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I am interested knowing the best approach for bulk memory copies on an x86 architecture. I realize this depends on machine-specific characteristics. The main target is typical desktop machines made in the last 4-5 years.

I know that in the old days MOVSD with REPE was nominally the fastest approach because you could move 4 bytes at a time, but I have read that nowadays MOVSB is just as fast and is simpler to write, so you may as well do a byte move and just forget about the complexities of a 4-byte move.

A surrounding question is whether MOVxx instructions are worth it at all. If the CPU can run so much faster than the memory bus, then maybe it is pointless to use a CISC move and you may as well use a plain MOV. This would be most attractive because then I could use the same algorithms on other processor architectures like ARM. This brings up the analogous question of whether ARM's specialized instructions for bulk memory moves (which are totally different than Intels) are worth it or not.

Note: I have read section 3.7.6 in the Intel Optimization Reference Manual so I am familiar with the basics. I am hoping someone can relate practical experience in the area beyond what is in this manual.

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Isn't this quite simple to test? – MatBailie Dec 9 '12 at 20:45
Just because you write in ASM doesn't mean you can't call the C library memcpy. I have seen no modern C library implement memcpy as a plain unsigned byte copy, but I have seen many examples of wheel-reinvention resulting in worse performance than the system libraries would provide. – unixsmurf Dec 9 '12 at 21:29
@unixsmurf As I said above, optimized memory moves are hard-coded by high-end compilers. Run of the mill memcpy, especially as it exists on unix is poorly optimized and way less efficient than even naive ASM. If you read this article: software.intel.com/en-us/articles/memcpy-performance by Intel it makes clear some of the issues involved. – Tyler Durden Dec 9 '12 at 21:37
And I would then refer to sourceware.org/git/?p=glibc.git;a=blob;f=ports/sysdeps/arm/…, both as a reference of optimized implementations for ARM, and as a means of refuting the article. – unixsmurf Dec 9 '12 at 21:48
An interesting experiment done about a year ago, Linux Kernel mailing list, see lkml.org/lkml/2011/8/12/267 - the results on x86 are like: small buffer, generic alignment: use rep movs (and these, from tracing, are >>90% of all mem-mem transfers); big chunks (here: video frames), other techniques significantly outperform. If you have huge blocks to copy, other techniques make sense. On ARM, a blocked copy loop with prefetching, see code.metager.de/source/xref/linux/stable/arch/arm/lib/… , outperforms a 32bit-at-a-time tight loop by two orders of magnitude. – FrankH. Dec 10 '12 at 16:02
up vote 4 down vote accepted

Modern Intel and AMD processors have optimisations on REP MOVSB that make it copy entire cache lines at a time if it can, making it the best (may not be fastest, but pretty close) method of copying bulk data.

As for ARM, it depends on the architecture version, but in general using an unrolled loop would be the most efficient.

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On ARM, just unrolling the loop is neither necessary nor possible - because you can already load/store all registers in one instruction, that's the beauty of ldm / stm (load/store multiple). But you can, in addition to that, prefetch. Try the glibc ARM memcpy code as referenced above by @unixsmurf with/without the PLD() bits - the effect is very significant. – FrankH. Dec 10 '12 at 16:13
@FrankH. in ARM64 the ability to load/store all has been removed. You can only load a pair of registers now, but then it's no different than copy using NEON – Lưu Vĩnh Phúc Feb 9 '15 at 6:38

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