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Generally everything I come across 'on-the-net' with relation to SSE/MMX comes out as maths stuff for vectors and matracies. However, I'm looking for libraries of SSE optimized 'standard functions', like those provided by Agner Fog, or some of the SSE based string scanning algorithms in GCC.

As a quick general rundown: these would be things like memset, memcpy, strstr, memcmp BSR/BSF, ie an stdlib-esque built from SSE intrsuctions

I'd preferably like them to be for SSE1 (formally MMX2) using intrinsics rather than assembly, but either is fine. hopefully this not too broad a spectrum.

Update 1

I came across some promising stuff after some searching, one library caught my eye:

  • LibFreeVec: seems mac/IBM only (due to being AltiVec based), thus of little use(to me), plus I can't seem to find a direct download link, nor does it state the minimum supported SSE version

I also came across an article on a few vectorised string functions(strlen, strstr strcmp). However SSE4.2 is way out of my reach (as said before, I'd like to stick to SSE1/MMX).

Update 2

Paul R motivated me to do a little benchmarking, unfortunately as my SSE assembly coding experience is close to zip, I used someone else's ( benchmarking code and added to it. All tests(excluding the original, which is VC6 SP5) where compiled under VC9 SP1 with full/customized optimizations and /arch:SSE on.

First test was one my home machine (AMD Sempron 2200+ 512mb DDR 333), capped at SSE1 (thus no vectorization by MSVC memcpy):

comparing P-III SIMD copytest (blocksize 4096) to memcpy
calculated CPU speed: 1494.0 MHz
  size  SSE Cycles      thru-sse    memcpy Cycles   thru-memcpy     asm Cycles      thru-asm
   1 kB 2879        506.75 MB/s     4132        353.08 MB/s     2655        549.51 MB/s
   2 kB 4877        598.29 MB/s     7041        414.41 MB/s     5179        563.41 MB/s
   4 kB 8890        656.44 MB/s     13123       444.70 MB/s     9832        593.55 MB/s
   8 kB 17413       670.28 MB/s     25128       464.48 MB/s     19403       601.53 MB/s
  16 kB 34569       675.26 MB/s     48227       484.02 MB/s     38303       609.43 MB/s
  32 kB 68992       676.69 MB/s     95582       488.44 MB/s     75969       614.54 MB/s
  64 kB 138637      673.50 MB/s     195012      478.80 MB/s     151716      615.44 MB/s
 128 kB 277678      672.52 MB/s     400484      466.30 MB/s     304670      612.94 MB/s
 256 kB 565227      660.78 MB/s     906572      411.98 MB/s     618394      603.97 MB/s
 512 kB 1142478     653.82 MB/s     1936657     385.70 MB/s     1380146     541.23 MB/s
1024 kB 2268244     658.64 MB/s     3989323     374.49 MB/s     2917758     512.02 MB/s
2048 kB 4556890     655.69 MB/s     8299992     359.99 MB/s     6166871     484.51 MB/s
4096 kB 9307132     642.07 MB/s     16873183        354.16 MB/s     12531689    476.86 MB/s

full tests

Second test batch was done on a university workstation(Intel E6550, 2.33Ghz, 2gb DDR2 800?)

VC9 SSE/memcpy/ASM:
comparing P-III SIMD copytest (blocksize 4096) to memcpy
calculated CPU speed: 2327.2 MHz
  size  SSE Cycles      thru-sse    memcpy Cycles   thru-memcpy     asm Cycles      thru-asm
   1 kB 392         5797.69 MB/s    434         5236.63 MB/s    420         5411.18 MB/s
   2 kB 882         5153.51 MB/s    707         6429.13 MB/s    714         6366.10 MB/s
   4 kB 2044        4447.55 MB/s    1218        7463.70 MB/s    1218        7463.70 MB/s
   8 kB 3941        4613.44 MB/s    2170        8378.60 MB/s    2303        7894.73 MB/s
  16 kB 7791        4667.33 MB/s    4130        8804.63 MB/s    4410        8245.61 MB/s
  32 kB 15470       4701.12 MB/s    7959        9137.61 MB/s    8708        8351.66 MB/s
  64 kB 30716       4735.40 MB/s    15638       9301.22 MB/s    17458       8331.57 MB/s
 128 kB 61019       4767.45 MB/s    31136       9343.05 MB/s    35259       8250.52 MB/s
 256 kB 122164      4762.53 MB/s    62307       9337.80 MB/s    72688       8004.21 MB/s
 512 kB 246302      4724.36 MB/s    129577      8980.15 MB/s    142709      8153.80 MB/s
1024 kB 502572      4630.66 MB/s    332941      6989.95 MB/s    290528      8010.38 MB/s
2048 kB 1105076     4211.91 MB/s    1384908     3360.86 MB/s    662172      7029.11 MB/s
4096 kB 2815589     3306.22 MB/s    4342289     2143.79 MB/s    2172961     4284.00 MB/s

full tests

As can be seen, SSE is very fast on my home system, but falls on the intel machine (probably due to bad coding?). my x86 assembly variant comes in second on my home machine, and second on the intel system (but the results look a bit inconsistent, one hug blocks it dominates the SSE1 version). the MSVC memcpy wins the intel system tests hands done, this is due to SSE2 vectorization though, on my home machine, it fails dismally, even the horrible __movsd beats it...

pitfalls: the memory was all aligned powers of 2. cache was (hopefully) flushed. rdtsc was used for timing.

points of interest: MSVC has an (unlisted in any reference) __movsd intrinsic, it outputs the same assembly code I'm using, but it fails dismally(even when inlined!). That's probably why its unlisted.

VC9 memcpy can be forced to vectorize on my non-sse 2 machine, it will however corrupt the FPU stack, it also seems to have a bug.

This is the full source to what I used to test (including my alterations, again, credit to for the original). The binaries an project files are available on request.

In conclusion, it seems a switching variant might be the best, similar to the MSVC crt one, only a lot more sturdy with more options and single once-off checks (via inline'd function pointers? or something more devious like internal direct call patch), however inlining would probably have to use a best case method instead

Update 3

A question asked by Eshan reminded of something useful and related to this, although only for bit sets and bit ops, BitMagic and be quite useful for large bit sets, it even has a nice article on SSE2 (bit) optimization. Unfortunatly, this still isn't a CRT/stdlib esque type library. its seems most of these projects are dedicated to a specific, small section (of problems).

This raises the question, would it then rather be worth will to create a open-source, probably multi-platform performance crt/stdlib project, creating various versions of the standardised functions, each optimized for certain situation as well as a 'best-case'/general use variant of the function, with either runtime branching for scalar/MMX/SSE/SSE2+ (à la MSVC) or a forced compile time scalar/SIMD swich.

This could be useful for HPC, or projects where every bit of performance counts (like games), freeing the programmer from worrying about the speed of the inbuilt functions, only requiring a small bit of tuning to find the optimal optimized variant.

Update 4

I think the nature of this question should be expanded, to include techniques that can be applied using SSE/MMX to optimization for non-vector/matrix applications, this could probably be used for 32/64bit scalar code as well. A good example is how to check for the occurence of a byte in a given 32/64/128/256 bit data type, at once using scalar techniques(bit manip), MMX & SSE/SIMD

Also, I see a lot of answers along the lines of "just use ICC", and thats a good answer, it not my kinda of answer, as firstly, ICC is not something I can use continuously (unless Intel have a free student version for windows), due to the 30 trial. secondly, and more pertinently, I'm not only after the libraries its self, but the techniques used to optimize/create the functions they contain, for my personal eddification and improvement, and so I can apply such techniques and principles to my own code (where needed), in conjunction with the use of these libraries. hopefully that clears up that part :)

share|improve this question
What makes you think these functions aren't already implemented to use SSE where possible? – jalf Oct 5 '10 at 12:14
@jalf: because I regularly debug into my applications(with ollydbg), for various reasons, so I know the code its outputting, and I can see its short comings. The only time I see some SSE code is for memset's, when /arch:SSE2 is on, its SSE2 code however, thus won't run on my system. also being a reverse engineer, I know just from generally activities how MSVC has implemented crt functions :P – Necrolis Oct 5 '10 at 12:20

Here's an article on how to use SIMD instructions to vectorize the counting of characters:

share|improve this answer
+1, very nice, just a pitty its SSE2 and one needs to map GCC built-ins to MSVC :( – Necrolis Oct 6 '10 at 14:46

For simple operations such as memset, memcpy, etc, where there is very little computation, there is little point in SIMD optimisation, since memory bandwidth will usually be the limiting factor.

share|improve this answer
But for memory ops your not leveraging the power of the coprocessor for processing, but rather for its ability to operate on much larger data sets(8, 16 + bytes at a time) with the same latency as using the inbuilt x86 instructions. Dr Fog should have some comparisons showing this somewhere in his 5 volume 'guide'. And yes, i'm aware this only matters for hotspots, and thats what i'm using this for – Necrolis Oct 5 '10 at 11:04
@Necrolis: it doesn't matter how much more efficient your loads/stores are - if you can max out your memory bandwidth with scalar code (which is usually pretty easy with e.g. memcpy, memset) then there is nothing to be gained from further optimisation. – Paul R Oct 5 '10 at 11:13
the thing is I'm not maxing it out with scalar code, except for very small buffers(though I attribute this in part to MSVC not inlining calls to memset etc. if this wasn't the case, __assume can be used to 'force' aligned copies, removing the branching, ie: why bother with word and byte cases when everything is multiples of long, then it would probably be very close to SSE, atleast on my system) – Necrolis Oct 5 '10 at 11:41
@Necrolis: it may well be that you have inefficient implementations of memset/memcpy, but that still does not justify a SIMD implementation - you can almost certainly write a more efficient scalar implementation of these routines that will max out memory bandwidth without resorting to SIMD. However it's an interesting exercise and you'll learn a lot in the process so if you have the time and inclination then go for it. – Paul R Oct 5 '10 at 12:25
@Paul R - I do have some of these SSEx general-purpose functions that do outperform the respective non-SSE versions, although I don't know how far from optimal the non-SSE versions are. I was therefore wondering if you have any data to support your claim re. scalar code being as performant as SSE? Or could you point us to some scalar code, that in your view, does max out memory bandwidth? – PhiS Oct 5 '10 at 14:35

Maybe libSIMDx86?

share|improve this answer
Although a nice library, its mainly geared toward matrix and vector math(the only parts of interest to me in it are the 3 rooting functions from the math section). – Necrolis Oct 5 '10 at 15:03

You can use the apple's or OpenSolaris's libc. These libc implementations contain what you are looking for. I was looking for these kind of things some 6 years back and I had to painfully write it the hard-way.

Ages ago I remember following a coding contest called 'fastcode' project. They did some awesome ground breaking optimisation for that time using Delphi. See their results page. Since it is written in Pascal's fast function call-model (copying arguments to registers) converting to C styled stdc function call-models (pushing on stack) may be a bit awkward. This project has no updates since a long-time especially, no code is written for SSE4.2.

Solaris ->

Apple ->
share|improve this answer
these look promising, unfortunately I don't have time to go spelunking around the Apple/Solaris libs(looks like a maze of folders to me). the fast code looks real good though, pity not every thing there seems to have source code – Necrolis Oct 6 '10 at 6:45
Just a small note: Most such implementations put each function in their own file. So all you need to search is for some directory which mentions the platform architecture say 'x86' or 'i386' and search for file names which end with '.s'. – Unmanned Player Oct 7 '10 at 14:26
@Necrolis, @Paul R: Did you people bump into similar high-speed optimisation using GPUs like nVidia, or ATI? Is it possible? Heard a lot about it, but never had a chance to see any assembly stuff that actually makes use of it. At best I end up with OpenGL or DirectX calls but nothing below that. – Unmanned Player Oct 8 '10 at 6:18
are you refering to CUDA(nVidia) or Stream(ATI)? if so, then yes, have a look at this: & – Necrolis Oct 8 '10 at 7:28

Here's a fast memcpy implementation in C that can replace the standard library version of memcpy if necessary:

share|improve this answer
its a nice link, however, his version falls quite hard, my assembly version goes at almost double the speed, and sometimes more than double(first is his, under thru-c, second set is mine, under thru-asm): – Necrolis Oct 8 '10 at 10:07

Honestly, what I would do is just install the Intel C++ Compiler and learn the various automated SIMD optimization flags available. We've had very good experience optimizing code performance by simply compiling it with ICC.

Keep in mind that the entire STL library is basically just header files, so the whole thing is compiled into your exe/lib/dll, and as such can be optimized however you like.

ICC has many options and lets you specify (at the simplest) which SSE levels to target. You can also use it to generate a binary file with multiple code paths, such that if the optimal SSE configuration you compiled against isn't available, it'll run a different set of (still optimized) code configured for a less capable SIMD CPU.

share|improve this answer
of course I'd have to do that all within 30 days, as I don't have the money to purchase a 'full' licence. I decided one path is to do what you recommeneded, but using GCC 4.5.x instead. however its still time consuming, and I was hoping someone had already gone through part of this. also, the STD library isn't always shoved(statically linked) in the binary, with MSVC, it'll link to msvcrtxx.dll for most non-trivial functions. – Necrolis Oct 8 '10 at 9:30
GCC doesn't do the same optimizations ICC does - that's why there's a copy of ICC for linux and specially compiled Linux kernels that tout the fact they've been compiled with ICC. I didn't mean to say STD but rather STL. STL is always statically linked, IIRC. – Mahmoud Al-Qudsi Oct 8 '10 at 10:29

strstr is hard to optimize because (a) \0-termination means you have to read every byte anyway, and (b) it has to be good on all the edge cases, too.

With that said, you can beat standard strstr by a factor of 10, using SSE2 ops. I've noticed that gcc 4.4 uses these ops for strlen now, but not for the other string ops. More on how to use SSE2 registers for strlen, strchr, strpbrk, etc. at Pardon my super-terse code layout.

#include <emmintrin.h> // Other standard #includes you can figure out...

static inline unsigned under(unsigned x)
    { return (x - 1) & ~x; }
static inline __m128i xmfill(char b)
    { return _mm_set1_epi8(b); }
static inline __m128i xmload(void const*p)
    { return _mm_load_si128((__m128i const*)p); }
static inline unsigned xmatch(__m128i a, __m128i b)
    { return _mm_movemask_epi8(_mm_cmpeq_epi8(a, b)); }

char const *sse_strstr(char const *tgt, char const *pat)
    unsigned    len = sse_strlen(pat);
    if (len == 0) return tgt;
    if (len == 1) return sse_strchr(tgt,*pat);
    __m128i     x, zero = {};
    __m128i     p0 = _m_set1_epi8(pat[0]), p1 = _m_set1_epi8(pat[1]);
    uint16_t    pair = *(uint16_t const*)pat;
    unsigned    z, m, f = 15 & (uintptr_t)tgt;
    char const* p;

    // Initial unaligned chunk of tgt:
    if (f) {
        z = xmatch(x = xmload(tgt - f), zero) >> f;
        m = under(z) & ((xmatch(x,p0) & (xmatch(x,p1) >> 1)) >> f);
        for (; m; m &= m - 1)
             if (!memcmp((p = tgt+ffs(m)-1)+2, pat+2, len-2))
                return p;
        if (z)
            return NULL;
        tgt += 16 - f;
        if (*(uint16_t const*)(tgt - 1) == pair
                && !memcmp(tgt+1, pat+2, len-2))
            return tgt - 1;

    // 16-byte aligned chunks of tgt:
    while (!(z = xmatch(x = xmload(tgt), zero))) {
        m = xmatch(x,p0) & (xmatch(x,p1) >> 1);
        for (; m; m &= m - 1)
             if (!memcmp((p = tgt+ffs(m)-1)+2, pat+2, len-2))
                return p;
        tgt += 16;
        if (*(uint16_t const*)(tgt - 1) == pair && !memcmp(tgt+1, pat+2, len-2))
            return tgt - 1;

    // Final 0..15 bytes of tgt:
    m = under(z) & xmatch(x,p0) & (xmatch(x,p1) >> 1);
    for (; m; m &= m - 1)
        if (!memcmp((p = tgt+ffs(m)-1)+2, pat+2, len-2))
            return p;

    return NULL;
share|improve this answer
LLVM has a very nice vectorized strstr for skipping block comments(it has branches for msvc, gcc and altivec, so its pretty portable too). Thanks for the link though, i'll have a look – Necrolis Sep 18 '11 at 7:56
This is so outdated. Current glibc has SSE 4.2 optimization where available, which contains exactly the instructions needed for fast string operations. – hirschhornsalz Sep 18 '11 at 23:14
Which version of glibc is that? I agree that it's best when glibc does the lifting and arch-deps. Unfortunately, it's a problem that SSE4.2 is intel-only, while pretty much ANY intel-compatible chip since 2003 has SSE2. For non-(intel SSE4.2) platforms, my glibc strstr doesn't seem to be quite so smart :-( – Mischa Nov 19 '11 at 2:57

I personally wouldn't bother trying to write super-optimized versions of libc functions trying to handle every possible scenario with good performance.

Instead, write optimized versions for specific situations, where you know enough about the problem at hand to write proper code... and where it matters. There's a semantic difference between memset and ClearLargeBufferCacheWriteThrough.

share|improve this answer
yes, thats why I mention both a best-case for general use, and versions that are far more specific(and configurable via defines). I think I'm just gonna start something on github during the christmas break, see if i can address this, my problem then boils down to my SSE knowledge being poor, my x86 optimization knowledge on the other hand is very strong. – Necrolis Oct 8 '10 at 9:33

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