@Stephane and fuz: the final divide-by-9 would be more efficient with a multiplicative inverse, or at least avoid 64-bit operand size for div. But more importantly, doing the horizontal sum inside the loop is very sub-optimal. You just need to sum 8-bit 0..9 integers without overflow (and undo a fixed bias), so do vertical addition for some unroll factor of iterations (up to 255/8), perhaps into multiple accumulators (note that one kortest can check for a bit in either of 2 masks being set, if you have 128-byte alignment to avoid loading from an unmapped page).

In an outer loop, vpsadbw to hsum those bytes into qwords (before or after undoing the +'0' bias which you know got added unroll_factor times) and vpaddq into an outer accumulator vector (which you horizontal sum outside the outer loop).

Also, start/end cleanup could take advantage of masked vmovdqu8 loads, using the misalignment count to generate a bitmask. That can get complicated if the end is in that first chunk, so if that's not expected then just special case that for scalar fallback.

At the very least, use vpsadbw / vpaddq as one non-nested loop to keep it simple. I removed my sleepily-cast upvote because this full hsum all the way to scalar is pretty much an anti-pattern. There are various tricks for widening hsums of byte and word vectors, including pmaddwd against a vector of set1_epi16(1), but even better here psadbw against all-zero. At worst the "naive" way to do this would be to widen to dword or qword vector elements the same way you're widening to word, and still save the vector->scalar for outside the loop.

@PeterCordes Do you have some reference for generating masks from a misalignment count? I actually had the same problem in some AVX2 code yesterday and it was infuriatingly annoying to do. If there is no question on this matter, I'll be glad to write one.

@PeterCordes And RE the other improvements: that's why I wrote about how the method could be improved. Didn't feel like making the example too complicated as it was more about showing the general principle.

My last comment is the simplest way, shortcut the byte->qword widening hsum into one instruction, and sink the qword-vector -> scalar hsum out of the loop. It comes out with as simple a loop structure as your current version, fewer total instructions, and a much tighter loop body. If you're willing to use a trick like a 0x0001000100010001 multiplier for hsumming, vpsadbw is no more complex.

Thanks for commenting on ways to improve this though. I really appreciate this.

Re: misalignment count to mask: It's harder without AVX512 because you need a vector mask, not a bitmask, and you only have masked loads with dword / qword granularity. But see Vectorizing with unaligned buffers: using VMASKMOVPS: generating a mask from a misalignment count? Or not using that insn at all for an unaligned load to take a sliding window from a 0 / -1 buffer.

@PeterCordes That sounds slow-ish, but it probably beats using rep movsb...

With AVX512, for startup you need an integer with bits [63:n] set and [n-1:0] cleared, where n is ptr & 63. So maybe k1 = -1ULL << n with a couple integer instructions including SHLX with the &63 masking implicit in how x86 integer shifts mask the shift count. Plus a kmovq. You use that with a vmovdqu8 load from ptr & -64, i.e. rounded down to the start of the cache line.

At the end of the buffer, there's probably some bithack we can do to turn the first 0 into all-zeros at that point + above. e.g. kmov back to an integer reg for inc to clear the lowest contiguous bits and set the first 0 (the stop point), blsi to isolate that 1 bit, then add -1 to that, letting carry clear that and all the higher bit positions. I didn't check corner cases like the first byte being zero, and I'm not sure I got this right even in general, but it's the kind of this you'd want to cook up to get all-ones up to the place you found the first zero. bitscan + bzhi maybe?

Not sure why you're comparing anything to rep movsb, unless you mean you were trying to implement unaligned memcpy with masked load/store...

@PeterCordes The stop-gap solution I had was clearing a 32 byte buffer, copying the head into the beginning of the buffer with rep movsb and then loading the entire thing. The goal is to load the first few bytes of the buffer (until alignment is reached) into a vector register, zeroing out the remaining bytes. With a mask this would have been pretty easy.

Thanks a lot for your help so far.

This is all about the positional population count routine you helped me with earlier.

@fuz Oh yuck, that sounds nasty. Slow rep movsb startup overhead, and a store-forwarding stall on the vector load when it doesn't forward from just a single store. Yeah I'm pretty sure a mov + and + unaligned load (that doesn't cache-line split) to feed a vpand would be much faster. And since having the earlier elements all zero works fine, you're all set.

Here's the prototype code of what I'm currently working on: github.com/fuzxxl/pospop/blob/master/kernelavx2_amd64.s

incidentally, I really learned to appreciate ARM64 SIMD while writing this. There are just so many convenience instructions in there that AVX is desperately missing.

Which reminds me, for the digit-sum you'd have to use this mask again to zero-mask subtracting '0', or do it with a saturating subtract. Because zero-masking produces 0 not '0'. Or if you defer the subtraction of '0' until after the loop(s), you'd need to popcnt (~mask) to get a correction offset for the number of vector elements that didn't have their expected +'0'

not sure what you mean. Though yeah, I should combine the subtraction with the vpsadbw step.

@fuz Not awake enough to review that right now. I'm curious which things you found AVX2 was missing that ARM64 has. (Clearly AVX2 is missing tons of stuff; AVX512 fills some gaps. But I don't really know ARM64 well enough to miss things from it.)

for example, it has a full and partial horizontal sum instructions for all data widths.

And very useful it has a bitwise mux instruction (like blend, but bitwise)

and the super-wide loads with built in aos/soa shuffles are extremely useful, too.

@fuz I guess if your final bias correction is based on doing total - len * '0' at the very end after the loop, that works if len is the true string length. I had been thinking of doing it as something equivalent to 64 * num_of_vectors which doesn't work when 2 of those vectors were masked. (I guess you could handle first/last masked vectors separately, doing the unbias before hsum for them, and only counting the number of full vectors for bias)

Though yes, I agree it would be better. I just don't feel like adding it in.

another nice feature of ARM64 SIMD is that it has a large array of instructions for generating immediates, both floating point and integer ones. Very useful.

@fuz Ah, that would be nice if it's truly efficient, not like SSE3 haddps and so on that got added but never got ALU support, just microcoded implementations. AVX512 vpternlogd gives us bit-blends, but yeah before that it's the traditional and/andn/or for blending.

ARM AoS shuffle vector load/store instructions are certainly interesting. I guess some (all?) microarchitectures do handle them reasonably efficiently. ARM has quite a few 2-output-register instructions; x86 has so few that existing microarchitectures only ever do 1 per uop, decoding the rare ones like mul to at least 2 uops.

@fuz Sure, nested loops and/or unrolling are more complicated, totally reasonable to just mention that possibility. Very different from changes that reduce complexity or keep it constant, like sinking part of the work out of the loop, and using a peephole optimization for hsum of bytes. There is an example of the nested-loop way on SO, in stackoverflow.com/questions/54541129/…

you're right

Kinda brainfart on my side. I was stuck with my own code where nested loops would be needed.

Have applied this enhancement too. Now I understand what you meant (hopefully).

I've addressed your remaining concerns now. Thanks for the assistance!

@PeterCordes Those microarchitecture manuals I checked indicated that the full-width sums had a latency of 1 cycle. Though I forgot which one that was exactly, have to see again.

And the super-wide loads can load up to 4 registers at a time. That's quite useful.

Hello, did you perform benchmarks on very long strings? I get a 12x speedup with a C version without any SIMD code...

will try

simple:   1000000 digits -> 3,   1.957 msec
naive:    1000000 digits -> 3,   1.689 msec
parallel: 1000000 digits -> 3,   0.184 msec
simd:     1000000 digits -> 3,   0.082 msec

Hm... will have to make the benchmark a bit more sophisticated; 82 µs is too little to be a representative result.

it looks like the compiler optimises away parts of your benchmark code. Let me investigate.

@chqrlie After changing the harness so it runs each function 10000 times, I get the following results for 1000000 digits:

simple    1000000 digits -> 30000,   0.614 msec
naive     1000000 digits -> 30000,   0.516 msec
parallel  1000000 digits -> 30000,   0.056 msec
simd      1000000 digits -> 30000,   0.017 msec

@PeterCordes see above for more benchmark results

See here for the code I ended up using: gist.github.com/fuzxxl/42f4cc547c2eafa2c6ce6a493b4e2a73

@PeterCordes RE “a modern x86 desktop / laptop can usually sustain 8 bytes from RAM per core clock cycle (or more, haven't done the math recently). If data is hot in L2 or even L3 cache, AVX2 or AVX512 can go significantly faster”

I found that on my machine at least, it's difficult to exceed 16 GB/s sustained bandwidth from RAM. This seems a bit low.

@fuz 1M digits takes just under 1MiB of RAM, right on the edge of capacity misses for L2 cache. (Well 48k of spare space, so I guess that's fine for code + other misc data, but an interrupt handler might end up causing a lot of evictions of data from L2 on the next pass if you get unlucky).

yeah

as for the benchmark results, are they what you expect?

@fuz I was talking about "client" chips like dual / quad cores, with their simple short ring bus. Not SKX-derived chips like SKX or Cascade-lake Xeon, which have worse memory latency and thus worse per-core / single-thread memory bandwidth. (Even ring-bus Xeons like Broadwell-E and earlier had worse single-core bandwidth: stackoverflow.com/q/39260020/224132). So yeah, unless you have an Ice Lake machine you're testing on?

@fuz Yeah, I think from L2 cache that's probably about right. SIMD about 3x better than 8-wide SWAR is very reasonable, but I wonder if we'd get all the way to 4x on L2 bandwidth, or if that would require having data hot in L1d cache. Or if max-turbo frequency is too big a factor; Did you mention what hardware you're testing on, and what clock speed is sustained during the SIMD test vs. the others?

It's still the old Skylake box, a Intel(R) Xeon(R) W-2133 CPU @ 3.60GHz

I suppose AVX-512 throttle might play a rôle here

I have not dug deep enough to set up a specific clock speed.

Oh, I forgot about 512-bit vectors shutting down the vector ALUs on port 1. There might be a back-end bottleneck there that I didn't look for, I was only looking at front-end bottlenecks since there are loads and branches. But on 2nd thought could limiting to worse than 2 clocks per iter.

Re: clocks dependent on workload: just isolate one test to a long-running repeat loop and have it do only that for the run-time of the process. Then you can use perf stat to see what average clock speed it ran for the whole process. stackoverflow.com/questions/56852812/… has more details of turbo "license" tables.

BeeOnRope found that only instructions that need the FMA unit are "heavy", so these should all be fine. vpsadbw needs some specialized hardware, but should be separate from FMA unless it uses some kind of multiply-and-shift trick.

good idea

I'll have to get back to my positional popcount code for today (need to get some more work done there). Will perhaps come back later to this one.

the result i have with fuzz gist code (2nd run) :

with clang

and now with gcc

"simple" is faster with clang !

(-Ofast -flto)