I am investigating performance hotspots in an application which spends 50% of its time in memmove(3). The application inserts millions of 4-byte integers into sorted arrays, and uses memmove to shift the data "to the right" in order to make space for the inserted value.

My expectation was that copying memory is extremely fast, and I was surprised that so much time is spent in memmove. But then I had the idea that memmove is slow because it's moving overlapping regions, which must be implemented in a tight loop, instead of copying large pages of memory. I wrote a small microbenchmark to find out whether there was a performance difference between memcpy and memmove, expecting memcpy to win hands down.

I ran my benchmark on two machines (core i5, core i7) and saw that memmove is actually faster than memcpy, on the older core i7 even nearly twice as fast! Now I am looking for explanations.

Here is my benchmark. It copies 100 mb with memcpy, and then moves about 100 mb with memmove; source and destination are overlapping. Various "distances" for source and destination are tried. Each test is run 10 times, the average time is printed.


Here are the results on the Core i5 (Linux 3.5.0-54-generic #81~precise1-Ubuntu SMP x86_64 GNU/Linux, gcc is 4.6.3 (Ubuntu/Linaro 4.6.3-1ubuntu5). The number in brackets is the distance (gap size) between source and destination:

memcpy        0.0140074
memmove (002) 0.0106168
memmove (004) 0.01065
memmove (008) 0.0107917
memmove (016) 0.0107319
memmove (032) 0.0106724
memmove (064) 0.0106821
memmove (128) 0.0110633

Memmove is implemented as a SSE optimized assembler code, copying from back to front. It uses hardware prefetch to load the data into the cache, and copies 128 bytes to XMM registers, then stores them at the destination.

(memcpy-ssse3-back.S, lines 1650 ff)

    prefetchnta -0x1c0(%rsi)
    prefetchnta -0x280(%rsi)
    prefetchnta -0x1c0(%rdi)
    prefetchnta -0x280(%rdi)
    sub $0x80, %rdx
    movdqu  -0x10(%rsi), %xmm1
    movdqu  -0x20(%rsi), %xmm2
    movdqu  -0x30(%rsi), %xmm3
    movdqu  -0x40(%rsi), %xmm4
    movdqu  -0x50(%rsi), %xmm5
    movdqu  -0x60(%rsi), %xmm6
    movdqu  -0x70(%rsi), %xmm7
    movdqu  -0x80(%rsi), %xmm8
    movdqa  %xmm1, -0x10(%rdi)
    movdqa  %xmm2, -0x20(%rdi)
    movdqa  %xmm3, -0x30(%rdi)
    movdqa  %xmm4, -0x40(%rdi)
    movdqa  %xmm5, -0x50(%rdi)
    movdqa  %xmm6, -0x60(%rdi)
    movdqa  %xmm7, -0x70(%rdi)
    movdqa  %xmm8, -0x80(%rdi)
    lea -0x80(%rsi), %rsi
    lea -0x80(%rdi), %rdi
    jae L(gobble_ll_loop)

Why is memmove faster then memcpy? I would expect memcpy to copy memory pages, which should be much faster than looping. In worst case I would expect memcpy to be as fast as memmove.

PS: I know that I cannot replace memmove with memcpy in my code. I know that the code sample mixes C and C++. This question is really just for academic purposes.


I ran some variations of the tests, based on the various answers.

  1. When running memcpy twice, then the second run is faster than the first one.
  2. When "touching" the destination buffer of memcpy (memset(b2, 0, BUFFERSIZE...)) then the first run of memcpy is also faster.
  3. memcpy is still a little bit slower than memmove.

Here are the results:

memcpy        0.0118526
memcpy        0.0119105
memmove (002) 0.0108151
memmove (004) 0.0107122
memmove (008) 0.0107262
memmove (016) 0.0108555
memmove (032) 0.0107171
memmove (064) 0.0106437
memmove (128) 0.0106648

My conclusion: based on a comment from @Oliver Charlesworth, the operating system has to commit physical memory as soon as the memcpy destination buffer is accessed for the very first time (if someone knows how to "proof" this then please add an answer!). In addition, as @Mats Petersson said, memmove is cache friendlier than memcpy.

Thanks for all the great answers and comments!

  • 2
    You looked at the memmove code, did you also look at the memcpy code? Feb 20, 2015 at 7:56
  • 9
    My expectation was that copying memory is extremely fast - only when memory is in L1 cache. When the data does not fit in caches your copying performance dwindles. Feb 20, 2015 at 8:19
  • 1
    BTW, you only copied one branch of memmove. This branch can't handle move when source overlaps destination and the destination is at lower addresses. Feb 20, 2015 at 8:23
  • 2
    I haven't had time to access a Linux machine, so I can't test this theory yet. But another possible explanation is overcommitting; your memcpy loop is the first time that the contents of b2 is accessed, thus the OS has to commit physical memory for it as it goes. Feb 20, 2015 at 8:26
  • 2
    PS: If this is a bottleneck I would reconsider the approach. How about putting the values into a list or tree structure (e.g. binary tree) and then reading them into an array at the end. The nodes in such an approach would be an excellent candidate for pool allocation. They are only added until the end when they're released en masse. That's particularly true if you know how many you will need at the start. The boost libraries have a pool allocator.
    – Persixty
    Feb 20, 2015 at 8:48

4 Answers 4


Your memmove calls are shuffling memory along by 2 to 128 bytes, while your memcpy source and destination are completely different. Somehow that's accounting for the performance difference: if you copy to the same place, you'll see memcpy ends up possibly a smidge faster, e.g. on ideone.com:

memmove (002) 0.0610362
memmove (004) 0.0554264
memmove (008) 0.0575859
memmove (016) 0.057326
memmove (032) 0.0583542
memmove (064) 0.0561934
memmove (128) 0.0549391
memcpy 0.0537919

Hardly anything in it though - no evidence that writing back to an already faulted in memory page has much impact, and we're certainly not seeing a halving of time... but it does show that there's nothing wrong making memcpy unnecessarily slower when compared apples-for-apples.

  • I would have expected that the CPU caches are not causing the difference because my buffers are much larger than the caches.
    – cruppstahl
    Feb 20, 2015 at 7:56
  • 2
    But each requires the same total number of main memory accesses, right? (I.e. 100MB of read, and 100MB of write). The cache pattern doesn't get round that. So the only way that one could be slower than the other is if some stuff has to be read/written from/to memory more than once. Feb 20, 2015 at 7:57
  • 2
    @Tony D - My conclusion was to ask people who are smarter than me ;)
    – cruppstahl
    Feb 20, 2015 at 8:03
  • 1
    Also, what happens if you copy to the same place, but do memcpy first again? Feb 20, 2015 at 8:27
  • 1
    @OliverCharlesworth: the first test run always takes a significant hit, but doing two memcpy tests: memcpy 0.0688002 0.0583162 | memmove 0.0577443 0.05862 0.0601029... see ideone.com/8EEAcA Feb 20, 2015 at 8:33

When you are using memcpy, the writes need to go into the cache. When you use memmove where when you are copying a small step forward, the memory you are copying over will already be in the cache (because it was read 2, 4, 16 or 128 bytes "back"). Try doing a memmove where the destination is several megabytes (> 4 * cache size), and I suspect (but can't be bothered to test) that you'll get similar results.

I guarantee that ALL is about cache maintenance when you do large memory operations.

  • +1 I think for the reasons you mentioned, a backwards looping memmove is cache friendlier than memcpy. However, I discovered that when running the memcpy test twice, the second run is as fast as memmove. Why? The buffers are so large that a second run of memcpy should be as inefficient (cache-wise) as the first run. So it seems there are additional factors here which cause the performance penalty.
    – cruppstahl
    Feb 20, 2015 at 9:49
  • 3
    Given the right circumstances, a second memcpy will be notably faster simply because the TLB is prefilled. Also, a second memcpy won't have to empty the cache of stuff you may need "getting rid of" (dirty cache-lines are "bad" for performance in so many ways. To say for sure, however, you'd need to run something like "perf" and sample things like cache-misses, TLB misses and so on. Feb 20, 2015 at 20:15

Historically, memmove and memcpy are the same function. They worked in the same way and had the same implementation. It was then realised that memcpy doesn't need to be (and frequently wasn't) defined to handle overlapping areas in any particular way.

The end result is that memmove was defined to handle overlapping regions in a particular way even if this impacts performance. memcpy is supposed to use the best algorithm available for non-overlapping regions. The implementations are normally almost identical.

The problem you have run into is that there are so many variations of the x86 hardware that it is impossible to tell which method of shifting memory around will be the fastest. And even if you think you have a result in one circumstance something as simple as having a different 'stride' in the memory layout can cause vastly different cache performance.

You can either benchmark what you're actually doing or ignore the problem and rely on the benchmarks done for the C library.

Edit: Oh, and one last thing; shifting lots of memory contents around is VERY slow. I would guess your application would run faster with something like a simple B-Tree implementation to handle your integers. (Oh you are, okay)

Edit2: To summarise my expansion in the comments: The microbenchmark is the issue here, it isn't measuring what you think it is. The tasks given to memcpy and memmove differ significantly from each other. If the task given to memcpy is repeated several times with memmove or memcpy the end results will not depend on which memory shifting function you use UNLESS the regions overlap.

  • But that's what it's about - i am benchmarking what i'm actually doing. This question is about interpreting the results of the benchmark, which contradict what you are claiming - that memcpy is faster for non-overlapping regions.
    – cruppstahl
    Feb 20, 2015 at 8:20
  • My application is a b-tree! Whenever integers are inserted in a leaf node memmove is called to make space. I am working on a database engine.
    – cruppstahl
    Feb 20, 2015 at 8:21
  • 1
    You're using a micro benchmark and you're not even having the memcopy and memmove shift the same data. The exact locations in memory that the data you're coping reside makes a difference to the caching and how many round trips to memory the CPU has to make. Feb 20, 2015 at 8:24
  • While this answer is correct, it doesn't actually explain why it's slower in this case, it's essentially saying "it's slower because in some cases it might be slower". Feb 20, 2015 at 8:24
  • I'm saying that for the same circumstances, including the same layout of memory to copy/move the benchmarks WILL be the same because the implementations are the same. The problem is in the microbenchmark. Feb 20, 2015 at 8:26

"memcpy is more efficient than memmove." In your case, you most probably are not doing the exact same thing while you run the two functions.

In general, USE memmove only if you have to. USE it when there is a very reasonable chance that the source and destination regions are over-lapping.

Reference: https://www.youtube.com/watch?v=Yr1YnOVG-4g Dr. Jerry Cain, (Stanford Intro Systems Lecture - 7) Time: 36:00

  • Actually, if there is even a tiny tiny chance that the regions may overlap, you should always use memmove. Because using memcpy on overlaping buffers gives you undefined behavior. Jun 1 at 14:02

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