I am not so well-versed in the C standard, so please bear with me.

I would like to know if it is guaranteed, by the standard, that memcpy(0,0,0) is safe.

The only restriction I could find is that if the memory regions overlap, then the behavior is undefined...

But can we consider that the memory regions overlap here ?

  • 6
    Mathematically the intersection of two empty sets is empty. – Benoit Mar 9 '11 at 8:22
  • I wanted to check for you want (x)libC does for you, but as it's asm (elibc/glibc here), it's a bit too complicated for an early morning :) – Kevin Mar 9 '11 at 8:25
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    +1 I love this question both because it's such a strange edge case and because I think memcpy(0,0,0) is one of the weirdest pieces of C code I've seen. – templatetypedef Mar 9 '11 at 8:29
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    @eq Do you really want to know, or are you implying that there are no situations when you would want it? Have you considered that the actual call might be, say, memcpy(outp, inp, len)? And that this could occur in code where outp and inp are dynamically allocated and are initially 0? This works, e.g., with p = realloc(p, len+n) when p and len are 0. I myself have used such a memcpy call -- while it is technically UB, I've never encountered an implementation where it isn't a no-op and don't ever expect to. – Jim Balter Mar 9 '11 at 8:50
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    @templatetypedef memcpy(0, 0, 0) is most likely intended to represent a dynamic, not static invocation ... i.e., those parameter values need not be literals. – Jim Balter Mar 9 '11 at 8:53
up vote 65 down vote accepted

I have a draft version of the C standard (ISO/IEC 9899:1999), and it has some fun things to say about that call. For starters, it mentions (§7.21.1/2) in regards to memcpy that

Where an argument declared as size_t n specifies the length of the array for a function, n can have the value zero on a call to that function. Unless explicitly stated otherwise in the description of a particular function in this subclause, pointer arguments on such a call shall still have valid values, as described in 7.1.4. On such a call, a function that locates a character finds no occurrence, a function that compares two character sequences returns zero, and a function that copies characters copies zero characters.

The reference indicated here points to this:

If an argument to a function has an invalid value (such as a value outside the domain of the function, or a pointer outside the address space of the program, or a null pointer, or a pointer to non-modifiable storage when the corresponding parameter is not const-qualified) or a type (after promotion) not expected by a function with variable number of arguments, the behavior is undefined.

So it looks like according to the C spec, calling

memcpy(0, 0, 0)

results in undefined behavior, because null pointers are considered "invalid values."

That said, I would be utterly astonished if any actual implementation of memcpy broke if you did this, since most of the intuitive implementations I can think of would do nothing at all if you said to copy zero bytes.

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    I can affirm that the quoted parts from the draft standard are identical in the final document. There shouldn't be any troubles with such a call, but it would still be undefined behaviour you're relying on. So the answer to "is it guaranteed" is "no". – DevSolar Mar 9 '11 at 8:33
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    No implementation that you will ever use in production will produce anything other than a no-op for such a call, but implementations that do otherwise are allowed and are reasonable ... e.g., a C interpreter or augmented compiler with error checking that rejects the call because it's non-conforming. Of course that wouldn't be reasonable if the Standard did allow the call, as it does for realloc(0, 0). The use cases are similar, and I've used them both (see my comment under the question). It's pointless and unfortunate that the Standard makes this UB. – Jim Balter Mar 9 '11 at 9:01
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    "I would be utterly astonished if any actual implementation of memcpy broke if you did this" - I've used one that would; in fact if you passed length 0 with valid pointers, it actually copied 65536 bytes. (Its loop decremented the length and then tested). – M.M Jul 12 '14 at 6:01
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    @MattMcNabb That implementation is broken. – Jim Balter Jul 13 '14 at 22:16
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    @MattMcNabb: Add "correct" to "actual", maybe. I think we all have not-so-fond memories of old, ghetto C libraries and I'm not sure how many of us appreciate those memories being recalled. :) – tmyklebu Sep 9 '14 at 11:20

Just for fun, the release-notes for gcc-4.9 indicate that its optimizer makes use of these rules, and for example can remove the conditional in

int copy (int* dest, int* src, size_t nbytes) {
    memmove (dest, src, nbytes);
    if (src != NULL)
        return *src;
    return 0;

which then gives unexpected results when copy(0,0,0) is called (see https://gcc.gnu.org/gcc-4.9/porting_to.html).

I am somewhat ambivalent about the gcc-4.9 behaviour; the behaviour might be standards compliant, but being able to call memmove(0,0,0) is sometimes a useful extension to those standards.

  • 2
    Interesting. I understand your ambivalence but this is the heart of optimizations in C: the compiler assumes that developers follow certain rules and thus deduces that some optimizations are valid (which they are if the rules are followed). – Matthieu M. Jul 19 '14 at 12:45
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    @tmyklebu: Given char *p = 0; int i=something;, evaluation of the expression (p+i) will yield Undefined Behavior even when i is zero. – supercat Dec 6 '14 at 21:32
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    @tmyklebu: I particularly dislike the notion that Undefined Behavior should be usable as a form of compiler-exploitable assertion exempt from normal the rules of causality--that to me is what represents "Clippy"-level annoyance. Given uint16_t foo=f(); int bar=0; if (foo > 50000) bar=3; if (foo*foo > 16383) bar |= 1;, what good can come from allowing 32-bit compiler to omit the first if? – supercat Dec 10 '14 at 17:03
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    @supercat: I don't understand why you care whether NULL + foo is a valid pointer to such an extent that you want to ensure that it never is. Messing with null pointer arithmetic in the way you describe would ruin the identity p + (q-p) == q that I'd want to hold in any hypothetical safe dialect of C. – tmyklebu Dec 10 '14 at 17:57
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    someone please tell me, why don't I get a stackoverflow badge "started a flame war" :-) – user1998586 Jun 20 '15 at 8:28

You can also consider this usage of memmove seen in Git 2.14.x (Q3 2017)

See commit 168e635 (16 Jul 2017), and commit 1773664, commit f331ab9, commit 5783980 (15 Jul 2017) by René Scharfe (rscharfe).
(Merged by Junio C Hamano -- gitster -- in commit 32f9025, 11 Aug 2017)

It uses an helper macro MOVE_ARRAY which calculates the size based on the specified number of elements for us and supports NULL pointers when that number is zero.
Raw memmove(3) calls with NULL can cause the compiler to (over-eagerly) optimize out later NULL checks.

MOVE_ARRAY adds a safe and convenient helper for moving potentially overlapping ranges of array entries.
It infers the element size, multiplies automatically and safely to get the size in bytes, does a basic type safety check by comparing element sizes and unlike memmove(3) it supports NULL pointers iff 0 elements are to be moved.

#define MOVE_ARRAY(dst, src, n) move_array((dst), (src), (n), sizeof(*(dst)) + \
    BUILD_ASSERT_OR_ZERO(sizeof(*(dst)) == sizeof(*(src))))
static inline void move_array(void *dst, const void *src, size_t n, size_t size)
    if (n)
        memmove(dst, src, st_mult(size, n));


- memmove(dst, src, (n) * sizeof(*dst));
+ MOVE_ARRAY(dst, src, n);

It uses the macro BUILD_ASSERT_OR_ZERO which asserts a build-time dependency, as an expression (with @cond being the compile-time condition which must be true).
The compilation will fail if the condition isn't true, or can't be evaluated by the compiler.

#define BUILD_ASSERT_OR_ZERO(cond) \
(sizeof(char [1 - 2*!(cond)]) - 1)


#define foo_to_char(foo)                \
     ((char *)(foo)                     \
      + BUILD_ASSERT_OR_ZERO(offsetof(struct foo, string) == 0))
  • The existence of optimizers that think "clever" and "dumb" are antonyms makes the test for n necessary, but more efficient code would generally be possible on an implementation that guaranteed that memmove(any,any,0) would be a no-op. Unless a compiler can replace a call to memmove() with a call to memmoveAtLeastOneByte(), the workaround to guard against clever/stupid compilers' "optimization" will generally result in an extra comparison a compiler won't be able to eliminate. – supercat Aug 14 '17 at 23:34

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