I want to implement *unsigned ^{a} 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 function^{1}:

```
/** 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 == 256`

^{2} 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.

## Benchmark

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 loop^{3}.

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 overlapped^{4}:

```
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`

:

- 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. - 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.
- 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.

# Results

## Overall

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".

## Analysis

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.

### Auto-vectorization

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.

### Latency

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 overhead^{5} (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
```

### Throughput

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.

`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`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 15:30reasonablerestricted set of values that don't work correctly, to be usable! For example, not working when`dividend == 0`

would qualify asreasonablyrestricted, as would when`(p + q - 1) > UINT_MAX`

(even though the latter coversa lotof 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`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