NASM: Count how many bits in a 32 Bit number are set to 1

Question

I have a 32 Bit number and want to count know how many bits are 1.

I'm thinking of this pseudocode:

mov eax, [number]
while(eax != 0)
{
  div eax, 2
  if(edx == 1)
  {
   ecx++;
  } 
  shr eax, 1
}

Is there a more efficient way?

I'm using NASM on a x86 processor.

(I'm just beginning with assembler, so please do not tell me to use code from extern libraries, because I do not even know how to include them ;) )

(I just found How to count the number of set bits in a 32-bit integer? which also contains my solution. There are other solutions posted, but unfortunatly I can't seem to figure out, how I would write them in assembler)

Answer 1

The most efficient way (in terms of execution time, anyway) is to have a lookup table. Obviously you're not going to have a 4-billion entry table, but you could break the 32 bits down into 8-bit chunks and only need a 256-entry table, or further down into 4-bit chunks and only need 16 entries. Good luck!

Answer 2

In processors that have SSE4 support, you have the POPCNT instruction that does this for you.

The most naive algorithm is actually faster than what you thought up (DIV instructions are really slow).

mov eax, [number]
xor ecx,ecx
loop_start:
  test eax,1
  jnz next
  inc ecx
next:
  shr eax, 1
  mov eax,ecx

Regarding your comment about previous SO answers, I'm going to take an example answer from there and walk you through how I'll convert it.

long count_bits(long n) {     
  unsigned int c; // c accumulates the total bits set in v
  for (c = 0; n; c++) 
    n &= n - 1; // clear the least significant bit set
  return c;
}

(I'm going to assume you know how to define a function and fun stuff like that). What is needed is a very simple loop, a counter variable (traditionally, ecx is both the index and a counter), and bit testing instructions.

    mov edx,n
    xor ecx,ecx
loop_start:
    test edx,edx
    jz end
    mov ebx,edx
    dec ebx
    and edx,ebx
    inc ecx
    jmp loop_start
end:
    mov eax,ecx
    ret

Implementing something like the Hamming Weight algorithm in assembly isn't complicated, but is just complicated enough that you'd rather not do it as an initial homework problem.

Answer 3

My x86 assembler is a bit rusty, but this comes to mind:

clc            ; clear carry
xor ecx, ecx   ; clear ecx

shl eax, 1     ; shift off one bit into carry
adc ecx, 0     ; add carry flag to ecx
; ... repeat the last two opcodes 31 more times

ecx contains your bit count.

x86 shift instructions set CF to the last bit shifted out, where adc ecx, 0 reads it.

Answer 4

For the record, if you want good performance, you usually want to avoid looping / branching, with either an 8-bit table lookup or a multiply bithack (GCC's current scalar fallback for __builtin_popcnt without -mpopcnt). Looping can be barely ok if your numbers are usually small (right shift by 1), or if your numbers usually only have a few bits set (looping on clearing the lowest set bit with x & (x-1)). But those perform rather poorly for numbers with half or more of their bits set.

---

Most modern x86 CPUs support the popcnt instruction. It's implied by SSE4.2, but also has its own CPUID feature bit so a CPU could have it without SSE4.2. Intel Core 2 and older do not have this.

xor     eax,eax     ; avoid false dependency on Sandybridge-family before IceLake
popcnt  eax,  edi

If you don't mind overwriting the same register, popcnt edi, edi for example avoids the danger of an output false dependency: you already have a true dependency on the same register. (Why does breaking the "output dependency" of LZCNT matter?)

---

Without HW popcnt, another option is SSSE3 pshufb, which is actually great for counting large arrays, especially if you have AVX2. See

• https://github.com/WojciechMula/sse-popcount
• Counting 1 bits (population count) on large data using AVX-512 or AVX-2
• and other links in an answer on the canonical SO Q&A about popcount.

---

Fallbacks with baseline x86 instructions

An array lookup is possible, extracting each byte with movzx ecx, al / movzx edx, ah / shr eax, 16 etc. Then movzx ecx, [table + rcx] / add cl, [table + rdx]. Note that the total result will be at most 64, so won't overflow an 8-bit register. That would need a 256-byte table to stay hot in cache for good performance. It may be a good choice if you do a lot of popcnt but can't use SIMD; benchmark it against the bithack for your use-case.

A bithack from https://graphics.stanford.edu/~seander/bithacks.html#CountBitsSetParallel / How to count the number of set bits in a 32-bit integer? is what GCC currently uses if HW popcnt isn't enabled at compile time. (i.e. in the libgcc helper function). See that answer for an explanation of how/why the bithack sums bits to 2-bit accumulators, then horizontally again to 4-bit, etc. (Fun fact: GCC and clang actually recognize that C logic as a popcnt idiom and compile it to a popcnt instruction with -mpopcnt. The following asm is GCC -O3 output without -mpopcnt; I don't see any way to improve it by hand. It's using EAX as the destination as much as possible for AND to allow the and eax, imm32 short-form without a modrm byte.)

This non-branching code and doesn't need any data lookups, so it can't cache miss (except for I-cache), and is probably good if you care about popcount performance (especially latency) but don't do it often enough to keep a lookup table hot in cache. (Or for 64-bit integers, a 64-bit version of this is probably even better than 8x byte lookups.)

; x86-64 System V calling convention
; but also of course works for 32-bit mode with the arg in a register
numberOfSetBits:     ; 32-bit unsigned int x    in EDI
    mov    eax, edi
    shr    eax, 1
    and    eax, 0x55555555          ; (x>>1) & 0x55555555
    sub    edi, eax                 ; x -= ((x>>1) & 0x55555555)   2-bit sums

    mov    eax, edi
    shr    edi, 0x2
    and    eax, 0x33333333
    and    edi, 0x33333333
    add    edi, eax                 ; pairs of 2-bit accumulators -> 4

    mov    eax, edi
    shr    eax, 0x4
    add    eax, edi                 ; we can add before masking this time without overflow risk
    and    eax, 0x0f0f0f0f

    imul   eax, eax, 0x01010101       ; sum the 4 bytes into the high byte (because their values are small enough)
    shr    eax, 24
    ret    

For 64-bit integers, it's the same sequence, ending with a 64-bit multiply. (But you need mov reg, imm64 to materialize 64-bit mask and multiplier constants; they won't work as immediates to AND or IMUL).

Instructions like RORX could be useful to more efficiently copy-and-shift instead of mov/shr, but any CPU with RORX would also have POPCNT so you should just use that! LEA to copy-and-left-shift doesn't help: addition propagates carry from low to high, so to avoid losing bits at the top in the first step, you need to be right-shifting. The >>2 step couldn't add into the higher of each pair of 2-bit accumulators either: the max sum at that point is 4, and that requires 3 bits to represent, so the highest accumulator (at the top of the register) would possibly lose a count if you did lea eax, [rdi + rdi] / 2x and / add, because instead of 4 bits misaligned, it only has 2. And you'd eventually need a right shift to put counters back at the bottom of their bytes at some point before imul, so you'd lengthen the critical path latency even if it was possible to use left-shift/add in earlier steps.

Looping: smaller code-size, much slower worst-case

There are three main choices:

• Lookup table of 8-bit chunks, used 4 times
• shift by 1 (left with add same,same or right with shr) and add the bit shifted out. Less bad if the set bits are usually clustered towards the high or low end so the register becomes zero after much fewer than 32 iterations, but that's still the worst case.
• clear the lowest set bit with x &= x-1 and count how many iterations to become zero. Less bad if there are few set bits total. (Or if you NOT the input first, if there are few cleared bits. Or maybe there's a bithack for setting the lowest zeroed bit, like x |= x+1 maybe?). Worst case is still 32 iterations, with a longer dep chain than just shifting.

For small code-size (but not speed), the loop shown in Hamming weight ( number of 1 in a number) mixing C with assembly is quite good. A NASM version of that looks like:

;;;   Good for small inputs (all set bits near the bottom)
;; input: EDI  (zeroed when we're done)
;; output: EAX = popcnt(EDI)
popcount_shr_loop:
    xor   eax, eax
  ; optional: make the first adc non-redundant by peeling the first iteration.  Otherwise just fall into the loop (with CF=0 from xor)
    shr   edi, 1         ; shift low bit into CF
                 ;; jz .done   ; not worth running an extra instruction for every case to skip the loop body only for the input == 0 or 1 case
 .loop:
    adc   eax, 0         ; add CF (0 or 1) to result
    shr   edi, 1
    jnz   .loop          ; leave the loop after shifting out the last bit
 ;.done:
    adc   eax, 0         ; and add that last bit
    ret

If the set bits in your input are likely to be near the top, use add edi, edi instead of shr, since it sets FLAGS we care about the same as shl would. add can macro-fuse with jcc on Sandybridge-family, so that's actually slightly better than shr; more hyperthreading-friendly, and fewer uops in the ROB so OoO exec can see farther past it, if the loop-exit branch predicts correctly. Or into the loop sooner if an earlier cache miss or something is still stalling retirement.

For even smaller code-size, you could skip the shr before falling into the loop, so the first adc is redundant. (xor-zeroing clears CF).

@spoulson's answer suggests unrolling the loop 32 times (without jz .done). The bithack shift/and/add ending with multiply is better when you want one big straight-line block of code for maximum speed with arbitrary bit-patterns. adc reg,0 is 1 uop on most CPUs, except Intel P6-family (PPro to Nehalem) (0 was a special case on Intel SnB-family before Broadwell). Anyway, 64 uops and 32-cycle latency is still bad vs. the 15-uop bithack, so a full unroll of this would be worse than other strategies.

However, unrolling this by 2 or 4 could make sense as a middle-ground. That would make different inputs branch the same way, e.g. every input with its set bits in the low 4 would run through the loop once, with the branch not-taken.

popcount_shr_loop_unroll2:
    xor   eax, eax
    shr   edi, 1         ; shift low bit into CF
          ;; jz .done     ; still optional, but saves more work in the input <= 1 case.  Still not worth it unless you expect that to be very common.
 .loop:
%rep 2            ;; Unroll
    adc   eax, 0         ; add CF (0 or 1) to result
    shr   edi, 1
%endrep           ;; still ending with ZF and CF set from a shift
    jnz   .loop          ; leave the loop on EDI == 0
 ;.done:
    adc   eax, 0         ; there may still be a bit we haven't added yet
    ret

You could try to let out-of-order exec see the loop-exit condition sooner by doing shr edi, 4 / jnz as the loop branch, and have the loop body copy EDI to another register and shift out the low 4 bits 1 at a time. But at that point you probably just want the bithack version; x86 CPUs with OoO exec also have fast imul r32, like 4 cycle latency on Pentium II/III, 3-cycle on AMD K8 and later, and Intel since Core 2. And their code fetch / decode capability should handle the larger instructions involving 32-bit mask constants well enough.

(Since we're considering old CPUs: On P5 Pentium, shr and adc can both only run in the U-pipe, so unrolling doesn't let them pair with each other to exploit the ILP. It would if you used add to shift the high bit into CR, though, since add can run in either the U or V pipe.)

Another unroll option is to split into two halves, high half going out the top, low half out the bottom. (Accumulate into separate counters, too, if you care about latency, otherwise it could still help OoO exec find the loop exit sooner. But then testing for both halves being zero gets clunky; maybe mov ecx, ebx/add ecx, edx/jnz. ADD can macro-fuse with jnz on SnB-family, unlike OR. Or use LEA / TEST+JNZ, 2 front-end uops on AMD Zen as well as Intel.)

---

Another option is looping on lea edx, [rdi-1] / and edi, edx (clear the lowest set bit, set ZF if it became zero). This can be ok for numbers with only a couple set bits.

  ;; could be good if very few bits are set, even if they're scattered around
;; Input: EDI  (zeroed when done)
;; output: EAX = popcount(EDI)
;; clobbers: EDX
popcount_loop_lsr:
    xor  eax,eax
    test edi,edi
    jz   .done            ; if(!x) return 0;
 .loop:                   ; do{
    inc  eax                 ; ++count
    lea  edx, [rdi-1]
    and  edi, edx            ; x &= x-1  clear lowest set bit
    jnz  .loop            ; }while(x)

 .done:
    ret

For more bithacks like x & (x-1), see https://catonmat.net/low-level-bit-hacks. Also note that the BMI1 instruction blsr does this, so that's a handy place to check as a reminder of the formula when you already have an x86 instruction reference open. But of course if you had BMI1, you'd have popcnt. popcnt actually has its own feature-bit, but there aren't any real-world CPUs that have BMI1 but not popcnt/SSE4.2.

Note that this has a 2-cycle loop-carried dependency through LEA and AND, unlike the 1-cycle dependency through SHR and ADC (assuming single-uop ADC) in the other loop. So each iteration has twice as long a data dependency. But on the plus side, we're only looping over the set bits, skipping past zeros. Still, the worst case (EDI=-1) has twice the latency.

and/jnz can actually macro-fuse on Intel SnB-family into a single and-and-branch uop. (Because it's like test). So it's still only 3 front-end uops per iteration, but the branch mispredict is unlikely to be detected soon, so in terms of overall front-end cost this version can be bad.

Since inc eax is just counting loop iterations, no data dependency on the x update logic, unrolling would still require a branch, I think, unless you did some extra logic after the loop to check if a middle temporary had already been zero. Since the x &= x-1; dep chain is the critical path, unrolling is probably not helpful.

(If you want to find the position of every set bit and store into an array, you can unroll with overshoot if you have a separate efficient way to popcount, as in @aqrit's answer on another Q&A)

Answer 5

      mov eax,[c]
      xor ebx,ebx
SSS:  shr eax,1    ; after shift, if eax=0 ZF flag=1
      jz  XXX      ; end (no more bit on eax)
      adc bl
      jmp SSS
XXX:  adc bl
      movb [Nbit],bl

Answer 6

This program gives you the number of 1's in a 32 bit number. Try out :)

extern printf                     
SECTION .data                   
msg:    db "The number of 1 bits are: %d",10,0
inta1:  dd  1234567  
num: dd  2147483647   
SECTION .text                     

global  main                  
main:     
    mov eax, [num]  
    mov ecx,32  
    mov edx,0  
.loop:  dec ecx  
    cmp ecx,0  
    jl .exit  
    shr eax,1  
    jnc .loop  
    inc edx  
jmp .loop 
.exit:
    push edx
    push    dword msg         
    call    printf            
    add     esp, 8  

Answer 7

Using bsf (Bit Scan Forward) is probably a bit more efficient than plain shifting.

xor         edx,edx  
mov         eax,num  
bsf         ecx,eax
je          end_bit_count
; align?
loop_bit_count:
inc         ecx  
inc         edx  
shr         eax,cl  
bsf         ecx,eax  
jne         loop_bit_count
end_bit_count:

Answer 8

    mov eax,dword [number]; we store the number in eax
    mov ecx,1
    mov edx,0
    loop_1:
    cmp eax,0            ;we compare the number with 0 
    je endl_loop         ;when the number is zero we exit the loop
    test eax,01h         ;is the last bit equal to 1?
    jpe the_bit_is_zero  ;jump if parity is even=the bit is zero
    inc edx              ;we found another 1 digit
    the_bit_is_zero:
    inc ecx              ;we continue the loop
    shr eax,1            ;shift the bits to right =nr/2
    loop loop_1
    endl_loop:
    ;the result is stored in edx

Answer 9

The best way:

tabx:array [0..255] of byte = //number of bit for each byte (COPY THIS TABLE)
    (0,1,1,2,1,2,2,3,1,2,2,3,2,3,3,4,
     1,2,2,3,2,3,3,4,2,3,3,4,3,4,4,5,
     1,2,2,3,2,3,3,4,2,3,3,4,3,4,4,5,
     2,3,3,4,3,4,4,5,3,4,4,5,4,5,5,6,
     1,2,2,3,2,3,3,4,2,3,3,4,3,4,4,5,
     2,3,3,4,3,4,4,5,3,4,4,5,4,5,5,6,
     2,3,3,4,3,4,4,5,3,4,4,5,4,5,5,6,
     3,4,4,5,4,5,5,6,4,5,5,6,5,6,6,7,
     1,2,2,3,2,3,3,4,2,3,3,4,3,4,4,5,
     2,3,3,4,3,4,4,5,3,4,4,5,4,5,5,6,
     2,3,3,4,3,4,4,5,3,4,4,5,4,5,5,6,
     3,4,4,5,4,5,5,6,4,5,5,6,5,6,6,7,
     2,3,3,4,3,4,4,5,3,4,4,5,4,5,5,6,
     3,4,4,5,4,5,5,6,4,5,5,6,5,6,6,7,
     3,4,4,5,4,5,5,6,4,5,5,6,5,6,6,7,
     4,5,5,6,5,6,6,7,5,6,6,7,6,7,7,8);

In MASM:
asm

mov   eax,number //32 bit 
movzx ecx,tabx[al] //for clear ecx except cl
addb  cl,tabx[ah]  //add ah to cl  
shr   eax,16  //put left part in ah-al
addb  cl,tabx[al]
addb  cl,tabx[ah]
mov   result,ecx