I want to implement unsigneda integer division by an arbitrary power of two, rounding up, efficiently. So what I want, mathematically, is ceiling(p/q)0. In C, the strawman implementation, which doesn't take advantage of the restricted domain of q could something like the following function1:

/** q must be a power of 2, although this version works for any q */
uint64_t divide(uint64_t p, uint64_t q) {
  uint64_t res = p / q;
  return p % q == 0 ? res : res + 1;

... of course, I don't actually want to use division or mod at the machine level, since that takes many cycles even on modern hardware. I'm looking for a strength reduction that uses shifts and/or some other cheap operation(s) - taking advantage of the fact that q is a power of 2.

You can assume we have an efficient lg(unsigned int x) function, which returns the base-2 log of x, if x is a power-of-two.

Undefined behavior is fine if q is zero.

Please note that the simple solution: (p+q-1) >> lg(q) doesn't work in general - try it with p == 2^64-100 and q == 2562 for example.

Platform Details

I'm interested in solutions in C, that are likely to perform well across a variety of platforms, but for the sake of concreteness, awarding the bounty and because any definitive discussion of performance needs to include a target architecture, I'll be specific about how I'll test them:

  • Skylake CPU
  • gcc 5.4.0 with compile flags -O3 -march=haswell

Using gcc builtins (such as bitscan/leading zero builtins) is fine, and in particular I've implemented the lg() function I said was available as follows:

inline uint64_t lg(uint64_t x) {
  return 63U - (uint64_t)__builtin_clzl(x);

inline uint32_t lg32(uint32_t x) {
  return 31U - (uint32_t)__builtin_clz(x);

I verified that these compile down to a single bsr instruction, at least with -march=haswell, despite the apparent involvement of a subtraction. You are of course free to ignore these and use whatever other builtins you want in your solution.


I wrote a benchmark for the existing answers, and will share and update the results as changes are made.

Writing a good benchmark for a small, potentially inlined operation is quite tough. When code is inlined into a call site, a lot of the work of the function may disappear, especially when it's in a loop3.

You could simply avoid the whole inlining problem by ensuring your code isn't inlined: declare it in another compilation unit. I tried to that with the bench binary, but really the results are fairly pointless. Nearly all implementations tied at 4 or 5 cycles per call, but even a dummy method that does nothing other than return 0 takes the same time. So you are mostly just measuring the call + ret overhead. Furthermore, you are almost never really going to use the functions like this - unless you messed up, they'll be available for inlining and that changes everything.

So the two benchmarks I'll focus the most on repeatedly call the method under test in a loop, allowing inlining, cross-function optmization, loop hoisting and even vectorization.

There are two overall benchmark types: latency and throughput. The key difference is that in the latency benchmark, each call to divide is dependent on the previous call, so in general calls cannot be easily overlapped4:

uint32_t bench_divide_latency(uint32_t p, uint32_t q) {
    uint32_t total = p;                         
    for (unsigned i=0; i < ITERS; i++) {                
      total += divide_algo(total, q);                       
      q = rotl1(q);                         
    return total;

Note that the running total depends so on the output of each divide call, and that it is also an input to the divide call.

The throughput variant, on the other hand, doesn't feed the output of one divide into the subsequent one. This allows work from one call to be overlapped with a subsequent one (both by the compiler, but especially the CPU), and even allows vectorization:

uint32_t bench_divide_throughput(uint32_t p, uint32_t q) { 
    uint32_t total = p;                         
    for (unsigned i=0; i < ITERS; i++) {                
      total += fname(i, q);                     
      q = rotl1(q);                     
    return total;                           

Note that here we feed in the loop counter as the the dividend - this is variable, but it doesn't depend on the previous divide call.

Furthermore, each benchmark has three flavors of behavior for the divisor, q:

  1. Compile-time constant divisor. For example, a call to divide(p, 8). This is common in practice, and the code can be much simpler when the divisor is known at compile time.
  2. Invariant divisor. Here the divisor is not know at compile time, but is constant for the whole benchmarking loop. This allows a subset of the optimizations that the compile-time constant does.
  3. Variable divisor. The divisor changes on each iteration of the loop. The benchmark functions above show this variant, using a "rotate left 1" instruction to vary the divisor.

Combining everything you get a total of 6 distinct benchmarks.



For the purposes of picking an overall best algorithm, I looked at each of 12 subsets for the proposed algorithms: (latency, throughput) x (constant a, invariant q, variable q) x (32-bit, 64-bit) and assigned a score of 2, 1, or 0 per subtest as follows:

  • The best algorithm(s) (within 5% tolerance) receive a score of 2.
  • The "close enough" algorithms (no more than 50% slower than the best) receive a score of 1.
  • The remaining algorithms score zero.

Hence, the maximum total score is 24, but no algorithm achieved that. Here are the overall total results:

║       Algorithm       ║ Score ║
║ divide_user23_variant ║    20 ║
║ divide_chux           ║    20 ║
║ divide_user23         ║    15 ║
║ divide_peter          ║    14 ║
║ divide_chrisdodd      ║    12 ║
║ stoke32               ║    11 ║
║ divide_chris          ║     0 ║
║ divide_weather        ║     0 ║

So the for the purposes of this specific test code, with this specific compiler and on this platform, user2357112 "variant" (with ... + (p & mask) != 0) performs best, tied with chux's suggestion (which is in fact identical code).

Here are all the sub-scores which sum to the above:

║                          ║ Total ║ LC ║ LI ║ LV ║ TC ║ TI ║ TV ║
║ divide_peter             ║     6 ║  1 ║  1 ║  1 ║  1 ║  1 ║  1 ║
║ stoke32                  ║     6 ║  1 ║  1 ║  2 ║  0 ║  0 ║  2 ║
║ divide_chux              ║    10 ║  2 ║  2 ║  2 ║  1 ║  2 ║  1 ║
║ divide_user23            ║     8 ║  1 ║  1 ║  2 ║  2 ║  1 ║  1 ║
║ divide_user23_variant    ║    10 ║  2 ║  2 ║  2 ║  1 ║  2 ║  1 ║
║ divide_chrisdodd         ║     6 ║  1 ║  1 ║  2 ║  0 ║  0 ║  2 ║
║ divide_chris             ║     0 ║  0 ║  0 ║  0 ║  0 ║  0 ║  0 ║
║ divide_weather           ║     0 ║  0 ║  0 ║  0 ║  0 ║  0 ║  0 ║
║                          ║       ║    ║    ║    ║    ║    ║    ║
║ 64-bit Algorithm         ║       ║    ║    ║    ║    ║    ║    ║
║ divide_peter_64          ║     8 ║  1 ║  1 ║  1 ║  2 ║  2 ║  1 ║
║ div_stoke_64             ║     5 ║  1 ║  1 ║  2 ║  0 ║  0 ║  1 ║
║ divide_chux_64           ║    10 ║  2 ║  2 ║  2 ║  1 ║  2 ║  1 ║
║ divide_user23_64         ║     7 ║  1 ║  1 ║  2 ║  1 ║  1 ║  1 ║
║ divide_user23_variant_64 ║    10 ║  2 ║  2 ║  2 ║  1 ║  2 ║  1 ║
║ divide_chrisdodd_64      ║     6 ║  1 ║  1 ║  2 ║  0 ║  0 ║  2 ║
║ divide_chris_64          ║     0 ║  0 ║  0 ║  0 ║  0 ║  0 ║  0 ║
║ divide_weather_64        ║     0 ║  0 ║  0 ║  0 ║  0 ║  0 ║  0 ║

Here, each test is named like XY, with X in {Latency, Throughput} and Y in {Constant Q, Invariant Q, Variable Q}. So for example, LC is "Latency test with constant q".


At the highest level, the solutions can be roughly divided into two categories: fast (the top 6 finishers) and slow (the bottom two). The difference is larger: all of the fast algorithms were the fastest on at least two subtests and in general when they didn't finish first they fell into the "close enough" category (they only exceptions being failed vectorizations in the case of stoke and chrisdodd). The slow algorithms however scored 0 (not even close) on every test. So you can mostly eliminate the slow algorithms from further consideration.


Among the fast algorithms, a large differentiator was the ability to auto-vectorize.

None of the algorithms were able to auto-vectorize in the latency tests, which makes sense since the latency tests are designed to feed their result directly into the next iteration. So you can really only calculate results in a serial fashion.

For the throughput tests, however, many algorithms were able to auto-vectorize for the constant Q and invariant Q case. In both of these tests tests the divisor q is loop-invariant (and in the former case it is a compile-time constant). The dividend is the loop counter, so it is variable, but predicable (and in particular a vector of dividends can be trivially calculated by adding 8 to the previous input vector: [0, 1, 2, ..., 7] + [8, 8, ..., 8] == [8, 9, 10, ..., 15]).

In this scenario, gcc was able to vectorize peter, stoke, chux, user23 and user23_variant. It wasn't able to vectorize chrisdodd for some reason, likely because it included a branch (but conditionals don't strictly prevent vectorization since many other solutions have conditional elements but still vectorized). The impact was huge: algorithms that vectorized showed about an 8x improvement in throughput over variants that didn't but were otherwise fast.

Vectorization isn't free, though! Here are the function sizes for the "constant" variant of each function, with the Vec? column showing whether a function vectorized or not:

Size Vec? Name
 045    N bench_c_div_stoke_64
 049    N bench_c_divide_chrisdodd_64
 059    N bench_c_stoke32_64
 212    Y bench_c_divide_chux_64
 227    Y bench_c_divide_peter_64
 220    Y bench_c_divide_user23_64
 212    Y bench_c_divide_user23_variant_64

The trend is clear - vectorized functions take about 4x the size of the non-vectorized ones. This is both because the core loops themselves are larger (vector instructions tend to be larger and there are more of them), and because loop setup and especially the post-loop code is much larger: for example, the vectorized version requires a reduction to sum all the partial sums in a vector. The loop count is fixed and a multiple of 8, so no tail code is generated - but if were variable the generated code would be even larger.

Furthermore, despite the large improvement in runtime, gcc's vectorization is actually poor. Here's an excerpt from the vectorized version of Peter's routine:

  on entry: ymm4 == all zeros
  on entry: ymm5 == 0x00000001 0x00000001 0x00000001 ...
  4007a4:       c5 ed 76 c4             vpcmpeqd ymm0,ymm2,ymm4
  4007ad:       c5 fd df c5             vpandn   ymm0,ymm0,ymm5
  4007b1:       c5 dd fa c0             vpsubd   ymm0,ymm4,ymm0
  4007b5:       c5 f5 db c0             vpand    ymm0,ymm1,ymm0

This chunk works independently on 8 DWORD elements originating in ymm2. If we take x to be a single DWORD element of ymm2, and y the incoming value of ymm1 these foud instructions correspond to:

                    x == 0   x != 0
x  = x ? 0 : -1; //     -1        0
x  = x & 1;      //      1        0
x  = 0 - x;      //     -1        0
x  = y1 & x;     //     y1        0

So the first three instructions could simple be replaced by the first one, as the states are identical in either case. So that's two cycles added to that dependency chain (which isn't loop carried) and two extra uops. Evidently gcc's optimization phases somehow interact poorly with the vectorization code here, since such trivial optimizations are rarely missed in scalar code. Examining the other vectorized versions similarly shows a lot of performance dropped on the floor.

Branches vs Branch-free

Nearly all of the solutions compiled to branch-free code, even if C code had conditionals or explicit branches. The conditional portions were small enough that the compiler generally decided to use conditional move or some variant. One exception is chrisdodd which compiled with a branch (checking if p == 0) in all the throughput tests, but none of the latency ones. Here's a typical example from the constant q throughput test:

0000000000400e60 <bench_c_divide_chrisdodd_32>:
  400e60:       89 f8                   mov    eax,edi
  400e62:       ba 01 00 00 00          mov    edx,0x1
  400e67:       eb 0a                   jmp    400e73 <bench_c_divide_chrisdodd_32+0x13>
  400e69:       0f 1f 80 00 00 00 00    nop    DWORD PTR [rax+0x0]
  400e70:       83 c2 01                add    edx,0x1
  400e73:       83 fa 01                cmp    edx,0x1
  400e76:       74 f8                   je     400e70 <bench_c_divide_chrisdodd_32+0x10>
  400e78:       8d 4a fe                lea    ecx,[rdx-0x2]
  400e7b:       c1 e9 03                shr    ecx,0x3
  400e7e:       8d 44 08 01             lea    eax,[rax+rcx*1+0x1]
  400e82:       81 fa 00 ca 9a 3b       cmp    edx,0x3b9aca00
  400e88:       75 e6                   jne    400e70 <bench_c_divide_chrisdodd_32+0x10>
  400e8a:       c3                      ret    
  400e8b:       0f 1f 44 00 00          nop    DWORD PTR [rax+rax*1+0x0]

The branch at 400e76 skips the case that p == 0. In fact, the compiler could have just peeled the first iteration out (calculating its result explicitly) and then avoided the jump entirely since after that it can prove that p != 0. In these tests, the branch is perfectly predictable, which could give an advantage to code that actually compiles using a branch (since the compare & branch code is essentially out of line and close to free), and is a big part of why chrisdodd wins the throughput, variable q case.

Detailed Test Results

Here you can find some detailed test results and some details on the tests themselves.


The results below test each algorithm over 1e9 iterations. Cycles are calculated simply by multiplying the time/call by the clock frequency. You can generally assume that something like 4.01 is the same as 4.00, but the larger deviations like 5.11 seem to be real and reproducible.

The results for divide_plusq_32 use (p + q - 1) >> lg(q) but are only shown for reference, since this function fails for large p + q. The results for dummy are a very simple function: return p + q, and lets you estimate the benchmark overhead5 (the addition itself should take a cycle at most).

Bench: Compile-time constant Q
                  Function         ns/call    cycles
           divide_peter_32            2.19      5.67
           divide_peter_64            2.18      5.64
                stoke32_32            1.93      5.00
                stoke32_64            1.97      5.09
              stoke_mul_32            2.75      7.13
              stoke_mul_64            2.34      6.06
              div_stoke_32            1.94      5.03
              div_stoke_64            1.94      5.03
            divide_chux_32            1.55      4.01
            divide_chux_64            1.55      4.01
          divide_user23_32            1.97      5.11
          divide_user23_64            1.93      5.00
  divide_user23_variant_32            1.55      4.01
  divide_user23_variant_64            1.55      4.01
       divide_chrisdodd_32            1.95      5.04
       divide_chrisdodd_64            1.93      5.00
           divide_chris_32            4.63     11.99
           divide_chris_64            4.52     11.72
         divide_weather_32            2.72      7.04
         divide_weather_64            2.78      7.20
           divide_plusq_32            1.16      3.00
           divide_plusq_64            1.16      3.00
           divide_dummy_32            1.16      3.00
           divide_dummy_64            1.16      3.00

Bench: Invariant Q
                  Function         ns/call    cycles
           divide_peter_32            2.19      5.67
           divide_peter_64            2.18      5.65
                stoke32_32            1.93      5.00
                stoke32_64            1.93      5.00
              stoke_mul_32            2.73      7.08
              stoke_mul_64            2.34      6.06
              div_stoke_32            1.93      5.00
              div_stoke_64            1.93      5.00
            divide_chux_32            1.55      4.02
            divide_chux_64            1.55      4.02
          divide_user23_32            1.95      5.05
          divide_user23_64            2.00      5.17
  divide_user23_variant_32            1.55      4.02
  divide_user23_variant_64            1.55      4.02
       divide_chrisdodd_32            1.95      5.04
       divide_chrisdodd_64            1.93      4.99
           divide_chris_32            4.60     11.91
           divide_chris_64            4.58     11.85
         divide_weather_32           12.54     32.49
         divide_weather_64           17.51     45.35
           divide_plusq_32            1.16      3.00
           divide_plusq_64            1.16      3.00
           divide_dummy_32            0.39      1.00
           divide_dummy_64            0.39      1.00

Bench: Variable Q
                  Function         ns/call    cycles
           divide_peter_32            2.31      5.98
           divide_peter_64            2.26      5.86
                stoke32_32            2.06      5.33
                stoke32_64            1.99      5.16
              stoke_mul_32            2.73      7.06
              stoke_mul_64            2.32      6.00
              div_stoke_32            2.00      5.19
              div_stoke_64            2.00      5.19
            divide_chux_32            2.04      5.28
            divide_chux_64            2.05      5.30
          divide_user23_32            2.05      5.30
          divide_user23_64            2.06      5.33
  divide_user23_variant_32            2.04      5.29
  divide_user23_variant_64            2.05      5.30
       divide_chrisdodd_32            2.04      5.30
       divide_chrisdodd_64            2.05      5.31
           divide_chris_32            4.65     12.04
           divide_chris_64            4.64     12.01
         divide_weather_32           12.46     32.28
         divide_weather_64           19.46     50.40
           divide_plusq_32            1.93      5.00
           divide_plusq_64            1.99      5.16
           divide_dummy_32            0.40      1.05
           divide_dummy_64            0.40      1.04


Here are the results for the throughput tests. Note that many of the algorithms here were auto-vectorized, so the performance is relatively very good for those: a fraction of a cycle in many cases. One result is that unlike most latency results, the 64-bit functions are considerably slower, since vectorization is more effective with smaller element sizes (although the gap is larger that I would have expected).

Bench: Compile-time constant Q
                  Function         ns/call    cycles
                stoke32_32            0.39      1.00
            divide_chux_32            0.15      0.39
            divide_chux_64            0.53      1.37
          divide_user23_32            0.14      0.36
          divide_user23_64            0.53      1.37
  divide_user23_variant_32            0.15      0.39
  divide_user23_variant_64            0.53      1.37
       divide_chrisdodd_32            1.16      3.00
       divide_chrisdodd_64            1.16      3.00
           divide_chris_32            4.34     11.23
           divide_chris_64            4.34     11.24
         divide_weather_32            1.35      3.50
         divide_weather_64            1.35      3.50
           divide_plusq_32            0.10      0.26
           divide_plusq_64            0.39      1.00
           divide_dummy_32            0.08      0.20
           divide_dummy_64            0.39      1.00

Bench: Invariant Q
                  Function         ns/call    cycles
                stoke32_32            0.48      1.25
            divide_chux_32            0.15      0.39
            divide_chux_64            0.48      1.25
          divide_user23_32            0.17      0.43
          divide_user23_64            0.58      1.50
  divide_user23_variant_32            0.15      0.38
  divide_user23_variant_64            0.48      1.25
       divide_chrisdodd_32            1.16      3.00
       divide_chrisdodd_64            1.16      3.00
           divide_chris_32            4.35     11.26
           divide_chris_64            4.36     11.28
         divide_weather_32            5.79     14.99
         divide_weather_64           17.00     44.02
           divide_plusq_32            0.12      0.31
           divide_plusq_64            0.48      1.25
           divide_dummy_32            0.09      0.23
           divide_dummy_64            0.09      0.23

Bench: Variable Q
                  Function         ns/call    cycles
                stoke32_32            1.16      3.00
            divide_chux_32            1.36      3.51
            divide_chux_64            1.35      3.50
          divide_user23_32            1.54      4.00
          divide_user23_64            1.54      4.00
  divide_user23_variant_32            1.36      3.51
  divide_user23_variant_64            1.55      4.01
       divide_chrisdodd_32            1.16      3.00
       divide_chrisdodd_64            1.16      3.00
           divide_chris_32            4.02     10.41
           divide_chris_64            3.84      9.95
         divide_weather_32            5.40     13.98
         divide_weather_64           19.04     49.30
           divide_plusq_32            1.03      2.66
           divide_plusq_64            1.03      2.68
           divide_dummy_32            0.63      1.63
           divide_dummy_64            0.66      1.71

a At least by specifying unsigned we avoid the whole can of worms related to the right-shift behavior of signed integers in C and C++.

0 Of course, this notation doesn't actually work in C where / truncates the result so the ceiling does nothing. So consider that pseudo-notation rather than straight C.

1 I'm also interested solutions where all types are uint32_t rather than uint64_t.

2 In general, any p and q where p + q >= 2^64 causes an issue, due to overflow.

3 That said, the function should be in a loop, because the performance of a microscopic function that takes half a dozen cycles only really matters if it is called in a fairly tight loop.

4 This is a bit of a simplification - only the dividend p is dependent on the output of the previous iteration, so some work related to processing of q can still be overlapped.

5 Use such estimates with caution however - overhead isn't simply additive. If the overhead shows up as 4 cycles and some function f takes 5, it's likely not accurate to say the cost of the real work in f is 5 - 4 == 1, because of the way execution is overlapped.

  • 1
    @mascoj - we are racing in the comments, see above :) – BeeOnRope Nov 4 '16 at 21:13
  • 2
    @user2357112 - regarding "1.4e19 is a double..." - I was using the notation in in a mathematical sense, not in a "C literal notation" sense. A number can both be an integer (math sense) and a double in the C sense, of course. You are right it's not a power of 2. My example and notation was misguided. I've made it clearer now. – BeeOnRope Nov 4 '16 at 21:42
  • 1
    Yes, I want dividend==0 to work correctly. Still I'm interested also interested in special case solutions, e.g., where some values don't work correctly, if they are a notable improvement over the general version. For the purposes of the bounty though, it should work correctly for all inputs. For the bounty I'm using -03 -march=haswell and I am running it on Skylake. Stick to C and gcc builtins for the bounty, but of course I'm also interested in asm versions that beat the C equivalent. The accepted answer should be all-around good and may be different than the bounty winner! If – BeeOnRope Nov 7 '16 at 15:30
  • 1
    About special case solutions - they should have a reasonable restricted set of values that don't work correctly, to be usable! For example, not working when dividend == 0 would qualify as reasonably restricted, as would when (p + q - 1) > UINT_MAX (even though the latter covers a lot of values, they are restricted to the upper end of the uint range, and you might well know you don't approach those values in practice). If it fails randomly for values in the middle of the range it's not going to be very helpful. – BeeOnRope Nov 7 '16 at 15:32
  • 1
    @user2357112 - yeah, it's artifact of the vectorization. The vectorizer gave up on vectorizing Chris D's solution, probably because of the implied branch (although that's glossing over a bit of detail since some other answers have an implied branch too, but it still vectorized). Other solutions (the ones with < 2 cycle throughput) all got vectorized for constant and invariant q. With the varying q (at least the way I varied it), the vectorizer gives up and then Chris code does well. – BeeOnRope Nov 9 '16 at 1:12

This answer is about what's ideal in asm; what we'd like to convince the compiler to emit for us. (I'm not suggesting actually using inline asm, except as a point of comparison when benchmarking compiler output. https://gcc.gnu.org/wiki/DontUseInlineAsm).

I did manage to get pretty good asm output from pure C for ceil_div_andmask, see below. (It's worse than a CMOV on Broadwell/Skylake, but probably good on Haswell. Still, the user23/chux version looks even better for both cases.) It's mostly just worth mentioning as one of the few cases where I got the compiler to emit the asm I wanted.

It looks like Chris Dodd's general idea of return ((p-1) >> lg(q)) + 1 with special-case handling for d=0 is one of the best options. I.e. the optimal implementation of it in asm is hard to beat with an optimal implementation of anything else. Chux's (p >> lg(q)) + (bool)(p & (q-1)) also has advantages (like lower latency from p->result), and more CSE when the same q is used for multiple divisions. See below for a latency/throughput analysis of what gcc does with it.

If the same e = lg(q) is reused for multiple dividends, or the same dividend is reused for multiple divisors, different implementations can CSE more of the expression. They can also effectively vectorize with AVX2.

Branches are cheap and very efficient if they predict very well, so branching on d==0 will be best if it's almost never taken. If d==0 is not rare, branchless asm will perform better on average. Ideally we can write something in C that will let gcc make the right choice during profile-guided optimization, and compiles to good asm for either case.

Since the best branchless asm implementations don't add much latency vs. a branchy implementation, branchless is probably the way to go unless the branch would go the same way maybe 99% of the time. This might be likely for branching on p==0, but probably less likely for branching on p & (q-1).

It's hard to guide gcc5.4 into emitting anything optimal. This is my work-in-progress on Godbolt).

I think the optimal sequences for Skylake for this algorithm are as follows. (Shown as stand-alone functions for the AMD64 SysV ABI, but talking about throughput/latency on the assumption that the compiler will emit something similar inlined into a loop, with no RET attached).

Branch on carry from calculating d-1 to detect d==0, instead of a separate test & branch. Reduces the uop count nicely, esp on SnB-family where JC can macro-fuse with SUB.

 xor    eax,eax          ; can take this uop off the fast path by adding a separate xor-and-return block, but in reality we want to inline something like this.
 sub    rdi, 1
 jc    .d_was_zero       ; fuses with the sub on SnB-family
 tzcnt  rax, rsi         ; tzcnt rsi,rsi also avoids any false-dep problems, but this illustrates that the q input can be read-only.
 shrx   rax, rdi, rax
 inc    rax
  • Fused-domain uops: 5 (not counting ret), and one of them is an xor-zero (no execution unit)
  • HSW/SKL latency with successful branch prediction:
    • (d==0): No data dependency on d or q, breaks the dep chain. (control dependency on d to detect mispredicts and retire the branch).
    • (d!=0): q->result: tzcnt+shrx+inc = 5c
    • (d!=0): d->result: sub+shrx+inc = 3c
  • Throughput: probably just bottlenecked on uop throughput

I've tried but failed to get gcc to branch on CF from the subtract, but it always wants to do a separate comparison. I know gcc can be coaxed into branching on CF after subtracting two variables, but maybe this fails if one is a compile-time constant. (IIRC, this typically compiles to a CF test with unsigned vars: foo -= bar; if(foo>bar) carry_detected = 1;)

Branchless with ADC / SBB to handle the d==0 case. Zero-handling adds only one instruction to the critical path (vs. a version with no special handling for d==0), but also converts one other from an INC to a sbb rax, -1 to make CF undo the -= -1. Using a CMOV is cheaper on pre-Broadwell, but takes extra instructions to set it up.

 tzcnt  rsi, rsi
 sub    rdi, 1
 adc    rdi, 0          ; d? d-1 : d.  Sets CF=CF
 shrx   rax, rdi, rsi
 sbb    rax, -1         ; result++ if d was non-zero
  • Fused-domain uops: 5 (not counting ret) on SKL. 7 on HSW
  • SKL latency:
    • q->result: tzcnt+shrx+sbb = 5c
    • d->result: sub+adc+shrx(dep on q begins here)+sbb = 4c
  • Throughput: TZCNT runs on p1. SBB, ADC, and SHRX only run on p06. So I think we bottleneck on 3 uops for p06 per iteration, making this run at best one iteration per 1.5c.

If q and d become ready at the same time, note that this version can run SUB/ADC in parallel with the 3c latency of TZCNT. If both are coming from the same cache-miss cache line, it's certainly possible. In any case, introducing the dep on q as late as possible in the d->result dependency chain is an advantage.

Getting this from C seems unlikely with gcc5.4. There is an intrinsic for add-with-carry, but gcc makes a total mess of it. It doesn't use immediate operands for ADC or SBB, and stores the carry into an integer reg between every operation. gcc7, clang3.9, and icc17 all make terrible code from this.

#include <x86intrin.h>
// compiles to completely horrible code, putting the flags into integer regs between ops.
T ceil_div_adc(T d, T q) {
  T e = lg(q);
  unsigned long long dm1;  // unsigned __int64
  unsigned char CF = _addcarry_u64(0, d, -1, &dm1);
  CF = _addcarry_u64(CF, 0, dm1, &dm1);
  T shifted = dm1 >> e;
  _subborrow_u64(CF, shifted, -1, &dm1);
  return dm1;
    # gcc5.4 -O3 -march=haswell
    mov     rax, -1
    tzcnt   rsi, rsi
    add     rdi, rax
    setc    cl
    xor     edx, edx
    add     cl, -1
    adc     rdi, rdx
    setc    dl
    shrx    rdi, rdi, rsi
    add     dl, -1
    sbb     rax, rdi

CMOV to fix the whole result: worse latency from q->result, since it's used sooner in the d->result dep chain.

 tzcnt  rsi, rsi
 sub    rdi, 1
 shrx   rax, rdi, rsi
 lea    rax, [rax+1]     ; inc preserving flags
 cmovc  rax, zeroed_register
  • Fused-domain uops: 5 (not counting ret) on SKL. 6 on HSW
  • SKL latency:
    • q->result: tzcnt+shrx+lea+cmov = 6c (worse than ADC/SBB by 1c)
    • d->result: sub+shrx(dep on q begins here)+lea+cmov = 4c
  • Throughput: TZCNT runs on p1. LEA is p15. CMOV and SHRX are p06. SUB is p0156. In theory only bottlenecked on fused-domain uop throughput, so one iteration per 1.25c. With lots of independent operations, resource conflicts from SUB or LEA stealing p1 or p06 shouldn't be a throughput problem because at 1 iter per 1.25c, no port is saturated with uops that can only run on that port.

CMOV to get an operand for SUB: I was hoping I could find a way to create an operand for a later instruction that would produce a zero when needed, without an input dependency on q, e, or the SHRX result. This would help if d is ready before q, or at the same time.

This doesn't achieve that goal, and needs an extra 7-byte mov rdx,-1 in the loop.

 tzcnt  rsi, rsi
 mov    rdx, -1
 sub    rdi, 1
 shrx   rax, rdi, rsi
 cmovnc rdx, rax
 sub    rax, rdx       ; res += d ? 1 : -res

Lower-latency version for pre-BDW CPUs with expensive CMOV, using SETCC to create a mask for AND.

 xor    edx, edx        ; needed every iteration

 tzcnt  rsi, rsi
 sub    rdi, 1

 setc   dl              ; d!=0 ?  0 : 1
 dec    rdx             ; d!=0 ? -1 : 0   // AND-mask

 shrx   rax, rdi, rsi
 inc    rax
 and    rax, rdx        ; zero the bogus result if d was initially 0

Still 4c latency from d->result (and 6 from q->result), because the SETC/DEC happen in parallel with the SHRX/INC. Total uop count: 8. Most of these insns can run on any port, so it should be 1 iter per 2 clocks.

Of course, for pre-HSW, you also need to replace SHRX.

We can get gcc5.4 to emit something nearly as good: (still uses a separate TEST instead of setting mask based on sub rdi, 1, but otherwise the same instructions as above). See it on Godbolt.

T ceil_div_andmask(T p, T q) {
    T mask = -(T)(p!=0);  // TEST+SETCC+NEG
    T e = lg(q);
    T nonzero_result = ((p-1) >> e) + 1;
    return nonzero_result & mask;

When the compiler knows that p is non-zero, it takes advantage and makes nice code:

// http://stackoverflow.com/questions/40447195/can-i-hint-the-optimizer-by-giving-the-range-of-an-integer
#if defined(__GNUC__) && !defined(__INTEL_COMPILER)
#define assume(x) do{if(!(x)) __builtin_unreachable();}while(0)
#define assume(x) (void)(x) // still evaluate it once, for side effects in case anyone is insane enough to put any inside an assume()

T ceil_div_andmask_nonzerop(T p, T q) {
  return ceil_div_andmask(p, q);
    # gcc5.4 -O3 -march=haswell
    xor     eax, eax             # gcc7 does tzcnt in-place instead of wasting an insn on this
    sub     rdi, 1
    tzcnt   rax, rsi
    shrx    rax, rdi, rax
    add     rax, 1

Chux / user23_variant

only 3c latency from p->result, and constant q can CSE a lot.

T divide_A_chux(T p, T q) {
  bool round_up = p & (q-1);  // compiles differently from user23_variant with clang: AND instead of 
  return (p >> lg(q)) + round_up;

    xor     eax, eax           # in-place tzcnt would save this
    xor     edx, edx           # target for setcc
    tzcnt   rax, rsi
    sub     rsi, 1
    test    rsi, rdi
    shrx    rdi, rdi, rax
    setne   dl
    lea     rax, [rdx+rdi]

Doing the SETCC before TZCNT would allow an in-place TZCNT, saving the xor eax,eax. I haven't looked at how this inlines in a loop.

  • Fused-domain uops: 8 (not counting ret) on HSW/SKL
  • HSW/SKL latency:
    • q->result: (tzcnt+shrx(p) | sub+test(p)+setne) + lea(or add) = 5c
    • d->result: test(dep on q begins here)+setne+lea = 3c. (the shrx->lea chain is shorter, and thus not the critical path)
  • Throughput: Probably just bottlenecked on the frontend, at one iter per 2c. Saving the xor eax,eax should speed this up to one per 1.75c (but of course any loop overhead will be part of the bottleneck, because frontend bottlenecks are like that).
  • 1
    Awesome stuff. Still, the C versions have the big advantage of being able to be inlined, and then have all the optimizations applied which result from that. Even if an inline-asm function can be inlined, the further optimizations that the inlining enables don't occur, so you only save the call + ret overhead. I am just finishing up my benchmark, and it does have a "call function" variant where the functions are declared in another compilation unit, disabling inlining, but pretty much every function tied at 4 or 5 cycles latency (even a dummy "empty" function). – BeeOnRope Nov 8 '16 at 19:24
  • ... so I'm mostly focusing on more "realistic" variants where the function body is available to the compiler at the call site, so inlining and cross-function optimization plays a huge role. The scenarios include where the divisor is a compile-time constant, where the divisor is not a compile-time constant, but is fixed for the duration of the benchmarking loop, and finally a scenarios where the divisor changes every iteration. – BeeOnRope Nov 8 '16 at 19:26
  • 1
    That makes sense, although even trying to get the compiler to emit great ASM for the standalone function may in some cases be wasted effort, since when inlined things look different (e.g., the note that it seems to use a branch for Chris Dodd's solution when compiled standalone, but when actually used and inlined, the jump always seems to go away replaced by a conditional). I've added some benchmark code to the question - the loops like this for latency, and see bench_throughput.c for tput. – BeeOnRope Nov 8 '16 at 22:41
  • 1
    I tried using STOKE to find answers exhaustively, and put some of my results in an answer. It was pretty clever for 32-bit, but didn't any 64-bit answers that were as good as your best, partly since it seems to misunderstand latency of some operations. – BeeOnRope Nov 12 '16 at 5:02
  • 1
    Yes, the chrisdodd solution did branch in the "throughput" variant of the test, but not the "latency" one. I added a little section just now in the question under heading branchfree. You can also check out the full assembly listing for the latency and throughput tests. – BeeOnRope Nov 15 '16 at 2:37
uint64_t exponent = lg(q);
uint64_t mask = q - 1;
//     v divide
return (p >> exponent) + (((p & mask) + mask) >> exponent)
//                       ^ round up

The separate computation of the "round up" part avoids the overflow issues of (p+q-1) >> lg(q). Depending on how smart your compiler is, it might be possible to express the "round up" part as ((p & mask) != 0) without branching.

  • Indeed, godbolt shows that at least recent versions of gcc, clang and icc produce branch free code for your != 0 variant. Based on my simple counting, both versions have a latency of 5 cycles, so the extra shifting doesn't hurt too much (at least if you target an architecture with BMI so you get shrx and friends. – BeeOnRope Nov 4 '16 at 22:16
  • Thannks @user2357113 - I exhaustively validated (for all p/q) the 32-bit versions of both versions of your code (the one shown and the with ((p & mask) != 0). No issues found. Will post performance results soon. – BeeOnRope Nov 5 '16 at 22:35
  • Your variant with ((p & mask) != 0) was the winner overall! In practice compilers optimize it well and it vectorized well. Enjoy your bounty! – BeeOnRope Nov 15 '16 at 1:54
  • 1
    I accepted Peter's answer as the overall answer because the truth is everything is highly dependent on the input, the compiler and the surrounding code, so his survey is probably the most comprehensive way to look at the issue. – BeeOnRope Nov 15 '16 at 1:55

The efficient way of dividing by a power of 2 for an unsigned integer in C is a right shift -- shifting right one divides by two (rounding down), so shifting right by n divides by 2n (rounding down).

Now you want to round up rather than down, which you can do by first adding 2n-1, or equivalently subtracting one before the shift and adding one after (except for 0). This works out to something like:

unsigned ceil_div(unsigned d, unsigned e) {
    /* compute ceil(d/2**e) */
    return d ? ((d-1) >> e) + 1 : 0;

The conditional can be removed by using the boolean value of d for addition and subtraction of one:

unsigned ceil_div(unsigned d, unsigned e) {
    /* compute ceil(d/2**e) */
    return ((d - !!d) >> e) + !!d;

Due to its size, and the speed requirement, the function should be made static inline. It probably won't make a different for the optimizer, but the parameters should be const. If it must be shared among many files, define it in a header:

static inline unsigned ceil_div(const unsigned d, const unsigned e){...
  • Nice!. Will have to remember. – chux Nov 4 '16 at 22:42
  • Thanks. Keep in mind that per my question, the second argument q is the divisor, which is a power of two by contract, but the value of q is the plain divisor, not the power. That is, to execute 10 / 8 you would call divide(10, 8), not divide(10, 3) (as 8 = 2^3). You can use the method lq(x) in your answer if you want to get the exponent. – BeeOnRope Nov 4 '16 at 22:46
  • @BeeOnRope: then you can safely use gcc's __builtin_ctzll(q) or whatever other trailing-zero count method to get the log2 (shift count). If you want to put in an assert, there are efficient ways to check that an integer is a power of 2 (only has a single bit set). (That GNU C builtin gives an undefined result if q == 0, so on x86 it can compile to just a BSF with no error check.) – Peter Cordes Nov 6 '16 at 20:55
  • Yes, of course - just pointing out to the OP that I will have to modify his function to compare it on an apples-for-apples basis with the other solutions. – BeeOnRope Nov 6 '16 at 20:56
  • Thanks @Chris - I've exhaustively validated your solution for all 32-bit values, and preliminary indications are that it is performance competitive with the other top solutions. – BeeOnRope Nov 6 '16 at 21:23

Efficiently dividing unsigned value by a power of two, rounding up

[Re-write] given OP's clarification concerning power-of-2.

The round-up or ceiling part is easy when overflow is not a concern. Simple add q-1, then shift.

Otherwise as the possibility of rounding depends on all the bits of p smaller than q, detection of those bits is needed first before they are shifted out.

uint64_t divide_A(uint64_t p, uint64_t q) {
  bool round_up = p & (q-1);
  return (p >> lg64(q)) + round_up;

This assumes code has an efficient lg64(uint64_t x) function, which returns the base-2 log of x, if x is a power-of-two.`

  • Thanks. Keep in mind that per my question, the second argument q is the divisor, which is a power of two by contract, but the value of q is the plain divisor, not the power. That is, to execute 10 / 8 you would call divide(10, 8), not divide(10, 3) (as 8 = 2^3). – BeeOnRope Nov 4 '16 at 22:45
  • I used your functions as shown here - including 32-bit implementation, using stdbool.h for bool. It validated fine for all ~137 billion 32-bit inputs, so it almost certainly works in general. I think this answer is equivalent to @user2357112's variant with (p & mask) != 0 and initial timing shows they are the same. – BeeOnRope Nov 6 '16 at 21:38
  • Chux, I added benchmarks of your solution using the suffix _chux above. Your solution is competitive with the best! – BeeOnRope Nov 8 '16 at 22:38
  • @BeeOnRope: This version has the lowest p->result latency of any branchless version, and compiles to non-terrible asm. I added the asm to my answer in an update. It probably also auto-vectorizes better than most (when the same q is used with multiple dividends). – Peter Cordes Nov 8 '16 at 22:39
  • 1
    @PeterCordes, yes - but note also that this is identical to user2357112's "variant" answer (see the last part of his answer), which I've included as divide_user23_variant above. user23... had the first answer and already included that there, so I'll give him credit if it comes to it. – BeeOnRope Nov 8 '16 at 22:49

My old answer didn't work if p was one more than a power of two (whoops). So my new solution, using the __builtin_ctzll() and __builtin_ffsll() functions0 available in gcc (which as a bonus, provides the fast logarithm you mentioned!):

uint64_t divide(uint64_t p,uint64_t q) {
    int lp=__builtin_ffsll(p);
    int lq=__builtin_ctzll(q);
    return (p>>lq)+(lp<(lq+1)&&lp);

Note that this is assuming that a long long is 64 bits. It has to be tweaked a little otherwise.

The idea here is that if we need an overflow if and only if p has fewer trailing zeroes than q. Note that for a power of two, the number of trailing zeroes is equal to the logarithm, so we can use this builtin for the log as well.

The &&lp part is just for the corner case where p is zero: otherwise it will output 1 here.

0 Can't use __builtin_ctzll() for both because it is undefined if p==0.

  • 2
    This fails for p=1, q=2. Correct answer is 1, but your code gives zero: ((1>>1)+(2>>1)-1)>>(lg(2)-1) == (0+1-1)>>(1-1) == 0 >> 0 == 0. – BeeOnRope Nov 6 '16 at 22:11
  • @BeeOnRope Looking at it a bit more, it failed for any number one more than a power of two. Whoops! Hopefully this answer will be more satisfying. And I actually tested thoroughly this time. – Chris Nov 7 '16 at 6:59
  • Right, I only report the first failure :) – BeeOnRope Nov 7 '16 at 15:12
  • Chris, are you missing parens around p>>lq? The code as shown fails still for p=1, q=2, but I think you likely meant return (p>>lq)+(lp<(lq+1)&&lp). Recall that + is higher precedence than >>. – BeeOnRope Nov 7 '16 at 15:22
  • 2
    Your new function works and I added benchmarks for it above. It's considerably slower than the leading solutions however. – BeeOnRope Nov 8 '16 at 22:45

If the dividend/divisor can be guaranteed not to exceed 63 (or 31) bits, you can use the following version mentioned in the question. Note how p+q could overflow if they use all 64 bit. This would be fine if the SHR instruction shifted in the carry flag, but AFAIK it doesn't.

uint64_t divide(uint64_t p, uint64_t q) {
  return (p + q - 1) >> lg(q);

If those constraints cannot be guaranteed, you can just do the floor method and then add 1 if it would round up. This can be determined by checking if any bits in the dividend are within the range of the divisor. Note: p&-p extracts the lowest set bit on 2s complement machines or the BLSI instruction

uint64_t divide(uint64_t p, uint64_t q) {
  return (p >> lg(q)) + ( (p & -p ) < q );

Which clang compiles to:

    bsrq    %rax, %rsi
    shrxq   %rax, %rdi, %rax
    blsiq   %rdi, %rcx
    cmpq    %rsi, %rcx
    adcq    $0, %rax

That's a bit wordy and uses some newer instructions, so maybe there is a way to use the carry flag in the original version. Lets see: The RCR instruction does but seems like it would be worse ... perhaps the SHRD instruction... It would be something like this (unable to test at the moment)

    xor     edx, edx     ;edx = 0 (will store the carry flag)
    bsr     rcx, rsi     ;rcx = lg(q) ... could be moved anywhere before shrd
    lea     rax, [rsi-1] ;rax = q-1 (adding p could carry)
    add     rax, rdi     ;rax += p  (handle carry)
    setc    dl           ;rdx = carry flag ... or xor rdx and setc
    shrd    rax, rdx, cl ;rax = rdx:rax >> cl

1 more instruction, but should be compatible with older processors (if it works ... I'm always getting a source/destination swapped - feel free to edit)


I've implemented the lg() function I said was available as follows:

inline uint64_t lg(uint64_t x) {
  return 63U - (uint64_t)__builtin_clzl(x);

inline uint32_t lg32(uint32_t x) {
  return 31U - (uint32_t)__builtin_clz(x);

The fast log functions don't fully optimize to bsr on clang and ICC but you can do this:

#if defined(__x86_64__) && (defined(__clang__) || defined(__INTEL_COMPILER))
static inline uint64_t lg(uint64_t x){
  inline uint64_t ret;
  //other compilers may want bsrq here
  __asm__("bsr  %0, %1":"=r"(ret):"r"(x));
  return ret;

#if defined(__i386__) && (defined(__clang__) || defined(__INTEL_COMPILER))    
static inline uint32_t lg32(uint32_t x){
  inline uint32_t ret;
  __asm__("bsr  %0, %1":"=r"(ret):"r"(x));
  return ret;
  • FWIW, that's exactly how I implemented lg32 and lg64. It does fully optimize down to a single bsr with -mtune=haswell, but not without that flag, which is weird since that instruction has been around forever and the added stuff is just cruft. Weird enough that I made another question about it specifically. – BeeOnRope Nov 9 '16 at 2:50
  • ... and the problem with the inline asm stuff is it will break optimization around it. I don't think it will do CSE on it, and it certainly won't calculate the value if the input is a compile-time constant. – BeeOnRope Nov 9 '16 at 2:52
  • @BeeOnRope: non-volatile asm statements are considered pure functions of their inputs, and assumed to have no side-effects, so they can CSE (or be optimized away entirely if their output operands are unused). gcc and clang do that, but ICC doesn't (godbolt.org/g/zsvPYA) :/ BTW, those defined() conditions need parens around clang||icc, and the inline keyword doesn't do anything on function args or locals. It does prevent constant propagation, so I highly don't recommend it. – Peter Cordes Nov 9 '16 at 3:33
  • But anyway, for clang at least, the right solution is to just use __builtin_ctz to count trailing zeros, so there's no 64 - x to optimize away in the first place. Then compilers can use tzcnt or bsf, whichever they prefer. @techno: see the godbolt link in my answer. – Peter Cordes Nov 9 '16 at 3:35
  • Huh, so they are better supported than I thought! The last part still holds though - the compiler won't "look into" the asm and calculate the result of the bsr, which could be key to speeding up the "constant q" case. In fact though, on Haswell, constant q is only about as fast as the weaker "invariant q" - partly because shrx and friends are better than the old variable shifts. Vectorization is somewhat better with constant q versus invariant. – BeeOnRope Nov 9 '16 at 3:37

There has already been a lot of human brainpower applied to this problem, with several variants of great answers in C along with Peter Cordes's answer which covers the best you could hope for in asm, with notes on trying to map it back to C.

So while the humans are having their kick at the can, I thought see what some brute computing power has to say! To that end, I used Stanford's STOKE superoptimizer to try to find good solutions to the 32-bit and 64-bit versions of this problem.

Usually, a superoptimizer is usually something like a brute force search through all possible instruction sequences until you find the best one by some metric. Of course, with something like 1,000 instructions that will quickly spiral out of control for more than a few instructions1. STOKE, on the hand, takes a guided randomized approach: it randomly makes mutations to an existing candidate program, evaluating at each step a cost function that takes both performance and correctness into effect. That's the one-liner anyway - there are plenty of papers if that stoked your curiosity.

So within a few minutes STOKE found some pretty interesting solutions. It found almost all the high-level ideas in the existing solutions, plus a few unique ones. For example, for the 32-bit function, STOKE found this version:

neg rsi                         
dec rdi                         
pext rax, rsi, rdi
inc eax

It doesn't use any leading/trailing-zero count or shift instructions at all. Pretty much, it uses neg esi to turn the divisor into a mask with 1s in the high bits, and then pext effectively does the shift using that mask. Outside of that trick it's using the same trick that user QuestionC used: decrement p, shift, increment p - but it happens to work even for zero dividend because it uses 64-bit registers to distinguish the zero case from the MSB-set large p case.

I added the C version of this algorithm to the benchmark, and added it to the results. It's competitive with the other good algorithms, tying for first in the "Variable Q" cases. It does vectorize, but not as well as the other 32-bit algorithms, because it needs 64-bit math and so the vectors can process only half as many elements at once.

Even better, in the 32-bit case it came up with a variety of solutions which use the fact that some of the intuitive solutions that fail for edge cases happen to "just work" if you use 64-bit ops for part of it. For example:

tzcntl ebp, esi      
dec esi             
add rdi, rsi        
sarx rax, rdi, rbp

That's the equivalent of the return (p + q - 1) >> lg(q) suggestion I mentioned in the question. That doesn't work in general since for large p + q it overflows, but for 32-bit p and q this solution works great by doing the important parts in 64-bit. Convert that back into C with some casts and it actually figures out that using lea will do the addition in one instruction1:

stoke_32(unsigned int, unsigned int):
        tzcnt   edx, esi
        mov     edi, edi          ; goes away when inlining
        mov     esi, esi          ; goes away when inlining
        lea     rax, [rsi-1+rdi]
        shrx    rax, rax, rdx

So it's a 3-instruction solution when inlined into something that already has the values zero-extended into rdi and rsi. The stand-alone function definition needs the mov instructions to zero-extend because that's how the SysV x64 ABI works.

For the 64-bit function it didn't come up with anything that blows away the existing solutions but it did come up with some neat stuff, like:

  tzcnt  r13, rsi      
  tzcnt  rcx, rdi      
  shrx   rax, rdi, r13 
  cmp    r13b, cl        
  adc    rax, 0        

That guy counts the trailing zeros of both arguments, and then adds 1 to the result if q has fewer trailing zeros than p, since that's when you need to round up. Clever!

In general, it understood the idea that you needed to shl by the tzcnt really quickly (just like most humans) and then came up with a ton of other solutions to the problem of adjusting the result to account for rounding. It even managed to use blsi and bzhi in several solutions. Here's a 5-instruction solution it came up with:

tzcnt r13, rsi                  
shrx  rax, rdi, r13             
imul  rsi, rax                   
cmp   rsi, rdi                    
adc   rax, 0                    

It's a basically a "multiply and verify" approach - take the truncated res = p \ q, multiply it back and if it's different than p add one: return res * q == p ? ret : ret + 1. Cool. Not really better than Peter's solutions though. STOKE seems to have some flaws in its latency calculation - it thinks the above has a latency of 5 - but it's more like 8 or 9 depending on the architecture. So it sometimes narrows in solutions that are based on its flawed latency calculation.

1 Interestingly enough though this brute force approach reaches its feasibility around 5-6 instructions: if you assume you can trim the instruction count to say 300 by eliminating SIMD and x87 instructions, then you would need ~28 days to try all 300 ^ 5 5 instruction sequences at 1,000,000 candidates/second. You could perhaps reduce that by a factor of 1,000 with various optimizations, meaning less than an hour for 5-instruction sequences and maybe a week for 6-instruction. As it happens, most of the best solutions for this problem fall into that 5-6 instruction window...

2 This will be a slow lea, however, so the sequence found by STOKE was still optimal for what I optimized for, which was latency.

  • Is pext rsi, rdi, rax in .att_syntax noprefix, with the destination last? Or did it just end up that way after removing the % decorators manually but not reversing the operands? >.< Neat stuff, but the code blocks need fixing. Maybe just leave them in proper AT&T syntax to avoid risk of error. – Peter Cordes Nov 12 '16 at 5:29
  • It looks like some of the 32-bit sequences assume that the 32-bit values are zero-extended to fill a 64-bit register. That is of course normally free when inlining. – Peter Cordes Nov 12 '16 at 5:34
  • The output was AT&T so yeah I tried to fix everything up by hand (is there a converter out there?). I certainly may have made some mistakes - let me double check them. About the high bits - the way STOKE works is that it captures the actual function input across a variety of test cases and uses that for its search and to validate solutions. Since in practice the high bits of rdi and rsi were always zero, it created solutions that rely on it. So yeah it's not 100℅ apples to with the compiler output that needs to deal with garbage. @PeterCordes – BeeOnRope Nov 12 '16 at 13:47
  • 1
    One safe way to convert is assemble -> disassemble. It's really easy to miss something when converting by hand if you ever get distracted part way through. – Peter Cordes Nov 12 '16 at 18:13
  • @PeterCordes - good point, that's pretty safe way to do it. I don't think STOKE has any Intel output options, so I was stuck with AT&T. – BeeOnRope Nov 14 '16 at 18:38

You can do it like this, by comparing dividing n / d with dividing by (n-1) / d.

#include <stdio.h>

int main(void) {
    unsigned n;
    unsigned d;
    unsigned q1, q2;
    double actual;

    for(n = 1; n < 6; n++) {
        for(d = 1; d < 6; d++) {
            actual = (double)n / d;
            q1 = n / d;
            if(n) {
                q2 = (n - 1) / d;
                if(q1 == q2) {
            printf("%u / %u = %u (%f)\n", n, d, q1, actual);

    return 0;

Program output:

1 / 1 = 1 (1.000000)
1 / 2 = 1 (0.500000)
1 / 3 = 1 (0.333333)
1 / 4 = 1 (0.250000)
1 / 5 = 1 (0.200000)
2 / 1 = 2 (2.000000)
2 / 2 = 1 (1.000000)
2 / 3 = 1 (0.666667)
2 / 4 = 1 (0.500000)
2 / 5 = 1 (0.400000)
3 / 1 = 3 (3.000000)
3 / 2 = 2 (1.500000)
3 / 3 = 1 (1.000000)
3 / 4 = 1 (0.750000)
3 / 5 = 1 (0.600000)
4 / 1 = 4 (4.000000)
4 / 2 = 2 (2.000000)
4 / 3 = 2 (1.333333)
4 / 4 = 1 (1.000000)
4 / 5 = 1 (0.800000)
5 / 1 = 5 (5.000000)
5 / 2 = 3 (2.500000)
5 / 3 = 2 (1.666667)
5 / 4 = 2 (1.250000)
5 / 5 = 1 (1.000000)


I posted an early answer to the original question, which works, but did not consider the efficiency of the algorithm, or that the divisor is always a power of 2. Performing two divisions was needlessly expensive.

I am using MSVC 32-bit compiler on a 64-bit system, so there is no chance that I can provide a best solution for the required target. But it is an interesting question so I have dabbled around to find that the best solution will discover the bit of the 2**n divisor. Using the library function log2 worked but was so slow. Doing my own shift was much better, but still my best C solution is

unsigned roundup(unsigned p, unsigned q)
    return p / q + ((p & (q-1)) != 0);

My inline 32-bit assembler solution is faster, but of course that will not answer the question. I steal some cycles by assuming that eax is returned as the function value.

unsigned roundup(unsigned p, unsigned q)
    __asm {
        mov eax,p
        mov edx,q
        bsr ecx,edx     ; cl = bit number of q
        dec edx         ; q-1
        and edx,eax     ; p & (q-1)
        shr eax,cl      ; divide p by q, a power of 2
        sub edx,1       ; generate a carry when (p & (q-1)) == 0
        adc eax,0       ; add 1 to result when (p & (q-1)) != 0
}                       ; eax returned as function value
  • double can't exactly represent every 64-bit integer, so this can't work for uint64_t inputs (e.g. divisor = 1 will just return a value rounded to the nearest integer that a double can represent, instead of the original. It might work for all dividends with divisors of 2^(64-53) or higher). It's also very clunky to convert unsigned 64-bit integers to/from double, on x86, so it's even slower than if the inputs were signed. Good thing it's possible to do this with shifts/adds while avoiding overflow, since this idea has a lot of downsides. – Peter Cordes Nov 6 '16 at 22:02
  • @PeteCordes I think you misread my answer. The double was only there to show how the integer was correctly rounded up - not suggested as part of the solution. – Weather Vane Nov 6 '16 at 22:50
  • Oh, yes I did, sorry. I was surprised you were suggesting anything as lame as dividing doubles, but I didn't look carefully and the C89-style separate declarations of variables didn't help. – Peter Cordes Nov 7 '16 at 0:05
  • 1
    @WeatherVane - I have validated your solution as correct for all 32-bit inputs, but timing-wise preliminary results indicate that it isn't competitive with the other solutions (taking ~2300 seconds for all 137,000,000,000 iterations vs ~200 seconds for the fastest solutions). – BeeOnRope Nov 7 '16 at 1:36
  • 1
    In MSVC you can use the _BitScanForward/Backward intrinsics to emit bsr or bsf. Not sure about the newer tzcnt instructions - perhaps there are some intrinsics (there seems to be intrinsics for most of the BMI stuff). – BeeOnRope Nov 12 '16 at 5:01

This seems efficient and works for signed if your compiler is using arithmetic right shifts (usually true).

#include <stdio.h>

int main (void)
    for (int i = -20; i <= 20; ++i) {
        printf ("%5d %5d\n", i, ((i - 1) >> 1) + 1);
    return 0;

Use >> 2 to divide by 4, >> 3 to divide by 8, &ct. Efficient lg does the work there.

You can even divide by 1! >> 0

  • depends on implementation-defined behavior for right shifts of negative numbers... – Chris Dodd Nov 4 '16 at 22:11
  • 2
    Yeah I specified unsigned (at least for now) to avoid the whole ball-of-wax surrounding signed right shifts. – BeeOnRope Nov 4 '16 at 22:24
  • 1
    @QuestionC - I implemented your code (for unsigned arguments) like this - does that seem right? It fails for large p (where the MSB is set), because the shift results in a negative number (the MSB is still 1). For example for p=2147483649, q=2 your method gives 3221225473 - which is larger than the dividend! The correct result is 1073741825. – BeeOnRope Nov 7 '16 at 2:03
  • @BeeOnRope The problem there is that int p = 2147483649 is actually int p = -2147483647. If you perform right shift with sign propagation, the result is still correct. If you want to represent that number you need to use wider integer types such as long. For treating it as an unsigned, you would just need to change your int i by an unsigned i and printf formatting string to %u. – Jorge Bellon Nov 7 '16 at 16:39
  • Yes, I understand the issue, but it's not clear the transformation you propose will work either. If you have an answer, post it! – BeeOnRope Nov 7 '16 at 17:14

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