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What is the difference between memmove and memcpy? Which one do you usually use and how?

1

9 Answers 9

178

With memcpy, the destination cannot overlap the source at all. With memmove it can. This means that memmove might be very slightly slower than memcpy, as it cannot make the same assumptions.

For example, memcpy might always copy addresses from low to high. If the destination overlaps after the source, this means some addresses will be overwritten before copied. memmove would detect this and copy in the other direction - from high to low - in this case. However, checking this and switching to another (possibly less efficient) algorithm takes time.

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  • 1
    when using memcpy, how can I guarantee that the src and dest addresses don't overlap? Should I personally make sure that src and dest do not overlap?
    – Alcott
    Sep 9, 2011 at 13:08
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    @Alcott, don't use memcpy if you don't know that they don't overlap - use memmove instead. When there is no overlap, memmove and memcpy are equivalent (although memcpy might be very, very, very slightly faster).
    – bdonlan
    Sep 9, 2011 at 21:33
  • You can use 'restrict' keyword if you are working with long arrays and want to protect your copying process. For example if you method takes as parameters input and output arrays and you must verify that user does not pass the same address as input and output. Read more here stackoverflow.com/questions/776283/…
    – DanielHsH
    Jan 1, 2015 at 10:46
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    @DanielHsH 'restrict' is a promise you make the compiler; it is not enforced by the compiler. If you put 'restrict' on your arguments and do, in fact, have overlap (or more generally, access the restricted data from pointer derived from multiple places), the behavior of the program is undefined, weird bugs will happen, and the compiler will usually not warn you about it.
    – bdonlan
    Feb 9, 2015 at 6:34
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    @Mecki then I don't see the difference between your comment and bdonlan. It seems you are saying the same thing. Restrict is a promise made to the compiler. But the compiler will let you violate that promise with potentially undefined results. Replace "promise" with "requirement" and you are saying the same thing.
    – iheanyi
    Aug 5, 2021 at 21:03
38

memmove can handle overlapping memory, memcpy can't.

Consider

char[] str = "foo-bar";
memcpy(&str[3], &str[4], 4); // might blow up

Obviously the source and destination now overlap, we're overwriting "-bar" with "bar". It's undefined behavior using memcpy if the source and destination overlap so in this case we need memmove.

memmove(&str[3], &str[4], 4); // fine
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    @ultraman: Because it MAY have been implemented using low level assembley that requires that memory does not overlap. If it does you could for example generate a signal or hardware exception to the processor that aborts the application. The documentation specifies that it does not handle the condition, but the standard does not specify what will happen when these conditions are vialoated (this is known as undefined behavior). Undefined behavior can do anything. Jul 29, 2009 at 17:21
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    with gcc 4.8.2 , Even memcpy also accepts overlapping source and destination pointers and working fine.
    – Jagdish
    Jun 26, 2015 at 2:18
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    @jagsgediya Sure it might. But since memcpy is documented to not support this, you should not rely on that implementation specific behavior, that's why memmove() exist. It might be different in another version of gcc. It might be different if gcc inlines the memcpy instead of calling out to memcpy() in glibc, it might be different on an older or newer version of glibc and so on.
    – nos
    Jun 26, 2015 at 8:32
  • From practice, it seems the memcpy and memmove did the same thing. Such a deep undefined behavior.
    – Life
    Feb 8, 2016 at 22:52
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Assuming you would have to implement both, the implementation could look like that:

void memmove ( void * dst, const void * src, size_t count ) {
    if ((uintptr_t)src < (uintptr_t)dst) {
        // Copy from back to front

    } else if ((uintptr_t)dst < (uintptr_t)src) {
        // Copy from front to back
    }
}

void memcpy ( void * dst, const void * src, size_t count ) {
    if ((uintptr_t)src != (uintptr_t)dst) {
        // Copy in any way you want
    }
}

And this should pretty well explain the difference. memmove always copies in such a way, that it is still safe if src and dst overlap, whereas memcpy just doesn't care as the documentation says when using memcpy, the two memory areas must not overlap.

E.g. if memcpy copies "front to back" and the memory blocks are aligned as this

[---- src ----]
            [---- dst ---]

copying the first byte of src to dst already destroys the content of the last bytes of src before these have been copied. Only copying "back to front" will lead to correct results.

Now swap src and dst:

[---- dst ----]
            [---- src ---]

In that case it's only safe to copy "front to back" as copying "back to front" would destroy src near its front already when copying the first byte.

You may have noticed that the memmove implementation above doesn't even test if they actually do overlap, it just checks their relative positions, but that alone will make the copy safe. As memcpy usually uses the fastest way possible to copy memory on any system, memmove is usually rather implemented as:

void memmove ( void * dst, const void * src, size_t count ) {
    if ((uintptr_t)src < (uintptr_t)dst
        && (uintptr_t)src + count > (uintptr_t)dst
    ) {
        // Copy from back to front

    } else if ((uintptr_t)dst < (uintptr_t)src
        && (uintptr_t)dst + count > (uintptr_t)src
    ) {
        // Copy from front to back

    } else {
        // They don't overlap for sure
        memcpy(dst, src, count);
    }
}

Sometimes, if memcpy always copies "front to back" or "back to front", memmove may also use memcpy in one of the overlapping cases but memcpy may even copy in a different way depending on how the data is aligned and/or how much data is to be copied, so even if you tested how memcpy copies on your system, you cannot rely on that test result to be always correct.

What does that mean for you when deciding which one to call?

  1. Unless you know for sure that src and dst don't overlap, call memmove as it will always lead to correct results and is usually as fast as that is possible for the copy case you require.

  2. If you know for sure that src and dst don't overlap, call memcpy as it won't matter which one you call for the result, both will work correctly in that case, but memmove will never be faster than memcpy and if you are unlucky, it may even be slower, so you can only win calling memcpy.

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  • Note that the result of relational comparing pointers to different objects/arrays is unspecified. So there is no way to safely detect if two objects overlay with each other. In fact, the typical implementation of memmove copies data from front to back if dst < src otherwise copies data from back to front. It is safe because if there's overlay, the result is defined(and correct) so the behavior is safe, otherwise if there's no overlay, the result is unspecified but copying in both directions is safe.
    – VainMan
    Sep 24, 2020 at 1:15
23

From the memcpy man page.

The memcpy() function copies n bytes from memory area src to memory area dest. The memory areas should not overlap. Use memmove(3) if the memory areas do overlap.

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The main difference between memmove() and memcpy() is that in memmove() a buffer - temporary memory - is used, so there is no risk of overlapping. On the other hand, memcpy() directly copies the data from the location that is pointed by the source to the location pointed by the destination. (http://www.cplusplus.com/reference/cstring/memcpy/)

Consider the following examples:

  1. #include <stdio.h>
    #include <string.h>
    
    int main (void)
    {
        char string [] = "stackoverflow";
        char *first, *second;
        first = string;
        second = string;
    
        puts(string);
        memcpy(first+5, first, 5);
        puts(first);
        memmove(second+5, second, 5);
        puts(second);
        return 0;
    }
    

    As you expected, this will print out:

    stackoverflow
    stackstacklow
    stackstacklow
    
  2. But in this example, the results will not be the same:

    #include <stdio.h>
    #include <string.h>
    
    int main (void)
    {
        char string [] = "stackoverflow";
        char *third, *fourth;
        third = string;
        fourth = string;
    
        puts(string);
        memcpy(third+5, third, 7);
        puts(third);
        memmove(fourth+5, fourth, 7);
        puts(fourth);
        return 0;
    }
    

    Output:

    stackoverflow
    stackstackovw
    stackstackstw
    

It is because "memcpy()" does the following:

1.  stackoverflow
2.  stacksverflow
3.  stacksterflow
4.  stackstarflow
5.  stackstacflow
6.  stackstacklow
7.  stackstacksow
8.  stackstackstw
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    But, it seems the output you mentioned is reversed !!
    – kumar
    Nov 20, 2014 at 16:15
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    When I run the same program , I get the following result : stackoverflow stackstackstw stackstackstw // means there is NO difference in output between memcpy and memmove
    – kumar
    Nov 20, 2014 at 16:16
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    "is that in "memmove()", a buffer - a temporary memory - is used;" Is not true. it says "as if" so it just has to behave so, not that it has to be that way. Thats indeed relevant as most memmove implementations just do a XOR-swap.
    – dhein
    May 8, 2015 at 11:25
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    I don't think the implementation of memmove() is required to use a buffer. It's perfectly entitled to move in-place (as long as each read completes before any write to the same address). May 20, 2016 at 10:54
10

One (memmove) handles overlapping destinations the other (memcpy) doesn't.

7

simply from the ISO/IEC:9899 standard it is well described.

7.21.2.1 The memcpy function

[...]

2 The memcpy function copies n characters from the object pointed to by s2 into the object pointed to by s1. If copying takes place between objects that overlap, the behavior is undefined.

And

7.21.2.2 The memmove function

[...]

2 The memmove function copies n characters from the object pointed to by s2 into the object pointed to by s1. Copying takes place as if the n characters from the object pointed to by s2 are first copied into a temporary array of n characters that does not overlap the objects pointed to by s1 and s2, and then the n characters from the temporary array are copied into the object pointed to by s1.

Which one I usually use acording to the question, depends on what functionallity I need.

In plain text memcpy() doesn't allow s1 and s2 to overlap, while memmove() does.

1

There are two obvious ways to implement mempcpy(void *dest, const void *src, size_t n) (ignoring the return value):

  1. for (char *p=src, *q=dest;  n-->0;  ++p, ++q)
        *q=*p;
    
  2. char *p=src, *q=dest;
    while (n-->0)
        q[n]=p[n];
    

In the first implementation, the copy proceeds from low to high addresses, and in the second, from high to low. If the range to be copied overlaps (as is the case when scrolling a framebuffer, for example), then only one direction of operation is correct, and the other will overwrite locations that will subsequently be read from.

A memmove() implementation, at its simplest, will test dest<src (in some platform-dependent way), and execute the appropriate direction of memcpy().

User code can't do that of course, because even after casting src and dst to some concrete pointer type, they don't (in general) point into the same object and so can't be compared. But the standard library can have enough platform knowledge to perform such a comparison without causing Undefined Behaviour.


Note that in real life, implementations tend to be significantly more complex, to gain the maximum performance from larger transfers (when alignment permits) and/or good data cache utilisation. The code above is just to make the point as simply as possible.

0

memmove can deal with overlapping source and destination regions, while memcpy cannot. Among the two, memcpy is much more efficient. So, better to USE memcpy it if you can.

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

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    This answer says "possibly a smidge faster" and provides quantitative data indicating only a slight difference. This answer asserts one is "much more efficient". How much more efficient have you found the faster one to be? BTW: I assume you mean memcpy() and not memcopy(). Dec 10, 2016 at 3:14
  • The comment is made based on the lecture of Dr. Jerry Cain. I would request you listen to his lecture at time 36:00, only 2-3 minutes will suffice. And thanks for the catch. :D
    – Ehsan
    Dec 10, 2016 at 3:45