70

I have observed on a system that std::fill on a large std::vector<int> was significantly and consistently slower when setting a constant value 0 compared to a constant value 1 or a dynamic value:

5.8 GiB/s vs 7.5 GiB/s

However, the results are different for smaller data sizes, where fill(0) is faster:

performance for single thread at different data sizes

With more than one thread, at 4 GiB data size, fill(1) shows a higher slope, but reaches a much lower peak than fill(0) (51 GiB/s vs 90 GiB/s):

performance for various thread counts at large data size

This raises the secondary question, why the peak bandwidth of fill(1) is so much lower.

The test system for this was a dual socket Intel Xeon CPU E5-2680 v3 set at 2.5 GHz (via /sys/cpufreq) with 8x16 GiB DDR4-2133. I tested with GCC 6.1.0 (-O3) and Intel compiler 17.0.1 (-fast), both get identical results. GOMP_CPU_AFFINITY=0,12,1,13,2,14,3,15,4,16,5,17,6,18,7,19,8,20,9,21,10,22,11,23 was set. Strem/add/24 threads gets 85 GiB/s on the system.

I was able to reproduce this effect on a different Haswell dual socket server system, but not any other architecture. For example on Sandy Bridge EP, memory performance is identical, while in cache fill(0) is much faster.

Here is the code to reproduce:

#include <algorithm>
#include <cstdlib>
#include <iostream>
#include <omp.h>
#include <vector>

using value = int;
using vector = std::vector<value>;

constexpr size_t write_size = 8ll * 1024 * 1024 * 1024;
constexpr size_t max_data_size = 4ll * 1024 * 1024 * 1024;

void __attribute__((noinline)) fill0(vector& v) {
    std::fill(v.begin(), v.end(), 0);
}

void __attribute__((noinline)) fill1(vector& v) {
    std::fill(v.begin(), v.end(), 1);
}

void bench(size_t data_size, int nthreads) {
#pragma omp parallel num_threads(nthreads)
    {
        vector v(data_size / (sizeof(value) * nthreads));
        auto repeat = write_size / data_size;
#pragma omp barrier
        auto t0 = omp_get_wtime();
        for (auto r = 0; r < repeat; r++)
            fill0(v);
#pragma omp barrier
        auto t1 = omp_get_wtime();
        for (auto r = 0; r < repeat; r++)
            fill1(v);
#pragma omp barrier
        auto t2 = omp_get_wtime();
#pragma omp master
        std::cout << data_size << ", " << nthreads << ", " << write_size / (t1 - t0) << ", "
                  << write_size / (t2 - t1) << "\n";
    }
}

int main(int argc, const char* argv[]) {
    std::cout << "size,nthreads,fill0,fill1\n";
    for (size_t bytes = 1024; bytes <= max_data_size; bytes *= 2) {
        bench(bytes, 1);
    }
    for (size_t bytes = 1024; bytes <= max_data_size; bytes *= 2) {
        bench(bytes, omp_get_max_threads());
    }
    for (int nthreads = 1; nthreads <= omp_get_max_threads(); nthreads++) {
        bench(max_data_size, nthreads);
    }
}

Presented results compiled with g++ fillbench.cpp -O3 -o fillbench_gcc -fopenmp.

12
  • What is the data size when you are comparing the number of threads? – Gavin Portwood Mar 3 '17 at 22:26
  • 1
    @GavinPortwood 4 GiB, so in memory, not cache. – Zulan Mar 3 '17 at 23:41
  • Then there must be something wrong with the second plot, the weak-scaling. I can't imagine it would take more than two or so threads to saturate memory bandwidth for a loop with minimal intermediate operations. In fact, you haven't identified the threads count where the bandwidth saturates even at 24 threads. Can you show that it does level out at some finite thread count? – Gavin Portwood Mar 4 '17 at 18:19
  • 2
    I suspect the anomalous scaling in your original experiment (on the second socket) is related to non-homogenous memory allocation and the resulting QPI communication. That can be verified with Intel's "uncore" PMUs (i think) – Gavin Portwood Mar 5 '17 at 22:49
  • 1
    FWIW - you found the code difference in your answer and I think Peter Cordes has the answer below: that rep stosb is using a non-RFO protocol which halves the number of transactions needed to do a fill. The rest of the behavior mostly falls out of that. There is one other disadvantage the fill(1) code has: it can't use 256-bit AVX stores because you aren't specifying -march=haswell or whatever, so it has to fall back to 128-bit code. fill(0) which calls memset get the advantage of libc dispatching that calls the AVX version on your platform. – BeeOnRope Jul 10 '17 at 19:47
43
+100

From your question + the compiler-generated asm from your answer:

  • fill(0) is an ERMSB rep stosb which will use 256b stores in an optimized microcoded loop. (Works best if the buffer is aligned, probably to at least 32B or maybe 64B).
  • fill(1) is a simple 128-bit movaps vector store loop. Only one store can execute per core clock cycle regardless of width, up to 256b AVX. So 128b stores can only fill half of Haswell's L1D cache write bandwidth. This is why fill(0) is about 2x as fast for buffers up to ~32kiB. Compile with -march=haswell or -march=native to fix that.

    Haswell can just barely keep up with the loop overhead, but it can still run 1 store per clock even though it's not unrolled at all. But with 4 fused-domain uops per clock, that's a lot of filler taking up space in the out-of-order window. Some unrolling would maybe let TLB misses start resolving farther ahead of where stores are happening, since there is more throughput for store-address uops than for store-data. Unrolling might help make up the rest of the difference between ERMSB and this vector loop for buffers that fit in L1D. (A comment on the question says that -march=native only helped fill(1) for L1.)

Note that rep movsd (which could be used to implement fill(1) for int elements) will probably perform the same as rep stosb on Haswell. Although only the official documentation only guarantees that ERMSB gives fast rep stosb (but not rep stosd), actual CPUs that support ERMSB use similarly efficient microcode for rep stosd. There is some doubt about IvyBridge, where maybe only b is fast. See the @BeeOnRope's excellent ERMSB answer for updates on this.

gcc has some x86 tuning options for string ops (like -mstringop-strategy=alg and -mmemset-strategy=strategy), but IDK if any of them will get it to actually emit rep movsd for fill(1). Probably not, since I assume the code starts out as a loop, rather than a memset.


With more than one thread, at 4 GiB data size, fill(1) shows a higher slope, but reaches a much lower peak than fill(0) (51 GiB/s vs 90 GiB/s):

A normal movaps store to a cold cache line triggers a Read For Ownership (RFO). A lot of real DRAM bandwidth is spent on reading cache lines from memory when movaps writes the first 16 bytes. ERMSB stores use a no-RFO protocol for its stores, so the memory controllers are only writing. (Except for miscellaneous reads, like page tables if any page-walks miss even in L3 cache, and maybe some load misses in interrupt handlers or whatever).

@BeeOnRope explains in comments that the difference between regular RFO stores and the RFO-avoiding protocol used by ERMSB has downsides for some ranges of buffer sizes on server CPUs where there's high latency in the uncore/L3 cache. See also the linked ERMSB answer for more about RFO vs non-RFO, and the high latency of the uncore (L3/memory) in many-core Intel CPUs being a problem for single-core bandwidth.


movntps (_mm_stream_ps()) stores are weakly-ordered, so they can bypass the cache and go straight to memory a whole cache-line at a time without ever reading the cache line into L1D. movntps avoids RFOs, like rep stos does. (rep stos stores can reorder with each other, but not outside the boundaries of the instruction.)

Your movntps results in your updated answer are surprising.
For a single thread with large buffers, your results are movnt >> regular RFO > ERMSB. So that's really weird that the two non-RFO methods are on opposite sides of the plain old stores, and that ERMSB is so far from optimal. I don't currently have an explanation for that. (edits welcome with an explanation + good evidence).

As we expected, movnt allows multiple threads to achieve high aggregate store bandwidth, like ERMSB. movnt always goes straight into line-fill buffers and then memory, so it is much slower for buffer sizes that fit in cache. One 128b vector per clock is enough to easily saturate a single core's no-RFO bandwidth to DRAM. Probably vmovntps ymm (256b) is only a measurable advantage over vmovntps xmm (128b) when storing the results of a CPU-bound AVX 256b-vectorized computation (i.e. only when it saves the trouble of unpacking to 128b).

movnti bandwidth is low because storing in 4B chunks bottlenecks on 1 store uop per clock adding data to the line fill buffers, not on sending those line-full buffers to DRAM (until you have enough threads to saturate memory bandwidth).


@osgx posted some interesting links in comments:

See also other stuff in the tag wiki.

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  • 3
    The behavior described above of rep movsb versus an explicit loop of movaps on a single core across various buffer sizes is pretty consistent with what we have seen before on server cores. As you point out, the competition is between a non-RFO protocol and the RFO protocol. The former uses less bandwidth between all cache levels, but especially on server chips has a long latency handoff all the way to memory. Since a single core is generally concurrency limited, the latency matters, and the non-RFO protocol wins, which is what you see in the region beyond the 30 MB L3. – BeeOnRope Jul 10 '17 at 19:37
  • 3
    ... in the middle of the graph that fits in L3, however, the long server uncore to memory handoff apparently doesn't come into play, so the read reduction offered by non-RFO wins (but actually it's interesting to compare this to NT stores: would they show the same behavior, or is rep stosb able to stop the write at L3 rather than go all the way to memory)? FWIW, the situation for rep stosb for fill is relatively better, empirically, than for rep movsb for memcpy. Possibly because the former has a 2:1 advantage in traffic versus 3:2 for the latter. – BeeOnRope Jul 10 '17 at 19:42
  • 1
    I tried movntps and if I'm using it correctly, it shows the memory-bandwidth among all data sizes - so it doesn't benefit from caches at all. But for a single thread, that is twice the memory bandwidth of movaps, and for 24 threads it's slightly higher than rep stosb. – Zulan Jul 10 '17 at 22:45
  • 1
    @Noah: it should be obvious that after any store, the cache line will definitely not still be hot in some other core's private cache. There's no shared bus for a core to broadcast the new data on (instead it's directory-based coherence with L3 tags or similar structure as the directory). The storing core needs exclusive ownership before updating its own L1d, by invalidating other copies, and has to wait for an acknowledgement of the invalidation. It has to maintain coherence if 2 cores triy to rep movsb to the same destination at once. – Peter Cordes Jan 12 at 2:46
  • 1
    @Noah: Re: full-line ZMM stores avoiding an RFO: good question, I don't know but it's 100% possible. Internally it could work exactly like a full-line store from rep stos / rep movs. It's something I've wondered, but I forget if I ever found an answer, or what it was for different microarchitectures. (It's an optimization that can of course be added to a later design if SKX or KNL didn't have it.) There might be some reason it's only worth it for a long stream of stores, like somehow taking longer to do something, maybe delaying later stores and stalling the store buffer. – Peter Cordes Jan 12 at 2:50
29

I'll share my preliminary findings, in the hope to encourage more detailed answers. I just felt this would be too much as part of the question itself.

The compiler optimizes fill(0) to a internal memset. It cannot do the same for fill(1), since memset only works on bytes.

Specifically, both glibcs __memset_avx2 and __intel_avx_rep_memset are implemented with a single hot instruction:

rep    stos %al,%es:(%rdi)

Wheres the manual loop compiles down to an actual 128-bit instruction:

add    $0x1,%rax                                                                                                       
add    $0x10,%rdx                                                                                                      
movaps %xmm0,-0x10(%rdx)                                                                                               
cmp    %rax,%r8                                                                                                        
ja     400f41

Interestingly while there is a template/header optimization to implement std::fill via memset for byte types, but in this case it is a compiler optimization to transform the actual loop. Strangely,for a std::vector<char>, gcc begins to optimize also fill(1). The Intel compiler does not, despite the memset template specification.

Since this happens only when the code is actually working in memory rather than cache, makes it appears the Haswell-EP architecture fails to efficiently consolidate the single byte writes.

I would appreciate any further insight into the issue and the related micro-architecture details. In particular it is unclear to me why this behaves so differently for four or more threads and why memset is so much faster in cache.

Update:

Here is a result in comparison with

  • fill(1) that uses -march=native (avx2 vmovdq %ymm0) - it works better in L1, but similar to the movaps %xmm0 version for other memory levels.
  • Variants of 32, 128 and 256 bit non-temporal stores. They perform consistently with the same performance regardless of the data size. All outperform the other variants in memory, especially for small numbers of threads. 128 bit and 256 bit perform exactly similar, for low numbers of threads 32 bit performs significantly worse.

For <= 6 thread, vmovnt has a 2x advantage over rep stos when operating in memory.

Single threaded bandwidth:

single threaded performance by data size

Aggregate bandwidth in memory:

memory performance by thread count

Here is the code used for the additional tests with their respective hot-loops:

void __attribute__ ((noinline)) fill1(vector& v) {
    std::fill(v.begin(), v.end(), 1);
}
┌─→add    $0x1,%rax
│  vmovdq %ymm0,(%rdx)
│  add    $0x20,%rdx
│  cmp    %rdi,%rax
└──jb     e0


void __attribute__ ((noinline)) fill1_nt_si32(vector& v) {
    for (auto& elem : v) {
       _mm_stream_si32(&elem, 1);
    }
}
┌─→movnti %ecx,(%rax)
│  add    $0x4,%rax
│  cmp    %rdx,%rax
└──jne    18


void __attribute__ ((noinline)) fill1_nt_si128(vector& v) {
    assert((long)v.data() % 32 == 0); // alignment
    const __m128i buf = _mm_set1_epi32(1);
    size_t i;
    int* data;
    int* end4 = &v[v.size() - (v.size() % 4)];
    int* end = &v[v.size()];
    for (data = v.data(); data < end4; data += 4) {
        _mm_stream_si128((__m128i*)data, buf);
    }
    for (; data < end; data++) {
        *data = 1;
    }
}
┌─→vmovnt %xmm0,(%rdx)
│  add    $0x10,%rdx
│  cmp    %rcx,%rdx
└──jb     40


void __attribute__ ((noinline)) fill1_nt_si256(vector& v) {
    assert((long)v.data() % 32 == 0); // alignment
    const __m256i buf = _mm256_set1_epi32(1);
    size_t i;
    int* data;
    int* end8 = &v[v.size() - (v.size() % 8)];
    int* end = &v[v.size()];
    for (data = v.data(); data < end8; data += 8) {
        _mm256_stream_si256((__m256i*)data, buf);
    }
    for (; data < end; data++) {
        *data = 1;
    }
}
┌─→vmovnt %ymm0,(%rdx)
│  add    $0x20,%rdx
│  cmp    %rcx,%rdx
└──jb     40

Note: I had to do manual pointer calculation in order to get the loops so compact. Otherwise it would do vector indexing within the loop, probably due to the intrinsic confusing the optimizer.

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  • 3
    rep stos is microcoded in most CPUs (find "REP STOS" and its "Fused µOps column" in agner.org/optimize/instruction_tables.pdf tables of Haswell around page 189). Also check CPUID EAX=7, EBX, bit 9 "erms Enhanced REP MOVSB/STOSB" (grep erms /proc/cpuinfo) which is flag of additionally optimized microcode for rep stos since Nehalem: intel.com/content/dam/www/public/us/en/documents/manuals/… "2.5.6 REP String Enhancement" & 3.7.6 ERMSB. You should compare PMU counters to get some information about implementation. – osgx Mar 12 '17 at 11:46
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    Also, check stackoverflow.com/a/26256216 for different optimized memcpy/set (and limits of CPU) and try to ask specific questions on software.intel.com/en-us/forums to get some attention from software.intel.com/en-us/user/545611. The actual microcode of Haswell may have some problems in NUMA case with coherency protocol, when some of the memory is allocated in memory of different numa node (socket) or memory just can be allocated on other node, so multi-socket coherency protocol is active when cachelines are allocated. Also check errata of Haswell about its microcode. – osgx Mar 12 '17 at 11:55
  • 1
    Welcome to the NUMA world. vector is allocated with malloc, used correctly with first touch placing, but its deallocation with free will just mark memory as unused, without returning memory back to OS - there will be no next touch for next iteration (some outdated info on malloc in stackoverflow.com/questions/2215259 and some in stackoverflow.com/a/42281428 "Since 2007 (glibc 2.9 and newer)"). With glibc do call malloc_trim() between bench and the freed memory will be marked as free to OS and retouched for NUMA. Stack is allocated by main thread... – osgx Mar 21 '17 at 13:26
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    Zulan, no, software will not disable cache coherency between sockets (second socket should not be booted/QPI disabled). Your E5-2680 v3 is 12 core haswell in MCC (Medium Core Count) die (anandtech.com/show/8679/…) and there is cache snooping messages on access: frankdenneman.nl/2016/07/11/…. They are sent both in the ring of local socket and over QPI to next socket. Some versions of Xeons may use "directory" to limit snooping message storms in memory-bound tasks like this one. – osgx Mar 21 '17 at 20:30
  • 1
    You can also check Intel MLC - software.intel.com/en-us/articles/intelr-memory-latency-checker for measuring maximal bandwidth of the tested systems as mlc --bandwidth_matrix and mlc --peak_bandwidth. Also - paper about your Haswell and its cache coherency tu-dresden.de/zih/forschung/ressourcen/dateien/… – osgx Mar 21 '17 at 20:41

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