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I have a byte I'm using for bitflags. I know that one and only one bit in the byte is set at any give time.

Ex: unsigned char b = 0x20; //(00100000) 6th most bit set

I currently use the following loop to determine which bit is set:

int getSetBitLocation(unsigned char b) {
  int i=0;
  while( !((b >> i++) & 0x01) ) { ; }
  return i;

How do I most efficiently determine the position of the set bit? Can I do this without iteration?

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Assuming an 8-bit byte, the use of a lookup table might help, unless you can make use of a 'count leading zeroes' primitive / instruction. – Brett Hale Jan 20 '13 at 21:42
"Can I do this without iteration?" Use a lookup table or a switch statement. – David Heffernan Jan 20 '13 at 21:44
I was hoping for a bit-twiddling hack, not an obvious switch statement – Jan 20 '13 at 21:46
You can get to three comparisons and some math. Will it be actually faster than this loop? Hard to tell. – Jan Dvorak Jan 20 '13 at 21:48
If this is your bottleneck, then you won't beat lookup table. I'm guessing that you've not actually done any profiling and are optimising without the benefit of that. – David Heffernan Jan 20 '13 at 21:57

8 Answers 8

up vote 6 down vote accepted

Can I do this without iteration?

It is indeed possible.

How do I most efficiently determine the position of the set bit?

You can try this algorithm. It splits the char in half to search for the top bit, shifting to the low half each time:

int getTopSetBit(unsigned char b) {
  int res = 0;
    b = b >> 4;
    res = res + 4;
    b = b >> 2;
    res = res + 2;

  //thanks @JasonD
  return res + (b>>1);

It uses two comparisons (three for uint16s, four for uint32s...). and it might be faster than your loop. It is definitely not shorter.

Based on the idea by Anton Kovalenko (hashed lookup) and the comment by 6502 (division is slow), I also suggest this implementation (8-bit => 3-bit hash using a de-Bruijn sequence)

int[] lookup = {7, 0, 5, 1, 6, 4, 3, 2};

int getBitPosition(unsigned char b) {
  // return lookup[(b | (b>>1) | (b>>2) | (b>>4)) & 0x7];
  return lookup[((b * 0x1D) >> 4) & 0x7];

or (larger LUT, but uses just three terms instead of four)

int[] lookup = {0xFF, 0, 1, 4, 2, 0xFF, 5, 0xFF, 7, 3, 0xFF, 0xFF, 6, 0xFF, 0xFF, 0xFF};

int getBitPosition(unsigned char b) {
  return lookup[(b | (b>>3) | (b>>4)) & 0xF];
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You can remove the last if() and just add b-1 – JasonD Jan 20 '13 at 21:57
@JasonD not b-1, but b>>1. b could be 2 or 3. – Jan Dvorak Jan 20 '13 at 21:59
@JanDvorak clever, this might be more efficient – Jan 20 '13 at 22:00
@JanDvorak He said only 1 bit was set, so it should only be 1 or 2. Your alternative is more general though. – JasonD Jan 20 '13 at 22:01
@JanDvorak Your hashed lookup-table lookup[((b * 0x1D) >> 4) & 0x7]; passed my 8 test-cases for bytes { 0x01,0x02,0x04,0x08,0x10,0x20,0x40,0x80 } when checking for the location of the only set bit. Very elegant! Might I ask where you got the hash from? Could you link to the De-Brujin sequences? – Jan 20 '13 at 23:51

Lookup table is simple enough, and you can reduce its size if the set of values is sparse. Let's try with 11 elements instead of 128:

unsigned char expt2mod11_bits[11]={0xFF,0,1,0xFF,2,4,0xFF,7,3,6,5};
unsigned char pos = expt2mod11_bits[b%11];
assert(pos < 8);
assert(1<<pos == b);

Of course, it's not necessarily more effective, especially for 8 bits, but the same trick can be used for larger sizes, where full lookup table would be awfully big. Let's see:

unsigned int w; 
unsigned char expt2mod19_bits[19]={0xFF,0,1,13,2,0xFF,14,6,3,8,0xFF,12,15,5,7,11,4,10,9};
unsigned char pos = expt2mod19_bits[w%19];
assert(pos < 16);
assert(1<<pos == w);
share|improve this answer
Nice idea for larger sizes... but for 8 bit I suppose that the modulo operation is going to be a problem. – 6502 Jan 20 '13 at 22:08
On x86, I would try inline assembly with BSF. – Anton Kovalenko Jan 20 '13 at 22:15
@AntonKovalenko except mod-11 is platform-agnostic while BSF isn't. – Jan Dvorak Jan 20 '13 at 22:19
@JanDvorak: you're a bit too optimistic. Division has always been annoyingly slow... so slow that when designing the first Pentium processor they even tried to cut some corners ;-). If you need the quotient the division can be traded for a multiplication in many cases, but if you need the remainder that trick doesn't work. And not even integer multiplication IIRC is 2 cycles on any processor I used. – 6502 Jan 20 '13 at 22:22
@JanDvorak It doesn't fit in the comment area, but it starts with a multiplication by 780903145. Note that that number is exactly 0x200000003 / 11. – hvd Jan 20 '13 at 22:33

This is a quite common problem for chess programs that use 64 bits to represent positions (i.e. one 64-bit number to store where are all the white pawns, another for where are all the black ones and so on).

With this representation there is sometimes the need to find the index 0...63 of the first or last set bit and there are several possible approaches:

  1. Just doing a loop like you did
  2. Using a dichotomic search (i.e. if x & 0x00000000ffffffffULL is zero there's no need to check low 32 bits)
  3. Using special instruction if available on the processor (e.g. bsf and bsr on x86)
  4. Using lookup tables (of course not for the whole 64-bit value, but for 8 or 16 bits)

What is faster however really depends on your hardware and on real use cases. For 8 bits only and a modern processor I think that probably a lookup table with 256 entries is the best choice...

But are you really sure this is the bottleneck of your algorithm?

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...FULL means "unsigned long long"? – Jan Dvorak Jan 20 '13 at 22:06
ULL is the suffix, the F is just last hexadecimal digit, I'll edit to make it more clear – 6502 Jan 20 '13 at 22:11
I meant, is it actually compilable, or just a placeholder/elliplis :-) – Jan Dvorak Jan 20 '13 at 22:13
unsigned getSetBitLocation(unsigned char b) {
  unsigned pos=0;
  pos = (b & 0xf0) ? 4 : 0; b |= b >>4;
  pos += (b & 0xc) ? 2 : 0; b |= b >>2;
  pos += (b & 0x2) ? 1 : 0; 
  return pos; 

It would be hard to do it jumpfree. Maybe with the Bruin sequences ?

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Easiest thing is to create a lookup table. The simplest one will be sparse (having 256 elements) but it would technically avoid iteration.

This comment here technically avoids iteration, but who are we kidding, it is still doing the same number of checks: How to write log base(2) in c/c++

Closed form would be log2(), a la, log2() + 1 But I'm not sure how efficient that is - possibly the CPU has an instruction for taking base 2 logrithms?

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FYL2X instruction v/s bit-shifts? Not sure there. – Anirudh Ramanathan Jan 20 '13 at 21:57
The memory requirements of a sparse look-up table with 255 elements do not outweigh the minor performance optimization. – Jan 20 '13 at 22:01
How many elements will a sparse lookup table have when CHAR_BIT == 16, or when CHAR_BIT == 32? – Seb Jan 20 '13 at 22:03
“possibly the CPU has an instruction for taking base 2 logrithms?” There is an instruction to count leading zeroes in most processors. – Pascal Cuoq Jan 21 '13 at 2:45

Based on log2 calculation in Find the log base 2 of an N-bit integer in O(lg(N)) operations:

int getSetBitLocation(unsigned char c) {
  // c is in {1, 2, 4, 8, 16, 32, 64, 128}, returned values are {0, 1, ..., 7}
  return (((c & 0xAA) != 0) |
          (((c & 0xCC) != 0) << 1) |
          (((c & 0xF0) != 0) << 2));
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This relies on the fact that != returns 0 or 1. Is that guaranteed by the spec? I also guess it doesn't really avoid branching due to how != is implemented. – Jan Dvorak Jan 20 '13 at 22:49
@JanDvorak: yes, it was added in c99. (I used the ternary to be downward compatible with c89/c90) And it indeeds looks not jumpfree. (but there are some strange instructions nowadays) – wildplasser Jan 20 '13 at 22:54
@JanDvorak: yes, it is guaranteed even before c99. Also I don't see any branching in the code. You could see its assembly online. Could you point out the branching instructions? – J.F. Sebastian Jan 22 '13 at 2:52
@J.F.Sebastian Without optimisation, wrapped in int main(char c), the three !=s turn to set if not equal on line 0x14 (impressive), 0x25: je 0x2E / 0x2C: jmp 0x33 (ouch, a branching instruction), and the same combo appears at 0x40. With optimisations turned on, the jes turn to subtract with borrows (impressive) ARM uses a move if not equal / move if equals combo (nice instructions). Thanks for the link to the compiler. – Jan Dvorak Jan 22 '13 at 8:15
Note that by deBrujin-based solution turns to mere five operations: MOVZB, IMUL, SAR, AND, MOV – Jan Dvorak Jan 22 '13 at 8:35

if you define

const char bytes[]={1,2,4,8,16,32,64,128}

and use

struct byte{
char data;
int pos;
void assign(struct byte b,int i){[i];

you don't need to determine the position of the set bit

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you don't need to determine the position of the set bit -- I'd like to dispute – Jan Dvorak Jan 20 '13 at 21:56
He's fighting the OPPOSITE problem... given the value finding the index. Scanning your table is more or less like just checking the bits. – 6502 Jan 20 '13 at 22:04

Using divide and conquer, like doing a binary search on a sorted array, except on a byte, involves comparisons based on log2 CHAR_BIT. That code is more complex, however, and I'm not interested in spoonfeeding people. A lookup table is fast and easy when CHAR_BIT == 8, but on some systems, CHAR_BIT == 16 or 32 and a lookup table becomes insanely bulky. If you're considering a lookup table, I'd suggest wrapping it; Make it a "lookup table function", instead, so that you can implement some logic when these cases occur.

ps. This sounds like micro-optimisation. Get your solution done, then worry about optimisations based on your profiling. Make sure your profiling targets the system that your solution will run on if you're going to focus on micro-optimisations, because the efficiency of micro-optimisations differ widely as hardware differs even slightly... It's usually a better idea to buy a faster PC ;)

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