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So I had an interview question before regarding bit manipulation. The company is a well known GPU company. I had very little background in assembly language (weird despite being a phd student in computer architecture) and as this narrative would indicate, I botched it. The question was a simple:

"Write a fast code that will count the number of 1's in a 32-bit register."

Now I am in the process of studying arm assembly. So naturally I revisited this problem again and have come up with this code just by studying the ISA.

For you arm experts out there, is this correct? Is there a faster way to do this? Being a beginner, I naturally think this is incomplete. The AND instruction in "xx" feels redundant but there is no other way to shift a register in ARM isa...

R1 will contain the number of bits at the end while R2 is the register with bits we want to count. r6 is just a dummy register. Comments are enclosed in ()

    MOV   R1, #0                (initialize R1 and R6 to zero)
    MOV   R6, #0        
xx: AND   R6, R6, R2, LSR #1    (Right shift by 1, right most bit is in carry flag)
    ADDCS R1, #1                (Add #1 to R1 if carry  flag is set)
    CMP R2, #0                  (update the status flags if R2 == 0 or not)
    BEQ xx                      (branch back to xx until R2==0)
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What is fastest also depends on the number of bits you expect to be set. With very few 1's, Kernighan's bit counter will win as it runs one round of the loop for each bit set. –  Bo Persson Apr 1 '13 at 11:38
    
Your algorithm takes 4*32+2 instructions for all 1. Dave Seal's algorithm takes six instructions plus a memory access; it will probably be as fast for all types of input unless memory is extremely slow. I doubt few people would get Dave Seal's solution. The reverse subtract is just weird to me. –  artless noise Apr 1 '13 at 13:39

4 Answers 4

up vote 5 down vote accepted

You could use a precomputed look up table and reduce the number of iterations to 2 or 4.

You could also use the logarithmic approach.

For more info see this Wikipedia article.

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1  
Looks like Hamming-weight is a pretty well-known problem. Thanks! –  dean Apr 1 '13 at 2:14
    
@dean It is. :) –  Alexey Frunze Apr 1 '13 at 2:26
1  
+1 for the hamming weight article. Note that, specifically for ARM, it mentions that Neon SIMD instructions provide vcnt, infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.dui0489c/… to perform exactly this operation. There are also, for SIMD-type instruction sets. methods to speed it up using shuffling instructions as table lookups (every SSE2 register can be used as a 16-byte lookup table via pshufb, or in case of ARM Neon, vtbl). See stackoverflow.com/questions/3693981/… –  FrankH. Apr 1 '13 at 8:07

If this code is fast or not depends on the processor. For sure it will be not very fast on Cortex-A8 but may run very fast on Cortex-A9 and newer CPU.

It is however a very short solution.

Expects input in r0, and returns output in r0

  vmov.32 d0[0], r0
  vcnt.8  d0, d0
  vmov.32 r0, d0[0]

  add r0, r0, r0, lsr #16
  add r0, r0, r0, lsr #8
  and r0, r0, #31

The main work is done in the vcnt.8 instruction which counts the bits of each byte in a NEON register and stores the bitcount back into the bytes of D0.

The rest of the code is just adding the four bytes together.

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+1 for actual ARM code. –  artless noise Apr 1 '13 at 13:28

Since this is tagged ARM, the clz instruction is most helpful. The problem is also described as a population count. gcc has __builtin_popcount() for this. As does the ARM tools. There is this link (don't feel bad about your solution, some one made a web page with nearly the same) and also there is Dave Seal's version with six instruction for non-clz ARMs. The clz is advantageous and can be used to produce a faster algorithm, depending on the input.

As well as auselen's good reading suggestion,Hacker's Delight this bit twiddling blog maybe helpful which is talking about such things in a graphic context. At least I found it useful to understand some of Qt's blitting code. However, it has some usefulness in coding a population count routine.

The carry add unit is useful in a divide and conquer sense, making the problem O(ln n). clz is more useful if the data has runs of ones or zeros.

The Hacker's Delight entry has more background on Dave Seal's ARM code.

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1  
I think __builtin_popcount is compiled from look up table implementation, it should be good enough but nothing specially crafted for arm. –  auselen Apr 2 '13 at 8:38
    
@auselen: check what ARM architecture level you're targeting. clz is available only since ARMv5. –  Igor Skochinsky Apr 2 '13 at 8:45
    
@IgorSkochinsky I don't think there is a clz implementation provided by gcc or llvm. __builtin_popcount() links to __popcountsi2. –  auselen Apr 2 '13 at 8:55
    
Well, popcount does more than clz so it needs a helper routine. __builtin_clz or __builtin_ctz emit clz directly for supported architectures. –  Igor Skochinsky Apr 2 '13 at 9:09
    
@IgorSkochinsky may be I should clarify by saying I don't think there is any popcount implementation using clz - at least I couldn't see any. –  auselen Apr 2 '13 at 9:24

Best references for bit hacks are

Bit Twiddling Hacks page says

The best method for counting bits in a 32-bit
integer v is the following:

v = v - ((v >> 1) & 0x55555555);                    // reuse input as temporary
v = (v & 0x33333333) + ((v >> 2) & 0x33333333);     // temp
c = ((v + (v >> 4) & 0xF0F0F0F) * 0x1010101) >> 24; // count

Then I would suggest you to use gcc and objdump to see how this high level snippet would look like as arm instructions.

00000000 <popcount>:
 0: 1043        asrs    r3, r0, #1
 2: f003 3355   and.w   r3, r3, #1431655765 ; 0x55555555
 6: 1ac0        subs    r0, r0, r3
 8: 1083        asrs    r3, r0, #2
 a: f000 3033   and.w   r0, r0, #858993459  ; 0x33333333
 e: f003 3333   and.w   r3, r3, #858993459  ; 0x33333333
12: 18c0        adds    r0, r0, r3
14: eb00 1010   add.w   r0, r0, r0, lsr #4
18: f000 300f   and.w   r0, r0, #252645135  ; 0xf0f0f0f
1c: eb00 2000   add.w   r0, r0, r0, lsl #8
20: eb00 4000   add.w   r0, r0, r0, lsl #16
24: 1600        asrs    r0, r0, #24
26: 4770        bx  lr

So it looks like this gives you result in 12 instructions, which roughly can translate to same amount of cycles.

Comparing integer twiddling above to look up table approach used by libgcc, look up table should be even slower considering extra memory accesses.

00000028 <__popcountSI2>:
28: b410        push    {r4}
2a: 2200        movs    r2, #0
2c: 4c06        ldr r4, [pc, #24]   ; (48 <__popcountSI2+0x20>)
2e: 4613        mov r3, r2
30: fa40 f103   asr.w   r1, r0, r3
34: 3308        adds    r3, #8
36: 2b20        cmp r3, #32
38: b2c9        uxtb    r1, r1
3a: 5c61        ldrb    r1, [r4, r1]
3c: 440a        add r2, r1
3e: d1f7        bne.n   30 <__popcountSI2+0x8>
40: 4610        mov r0, r2
42: bc10        pop {r4}
44: 4770        bx  lr
46: bf00        nop
48: 00000000    andeq   r0, r0, r0
<.. snipped ..>
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