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Does rewriting memcpy/memcmp/... with SIMD instructions make sense in a large scale software?

If so, why gcc doesn't generate simd instructions for these library functions by default.

Also, are there any other functions can be possibly improved by SIMD?

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It depends on what OS and compiler libraries you are using. E.g. Mac OS X already has SIMD-optimised memcpy et al. Also Intel's ICC generates inline memcpys which are faster than anything you are likely to be able to implement in a library. – Paul R Mar 16 '11 at 6:41
@Paul: memcpy is actually the worst case for an SSE intrinsic, because SSE can't be used for the edge cases. Do those compilers emit SIMD code for strlen and memchr? – Ben Voigt Mar 16 '11 at 13:56
@Ben: I just checked with ICC 12 - memcpy and strlen both emit inline SSE code, strchr is a library function which appears to just be straight scalar code. – Paul R Mar 16 '11 at 15:12
up vote 3 down vote accepted

Yes, these functions are much faster with SSE instructions. It would be nice if your runtime library/compiler instrinsics would include optimized versions, but that doesn't seem to be pervasive.

I have a custom SIMD memchr which is a hell-of-a-lot faster than the library version. Especially when I'm finding the first of 2 or 3 characters (example, I want to know if there's an equation in this line of text, I search for the first of =, \n, \r).

On the other hand, the library functions are well tested, so it's only worth writing your own if you call them a lot and a profiler shows they're a significant fraction of your CPU time.

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A SIMD memcpy will normally only be faster for copies where source and/or dest are already in cache, since almost any half decent memcpy should be able to saturate the available DRAM bandwidth. – Paul R Mar 16 '11 at 6:38
@Paul: SIMD is better always. If it's not strictly faster because memory access can't keep up, that core is freed up for hyperthreading, power saving, or speculative out-of-order execution. As Crashworks said, SSE will also fetch data into cache faster, because of prefetch hinting. Without SSE, the CPU may have to alternate between fetching data and doing the copy, with SSE both occur in parallel. – Ben Voigt Mar 16 '11 at 13:37
in the case of memcpy et al there isn't anything else going on in the execution thread, so no benefit there. If your core is stalled waiting for a DRAM access there's not much you can do - DRAM latency can be of the order of 200 clocks, which is a lot of instructions cycles with nothing to do. – Paul R Mar 16 '11 at 13:41
@Paul: (1) Not all memcpy calls are for thousands of bytes. You may easily have a memcpy call for ~20 bytes inside a loop with other processing. (2) Modern CPU cores aren't limited to processing instructions from a single thread, hence my mention of hyperthreading. (3) DRAM latency is less important when read prefetches are pipelined, only throughput is. (4) Even if DRAM throughput is hobbling the code, it's still better to perform the copy efficiently because the CPU can do the work in the same time and less power consumption (for example, dynamically lowered clock frequency) – Ben Voigt Mar 16 '11 at 13:55

It probably doesn't matter. The CPU is much faster than memory bandwidth, and the implementations of memcpy etc. provided by the compiler's runtime library are probably good enough. In "large scale" software your performance is not going to be dominated by copying memory, anyway (it's probably dominated by I/O).

To get a real step up in memory copying performance, some systems have a specialised implementation of DMA that can be used to copy from memory to memory. If a substantial performance increase is needed, hardware is the way to get it.

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That largely depends on whether you're using a horribly slow I/O API like C++ iostreams. It's hard to perform any non-trivial processing at the speed the OS can deliver I/O. Besides, SIMD is faster for a variety of reasons, especially on smaller blocks where the setup of a DMA engine would be prohibitively expensive. For one thing, SSE uses a different set of CPU registers, so your working variables stay enregistered and don't get spilled to cache. – Ben Voigt Mar 16 '11 at 5:37

It does not make sense. Your compiler ought to be emitting these instructions implicitly for memcpy/memcmp/similar intrinsics, if it is able to emit SIMD at all.

You may need to explicitly instruct GCC to emit SSE opcodes with eg -msse -msse2; some GCCs do not enable them by default. Also, if you do not tell GCC to optimize (ie, -o2), it won't even try to emit fast code.

The use of SIMD opcodes for memory work like this can have a massive performance impact, because they also include cache prefetches and other DMA hints that are important for optimizing bus access. But that doesn't mean that you need to emit them manually; even though most compiler stink at emitting SIMD ops generally, every one I've used at least handles them for the basic CRT memory functions.

Basic math functions can also benefit a lot from setting the compiler to SSE mode. You can easily get an 8x speedup on basic sqrt() just by telling the compiler to use the SSE opcode instead of the terrible old x87 FPU.

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Agreed that memcpy is the most likely to be properly optimized. A lot of other functions from <string.h> and <memory.h> also benefit immensely and aren't widely optimized by the compiler. – Ben Voigt Mar 16 '11 at 5:40

on x86 hardware, it should not matter much, with out-of-order processing. Processor will achieve necessary ILP and try to issue max number of load/store operations per cycle for memcpy, whether it be SIMD or Scalar instruction set.

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