I was reading sehe's answer to this question and was surprised to see sehe found using a hand written loop using std::memchr to be over 3 times faster than using std::count (see comments). The code using std::count can be seen in edit 2, but it basically boils down to:

const auto num_lines = std::count(f, l, '\n');


uintmax_t num_lines = 0;
while (f && f != l)
    if ((f = static_cast<const char*>(memchr(f, '\n', l - f))))
        num_lines++, f++;

I would have expected the std::count version to be at least as fast as the std::memchr one - for a similar reason to why using std::copy should be at least as fast as std::memcpy.

I checked my standard library's (libc++) implementation of std::count, and there is no attempt to optimise for char input types (ditto for std::find).

Why is this? Could the implementations not dispatch to std::memchr if provided with char* iterators, and a char value?

  • 6
    It's open source. Submit a patch :-).
    – rici
    Apr 19, 2017 at 0:24
  • @rici, haha ... however, in reality submitting a patch is often the easiest part. Getting it applied is the real challenge. For example, I've submitted a libstdc++ patch which specializes std::find() for simple random access cases to just call __builtin_memchr(). This was 2 years ago - and just submitting it didn't spark any interest. Jan 9, 2021 at 15:50

1 Answer 1


Using an actual function call to memchr is only a win if the average distance between matches is not small.

Especially for count, calling memchr could be a lot slower if you were counting t characters when they appear on average every 2 or maybe every 4. (e.g. with DNA base-pairs using an alphabet of ACGT).

I'd be skeptical of using a memchr loop as the default implementation for std::count over char arrays. There are more likely other ways to tweak the source so it compiles to better asm.

For find it would make more sense, even though it does potentially increase the overhead significantly vs. a simple byte-at-a-time loop if there's a hit in the first couple bytes.

You could also look at this as a compiler missed-optimization. If compilers made better code for the loops in std::count and std::find, there'd be less to gain from calling hand-written asm library functions.

gcc and clang never auto-vectorize loops when the trip-count isn't known before entering the loop. (i.e. they don't do search loops, which is a major missed optimization for element sizes as small as bytes). ICC doesn't have this limitation, and can vectorize search loops. I haven't looked at how it does with libc++'s std::count or find, though.

std::count has to check every element, so it should auto-vectorize. But if gcc or clang don't even with -O3, then that's unfortunate. It should vectorize very well on x86 with pcmpeqb (packed compare bytes), and then paddb the 0/-1 compare results. (every 255 iterations at least, psadbw against zero to horizontally sum the byte elements).

Library function call overhead is at least an indirect call with a function pointer from memory (which can cache miss). On Linux with dynamic linking there's usually an extra jmp through the PLT as well (unless you compiled with -fno-plt). memchr is easier to optimize with low startup overhead than strchr, because you can quickly check whether a 16B vector load can go past the end (vs. aligning the pointer for strchr or strlen to avoid crossing a page or cache-line boundary)

If calling memchr is the best way to implement something in asm, then in theory that's what the compiler should emit. gcc/clang already optimize large copy loops to calls to libc memcpy, depending on target options (-march=). e.g. when the copy is large enough that the libc version may decide to use NT stores on x86.

  • 1
    @BeeOnRope: hmm, good point. That part of my answer wasn't thoroughly thought out. With memchr, touching a 2nd possibly-not-needed cache line is still part of the same object. Unlike strlen, the calling code for memchr might well also load from memory after the match. I'm not sure about optimal strlen startup strategy. I guess aligned vector load that includes the start of the string is good, then pcmpeqb / pmovmskb / not / bsr and compare against p&-16 (the offset of the string start relative to 16B alignment.) Nov 15, 2017 at 19:39
  • 1
    Huh, based on my reading of the C11 standard, you can't actually make the optimization for memchr that you suggest[1]: even if the user passes in an n > 16, it seems that maybe you cannot read 16 bytes if it were to cross a page since the element could be found before (i.e., the user can pass a too-long length if the function will never access the out-of-bounds region because it found the element). I'm not sure though, so I asked here. [1] I'm assuming you are suggesting that it's safe to read the entire region implied by the user-passed n.
    – BeeOnRope
    Nov 15, 2017 at 19:42
  • 1
    @BeeOnRope: You don't like the idea of an aligned vector load that includes the start of the buffer? You can BSF it to ignore matches from before the start of the bytes you're supposed to be looking at. That avoids even crossing a cache-line. Not a big deal, but it avoids any branching. Hmm, I guess it's not as easy if the vector load includes data from before and after the region you're supposed to be looking at. I guess a variable-count shift of the pmovmskb result could help... But maybe branching is easier. Nov 15, 2017 at 20:05
  • 1
    I like the idea too, but if you ignore the "problem" with accessing into the next cache line, it seems strictly worse, because you (a) examine fewer bytes in the first load which is bad by itself (less work done) and it also implies (b) worse quantization of the branching behavior (c) slightly more work to mask out/check that you didn't match before the buffer. It's (b) that can bite you the most: if most of your matches are quite short it's really good to capture all matches < 16 in the first load & branch.
    – BeeOnRope
    Nov 15, 2017 at 20:12
  • 1
    Of course, you can't ignore the cost of going into the next cache line, so maybe B is better after all. It's hard to compare them in a general way (certainly for specific applications one may be obviously better than the other). Also you avoid the need for the special case near the end of the page if you do aligned loads only.
    – BeeOnRope
    Nov 15, 2017 at 20:13

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