
n = 1;
while( ( n = n << 1 ) <= lim );

Multiply your number by 2 until it's bigger than lim.

Left shift of one multiplies value by 2.

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@EricPostpischil Tnx for noticing, fixed... ( doesn't work for lim = zero but that can be solved using if() ) – user1944441 Mar 20 '13 at 14:19

Yes, You can calculate this by simply taking the number in question, and using bit-shifts to determine the power of 2.
Right-shifting takes all the bits in the number and moves them to the right, dropping the far right (least significant) digit. It is equivalent to performing an integer division by 2. Left-shifting a value moves all the bits to the left, dropping the bits that shift off the left end, and adding zeroes to the right end, effectively multiplying the value by 2. So if you count how many times you need to right shift before the number reaches zero, you have calculated the integer portion of the base 2 logarithm. Then use it to create your result by left-shifting the value 1 that many times.

  int CalculateK(int val)
      int cnt = 0;
      while(val > 0)
           val = val >> 1;
      return 1 << cnt;

EDIT: Alternatively, and a bit simpler: you don't have to calculate the count

  int CalculateK(int val)
      int res = 1;
      while(res <= val) res <<= 1;
      return res ;
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ahhh, then the +1 is an error I removed it – Charles Bretana Mar 20 '13 at 14:30
Yes, Thanks Eric! – Charles Bretana Mar 20 '13 at 15:03
k = 1 << (int)(ceil(log2(n)));

You can take advantage of the fact that binary digits represent powers of two (1 is 1, 10 is 2, 100 is 4, etc). Shifting 1 left by the exponent of 2 gives you the same value, but it's much faster.

Although if you can somehow avoid the ceil(log2(n)) you will see a much larger performance increase.

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This code does not compile because ceil has type double and cannot be used with <<. When a cast to int is inserted and n is 32, this code produces 32, but the desired result is 64. – Eric Postpischil Mar 20 '13 at 14:18
I added a cast to int to the example. I'm not sure why the desired result for n=32 would be 64... maybe I did not understand the original question. – Zach Mar 20 '13 at 14:20
@EricPostpischil, it appears to be asking for the smallest power of 2 greater than or equal to n. 32 is equal to 32. But maybe I am still misunderstanding. Either way, Randy Howard's answer is better. – Zach Mar 20 '13 at 14:24


/* altered to: power of 2 which is greater than an integer value */

unsigned clp2(unsigned x) {
   x = x | (x >> 1);
   x = x | (x >> 2);
   x = x | (x >> 4);
   x = x | (x >> 8);
   x = x | (x >>16);
   return x + 1;

Keep in mind you will need to add:

x = x | (x >> 32);

For 64bit numbers.

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