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Update: Please read the code, it is NOT about counting bits in one int

Is it possible to improve performance of the following code with some clever assembler?

uint bit_counter[64];

void Count(uint64 bits) {
  bit_counter[0] += (bits >> 0) & 1;
  bit_counter[1] += (bits >> 1) & 1;
  // ..
  bit_counter[63] += (bits >> 63) & 1;

Count function is in the most inner loop of my algorithm.

Update: Architecture: x86, Sandy Bridge, so SSE5, AVX and older tech can be used. "bits" variable has almost random bits (close to half zeros and half ones)

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Ahem, assembly for which architecture? –  NPE Oct 17 '11 at 12:52
You can, at the very least, make that Count function prettier: for(int i=0; i < 64; ++i) bit_counter[i] += (bits >> i) & 1;. –  Xeo Oct 17 '11 at 13:29
How wide do the bit counters have to be? Must they be uints or is narrower allowed? –  harold Oct 17 '11 at 13:39
@Lukasz: Are you sure? I'd leave the loop unrolling to the compiler. Since the bounds of the for loop are compile time constants, I'm pretty sure that can and will be optimized by a good compiler. –  Xeo Oct 17 '11 at 14:51
@Xeo: Time it. Prettier (in this case) is significantly slower. Łukasz Lew's manual loop unrolling is faster -- at least with gcc 4.2 and LLVM –  the wolf Oct 18 '11 at 0:32

9 Answers 9

up vote 6 down vote accepted

Maybe you can do 8 at once, by taking 8 bits spaced 8 apart and keeping 8 uint64's for the counts. That's only 1 byte per single counter though, so you can only accumulate 255 invocations of count before you'd have to unpack those uint64's.

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This is VERY interesting. Best answer so far. –  Łukasz Lew Oct 17 '11 at 14:00
In theory, you can do the unpacking with quite similar logic. Unpack the uint64[8] to an uint64[16] every 256*255 iterations. However, you'll quickly notice that this second stage is far less common and therefore adds <1% of an improvement. I.e. the first step is already so efficient that you're hard-pressed to improve it further. This algortihm also lends itself quite well to SSE optimization. –  MSalters Oct 17 '11 at 14:11

You could try doing it with SSE, incrementing 4 elements per iteration.

Warning: untested code follows...

#include <stdint.h>
#include <emmintrin.h>

uint32_t bit_counter[64] __attribute__ ((aligned(16)));
                     // make sure bit_counter array is 16 byte aligned for SSE

void Count_SSE(uint64 bits)
    const __m128i inc_table[16] = {
        _mm_set_epi32(0, 0, 0, 0),
        _mm_set_epi32(0, 0, 0, 1),
        _mm_set_epi32(0, 0, 1, 0),
        _mm_set_epi32(0, 0, 1, 1),
        _mm_set_epi32(0, 1, 0, 0),
        _mm_set_epi32(0, 1, 0, 1),
        _mm_set_epi32(0, 1, 1, 0),
        _mm_set_epi32(0, 1, 1, 1),
        _mm_set_epi32(1, 0, 0, 0),
        _mm_set_epi32(1, 0, 0, 1),
        _mm_set_epi32(1, 0, 1, 0),
        _mm_set_epi32(1, 0, 1, 1),
        _mm_set_epi32(1, 1, 0, 0),
        _mm_set_epi32(1, 1, 0, 1),
        _mm_set_epi32(1, 1, 1, 0),
        _mm_set_epi32(1, 1, 1, 1)

    for (int i = 0; i < 64; i += 4)
        __m128i vbit_counter = _mm_load_si128(&bit_counter[i]);
                                          // load 4 ints from bit_counter
        int index = (bits >> i) & 15;     // get next 4 bits
        __m128i vinc = inc_table[index];  // look up 4 increments from LUT
        vbit_counter = _mm_add_epi32(vbit_counter, vinc);
                                          // increment 4 elements of bit_counter
        _mm_store_si128(&bit_counter[i], vbit_counter);
    }                                     // store 4 updated ints

How it works: essentially all we are doing here is vectorizing the original loop so that we process 4 bits per loop iteration instead of 1. So we now have 16 loop iterations instead of 64. For each iteration we load 4 bits from bits, then use them as an index into a LUT which contains all possible combinations of 4 increments for the current 4 bits. We then add these 4 increments to the current 4 elements of bit_counter.

The number of loads and stores and adds is reduced by a factor of 4, but this will be offset somewhat by the LUT load and other housekeeping. You may still see a 2x speed up though. I'd be interested to know the result if you do decide to try it.

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wow. I really can't see what this does. But it sure looks promising. –  sehe Oct 17 '11 at 13:57
Can you explain how the code works? –  Łukasz Lew Oct 17 '11 at 14:03
Sure - I've just added some comments to the code which you may not have seen yet - I'll put some additional explanation shortly. –  Paul R Oct 17 '11 at 14:05
Not sure about that LUT - PSHUFB suggests that you can use an XMM register for a parallel LUT instead, which should be a lot faster than sequential memory lookups. (The linked article uses PSHUFB for a regular popcount, but that's obviously not the only possible use of a LUT). –  MSalters Oct 17 '11 at 14:36
@MSalters: I don't think you can do a PSHUB lookup table in this case, since the lookup table would need to be different for each element. –  Paul R Oct 17 '11 at 15:04

Look at Bit Twiddling Hacks

Edit As for the 'bit position bucket accumulation' (bit_counter[]) I have a feeling that this might be a good case for valarrays + masking. That'd be a fair bit of coding+testing+profiling though. Let me know if you are really interested.

You could, these days, come very close to valarray behaviour using tied tuples (TR1, boost or C++11); I have a feeling it would come out being simpler to read and slower to compile.

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+1, I was just about to suggest the same webpage. Using the lookup table you can do it in O(1). –  Gaston Oct 17 '11 at 13:34
@PaulR: I don't agree. It frames the subject. I share my thoughts on how to apply it to this question (you can use a lookup per byte to store valarray masks. Or mimic the same using tuples. A vectorizing compiler (Intel, gcc) will likely optimize the result into proper SIMD instructions. Sadly, I don't have time to work this out right away :) –  sehe Oct 17 '11 at 13:53
This does not answer my question in any way. Also I don't see valarrays helping here. –  Łukasz Lew Oct 17 '11 at 13:54
Although the bit twiddling hacks are indeed very useful I don't think they really help with this particular question. –  Paul R Oct 17 '11 at 13:54
@Gastón: The O(1) is idealized and ignores the effects of lookup table size (cache locality: if the table becomes too big, things will stop scaling - the algorithmic complexity may be O(1) but that doesn't mean the CPU is able to execute it efficiently, because the CPU is not a perfect model) –  sehe Oct 17 '11 at 14:35

This is fairly fast:

void count(uint_fast64_t bits){
    uint_fast64_t i64=ffs64(bits);
        bits=bits & 0xFFFFFFFFFFFFFFFF << i64;

You need to have a fast implementation of ffs for 64 bits. For most compiler and CPU's this is a single instruction. The loop is executed once for each bit in the word, so bits=0 will be very fast and bits being 64 bits of 1 will be slower.

I tested this under 64 bit Ubuntu with GCC, and it produces the same data output as your:

void Count(uint64 bits) {
  bit_counter[0] += (bits >> 0) & 1;
  bit_counter[1] += (bits >> 1) & 1;
  // ..
  bit_counter[63] += (bits >> 63) & 1;

The speed is variable based on the number of 1 bits in the 64 bit word.

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+1 for effort, best alternative here, but this won't be as fast as his original... –  Colt 45 Oct 18 '11 at 2:49

You can unroll your function like this. It is probably faster than what your compiler can do!

//   rax as 64 bit input
   xor  rcx, rcx                //clear addent

   add  rax, rax                //Copy 63th bit to carry flag
   adc  dword ptr [@bit_counter + 63 * 4], ecx    //Add carry bit to counter[64]

   add  rax, rax                //Copy 62th bit to carry flag
   adc  dword ptr [@bit_counter + 62 * 4], ecx    //Add carry bit to counter[63]

   add  rax, rax                //Copy 62th bit to carry flag
   adc  dword ptr [@bit_counter + 61 * 4], ecx    //Add carry bit to counter[62]
//   ...
   add  rax, rax                //Copy 1th bit to carry flag
   adc  dword ptr [@bit_counter + 1 * 4], ecx     //Add carry bit to counter[1]

   add  rax, rax                //Copy 0th bit to carry flag
   adc  dword ptr [@bit_counter], ecx             //Add carry bit to counter[0]


You can try also with double increment like this:

//   rax as 64 bit input
   xor  rcx, rcx                //clear addent
   add  rax, rax                //Copy 63th bit to carry flag
   rcl  rcx, 33                 //Mov carry to 32th bit as 0bit of second uint
   add  rax, rax                //Copy 62th bit to carry flag
   adc  qword ptr [@bit_counter + 62 * 8], rcx  //Add rcx to 63th and 62th counters

   add  rax, rax                //Copy 61th bit to carry flag
   rcl  rcx, 33                 //Mov carry to 32th bit as 0bit of second uint
   add  rax, rax                //Copy 60th bit to carry flag
   adc  qword ptr [@bit_counter + 60 * 8], rcx  //Add rcx to 61th and 60th counters
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This probably will not be much faster, and not worth the maintenance effort... –  Colt 45 Oct 18 '11 at 2:50
@Colt 45: probably? Probably is second solution the fastest! Only harolds solution can be faster. –  GJ. Oct 18 '11 at 8:52
Can you back that up with timings? The OP's code probably is compiled into something nearly like this is my point. It may be faster, but not by orders of magnitude. –  Colt 45 Oct 18 '11 at 16:42
@Colt 45: my second rutine should be faster for about 50%! –  GJ. Oct 18 '11 at 17:24

I found what seems to be exactly the problem you describe.


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There's no way to answer this in general; it all depends on the compiler and the underlying architecture. The only real way to know is to try different solutions, and measure. (On some machines, for example, shifts can be very expensive. On others, no.) For starters, I'd use something like:

uint64_t mask = 1;
int index = 0;
while ( mask != 0 ) {
    if ( (bits & mask) != 0 ) {
        ++ bit_counter[index];
    ++ index;
    mask <<= 1;

Unrolling the loop completely will likely improve performance. Depending on the architecture, replacing the if with:

bit_counter[index] += ((bits & mask) != 0);

might be better. Or worse... it's impossible to know in advance. It's also possible that on some machines, systematically shifting into the low order bit and masking, as you are doing, would be best.

Some optimizations will also depend on what typical data looks like. If most of the words only have one or two bits set, you might gain by testing a byte at at time, or four bits at a time, and skipping those that are all zeros completely.

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Branching in your example is much more costly than the original code. –  Łukasz Lew Oct 17 '11 at 13:26
@ŁukaszLew Maybe. That's why I presented several different solutions, with the recommendation to measure them. Different processors take different times for different operations. (I've used processors where shifting multiple bits was very slow, for example.) –  James Kanze Oct 17 '11 at 15:39

If you count how often each nibble (16 possibilities) occurs at each offset (16 possibilities), you can easily sum the results. And those 256 sums are easily kept:

unsigned long nibble_count[16][16]; // E.g. 0x000700B0 corresponds to [4][7] and [2][B]
unsigned long bitcount[64];

void CountNibbles(uint64 bits) {
  // Count nibbles
  for (int i = 0; i != 16; ++i) {
     bits >>= 4;
void SumNibbles() {
  for (int i = 0; i != 16; ++i) {
    for (int nibble = 0; nibble != 16; ++nibble) {
        for(int bitpos = 0; bitpos != 3; ++bitpos) {
           if (nibble & (1<<bitpos)) {
              bitcount[i*4 + bitpos] += nibble_count[i][nibble];
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why not go all the way and store count per byte? e.g byte_count[8][256]? Then your loop unrolls quite nicely. Should have the same impact on the cache... –  Nim Oct 17 '11 at 16:24
@Nim: Not entirely; byte_count has 8 times more elements. Since it's accessed at random, that's quite unfortunate for the L1 cache. But profiling should quickly show what's most efficient. And, of course, you can also profile quintet_count[13][32] etc ;) –  MSalters Oct 18 '11 at 6:57

You could use the set of counters, each of different size. Firstly accumulate 3 values in 2-bit counters, then unpack them and update 4-bit counters. When 15 values are ready, unpack to byte-sized counters, and after 255 values update bit_counter[].

All this work may be done in parallel in 128 bit SSE registers. On modern processors only one instruction is needed to unpack 1 bit to 2. Just multiply source quadword to itself with PCLMULQDQ instruction. This will interleave source bits with zeros. The same trick may help to unpack 2 bits to 4. And unpacking of 4 and 8 bits may be done with shuffles, unpacks and simple logical operations.

Average performance seems to be good, but the price is 120 bytes for additional counters and quite a lot of assembly code.

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