38

I've tried to compile this program on an x64 computer:

#include <cstring>

int main(int argc, char* argv[])
{
  return ::std::strcmp(argv[0],
    "really really really really really really really really really"
    "really really really really really really really really really"
    "really really really really really really really really really"
    "really really really really really really really really really"
    "really really really really really really really really really"
    "really really really really really really really really really"
    "really really really really really really really really really"
    "really really really really really really really really really"
    "really really really really really really really long string"
  );
}

I compiled it like this:

g++ -std=c++11 -msse2 -O3 -g a.cpp -o a

But the resulting disassembly is like this:

   0x0000000000400480 <+0>:     mov    (%rsi),%rsi
   0x0000000000400483 <+3>:     mov    $0x400628,%edi
   0x0000000000400488 <+8>:     mov    $0x22d,%ecx
   0x000000000040048d <+13>:    repz cmpsb %es:(%rdi),%ds:(%rsi)
   0x000000000040048f <+15>:    seta   %al
   0x0000000000400492 <+18>:    setb   %dl
   0x0000000000400495 <+21>:    sub    %edx,%eax
   0x0000000000400497 <+23>:    movsbl %al,%eax
   0x000000000040049a <+26>:    retq 

Why is no SIMD used? I suppose it could be to compare, say, 16 chars at once. Should I write my own SIMD strcmp, or is it a nonsensical idea for some reason?

12
  • 6
    TBH who cares? Use std::string::operator==. Checking string lengths up front is a very effective optimization. Also: which compiler, which settings?
    – MSalters
    Oct 27 '14 at 11:03
  • 2
    Doesn't the null terminators make this difficult? Because the compiler can't simply assume that there's 16 bytes worth of characters to be read. There might be 1. Oct 27 '14 at 11:08
  • 4
    That's why the O(1) length test of std::string is so good. Not only do you know whether there's a point to comparing contents, when the lengths are equal you also know how much content you need to compare. And therefore I don't believe the claim that strcmp "pops up for performance reasons". (GCC's has an outdated std::string implementation, that could also matter)
    – MSalters
    Oct 27 '14 at 11:11
  • 12
    strcmp compare 2 null terminated C strings. So if you want to use SIMD you need to find the length first to ensure you didn't get out of the range. But to find the length you need to compare every char with NULL in both strings. So while you will be comparing every char in your C strings with NULL, strcmp will already return a result before you will load your SIMD instructions. Oct 27 '14 at 11:11
  • 3
    @JustAnotherCurious actually, std::string stores the length of the string upon any changes made. So if std::string is used everywhere, it may be faster for comparison. Oct 27 '14 at 11:13
43

In a SSE2 implementation, how should the compiler make sure that no memory accesses happen over the end of the string? It has to know the length first and this requires scanning the string for the terminating zero byte.

If you scan for the length of the string you have already accomplished most of the work of a strcmp function. Therefore there is no benefit to use SSE2.

However, Intel added instructions for string handling in the SSE4.2 instruction set. These handle the terminating zero byte problem. For a nice write-up on them read this blog-post:

http://www.strchr.com/strcmp_and_strlen_using_sse_4.2

13
  • 5
    I've tried immediately to compile with -msse4.2 and the same machine code is generated. Good to know I wasn't completely wrong, that it could be done, though. Oct 27 '14 at 11:32
  • 5
    It doesn't have to ensure that no memory accesses happen over the end of the string. It only has to ensure that no memory accesses happen on pages that the string is not at least partly on, and that's much easier.
    – harold
    Oct 27 '14 at 12:01
  • 2
    @Zboson: And how do you know what you're comparing is not heap-allocated, and at the very end of the page, making any access beyond the '\0' an immediate pagefault? How do you know the system is, and ever will be, using page-based memory protection in the first place?
    – DevSolar
    Oct 27 '14 at 14:37
  • 2
    @DevSolar you can safely make those assumptions, and you can't go onto the next page with aligned reads.
    – harold
    Oct 27 '14 at 17:17
  • 2
    This is a bogus argument. Optimized C library strcmp can use SIMD. It's harder to do safely with two pointers that could be misaligned relative to each other, though. See Is it safe to read past the end of a buffer within the same page on x86 and x64?. Answer: yes in ASM, dicey in C because of UB for reading outside objects. The compiler is emitting asm directly so it knows what is safe. Sep 28 '17 at 14:27
18

GCC in this case is using a builtin strcmp. If you want it to use the version from glibc use -fno-builtin. But you should not assume that GCC's builtin version of strcmp or glibc's implementaiton of strcmp are efficient. I know from experience that GCC's builtin memcpy and glibc's memcpy are not as efficient as they could be.

I suggest you look at Agner Fog's asmlib. He has optimized several of the standard library functions in assembly. See the file strcmp64.asm. This has two version: a generic version for CPUs without SSE4.2 and a version for CPUs with SSE4.2. Here is the main loop for the SSE4.2 version

compareloop:
        add     rax, 16                ; increment offset
        movdqu  xmm1, [rs1+rax]        ; read 16 bytes of string 1
        pcmpistri xmm1, [rs2+rax], 00011000B ; unsigned bytes, equal each, invert. returns index in ecx
        jnbe    compareloop            ; jump if not carry flag and not zero flag

For the generic version he writes

This is a very simple solution. There is not much gained by using SSE2 or anything complicated

Here is the main loop of the generic version:

_compareloop:
        mov     al, [ss1]
        cmp     al, [ss2]
        jne     _notequal
        test    al, al
        jz      _equal
        inc     ss1
        inc     ss2
        jmp     _compareloop 

I would compare the performance of GCC's builtin strcmp , GLIBC's strcmp and the asmlib strcmp. You should look at the disassembly to make sure that you get the builtin code. For example GCC's memcpy does not use the builtin version from sizes larger than 8192.

Edit: In regards to the the string length, Agner's SSE4.2 version reads up to 15 bytes beyond the of the string. He argues this is rarely a problem since nothing is written. It's not a problem for stack allocated arrays. For statically allocated arrays it could be a problem for memory page boundaries. To get around this he adds 16 bytes to the .bss section after the .data section. For more details see the section 1.7 String instructions and safety precautions in the manaul of the asmlib.

5
  • Comparing 16 bytes at a time is a real win, even if you have to check for both null and the actual string. The beauty of it is that once you have made the code you can use it "forever" and benefit in new programs.
    – Surt
    Oct 27 '14 at 12:14
  • 1
    @Surt, can you say a little more of what you mean? Are you saying that the generic version can be done better or just that the SSE4.2 version is the right idea?
    – Z boson
    Oct 27 '14 at 12:20
  • I would think the non-SSE loop could be improved by subtracting one pointer from the other before the start and then using an indexed addressing mode, or does that optimization not help on newer processors?
    – supercat
    Oct 27 '14 at 22:12
  • @supercat, I don't know. From theory one would have to look at the latency and throughput and how many cycles it takes. For example if one port always needs two cycles and the rest one then adding another instruction to another port might not make a difference. This could be checked with IACA. But I have never profiled strcmp so I only know what I read.
    – Z boson
    Oct 28 '14 at 8:27
  • A byte-at-a-time loop can't be optimal! glibc's sse2 strcmp checks for page-crossing and then uses unaligned loads. It is of course fully safe, never reading from a page that doesn't contain any part of either string, because anything else would be unacceptable in a standard library. Having even less overhead is certainly possible if you can arrange to skip those checks, but it looks pretty reasonable. It uses pcmpeqb and pminub to check for non-match or 0 (end of string). Sep 28 '17 at 15:36
7

When the standard library for C was designed, the implementations of string.h methods that were most efficient when dealing with large amounts of data would be reasonably efficient for small amounts, and vice versa. While there may be some string-comparison scenarios were sophisticated use of SIMD instructions could yield better performance than a "naive implementation", in many real-world scenarios the strings being compared will differ in the first few characters. In such situations, the naive implementation may yield a result in less time than a "more sophisticated" approach would spend deciding how the comparison should be performed. Note that even if SIMD code is able to process 16 bytes at a time and stop when a mismatch or end-of-string condition is detected, it would still have to do additional work equivalent to using the naive approach on the last 16 characters scanned. If many groups of 16 bytes match, being able to scan through them quickly may benefit performance. But in cases where the first 16 bytes don't match, it would be more efficient to just start with the character-by-character comparison.

Incidentally, another potential advantage of the "naive" approach is that it would be possible to define it inline as part of the header (or a compiler might regard itself as having special "knowledge" about it). Consider:

int strcmp(char *p1, char *p2)
{
  int idx=0,t1,t2;
  do
  {
    t1=*p1; t2=*p2;
    if (t1 != t2)
    {
      if (t1 > t2) return 1;
      return -1;
    }
    if (!t1)
      return 0;
    p1++; p2++;
  } while(1);
}
...invoked as:
if (strcmp(p1,p2) > 0) action1();
if (strcmp(p3,p4) != 0) action2();

While the method would be a little big to be in-lined, in-lining could in the first case allow a compiler to eliminate the code to check whether the returned value was greater than zero, and in the second eliminate the code which checked whether t1 was greater than t2. Such optimization would not be possible if the method were dispatched via indirect jump.

5
  • Although what you say sounds reasonable you don't provide any evidence that " But in cases where the first 16 bytes don't match, it would be more efficient to just start with the character-by-character comparison." In fact when I look at the preamble and epilogue of the main loops of the SSE4.2 and the generic function in the asmlib they are almost identical. I would not be surprised if the SSE4.2 version is never slower than the generic version even for arrays less than or equal to 16 bytes.
    – Z boson
    Oct 28 '14 at 8:20
  • @Zboson: I wasn't aware of the SSE 4.2 additions; string-compare code could benefit from earlier SSE functions but not as greatly. If library code were being compiled for 4.2 only, I could see the string functions as a potential "unconditional win", but if code had to check for their availability before executing them such a check would be a 100% loss on processors which don't support them (which I understand are still quite numerous) and even on processors which do might not come out ahead when strings differ in the first character.
    – supercat
    Oct 28 '14 at 15:21
  • Using a CPU dispatcher the strcmp function only has to check the CPUID the first time it's called. Every call after that will jump directly to the SSE4.2 or the generic version. This is how the asmlib does it. So there is only an overhead on the first call. You could also call an init function for a library with all function you are replacing which makes all the function pointers point to the appropriate version.
    – Z boson
    Oct 28 '14 at 19:00
  • @Zboson: A CPU dispatcher would add an indirect jump; I know that's a much smaller penalty than it used to be, but I don't know how small. Further, strcmp() is small enough that an aggressive in-lining optimizer might possibly tackle it (if a header were defined such that it could do so). See edit above.
    – supercat
    Oct 28 '14 at 19:59
  • That's a good point. Actually, GCC already inlines strcmp in the OPs example. Like I said in my answer, it would be interesting to profile and compare the inline, glibc, and asmlib methods. I'm not going to do it anytime soon though...
    – Z boson
    Oct 28 '14 at 20:07
3

I suspect there's simply no point in SIMD versions of library functions with very little computation. I imagine that functions like strcmp, memcpy and similiar are actually limited by the memory bandwidth and not the CPU speed.

2
  • 2
    It's only limited by memory bandwidth if the array does not fit in the cache. You could use memcpy or strcmp in a tight inner loop not limited by memory bandwidth.
    – Z boson
    Oct 27 '14 at 13:01
  • www-ssl.intel.com/content/www/us/en/processors/… (The optimization manual) spends a fair bit of time on memcpy implementation techniques, and performance on Ivy Bridge and later CPUs where REP STOSB triggers a microcoded high-performance memset, but has higher startup overhead than a 128b or 256b wide SSE/AVX implementation. See section 3.7.5, or search for memcpy. There's a CPUID feature bit for ERMSB (Enhanced Rep Movsb and StosB). May 1 '15 at 6:23
3

It depends on your implementation. On MacOS X, functions like memcpy, memmove and memset have implementations that are optimised depending on the hardware you are using (the same call will execute different code depending on the processor, set up at boot time); these implementations use SIMD and for big amounts (megabytes) use some rather fancy tricks to optimise cache usage. Nothing for strcpy and strcmp as far as I know.

Convincing the C++ standard library to use that kind of code is difficult.

2
  • 4
    Can you show some optimized mac disassembly for strcmp? Oct 27 '14 at 11:27
  • Yeah, according to Agner Fog when he looked into this the MacOS X versions were pretty good but the Linux and Windows versions were inefficient. So probably the MacOS X assembly is interesting.
    – Z boson
    Oct 27 '14 at 12:35
3

Making an SSE2 version of strcmp was an interesting challenge for me.
I don't really like compiler intrinsic functions because of code bloat, so I decided to choose auto-vectorization approach. My approach is based on templates and approximates SIMD register as an array of words of different sizes.

I tried to write an auto-vectorizing implementation and test it with GCC and MSVC++ compilers.

So, what I learned is:
1. GCC's auto-vectorizer is good (awesome?)
2. MSVC's auto-vectorizer is worse than GCC's (doesn't vectorize my packing function)
3. All compilers declined to generate PMOVMSKB instruction, it is really sad

Results:
Version compiled by online-GCC gains ~40% with SSE2 auto-vectorization. On my Windows machine with Bulldozer-architecture CPU auto-vectorized code is faster than online compiler's and results match the native implementation of strcmp. But the best thing about the idea is that the same code can be compiled for any SIMD instruction set, at least on ARM & X86.

Note:
If anyone will find a way to make compiler to generate PMOVMSKB instruction then overall performance should get a significant boost.

Command-line options for GCC: -std=c++11 -O2 -m64 -mfpmath=sse -march=native -ftree-vectorize -msse2 -march=native -Wall -Wextra

Links:
Source code compiled by Coliru online compiler
Assembly + Source code (Compiler Explorer)

@PeterCordes, thanks for the help.

21
  • You can and should make the godbolt link go directly to your code on godbolt, instead of expecting people to copy/paste for you. SSE2 is portable to any modern x86. It's only a mess if you write messy code. Aug 1 '16 at 23:01
  • @PeterCordes I've tried to make a short link to my code, but I just couldn't make one. I've always ended up with a 200-symbol link that would take half of the post, and Google's URL shortener didn't help either, it just doesn't recognize resulting URL as a valid.
    – Roman
    Aug 2 '16 at 5:52
  • Only use godbolt short-links for comments, because full links can't rot. When there's no relevant char-limit, just make full links that don't display in the text of your post. (godbolt shortlinks already use goo.gl internally. Oh that's weird, I think the shortlink button might be broken. I hardly ever use it.) Aug 2 '16 at 14:15
  • It doesn't look like g++ actually auto-vectorized your code at -O3 (which includes -ftree-vectorize). I only see a pcmpeqd, which it uses to generate a vector of all-ones for storing to the stack. I see a lot of byte-at-a-time copying and comparing, and testing bitfields. If that's faster than the builtin strcmp, I wonder just how bad it is... Aug 2 '16 at 14:23
  • @PeterCordes Yep, gcc starts to mess up the code badly at -O3.
    – Roman
    Aug 2 '16 at 15:23
0

AVX 2.0 would be faster actually

Edit: It is related to registers and IPC

Instead of relying on 1 big instruction, you can use a plethora of SIMD instructions with 16 registers of 32 bytes, well, in UTF16 you it gives you 265 chars to play with !

double that with avx512 in few years!

AVX instructions also do have high throughput.

According this blog: https://blog.cloudflare.com/improving-picohttpparser-further-with-avx2/

Today on the latest Haswell processors, we have the potent AVX2 instructions. The AVX2 instructions operate on 32 bytes, and most of the boolean/logic instructions perform at a throughput of 0.5 cycles per instruction. This means that we can execute roughly 22 AVX2 instructions in the same amount of time it takes to execute a single PCMPESTRI. Why not give it a shot?

Edit 2.0 SSE/AVX units are power gated, and mixing SSE and/or AVX instructions with regular ones involves a context switch with performance penalty, that you should not have with the strcmp instruction.

1
  • 1
    While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes.
    – Paul R
    Oct 19 '15 at 14:05
-3

I don't see the point in "optimizing" a function like strcmp.

You will need to find the length of the strings before applying any kind of parallel processing, which will force you to read the memory at least once. While you're at it, you might as well use the data to perform the comparison on the fly.

If you want to do anyting fast with strings, you will need specialized tools like finite state machines (lexx comes to mind for a parser).

As for C++ std::string, they are inefficient and slow for a large number of reasons, so the gain of checking length in comparisons is neglectible.

4
  • I've used lex and bison before and they generate a lot of code. It is (usually) valid c++, but efficient? I somehow doubt it. Anyhow parsing was not the relevant topic in my question. Oct 27 '14 at 11:38
  • 3
    better performance => lower energy use => longer battery duration => happy environmental conscious customer.
    – Surt
    Oct 27 '14 at 11:56
  • 1
    std::string maybe inefficient in some ways but they're good for determining string length
    – phuclv
    Oct 28 '14 at 10:02
  • The usual crowd of C++ zealots is barking at the blasphemator... Surt comment is irrelevant in the extreme ; you should stay in your marketing office and let the programmers do the talking, pal. As for you, Mr. OP, if you're afraid of the code generated by lexx, you should be terrified by SIMD instructions. They are much more difficult to master (I mean using them is easy enough, but writing code that actually runs better is another story entierely).
    – kuroi neko
    Oct 30 '14 at 11:35

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