If I have some integer n, and I want to know the position of the most significant bit (that is, if the least significant bit is on the right, I want to know the position of the furthest left bit that is a 1), what is the quickest/most efficient method of finding out?

I know that POSIX supports a ffs() method in strings.h to find the first set bit, but there doesn't seem to be a corresponding fls() method.

Is there some really obvious way of doing this that I'm missing?

What about in cases where you can't use POSIX functions for portability?

Edit: What about a solution that works on both 32 and 64 bit architectures (many of the code listings seem like they'd only work on 32 bit ints).

  • there's a few implementations here: graphics.stanford.edu/~seander/bithacks.html#ZerosOnRightLinear (Edit: After rereading your question, I realise that the link above is for finding the rightmost set bit, not leftmost as you require, although without a sense of word size, it's a tricky one to answer) – spender Mar 22 '09 at 23:44
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  • 2
    do you specifically want the bit number 'n', or would 2 ^ n suffice? – Alnitak Mar 22 '09 at 23:51
  • 1
    Look at the "Log Base 2" algorithms - as Anderson says in the article: "The log base 2 of an integer is the same as the position of the highest bit set (or most significant bit set, MSB)" – Michael Burr Mar 23 '09 at 0:46
  • 1
    Either would work. – Zxaos Mar 23 '09 at 1:23

25 Answers 25

GCC has:

 -- Built-in Function: int __builtin_clz (unsigned int x)
     Returns the number of leading 0-bits in X, starting at the most
     significant bit position.  If X is 0, the result is undefined.

 -- Built-in Function: int __builtin_clzl (unsigned long)
     Similar to `__builtin_clz', except the argument type is `unsigned
     long'.

 -- Built-in Function: int __builtin_clzll (unsigned long long)
     Similar to `__builtin_clz', except the argument type is `unsigned
     long long'.

I'd expect them to be translated into something reasonably efficient for your current platform, whether it be one of those fancy bit-twiddling algorithms, or a single instruction.

  • 3
    MSVC will have _BitScanReverse – ratchet freak Dec 17 '15 at 15:48
  • 1
    The undefined-on-zero behaviour lets them compile to a single BSR instruction on x86, even when LZCNT isn't available. This is a big advantage for __builtin_ctz over ffs, which compiles to a BSF and a CMOV to handle the input-was-zero case. On architectures without a short-enough implementation (e.g. old ARM without the clz instruction), gcc emits a call to a libgcc helper function. – Peter Cordes Dec 18 '16 at 6:58

Assuming you're on x86 and game for a bit of inline assembler, Intel provides a BSR instruction ("bit scan reverse"). It's fast on some x86s (microcoded on others). From the manual:

Searches the source operand for the most significant set bit (1 bit). If a most significant 1 bit is found, its bit index is stored in the destination operand. The source operand can be a register or a memory location; the destination operand is a register. The bit index is an unsigned offset from bit 0 of the source operand. If the content source operand is 0, the content of the destination operand is undefined.

(If you're on PowerPC there's a similar cntlz ("count leading zeros") instruction.)

Example code for gcc:

#include <iostream>

int main (int,char**)
{
  int n=1;
  for (;;++n) {
    int msb;
    asm("bsrl %1,%0" : "=r"(msb) : "r"(n));
    std::cout << n << " : " << msb << std::endl;
  }
  return 0;
}

See also this inline assembler tutorial, which shows (section 9.4) it being considerably faster than looping code.

  • 4
    Actually this instruction is usually microcoded into a loop and is rather slow. – rlbond Mar 23 '09 at 3:10
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    Which one ? BSR or CNTLZ ? As I read the x86-timing.pdf referenced above, BSR is only slow on the Netburst Pentiums. I know nothing about PowerPC though. – timday Mar 23 '09 at 9:26
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    ...OK, on closer inspection make that "BSR is only fast on P3/Pentium-M/Core2 x86s". Slow on Netburst and AMD. – timday Mar 23 '09 at 9:29
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    Just a heads up: Your last two links are dead. – Baum mit Augen Sep 21 '15 at 22:28
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    @rlbond: huh, BSR on P4 Prescott is 2 uops with 16 cycle latency(!), with one per 4c throughput. But on earlier Netburst, it's only 4 cycle latency (still 2 uops), and one per 2c throughput. (source: agner.org/optimize). On most CPUs, it also has a dependency on its output which gcc doesn't account for (when the input is zero, the actual behaviour is to leave the destination unchanged). This can lead to problems like stackoverflow.com/questions/25078285/…. IDK why gcc missed BSR when fixing that. – Peter Cordes Dec 18 '16 at 7:17

Since 2^N is an integer with only the Nth bit set (1 << N), finding the position (N) of the highest set bit is the integer log base 2 of that integer.

http://graphics.stanford.edu/~seander/bithacks.html#IntegerLogObvious

unsigned int v;
unsigned r = 0;

while (v >>= 1) {
    r++;
}

This "obvious" algorithm may not be transparent to everyone, but when you realize that the code shifts right by one bit repeatedly until the leftmost bit has been shifted off (note that C treats any non-zero value as true) and returns the number of shifts, it makes perfect sense. It also means that it works even when more than one bit is set — the result is always for the most significant bit.

If you scroll down on that page, there are faster, more complex variations. However, if you know you're dealing with numbers with a lot of leading zeroes, the naive approach may provide acceptable speed, since bit shifting is rather fast in C, and the simple algorithm doesn't require indexing an array.

NOTE: When using 64-bit values, be extremely cautious about using extra-clever algorithms; many of them only work correctly for 32-bit values.

  • 2
    @Johan Stepping through with a debugger can help explain why the loop exits. Basically, its' because the expression in the condition evaluates to 0 (which is treated as false) once the last 1 bit has been shifted off the right. – Quinn Taylor Sep 21 '11 at 19:31
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    Nice idea to use the end result like that :) – Johan Sep 22 '11 at 6:27
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    note: must be unsigned, for signed integers the right shift fails for negative numbers. – Xantix Sep 3 '12 at 5:56
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    Xantix: The shift in C/C++ is a logical shift, so it works fine. For Java, JavaScript, or D, you need to use the logical shift operator >>>. Plus probably the comparator != 0, and some unspecified number of parenthesis. – Chase Jan 3 '14 at 20:31
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    @Chase: No it's not. It's a logical shift for unsigned. For signed, it may or may not be a logical shift (and it's usually arithmetic, in fact). – Tim Čas Feb 12 '15 at 20:57

This should be lightning fast:

int msb(unsigned int v) {
  static const int pos[32] = {0, 1, 28, 2, 29, 14, 24, 3,
    30, 22, 20, 15, 25, 17, 4, 8, 31, 27, 13, 23, 21, 19,
    16, 7, 26, 12, 18, 6, 11, 5, 10, 9};
  v |= v >> 1;
  v |= v >> 2;
  v |= v >> 4;
  v |= v >> 8;
  v |= v >> 16;
  v = (v >> 1) + 1;
  return pos[(v * 0x077CB531UL) >> 27];
}
  • 18
    7 bit shifts, 5 or instructions, a multiplty and a potential cache miss. :) Did you benchmark it, or look at the assembler generated? It could end up quite slow, depending on how much of it the compiler can eliminate. – jalf Mar 23 '09 at 1:30
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    I'm new here. I don't get the negative votes guys. I have provided the only answer with source code that actually works. – Protagonist Mar 23 '09 at 19:59
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    The "possible cache miss" is probably due to this code requiring access to its lookup table. If that table is not cached when this is called, there will be a stall while it's fetched. This might make the worst-case performance far worse than the solutions not using a LUT. – unwind Mar 24 '09 at 15:00
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    not really the point. It uses a lot more data cache than necessary (more than one cache line, even), and more instruction cache than necessary. You'll likely get cache misses that could have been avoided the first time you call the function, and it will pollute the cache more than necessary, so after the call, other code might encounter more misses than necessary. LUT's often aren't worth the trouble because cache misses are expensive. But I only said it was something I'd want to benchmark before I claimed it was "lightning fast". Not that it is definitely a problem. – jalf Jul 8 '11 at 7:46
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    The table has 32 entries, and every value is < 255 (127), so define the table as type unsigned char, and it will fit in a single 32 byte L1 cache line. And the whole thing fits in two cache lines. – ChuckCottrill Oct 14 '15 at 1:31

This is sort of like finding a kind of integer log. There are bit-twiddling tricks, but I've made my own tool for this. The goal of course is for speed.

My realization is that the CPU has an automatic bit-detector already, used for integer to float conversion! So use that.

double ff=(double)(v|1);
return ((*(1+(uint32_t *)&ff))>>20)-1023;  // assumes x86 endianness

This version casts the value to a double, then reads off the exponent, which tells you where the bit was. The fancy shift and subtract is to extract the proper parts from the IEEE value.

It's slightly faster to use floats, but a float can only give you the first 24 bit positions because of its smaller precision.


To do this safely, without undefined behaviour in C++ or C, use memcpy instead of pointer casting for type-punning. Compilers know how to inline it efficiently.

// static_assert(sizeof(double) == 2 * sizeof(uint32_t), "double isn't 8-byte IEEE binary64");
// and also static_assert something about FLT_ENDIAN?

double ff=(double)(v|1);

uint32_t tmp;
memcpy(&tmp, ((const char*)&ff)+sizeof(uint32_t), sizeof(uint32_t));
return (tmp>>20)-1023;

Or in C99 and later, use a union {double d; uint32_t u[2];};. But note that in C++, union type punning is only supported on some compilers as an extension, not in ISO C++.


This will usually be slower than a platform-specific intrinsic for a leading-zeros counting instruction, but portable ISO C has no such function. Some CPUs also lack a leading-zero counting instruction, but some of those can efficiently convert integers to double. Type-punning an FP bit pattern back to integer can be slow, though (e.g. on PowerPC it requires a store/reload and usually causes a load-hit-store stall).

This algorithm could potentially be useful for SIMD implementations, because fewer CPUs have SIMD lzcnt. x86 only got such an instruction with AVX512CD

  • 2
    Yes. And gcc will do nasty things with code like this with -O2 due to type-aliasing optimizations. – MSN Mar 23 '09 at 0:51
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    casting between integer and floating point can be surprisingly expensive on x86 CPU's – jalf Mar 23 '09 at 1:23
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    Yep, the FPU costs are high. But actual time measurements showed this was faster than all-bit ops or especially any loops. Try it and take the fastest is always the best advice. I have not had a problem with GCC and -O2 with this though. – SPWorley Mar 23 '09 at 2:02
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    Isn't this undefined behaviour (reading a value through a pointer of an incompatible type)? – dreamlax Dec 11 '11 at 7:50
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    Hacker's Delight explains how to correct for the error in 32-bit floats in 5-3 Counting Leading 0's. Here's their code, which uses an anonymous union to overlap asFloat and asInt: k = k & ~(k >> 1); asFloat = (float)k + 0.5f; n = 158 - (asInt >> 23); (and yes, this relies on implementation-defined behavior) – D Coetzee Jan 3 '12 at 8:35

Kaz Kylheku here

I benchmarked two approaches for this over 63 bit numbers (the long long type on gcc x86_64), staying away from the sign bit.

(I happen to need this "find highest bit" for something, you see.)

I implemented the data-driven binary search (closely based on one of the above answers). I also implemented a completely unrolled decision tree by hand, which is just code with immediate operands. No loops, no tables.

The decision tree (highest_bit_unrolled) benchmarked to be 69% faster, except for the n = 0 case for which the binary search has an explicit test.

The binary-search's special test for 0 case is only 48% faster than the decision tree, which does not have a special test.

Compiler, machine: (GCC 4.5.2, -O3, x86-64, 2867 Mhz Intel Core i5).

int highest_bit_unrolled(long long n)
{
  if (n & 0x7FFFFFFF00000000) {
    if (n & 0x7FFF000000000000) {
      if (n & 0x7F00000000000000) {
        if (n & 0x7000000000000000) {
          if (n & 0x4000000000000000)
            return 63;
          else
            return (n & 0x2000000000000000) ? 62 : 61;
        } else {
          if (n & 0x0C00000000000000)
            return (n & 0x0800000000000000) ? 60 : 59;
          else
            return (n & 0x0200000000000000) ? 58 : 57;
        }
      } else {
        if (n & 0x00F0000000000000) {
          if (n & 0x00C0000000000000)
            return (n & 0x0080000000000000) ? 56 : 55;
          else
            return (n & 0x0020000000000000) ? 54 : 53;
        } else {
          if (n & 0x000C000000000000)
            return (n & 0x0008000000000000) ? 52 : 51;
          else
            return (n & 0x0002000000000000) ? 50 : 49;
        }
      }
    } else {
      if (n & 0x0000FF0000000000) {
        if (n & 0x0000F00000000000) {
          if (n & 0x0000C00000000000)
            return (n & 0x0000800000000000) ? 48 : 47;
          else
            return (n & 0x0000200000000000) ? 46 : 45;
        } else {
          if (n & 0x00000C0000000000)
            return (n & 0x0000080000000000) ? 44 : 43;
          else
            return (n & 0x0000020000000000) ? 42 : 41;
        }
      } else {
        if (n & 0x000000F000000000) {
          if (n & 0x000000C000000000)
            return (n & 0x0000008000000000) ? 40 : 39;
          else
            return (n & 0x0000002000000000) ? 38 : 37;
        } else {
          if (n & 0x0000000C00000000)
            return (n & 0x0000000800000000) ? 36 : 35;
          else
            return (n & 0x0000000200000000) ? 34 : 33;
        }
      }
    }
  } else {
    if (n & 0x00000000FFFF0000) {
      if (n & 0x00000000FF000000) {
        if (n & 0x00000000F0000000) {
          if (n & 0x00000000C0000000)
            return (n & 0x0000000080000000) ? 32 : 31;
          else
            return (n & 0x0000000020000000) ? 30 : 29;
        } else {
          if (n & 0x000000000C000000)
            return (n & 0x0000000008000000) ? 28 : 27;
          else
            return (n & 0x0000000002000000) ? 26 : 25;
        }
      } else {
        if (n & 0x0000000000F00000) {
          if (n & 0x0000000000C00000)
            return (n & 0x0000000000800000) ? 24 : 23;
          else
            return (n & 0x0000000000200000) ? 22 : 21;
        } else {
          if (n & 0x00000000000C0000)
            return (n & 0x0000000000080000) ? 20 : 19;
          else
            return (n & 0x0000000000020000) ? 18 : 17;
        }
      }
    } else {
      if (n & 0x000000000000FF00) {
        if (n & 0x000000000000F000) {
          if (n & 0x000000000000C000)
            return (n & 0x0000000000008000) ? 16 : 15;
          else
            return (n & 0x0000000000002000) ? 14 : 13;
        } else {
          if (n & 0x0000000000000C00)
            return (n & 0x0000000000000800) ? 12 : 11;
          else
            return (n & 0x0000000000000200) ? 10 : 9;
        }
      } else {
        if (n & 0x00000000000000F0) {
          if (n & 0x00000000000000C0)
            return (n & 0x0000000000000080) ? 8 : 7;
          else
            return (n & 0x0000000000000020) ? 6 : 5;
        } else {
          if (n & 0x000000000000000C)
            return (n & 0x0000000000000008) ? 4 : 3;
          else
            return (n & 0x0000000000000002) ? 2 : (n ? 1 : 0);
        }
      }
    }
  }
}

int highest_bit(long long n)
{
  const long long mask[] = {
    0x000000007FFFFFFF,
    0x000000000000FFFF,
    0x00000000000000FF,
    0x000000000000000F,
    0x0000000000000003,
    0x0000000000000001
  };
  int hi = 64;
  int lo = 0;
  int i = 0;

  if (n == 0)
    return 0;

  for (i = 0; i < sizeof mask / sizeof mask[0]; i++) {
    int mi = lo + (hi - lo) / 2;

    if ((n >> mi) != 0)
      lo = mi;
    else if ((n & (mask[i] << lo)) != 0)
      hi = mi;
  }

  return lo + 1;
}

Quick and dirty test program:

#include <stdio.h>
#include <time.h>
#include <stdlib.h>

int highest_bit_unrolled(long long n);
int highest_bit(long long n);

main(int argc, char **argv)
{
  long long n = strtoull(argv[1], NULL, 0);
  int b1, b2;
  long i;
  clock_t start = clock(), mid, end;

  for (i = 0; i < 1000000000; i++)
    b1 = highest_bit_unrolled(n);

  mid = clock();

  for (i = 0; i < 1000000000; i++)
    b2 = highest_bit(n);

  end = clock();

  printf("highest bit of 0x%llx/%lld = %d, %d\n", n, n, b1, b2);

  printf("time1 = %d\n", (int) (mid - start));
  printf("time2 = %d\n", (int) (end - mid));
  return 0;
}

Using only -O2, the difference becomes greater. The decision tree is almost four times faster.

I also benchmarked against the naive bit shifting code:

int highest_bit_shift(long long n)
{
  int i = 0;
  for (; n; n >>= 1, i++)
    ; /* empty */
  return i;
}

This is only fast for small numbers, as one would expect. In determining that the highest bit is 1 for n == 1, it benchmarked more than 80% faster. However, half of randomly chosen numbers in the 63 bit space have the 63rd bit set!

On the input 0x3FFFFFFFFFFFFFFF, the decision tree version is quite a bit faster than it is on 1, and shows to be 1120% faster (12.2 times) than the bit shifter.

I will also benchmark the decision tree against the GCC builtins, and also try a mixture of inputs rather than repeating against the same number. There may be some sticking branch prediction going on and perhaps some unrealistic caching scenarios which makes it artificially faster on repetitions.

  • 8
    I'm not saying this isn't good, but Your test program here only tests on the same number, which after 2-3 iterations will have set the branch predictors to their final position and after that they will make perfect branch predictions. The good thing is that with a totally random distribution half the numbers will have close to perfect prediction, namely bit63. – Surt Oct 2 '14 at 15:29

What about

int highest_bit(unsigned int a) {
    int count;
    std::frexp(a, &count);
    return count - 1;
}

?

  • This is a slow (but more portable) version of this answer, which explains why it works. – Peter Cordes Mar 11 at 4:43
unsigned int
msb32(register unsigned int x)
{
        x |= (x >> 1);
        x |= (x >> 2);
        x |= (x >> 4);
        x |= (x >> 8);
        x |= (x >> 16);
        return(x & ~(x >> 1));
}

1 register, 13 instructions. Believe it or not, this is usually faster than the BSR instruction mentioned above, which operates in linear time. This is logarithmic time.

From http://aggregate.org/MAGIC/#Most%20Significant%201%20Bit

  • 6
    The above code doesn't answer the question. It returns an unsigned integer where the most significant on bit in x remains on and all the other bits are turned off. The question was to return the position of the most significant on bit. – Protagonist Mar 23 '09 at 21:55
  • 3
    You can then use a De Bruijn sequence approach to find the index of the bit that's set. :-) – R.. Feb 6 '11 at 6:55
  • 5
    @Protagonist, he said in a comment that either suffices. – rlbond Feb 8 '11 at 1:27
  • This one (from that same page) would do what you need, but it requires an additional function. aggregate.org/MAGIC/#Log2%20of%20an%20Integer – Quinn Taylor Feb 11 '11 at 16:14
  • BSR is fast on Intel CPUs since Core2 at least. LZCNT is fast on AMD CPUs, and gcc uses it for __builtin_clz if it's enabled with -march=native or something (since it's fast on every CPU that supports it). Even on CPUs like AMD Bulldozer-family where BSR is "slow", it's not that slow: 7 m-ops with 4 cycle latency and one per 4c throughput. On Atom, BSR is really slow: 16 cycles. On Silvermont, it's 10 uops with 10 cycle latency. This might be slightly lower latency than BSR on Silvermont, but IDK. – Peter Cordes Dec 18 '16 at 7:07

Here are some (simple) benchmarks, of algorithms currently given on this page...

The algorithms have not been tested over all inputs of unsigned int; so check that first, before blindly using something ;)

On my machine clz (__builtin_clz) and asm work best. asm seems even faster then clz... but it might be due to the simple benchmark...

//////// go.c ///////////////////////////////
// compile with:  gcc go.c -o go -lm
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <time.h>

/***************** math ********************/

#define POS_OF_HIGHESTBITmath(a) /* 0th position is the Least-Signif-Bit */    \
  ((unsigned) log2(a))         /* thus: do not use if a <= 0 */  

#define NUM_OF_HIGHESTBITmath(a) ((a)               \
                  ? (1U << POS_OF_HIGHESTBITmath(a))    \
                  : 0)



/***************** clz ********************/

unsigned NUM_BITS_U = ((sizeof(unsigned) << 3) - 1);
#define POS_OF_HIGHESTBITclz(a) (NUM_BITS_U - __builtin_clz(a)) /* only works for a != 0 */

#define NUM_OF_HIGHESTBITclz(a) ((a)                    \
                 ? (1U << POS_OF_HIGHESTBITclz(a))  \
                 : 0)


/***************** i2f ********************/

double FF;
#define POS_OF_HIGHESTBITi2f(a) (FF = (double)(ui|1), ((*(1+(unsigned*)&FF))>>20)-1023)


#define NUM_OF_HIGHESTBITi2f(a) ((a)                    \
                 ? (1U << POS_OF_HIGHESTBITi2f(a))  \
                 : 0)




/***************** asm ********************/

unsigned OUT;
#define POS_OF_HIGHESTBITasm(a) (({asm("bsrl %1,%0" : "=r"(OUT) : "r"(a));}), OUT)

#define NUM_OF_HIGHESTBITasm(a) ((a)                    \
                 ? (1U << POS_OF_HIGHESTBITasm(a))  \
                 : 0)




/***************** bitshift1 ********************/

#define NUM_OF_HIGHESTBITbitshift1(a) (({   \
  OUT = a;                  \
  OUT |= (OUT >> 1);                \
  OUT |= (OUT >> 2);                \
  OUT |= (OUT >> 4);                \
  OUT |= (OUT >> 8);                \
  OUT |= (OUT >> 16);               \
      }), (OUT & ~(OUT >> 1)))          \



/***************** bitshift2 ********************/
int POS[32] = {0, 1, 28, 2, 29, 14, 24, 3,
             30, 22, 20, 15, 25, 17, 4, 8, 31, 27, 13, 23, 21, 19,
             16, 7, 26, 12, 18, 6, 11, 5, 10, 9};

#define POS_OF_HIGHESTBITbitshift2(a) (({   \
  OUT = a;                  \
  OUT |= OUT >> 1;              \
  OUT |= OUT >> 2;              \
  OUT |= OUT >> 4;              \
  OUT |= OUT >> 8;              \
  OUT |= OUT >> 16;             \
  OUT = (OUT >> 1) + 1;             \
      }), POS[(OUT * 0x077CB531UL) >> 27])

#define NUM_OF_HIGHESTBITbitshift2(a) ((a)              \
                       ? (1U << POS_OF_HIGHESTBITbitshift2(a)) \
                       : 0)



#define LOOPS 100000000U

int main()
{
  time_t start, end;
  unsigned ui;
  unsigned n;

  /********* Checking the first few unsigned values (you'll need to check all if you want to use an algorithm here) **************/
  printf("math\n");
  for (ui = 0U; ui < 18; ++ui)
    printf("%i\t%i\n", ui, NUM_OF_HIGHESTBITmath(ui));

  printf("\n\n");

  printf("clz\n");
  for (ui = 0U; ui < 18U; ++ui)
    printf("%i\t%i\n", ui, NUM_OF_HIGHESTBITclz(ui));

  printf("\n\n");

  printf("i2f\n");
  for (ui = 0U; ui < 18U; ++ui)
    printf("%i\t%i\n", ui, NUM_OF_HIGHESTBITi2f(ui));

  printf("\n\n");

  printf("asm\n");
  for (ui = 0U; ui < 18U; ++ui) {
    printf("%i\t%i\n", ui, NUM_OF_HIGHESTBITasm(ui));
  }

  printf("\n\n");

  printf("bitshift1\n");
  for (ui = 0U; ui < 18U; ++ui) {
    printf("%i\t%i\n", ui, NUM_OF_HIGHESTBITbitshift1(ui));
  }

  printf("\n\n");

  printf("bitshift2\n");
  for (ui = 0U; ui < 18U; ++ui) {
    printf("%i\t%i\n", ui, NUM_OF_HIGHESTBITbitshift2(ui));
  }

  printf("\n\nPlease wait...\n\n");


  /************************* Simple clock() benchmark ******************/
  start = clock();
  for (ui = 0; ui < LOOPS; ++ui)
    n = NUM_OF_HIGHESTBITmath(ui);
  end = clock();
  printf("math:\t%e\n", (double)(end-start)/CLOCKS_PER_SEC);

  start = clock();
  for (ui = 0; ui < LOOPS; ++ui)
    n = NUM_OF_HIGHESTBITclz(ui);
  end = clock();
  printf("clz:\t%e\n", (double)(end-start)/CLOCKS_PER_SEC);

  start = clock();
  for (ui = 0; ui < LOOPS; ++ui)
    n = NUM_OF_HIGHESTBITi2f(ui);
  end = clock();
  printf("i2f:\t%e\n", (double)(end-start)/CLOCKS_PER_SEC);

  start = clock();
  for (ui = 0; ui < LOOPS; ++ui)
    n = NUM_OF_HIGHESTBITasm(ui);
  end = clock();
  printf("asm:\t%e\n", (double)(end-start)/CLOCKS_PER_SEC);

  start = clock();
  for (ui = 0; ui < LOOPS; ++ui)
    n = NUM_OF_HIGHESTBITbitshift1(ui);
  end = clock();
  printf("bitshift1:\t%e\n", (double)(end-start)/CLOCKS_PER_SEC);

  start = clock();
  for (ui = 0; ui < LOOPS; ++ui)
    n = NUM_OF_HIGHESTBITbitshift2(ui);
  end = clock();
  printf("bitshift2\t%e\n", (double)(end-start)/CLOCKS_PER_SEC);

  printf("\nThe lower, the better. Take note that a negative exponent is good! ;)\n");

  return EXIT_SUCCESS;
}

Although I would probably only use this method if I absolutely required the best possible performance (e.g. for writing some sort of board game AI involving bitboards), the most efficient solution is to use inline ASM. See the Optimisations section of this blog post for code with an explanation.

[...], the bsrl assembly instruction computes the position of the most significant bit. Thus, we could use this asm statement:

asm ("bsrl %1, %0" 
     : "=r" (position) 
     : "r" (number));
  • To expand: the standard loop solution (shifting left and checking MSB) is probably the most readable. As in all cases involving bit twiddling, the speed of ASM can't be beaten, though there's no point cluttering your code unless necessary. Hacks are an in-between solution - go one way or the other. – Noldorin Mar 23 '09 at 0:05
  • I'd say taking the logarithm would be a perfectly readable solution (check the generated asm to see if the compiler can optimize it to use this asm instruction) – jalf Mar 23 '09 at 1:22
  • Sometimes the inline ASM solution is slower, depending on the implementation in CPU microcode. – rlbond Mar 23 '09 at 4:39
  • 5
    @rlbound: I can hardly believe that, although I may be mistaken. On any modern CPU one would think that it would get translated to a single instruction.... – Noldorin Mar 23 '09 at 12:04
  • 2
    @Noldorin it's a bit late but.. It's by definition a single instruction, but if it's microcoded as rlbond suggests then that single instruction could decode to a whole bunch of µops internally. That tends to be the case on AMD's microarchitectures, and Intel Atom, but on normal Intel microarchitectures it's a single operation all the way down. – harold Oct 26 '17 at 13:54

I had a need for a routine to do this and before searching the web (and finding this page) I came up with my own solution basedon a binary search. Although I'm sure someone has done this before! It runs in constant time and can be faster than the "obvious" solution posted, although I'm not making any great claims, just posting it for interest.

int highest_bit(unsigned int a) {
  static const unsigned int maskv[] = { 0xffff, 0xff, 0xf, 0x3, 0x1 };
  const unsigned int *mask = maskv;
  int l, h;

  if (a == 0) return -1;

  l = 0;
  h = 32;

  do {
    int m = l + (h - l) / 2;

    if ((a >> m) != 0) l = m;
    else if ((a & (*mask << l)) != 0) h = m;

    mask++;
  } while (l < h - 1);

  return l;
}

Some overly complex answers here. The Debruin technique should only be used when the input is already a power of two, otherwise there's a better way. For a power of 2 input, Debruin is the absolute fastest, even faster than _BitScanReverse on any processor I've tested. However, in the general case, _BitScanReverse (or whatever the intrinsic is called in your compiler) is the fastest (on certain CPU's it can be microcoded though).

If the intrinsic function is not an option, here is an optimal software solution for processing general inputs.

u8  inline log2 (u32 val)  {
    u8  k = 0;
    if (val > 0x0000FFFFu) { val >>= 16; k  = 16; }
    if (val > 0x000000FFu) { val >>= 8;  k |= 8;  }
    if (val > 0x0000000Fu) { val >>= 4;  k |= 4;  }
    if (val > 0x00000003u) { val >>= 2;  k |= 2;  }
    k |= (val & 2) >> 1;
    return k;
}

Note that this version does not require a Debruin lookup at the end, unlike most of the other answers. It computes the position in place.

Tables can be preferable though, if you call it repeatedly enough times, the risk of a cache miss becomes eclipsed by the speedup of a table.

u8 kTableLog2[256] = {
0,0,1,1,2,2,2,2,3,3,3,3,3,3,3,3,4,4,4,4,4,4,4,4,4,4,4,4,4,4,4,4,
5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,
6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,
6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,
7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,
7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,
7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,
7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7
};

u8 log2_table(u32 val)  {
    u8  k = 0;
    if (val > 0x0000FFFFuL) { val >>= 16; k  = 16; }
    if (val > 0x000000FFuL) { val >>=  8; k |=  8; }
    k |= kTableLog2[val]; // precompute the Log2 of the low byte

    return k;
}

This should produce the highest throughput of any of the software answers given here, but if you only call it occasionally, prefer a table-free solution like my first snippet.

  • Some of the answers are branchless, but this probably will compile with conditional branches. Did you only benchmark with the same value repeatedly, or a simple pattern or something? Branch misprediction is a killer for performance. stackoverflow.com/questions/11227809/… – Peter Cordes Mar 11 at 4:50

As the answers above point out, there are a number of ways to determine the most significant bit. However, as was also pointed out, the methods are likely to be unique to either 32bit or 64bit registers. The stanford.edu bithacks page provides solutions that work for both 32bit and 64bit computing. With a little work, they can be combined to provide a solid cross-architecture approach to obtaining the MSB. The solution I arrived at that compiled/worked across 64 & 32 bit computers was:

#if defined(__LP64__) || defined(_LP64)
# define BUILD_64   1
#endif

#include <stdio.h>
#include <stdint.h>  /* for uint32_t */

/* CHAR_BIT  (or include limits.h) */
#ifndef CHAR_BIT
#define CHAR_BIT  8
#endif  /* CHAR_BIT */

/* 
 * Find the log base 2 of an integer with the MSB N set in O(N)
 * operations. (on 64bit & 32bit architectures)
 */
int
getmsb (uint32_t word)
{
    int r = 0;
    if (word < 1)
        return 0;
#ifdef BUILD_64
    union { uint32_t u[2]; double d; } t;  // temp
    t.u[__FLOAT_WORD_ORDER==LITTLE_ENDIAN] = 0x43300000;
    t.u[__FLOAT_WORD_ORDER!=LITTLE_ENDIAN] = word;
    t.d -= 4503599627370496.0;
    r = (t.u[__FLOAT_WORD_ORDER==LITTLE_ENDIAN] >> 20) - 0x3FF;
#else
    while (word >>= 1)
    {
        r++;
    }
#endif  /* BUILD_64 */
    return r;
}
  • Wasn't int r; originally defined above the #ifdef BUILD_64 flag? In which case it would not need redefinition within the conditional. – David C. Rankin Jun 21 '14 at 9:25

A version in C using successive approximation:

unsigned int getMsb(unsigned int n)
{
  unsigned int msb  = sizeof(n) * 4;
  unsigned int step = msb;
  while (step > 1)
 {
    step /=2;
    if (n>>msb)
     msb += step;
   else
     msb -= step;
 }
  if (n>>msb)
    msb++;
  return (msb - 1);
}

Advantage: the running time is constant regardless of the provided number, as the number of loops are always the same. ( 4 loops when using "unsigned int")

thats some kind of binary search, it works with all kinds of (unsigned!) integer types

#include <climits>
#define UINT (unsigned int)
#define UINT_BIT (CHAR_BIT*sizeof(UINT))

int msb(UINT x)
{
    if(0 == x)
        return -1;

    int c = 0;

    for(UINT i=UINT_BIT>>1; 0<i; i>>=1)
    if(static_cast<UINT>(x >> i))
    {
        x >>= i;
        c |= i;
    }

    return c;
}

to make complete:

#include <climits>
#define UINT unsigned int
#define UINT_BIT (CHAR_BIT*sizeof(UINT))

int lsb(UINT x)
{
    if(0 == x)
        return -1;

    int c = UINT_BIT-1;

    for(UINT i=UINT_BIT>>1; 0<i; i>>=1)
    if(static_cast<UINT>(x << i))
    {
        x <<= i;
        c ^= i;
    }

    return c;
}
  • 4
    Please consider not using ALL_CAPS for typedefs or indeed anything except preprocessor macros. This is a widely accepted convention. – underscore_d Oct 11 '15 at 16:21

has given us log2. This removes the need for all the special sauce log2 implementations you see on this page. You can use the standard's log2 implementation like this:

const auto n = 13UL;
const auto Index = (unsigned long)log2(n);

printf("MSB is: %u\n", Index); // Prints 3 (zero offset)

An n of 0UL needs to be guarded against as well, because:

-∞ is returned and FE_DIVBYZERO is raised

I have written an example with that check that arbitrarily sets Index to ULONG_MAX here: https://ideone.com/u26vsi


The corollary to ephemient's gcc only answer is:

const auto n = 13UL;
unsigned long Index;

_BitScanReverse(&Index, n);
printf("MSB is: %u\n", Index); // Prints 3 (zero offset)

The documentation for _BitScanReverse states that Index is:

Loaded with the bit position of the first set bit (1) found

In practice I've found that if n is 0UL that Index is set to 0UL, just as it would be for an n of 1UL. But the only thing guaranteed in the documentation in the case of an n of 0UL is that the return is:

0 if no set bits were found

Thus, similarly to the preferable log2 implementation above the return should be checked setting Index to a flagged value in this case. I've again written an example of using ULONG_MAX for this flag value here: http://rextester.com/GCU61409

  • No, _BitScanReverse returns 0 only if the input was 0. This is like x86's BSR instruction, which sets ZF based only on the input, not the output. Interesting that MS words the docs as leaving index unset when no 1 bit is found; that matches the x86 asm behaviour of bsr, too. (AMD documents it as leaving the destination register unmodified on src=0, but Intel just says undefined output even though their CPUs do implement the leave-unmodified behaviour.) This is unlike x86's lzcnt, which gives 32 for not-found. – Peter Cordes Mar 11 at 5:02
  • @PeterCordes _BitScanReverse uses zero-based indexing, thus if n is 1 then the index of the set bit is in fact 0. Unfortunately, as you say if n is 0 then the output is also 0 :( This means there's no way to use the return to distinguish between an n of 1 or 0. That's what I was trying to communicate. Do you think there's a better way to say this? – Jonathan Mee Mar 12 at 12:52
  • I think you're talking about how it sets Index. That's not the return value. It returns a boolean that's false if the input was zero (and this is why Index is passed by reference instead of being returned normally). godbolt.org/g/gQKJdE. And I checked: despite the wording of MS's docs, _BitScanReverse doesn't leave Index unset on n==0: you just get whatever value was in the register it happened to use. (Which in your case was probably the same register it used for Index afterward, leading to you seeing a 0). – Peter Cordes Mar 12 at 22:23
  • This question is not tagged c++. – technosaurus Mar 13 at 1:41
  • @technosaurus Thanks, I forgot myself. Given that the question is C we've actually had log2 since C99. – Jonathan Mee Mar 13 at 12:45

Think bitwise operators.

I missunderstood the question the first time. You should produce an int with the leftmost bit set (the others zero). Assuming cmp is set to that value:

position = sizeof(int)*8
while(!(n & cmp)){ 
   n <<=1;
   position--;
}
  • What do you mean converting to a string? The definition of ffs takes an int and returns an int. Where would the conversion be? And what purpose would the conversion serve if we are looking for bits in a word? – dreamlax Mar 23 '09 at 3:31
  • I didn't know of that function. – Vasil Mar 23 '09 at 3:37
  • The 8 should be CHAR_BIT. This is very unlikely to be the fastest way, because branch misprediction will happen on exiting the loop unless this is used with the same input repeatedly. Also, for small inputs (lots of zeros), it has to loop a lot. This is like the fallback way that you'd use as the easy-to-verify version in a unit test to compare against optimized versions. – Peter Cordes Mar 11 at 4:53

Expanding on Josh's benchmark... one can improve the clz as follows

/***************** clz2 ********************/

#define NUM_OF_HIGHESTBITclz2(a) ((a)                              \
                  ? (((1U) << (sizeof(unsigned)*8-1)) >> __builtin_clz(a)) \
                  : 0)

Regarding the asm: note that there are bsr and bsrl (this is the "long" version). the normal one might be a bit faster.

Note that what you are trying to do is calculate the integer log2 of an integer,

#include <stdio.h>
#include <stdlib.h>

unsigned int
Log2(unsigned long x)
{
    unsigned long n = x;
    int bits = sizeof(x)*8;
    int step = 1; int k=0;
    for( step = 1; step < bits; ) {
        n |= (n >> step);
        step *= 2; ++k;
    }
    //printf("%ld %ld\n",x, (x - (n >> 1)) );
    return(x - (n >> 1));
}

Observe that you can attempt to search more than 1 bit at a time.

unsigned int
Log2_a(unsigned long x)
{
    unsigned long n = x;
    int bits = sizeof(x)*8;
    int step = 1;
    int step2 = 0;
    //observe that you can move 8 bits at a time, and there is a pattern...
    //if( x>1<<step2+8 ) { step2+=8;
        //if( x>1<<step2+8 ) { step2+=8;
            //if( x>1<<step2+8 ) { step2+=8;
            //}
        //}
    //}
    for( step2=0; x>1L<<step2+8; ) {
        step2+=8;
    }
    //printf("step2 %d\n",step2);
    for( step = 0; x>1L<<(step+step2); ) {
        step+=1;
        //printf("step %d\n",step+step2);
    }
    printf("log2(%ld) %d\n",x,step+step2);
    return(step+step2);
}

This approach uses a binary search

unsigned int
Log2_b(unsigned long x)
{
    unsigned long n = x;
    unsigned int bits = sizeof(x)*8;
    unsigned int hbit = bits-1;
    unsigned int lbit = 0;
    unsigned long guess = bits/2;
    int found = 0;

    while ( hbit-lbit>1 ) {
        //printf("log2(%ld) %d<%d<%d\n",x,lbit,guess,hbit);
        //when value between guess..lbit
        if( (x<=(1L<<guess)) ) {
           //printf("%ld < 1<<%d %ld\n",x,guess,1L<<guess);
            hbit=guess;
            guess=(hbit+lbit)/2;
            //printf("log2(%ld) %d<%d<%d\n",x,lbit,guess,hbit);
        }
        //when value between hbit..guess
        //else
        if( (x>(1L<<guess)) ) {
            //printf("%ld > 1<<%d %ld\n",x,guess,1L<<guess);
            lbit=guess;
            guess=(hbit+lbit)/2;
            //printf("log2(%ld) %d<%d<%d\n",x,lbit,guess,hbit);
        }
    }
    if( (x>(1L<<guess)) ) ++guess;
    printf("log2(x%ld)=r%d\n",x,guess);
    return(guess);
}

Another binary search method, perhaps more readable,

unsigned int
Log2_c(unsigned long x)
{
    unsigned long v = x;
    unsigned int bits = sizeof(x)*8;
    unsigned int step = bits;
    unsigned int res = 0;
    for( step = bits/2; step>0; )
    {
        //printf("log2(%ld) v %d >> step %d = %ld\n",x,v,step,v>>step);
        while ( v>>step ) {
            v>>=step;
            res+=step;
            //printf("log2(%ld) step %d res %d v>>step %ld\n",x,step,res,v);
        }
        step /= 2;
    }
    if( (x>(1L<<res)) ) ++res;
    printf("log2(x%ld)=r%ld\n",x,res);
    return(res);
}

And because you will want to test these,

int main()
{
    unsigned long int x = 3;
    for( x=2; x<1000000000; x*=2 ) {
        //printf("x %ld, x+1 %ld, log2(x+1) %d\n",x,x+1,Log2(x+1));
        printf("x %ld, x+1 %ld, log2_a(x+1) %d\n",x,x+1,Log2_a(x+1));
        printf("x %ld, x+1 %ld, log2_b(x+1) %d\n",x,x+1,Log2_b(x+1));
        printf("x %ld, x+1 %ld, log2_c(x+1) %d\n",x,x+1,Log2_c(x+1));
    }
    return(0);
}

Putting this in since it's 'yet another' approach, seems to be different from others already given.

returns -1 if x==0, otherwise floor( log2(x)) (max result 31)

Reduce from 32 to 4 bit problem, then use a table. Perhaps inelegant, but pragmatic.

This is what I use when I don't want to use __builtin_clz because of portability issues.

To make it more compact, one could instead use a loop to reduce, adding 4 to r each time, max 7 iterations. Or some hybrid, such as (for 64 bits): loop to reduce to 8, test to reduce to 4.

int log2floor( unsigned x ){
   static const signed char wtab[16] = {-1,0,1,1, 2,2,2,2, 3,3,3,3,3,3,3,3};
   int r = 0;
   unsigned xk = x >> 16;
   if( xk != 0 ){
       r = 16;
       x = xk;
   }
   // x is 0 .. 0xFFFF
   xk = x >> 8;
   if( xk != 0){
       r += 8;
       x = xk;
   }
   // x is 0 .. 0xFF
   xk = x >> 4;
   if( xk != 0){
       r += 4;
       x = xk;
   }
   // now x is 0..15; x=0 only if originally zero.
   return r + wtab[x];
}

I know this question is very old, but just having implemented an msb() function myself, I found that most solutions presented here and on other websites are not necessarily the most efficient - at least for my personal definition of efficiency (see also Update below). Here's why:

Most solutions (especially those which employ some sort of binary search scheme or the naïve approach which does a linear scan from right to left) seem to neglect the fact that for arbitrary binary numbers, there are not many which start with a very long sequence of zeros. In fact, for any bit-width, half of all integers start with a 1 and a quarter of them start with 01. See where i'm getting at? My argument is that a linear scan starting from the most significant bit position to the least significant (left to right) is not so "linear" as it might look like at first glance.

It can be shown1, that for any bit-width, the average number of bits that need to be tested is at most 2. This translates to an amortized time complexity of O(1) with respect to the number of bits (!).

Of course, the worst case is still O(n), worse than the O(log(n)) you get with binary-search-like approaches, but since there are so few worst cases, they are negligible for most applications (Update: not quite: There may be few, but they might occur with high probability - see Update below).

Here is the "naïve" approach i've come up with, which at least on my machine beats most other approaches (binary search schemes for 32-bit ints always require log2(32) = 5 steps, whereas this silly algorithm requires less than 2 on average) - sorry for this being C++ and not pure C:

template <typename T>
auto msb(T n) -> int
{
    static_assert(std::is_integral<T>::value && !std::is_signed<T>::value,
        "msb<T>(): T must be an unsigned integral type.");

    for (T i = std::numeric_limits<T>::digits - 1, mask = 1 << i; i >= 0; --i, mask >>= 1)
    {
        if ((n & mask) != 0)
            return i;
    }

    return 0;
}

Update: While what i wrote here is perfectly true for arbitrary integers, where every combination of bits is equally probable (my speed test simply measured how long it took to determine the MSB for all 32-bit integers), real-life integers, for which such a function will be called, usually follow a different pattern: In my code, for example, this function is used to determine whether an object size is a power of 2, or to find the next power of 2 greater or equal than an object size. My guess is that most applications using the MSB involve numbers which are much smaller than the maximum number an integer can represent (object sizes rarely utilize all the bits in a size_t). In this case, my solution will actually perform worse than a binary search approach - so the latter should probably be preferred, even though my solution will be faster looping through all integers.
TL;DR: Real-life integers will probably have a bias towards the worst case of this simple algorithm, which will make it perform worse in the end - despite the fact that it's amortized O(1) for truly arbitrary integers.

1The argument goes like this (rough draft): Let n be the number of bits (bit-width). There are a total of 2n integers wich can be represented with n bits. There are 2n - 1 integers starting with a 1 (first 1 is fixed, remaining n - 1 bits can be anything). Those integers require only one interation of the loop to determine the MSB. Further, There are 2n - 2 integers starting with 01, requiring 2 iterations, 2n - 3 integers starting with 001, requiring 3 iterations, and so on.

If we sum up all the required iterations for all possible integers and divide them by 2n, the total number of integers, we get the average number of iterations needed for determining the MSB for n-bit integers:

(1 * 2n - 1 + 2 * 2n - 2 + 3 * 2n - 3 + ... + n) / 2n

This series of average iterations is actually convergent and has a limit of 2 for n towards infinity

Thus, the naïve left-to-right algorithm has actually an amortized constant time complexity of O(1) for any number of bits.

  • 1
    I don't think it's necessarily a fair assumption that the inputs to msb functions tend to be evenly distributed. In practice, these inputs tend to be interrupt registers or bitboards or some other data structure with unevenly distributed values. For a fair benchmark I think it is safer to assume that the outputs (not the inputs) will be evenly distributed. – johnwbyrd Oct 28 '17 at 21:29

Woaw, that was many answers. I am not sorry for answering on an old question.

int result = 0;//could be a char or int8_t instead
if(value){//this assumes the value is 64bit
    if(0xFFFFFFFF00000000&value){  value>>=(1<<5); result|=(1<<5);  }//if it is 32bit then remove this line
    if(0x00000000FFFF0000&value){  value>>=(1<<4); result|=(1<<4);  }//and remove the 32msb
    if(0x000000000000FF00&value){  value>>=(1<<3); result|=(1<<3);  }
    if(0x00000000000000F0&value){  value>>=(1<<2); result|=(1<<2);  }
    if(0x000000000000000C&value){  value>>=(1<<1); result|=(1<<1);  }
    if(0x0000000000000002&value){  result|=(1<<0);  }
}else{
  result=-1;
}

This answer is pretty similar to another answer... oh well.

  • Writing the shift amounts as 1<<k is a nice touch. What about the masks? (1 << (1<<k-1)-1<< (1<<k-1)? (most optimal? You compare a superlative?) – greybeard Oct 26 '17 at 17:31
  • @greybeard If you look at the edits of this question you will see when I added the "optimal" part. I forgot to remove it as I changed my answer. Also I'm not sure why you are are talking about the masks? (What masks? I'm not following you) – Harry Svensson Oct 27 '17 at 1:44
  • ((bit)mask are values used to select/clear bits selectively/used in & and &~.) You could replace the hex constants by the likes of ((type)1<<(1<<k))-1<<(1<<k). – greybeard Oct 27 '17 at 7:40
  • Oh right, I'm using masks, I totally forgot about that. I did answer this a couple of month's ago... - Hmmm, well since it's evaluated during compile time I say it's equivalent to the hex values. However, one is cryptic and one is hexadecimal. – Harry Svensson Oct 27 '17 at 21:33

The code:

    // x>=1;
    unsigned func(unsigned x) {
    double d = x ;
    int p= (*reinterpret_cast<long long*>(&d) >> 52) - 1023;
    printf( "The left-most non zero bit of %d is bit %d\n", x, p);
    }

Or get the integer part of FPU instruction FYL2X (Y*Log2 X) by setting Y=1

  • uhhhhh. what? how does this function? is it in any way portable? – underscore_d Oct 11 '15 at 16:20
  • Codes in the window is portable. The function FYL2X() is a fpu instruction, but may be ported and may found in some FPU/math library. – jemin Oct 25 '15 at 15:01
  • @underscore_d It works because floating point numbers are normalized ... converting to double shifts the mantissa bits to eliminate leading zeros, and this code extracts the exponent and adjusts it to determine the number of bits shifted. It certainly isn't architecture-independent, but it will probably work on any machine you come across. – Jim Balter Dec 28 '16 at 10:00
  • This is an alternate version of this answer, see there for comments on performance and portability. (Specifically the non-portability of pointer casting for type-punning.) It uses address math to only reload the high 32 bits of the double, which is probably good if it does actually store/reload instead of type-pun some other way, e.g. with a movq instruction like you might get here on x86. – Peter Cordes Mar 11 at 5:09

I assume your question is for an integer (called v below) and not an unsigned integer.

int v = 612635685; // whatever value you wish

unsigned int get_msb(int v)
{
    int r = 31;                         // maximum number of iteration until integer has been totally left shifted out, considering that first bit is index 0. Also we could use (sizeof(int)) << 3 - 1 instead of 31 to make it work on any platform.

    while (!(v & 0x8000000) && r--) {   // mask of the highest bit
        v <<= 1;                        // multiply integer by 2.
    }
    return r;                           // will even return -1 if no bit was set, allowing error catch
}

If you want to make it work without taking into account the sign you can add an extra 'v <<= 1;' before the loop (and change r value to 30 accordingly). Please let me know if I forgot anything. I haven't tested it but it should work just fine.

  • v <<= 1 is undefined behavior (UB) when v < 0. – chux Nov 3 at 21:19

Another poster provided a lookup-table using a byte-wide lookup. In case you want to eke out a bit more performance (at the cost of 32K of memory instead of just 256 lookup entries) here is a solution using a 15-bit lookup table, in C# 7 for .NET.

The interesting part is initializing the table. Since it's a relatively small block that we want for the lifetime of the process, I allocate unmanaged memory for this by using Marshal.AllocHGlobal. As you can see, for maximum performance, the whole example is written as native:

readonly static byte[] msb_tab_15;

// Initialize a table of 32768 bytes with the bit position (counting from LSB=0)
// of the highest 'set' (non-zero) bit of its corresponding 16-bit index value.
// The table is compressed by half, so use (value >> 1) for indexing.
static MyStaticInit()
{
    var p = new byte[0x8000];

    for (byte n = 0; n < 16; n++)
        for (int c = (1 << n) >> 1, i = 0; i < c; i++)
            p[c + i] = n;

    msb_tab_15 = p;
}

The table requires one-time initialization via the code above. It is read-only so a single global copy can be shared for concurrent access. With this table you can quickly look up the integer log2, which is what we're looking for here, for all the various integer widths (8, 16, 32, and 64 bits).

Notice that the table entry for 0, the sole integer for which the notion of 'highest set bit' is undefined, is given the value -1. This distinction is necessary for proper handling of 0-valued upper words in the code below. Without further ado, here is the code for each of the various integer primitives:

ulong (64-bit) Version

/// <summary> Index of the highest set bit in 'v', or -1 for value '0' </summary>
public static int HighestOne(this ulong v)
{
    if ((long)v <= 0)
        return (int)((v >> 57) & 0x40) - 1;      // handles cases v==0 and MSB==63

    int j = /**/ (int)((0xFFFFFFFFU - v /****/) >> 58) & 0x20;
    j |= /*****/ (int)((0x0000FFFFU - (v >> j)) >> 59) & 0x10;
    return j + msb_tab_15[v >> (j + 1)];
}

uint (32-bit) Version

/// <summary> Index of the highest set bit in 'v', or -1 for value '0' </summary>
public static int HighestOne(uint v)
{
    if ((int)v <= 0)
        return (int)((v >> 26) & 0x20) - 1;     // handles cases v==0 and MSB==31

    int j = (int)((0x0000FFFFU - v) >> 27) & 0x10;
    return j + msb_tab_15[v >> (j + 1)];
}

Various overloads for the above

public static int HighestOne(long v) => HighestOne((ulong)v);
public static int HighestOne(int v) => HighestOne((uint)v);
public static int HighestOne(ushort v) => msb_tab_15[v >> 1];
public static int HighestOne(short v) => msb_tab_15[(ushort)v >> 1];
public static int HighestOne(char ch) => msb_tab_15[ch >> 1];
public static int HighestOne(sbyte v) => msb_tab_15[(byte)v >> 1];
public static int HighestOne(byte v) => msb_tab_15[v >> 1];

This is a complete, working solution which represents the best performance on .NET 4.7.2 for numerous alternatives that I compared with a specialized performance test harness. Some of these are mentioned below. The test parameters were a uniform density of all 65 bit positions, i.e., 0 ... 31/63 plus value 0 (which produces result -1). The bits below the target index position were filled randomly. The tests were x64 only, release mode, with JIT-optimizations enabled.




That's the end of my formal answer here; what follows are some casual notes and links to source code for alternative test candidates associated with the testing I ran to validate the performance and correctness of the above code.


The version provided above above, coded as Tab16A was a consistent winner over many runs. These various candidates, in active working/scratch form, can be found here, here, and here.

 1  candidates.HighestOne_Tab16A               622,496
 2  candidates.HighestOne_Tab16C               628,234
 3  candidates.HighestOne_Tab8A                649,146
 4  candidates.HighestOne_Tab8B                656,847
 5  candidates.HighestOne_Tab16B               657,147
 6  candidates.HighestOne_Tab16D               659,650
 7  _highest_one_bit_UNMANAGED.HighestOne_U    702,900
 8  de_Bruijn.IndexOfMSB                       709,672
 9  _old_2.HighestOne_Old2                     715,810
10  _test_A.HighestOne8                        757,188
11  _old_1.HighestOne_Old1                     757,925
12  _test_A.HighestOne5  (unsafe)              760,387
13  _test_B.HighestOne8  (unsafe)              763,904
14  _test_A.HighestOne3  (unsafe)              766,433
15  _test_A.HighestOne1  (unsafe)              767,321
16  _test_A.HighestOne4  (unsafe)              771,702
17  _test_B.HighestOne2  (unsafe)              772,136
18  _test_B.HighestOne1  (unsafe)              772,527
19  _test_B.HighestOne3  (unsafe)              774,140
20  _test_A.HighestOne7  (unsafe)              774,581
21  _test_B.HighestOne7  (unsafe)              775,463
22  _test_A.HighestOne2  (unsafe)              776,865
23  candidates.HighestOne_NoTab                777,698
24  _test_B.HighestOne6  (unsafe)              779,481
25  _test_A.HighestOne6  (unsafe)              781,553
26  _test_B.HighestOne4  (unsafe)              785,504
27  _test_B.HighestOne5  (unsafe)              789,797
28  _test_A.HighestOne0  (unsafe)              809,566
29  _test_B.HighestOne0  (unsafe)              814,990
30  _highest_one_bit.HighestOne                824,345
30  _bitarray_ext.RtlFindMostSignificantBit    894,069
31  candidates.HighestOne_Naive                898,865

Notable is that the terrible performance of ntdll.dll!RtlFindMostSignificantBit via P/Invoke:

[DllImport("ntdll.dll"), SuppressUnmanagedCodeSecurity, SecuritySafeCritical]
public static extern int RtlFindMostSignificantBit(ulong ul);

It's really too bad, because here's the entire actual function:

    RtlFindMostSignificantBit:
        bsr rdx, rcx  
        mov eax,0FFFFFFFFh  
        movzx ecx, dl  
        cmovne      eax,ecx  
        ret

I can't imagine the poor performance originating with these five lines, so the managed/native transition penalties must be to blame. I was also surprised that the testing really favored the 32KB (and 64KB) short (16-bit) direct-lookup tables over the 128-byte (and 256-byte) byte (8-bit) lookup tables. I thought the following would be more competitive with the 16-bit lookups, but the latter consistently outperformed this:

public static int HighestOne_Tab8A(ulong v)
{
    if ((long)v <= 0)
        return (int)((v >> 57) & 64) - 1;

    int j;
    j =  /**/ (int)((0xFFFFFFFFU - v) >> 58) & 32;
    j += /**/ (int)((0x0000FFFFU - (v >> j)) >> 59) & 16;
    j += /**/ (int)((0x000000FFU - (v >> j)) >> 60) & 8;
    return j + msb_tab_8[v >> j];
}

The last thing I'll point out is that I was quite shocked that my deBruijn method didn't fare better. This is the method that I had previously been using pervasively:

const ulong N_bsf64 = 0x07EDD5E59A4E28C2,
            N_bsr64 = 0x03F79D71B4CB0A89;

readonly public static sbyte[]
bsf64 =
{
    63,  0, 58,  1, 59, 47, 53,  2, 60, 39, 48, 27, 54, 33, 42,  3,
    61, 51, 37, 40, 49, 18, 28, 20, 55, 30, 34, 11, 43, 14, 22,  4,
    62, 57, 46, 52, 38, 26, 32, 41, 50, 36, 17, 19, 29, 10, 13, 21,
    56, 45, 25, 31, 35, 16,  9, 12, 44, 24, 15,  8, 23,  7,  6,  5,
},
bsr64 =
{
     0, 47,  1, 56, 48, 27,  2, 60, 57, 49, 41, 37, 28, 16,  3, 61,
    54, 58, 35, 52, 50, 42, 21, 44, 38, 32, 29, 23, 17, 11,  4, 62,
    46, 55, 26, 59, 40, 36, 15, 53, 34, 51, 20, 43, 31, 22, 10, 45,
    25, 39, 14, 33, 19, 30,  9, 24, 13, 18,  8, 12,  7,  6,  5, 63,
};

public static int IndexOfLSB(ulong v) =>
    v != 0 ? bsf64[((v & (ulong)-(long)v) * N_bsf64) >> 58] : -1;

public static int IndexOfMSB(ulong v)
{
    if ((long)v <= 0)
        return (int)((v >> 57) & 64) - 1;

    v |= v >> 1; v |= v >> 2;  v |= v >> 4;   // does anybody know a better
    v |= v >> 8; v |= v >> 16; v |= v >> 32;  // way than these 12 ops?
    return bsr64[(v * N_bsr64) >> 58];
}

There's much discussion of how superior and great deBruijn methods at this SO question, and I had tended to agree. My speculation is that, while both the deBruijn and direct lookup table methods (that I found to be fastest) both have to do a table lookup, and both have very minimal branching, only the deBruijn has a 64-bit multiply operation. I only tested the IndexOfMSB functions here--not the deBruijn IndexOfLSB--but I expect the latter to fare much better chance since it has so many fewer operations (see above), and I'll likely continue to use it for LSB.

  • L1D cache on modern x86 CPUs is only 32kiB. A large LUT is likely to be worse than a small LUT unless you're using the same values repeatedly. If you aren't, you'll get frequent cache misses. – Peter Cordes Mar 11 at 5:12

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