Efficient computation of greatest power of 2 < x [duplicate]

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I have a requirement to compute the greatest power of 2 which is < an integer value, x

currently I am using:

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

x = round(pow(2,(ceil(log2(n))-1)));
``````

this is in a performance critical function

Is there a more computationally efficient way of calculating x?

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marked as duplicate by unkulunkulu, Bill Lynch, Carl Norum, Bo Persson, woodchips Apr 14 '13 at 17:42

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

up to how high? It might be easier to have a fixed lookup table for at least some common range. –  Joe Apr 14 '13 at 17:00
no more than 2^32 –  bph Apr 14 '13 at 17:01

6 Answers

I have an integer log2 function in my c-libutl library (hosted on googlecode if anyone is interested)

``````/*
** Integer log base 2 of a 32 bits integer values.
**   llog2(0) == llog2(1) == 0
*/
unsigned short llog2(unsigned long x)
{
long l = 0;

x &= 0xFFFFFFFF /* just in case 'long' is more than 32bit */

if (x==0) return 0;

#ifndef UTL_NOASM
#if defined(__POCC__) || defined(_MSC_VER) || defined (__WATCOMC__)
/* Pelles C            MS Visual C++         OpenWatcom */
__asm { mov eax, [x]
bsr ecx, eax
mov  l, ecx
}
#elif defined(__GNUC__)
l = (unsigned short) ((sizeof(long)*8 -1) - __builtin_clzl(x));
#else
#define UTL_NOASM
#endif
#endif

#ifdef UTL_NOASM  /* Make a binary search.*/
if (x & 0xFFFF0000) {l += 16; x >>= 16;} /* 11111111111111110000000000000000 */
if (x & 0xFF00)     {l += 8;  x >>= 8 ;} /* 1111111100000000*/
if (x & 0xF0)       {l += 4;  x >>= 4 ;} /* 11110000*/
if (x & 0xC)        {l += 2;  x >>= 2 ;} /* 1100 */
if (x & 2)          {l += 1;  }          /* 10 */
return l;
#endif

return (unsigned short)l;
}
``````

Then you can simply compute

`````` (1 << llog2(x))
``````

to compute the greatest power of two that is less than x. Beware 0! You should handle it separately.

It uses assembler code but can also be forced to plain C code by defining the UTL_NOASM symbol.

The code has been tested at the time but it's quite some time I don't use it and I can't say if it behaves in a 64-bit environment.

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this looks super efficient - thanks for the heads up on your library –  bph Apr 14 '13 at 20:12
Please note that the library is alpha and in constant rework. Though some code snippet may be useful. –  Remo.D Apr 16 '13 at 8:14

You are essentially looking for the highest non-zero bit in your number. Many processors have built-in instructions for this, which in turn are exposed by many compilers. For example, in GCC I would look at `__builtin_clz`, which

Returns the number of leading 0-bits in `x`, starting at the most significant bit position.

Together with `sizeof(int) * CHAR_BIT` and a shift, you can use this to figure out the corresponding pure-power-of-two integer. There's also a version for long integers.

(The CPU instruction is presumably called "CLZ" (count leading zeros), in case you need to look this up for other compilers.)

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Based on Bit Twiddling Hacks: Find the log base 2 of an N-bit integer in O(lg(N)) operations by Sean Eron Anderson (code contributed by Eric Cole and Andrew Shapira):

``````unsigned int highest_bit (uint32_t v) {
unsigned int r = 0, s;
s = (v > 0xFFFF) << 4; v >>= s; r |= s;
s = (v > 0xFF  ) << 3; v >>= s; r |= s;
s = (v > 0xF   ) << 2; v >>= s; r |= s;
s = (v > 0x3   ) << 1; v >>= s; r |= s;
return r | (v >> 1);
}
``````

This returns the index of the highest bit of the input; the greatest power of 2 no greater than the input is then `1 << highest_bit(x)`, and the greatest power of 2 strictly less than the input is thus simply `1 << highest_bit(x-1)`.

For 64-bit inputs, just change the input type to `uint64_t` and add the following extra line at the beginning of the function, after the variable declarations:

``````    s = (v > 0xFFFFFFFF) << 8; v >>= s; r |= s;
``````
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Left and right shift operators do this the best

``````int MaxPowerOf2(int x)
{
int out = 1;
while(x > 1) { x>>1; out<<1;}
return out;
}
``````
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``````#include <math.h>

double greatestPower( double x )
{
return floor(log( x ) / log( 2 ));
}
``````

That is true since `log` in monotony increasing function.

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Shifting bits around will most likely be much faster. Probably some bisection method on bits could make it even faster. Nice exercise for an improvement.

``````#include <stdio.h>

int closestPow2(int x)
{
int     p;

if (x <= 1) return 0; /* No such power exists */

x--;   /* Account for exact powers of 2, then one power less must be returned */
for (p = 0; x > 0; p++)
{
x >>= 1;
}

return 1<<(p-1);
}

int main(void)
{
printf("%x\n", closestPow2(0x7FFFFFFF));
return 0;
}
``````
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