Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

In embedded software domain for copying structure of same type people don't use direct assignment and do that by memcpy() function or each element copying.

lets have for example

struct tag

int a;

int b;

struct tag exmple1 = {10,20};

struct tag exmple2;

for copying exmple1 into exmple2.. instead of writing direct


people use

memcpy(exmple2,exmple1,sizeof(struct tag));



why ????

share|improve this question
This is definitely a C question. –  Puppy Jul 27 '11 at 9:58
@patel: suggest you use a different word in the title besides "dangerous" -- the word is too loaded with connotations. –  Jason S Jul 28 '11 at 16:49

9 Answers 9

up vote 10 down vote accepted

One way or the other there is nothing specific about embedded systems that makes this dangerous, the language semantics are identical for all platforms.

C has been used in embedded systems for many years, and early C compilers, before ANSI/ISO standardisation did not support direct structure assignment. Many practitioners are either from that era, or have been taught by those that were, or are using legacy code written by such practitioners. This is probably the root of the doubt, but it is not a problem on an ISO compliant implementation. On some very resource constrained targets, the available compiler may not be fully ISO compliant for a number of reasons, but I doubt that this feature would be affected.

One issue (that applies to embedded and non-embedded alike), is that when assigning a structure, an implementation need not duplicate the value of any undefined padding bits, therefore if you performed a structure assignment, and then performed a memcmp() rather than member-by-member comparison to test for equality, there is no guarantee that they will be equal. However if you perform a memcpy(), any padding bits will be copied so that memcmp() and member-by-member comparison will yield equality.

So it is arguably safer to use memcpy() in all cases (not just embedded), but the improvement is marginal, and not conducive to readability. It would be a strange implementation that did not use the simplest method of structure assignment, and that is a simple memcpy(), so it is unlikely that the theoretical mismatch would occur.

share|improve this answer
+1: I'd bet that the real reason you see memcpy() more often in embedded code is more of a result of cargo cult programming than making sure you can compare using memcmp(). –  Michael Burr Jul 27 '11 at 14:54
I had to look it up, but yes. –  Clifford Jul 28 '11 at 15:55
Your references to the == operator are unclear. ANSI C does not provide a == operator for structures. Regarding the last paragraph - why should using memcmp() in all cases be safer? For example for comparing two structures with equal attributes but different padding bits it is not safer. Safer - in all cases - would be to compare 2 structures attribute-wise. –  maxschlepzig Jul 4 '14 at 18:38
@maxschlepzig : It has taken three years for anyone to notice that - doh! –  Clifford Jul 5 '14 at 7:08

In your given code there is no problem even if you write:

example2 = example1;

But just assume if in future, the struct definition changes to:

struct tag
  int a[1000];
  int b;

Now if you execute the assignment operator as above then (some of the) compiler might inline the code for byte by byte (or int by int) copying. i.e.

example1.a[0] = example.a[0];
example1.a[1] = example.a[1];
example1.a[2] = example.a[2];

which will result in code bloat in your code segment. Such kind of memory errors are not trivial to find. That's why people use memcpy.

[However, I have heard that modern compilers are capable enough to use memcpy internally when such instruction is encountered especially for PODs.]

share|improve this answer
It would be an unusual C implementation that used member-member copy (or in your case element-element copy) for structure assignment. Is this really "the answer", and how is this issue specific to embedded systems? There is no "danger" here. –  Clifford Jul 27 '11 at 13:20
@iammilind: but are you aware of any compilers that actually perform structure assignment in the non-optimal fashion? –  Michael Burr Jul 27 '11 at 14:58
upvoted, because in embedded systems the effects of extra code will are much more expensive than on standard PCs, and that's why memcpy is sometimes needed. –  Jason S Jul 27 '11 at 18:00
...in my embedded world, I care about an extra 5 microseconds (my current project uses a 10kHz control loop), so I have to spend time double-checking the compiler. In parts of my code, I have to make sure it doesn't turn what should be a quicker block memory copy into a longer series of individual word copies. I have to make sure I'm leaving enough margin in my code space, my RAM space, stack space, and data execution time, because I'm dealing with a few kilobytes of available RAM and 100MHz CPU speeds (both luxuries compared with 5 yrs ago). –  Jason S Jul 28 '11 at 16:45
@Jason: I am not sure that warranted the run-on comment; comment length is restricted for a reason I suggest! Your point was well understood (I am sucking my eggs right now); my point was that there is in all probability no additional code. The "danger" if there is any comes from the lack of any guarantee that the content of any padding is copied. "Code bloat" itself may cause a project to fail to meet constraints, but that is not in itself "dangerous" - stick to the question in hand, which is about "dangerous" code. –  Clifford Jul 30 '11 at 9:47

That is a complete nonsense. Use whichever way you prefer. The simplest is :

share|improve this answer
then may be older version of compiler may be could not handle this type of assignment .? –  Mr.32 Jul 27 '11 at 10:02
@patel jigar: If it could not handle assignment then it is not a C compiler probably. –  Juraj Blaho Jul 27 '11 at 10:16
@Juraj Maybe with an ancient compiler (like for example gcc 2.95) that is not fully c standard compliant (also to add : I answered to the c++ part of that question, because c++ tag was there) –  BЈовић Jul 27 '11 at 10:19
@V jo ya you may right –  Mr.32 Jul 27 '11 at 11:53
@Juraj: GCC 2.95 is ISO C compliant, it is not ISO C++ compliant however. The ANSI C standard was completed in 1989, and adopted by ISO 1990 most existing compilers needed little modification to support it. –  Clifford Jul 28 '11 at 16:12

In C people probably do that, because they think that memcpy would be faster. But I don't think that is true. Compiler optimizations would take care of that.

In C++ it may also have different semantics because of user defined assignment operator and copy constructors.

share|improve this answer
" sometimes its gives error for using exmple2=exmple1; " –  Mr.32 Jul 27 '11 at 10:00
@patel jigar: Where did you hear that? –  Juraj Blaho Jul 27 '11 at 10:02
my proffesor says so... –  Mr.32 Jul 27 '11 at 10:04
@patel jigar: Ask him if he could explain why it could give an error. I am really interested. The only possibility, I can see, could be a faulty compiler or linking incompatible binaries. –  Juraj Blaho Jul 27 '11 at 10:11
@patel: "sometimes"!? Always or never is plausible, but not sometimes! When example2 and example1 are not of the same type perhaps. Your professor is either incorrect or you have misunderstood. You cannot for example assign an array to an array; perhaps that is what you are thinking of, a struct to a struct however is OK. If the struct contains pointers, the pointer values will be duplicated but not the data pointed to - that may also what he is referring to. –  Clifford Jul 28 '11 at 16:09

Copying C-structures via memcpy() is often used by programmers who learned C decades ago and did not follow the standardization process since. They simple don't know that C supports assignment of structures (direct structure assignment was not available in all pre-ANSI-C89 compilers).

When they learn about this feature some still stick to the memcpy() way because it is their custom. There are also motivations that originate in cargo cult programming, e.g. it is claimed that memcpy is just faster - of course - without being able to back this up with a benchmark test case.

Structures are also memcpy()ied by some newbie programmers because they either confuse structure assignment with the assignment of a pointer of a structure - or they simply overuse memcpy() (they often also use memcpy() where strcpy() would be more appropriate).

There is also the memcmp() structure comparison anti-pattern that is sometimes cited by some programmers for using memcpy() instead of structure assignment. The reasoning behind this is the following: since C does not automatically generate a == operator for structures and writing a custom structure comparison function is tedious, memcmp() is used to compare structures. In the next step - to avoid differences in the padding bits of compared structures - memset(...,0,...) is used to initialize all structures (instead of using the C99 initializer syntax or initializing all attributes separately) and memcpy() is used to copy the structures! Because memcpy() also copies the content of the padding bits ...

But note that this reasoning is flawed for several reasons:

  • the use of memcpy()/memcmp()/memset() introduce new error possibilities - e.g. supplying a wrong size
  • when the structure contains integer attributes the ordering under memcmp() changes between big- and little-endian architectures
  • a char array attribute of size n that is 0-terminated at position x must also have all elements after position x zeroed out at any time - else 2 otherwise equal structs compare unequal
  • assignment from a register to an attribute may also set the neighbouring padding bits to values unequal 0, thus, following comparisons with otherwise equal structures yield an unequal result

The last point is best illustrated with a small example (assuming architecture X):

struct S {
  int a;  // on X: sizeof(int) == 4
  char b; // on X: 24 padding bits are inserted after b
  int c;
typedef struct S S;
S s1;
memset(&s1, 0, sizeof(S));
s1.a = 0;
s1.b = 'a';
s1.c = 0;
S s2;
memcpy(&s2, &s1, sizeof(S));
assert(memcmp(&s1, &s2, sizeof(S)==0); // assertion is always true
s2.b = 'x';
assert(memcmp(&s1, &s2, sizeof(S)!=0); // assertion is always true
// some computation
char x = 'x'; // on X: 'x' is stored in a 32 bit register
              // as least significant byte
              // the other bytes contain previous data
s1.b = x;     // the complete register is copied
              // i.e. the higher 3 register bytes are the new
              // padding bits in s1
assert(memcmp(&s1, &s2, sizeof(S)==0); // assertion is not always true

The failure of the last assertion may depend on code reordering, change of the compiler, change of compiler options and stuff like that.


As a general rule: to increase code correctness and portability use direct struct assignment (instead of memcpy()), C99 struct initialization syntax (instead of memset) and a custom comparison function (instead of memcmp()).

share|improve this answer

Whatever you do, don't do this:


It poses a maintainability problem because any time that anyone adds a member to the structure, they have to add a line of code to do the copy of that member. Someone is going to forget to do that and it will cause a hard to find bug.

share|improve this answer
I agree it poses a maintainability problem, but in some cases the programmer has to be more explicit in what's going on rather than delegating that responsibility to the compiler. –  Jason S Jul 28 '11 at 16:52

On top of what the others wrote some additional points:

  • Using memcpy instead of a simple assignment gives a hint to someone who maintains the code that the operation might be expensive. Using memcpy in these cases will improves the understanding of the code.

  • Embedded systems are often written with portability and performance in mind. Portability is important because you may want to re-use your code even if the CPU in the original design is not available or if a cheaper micro-controller can do the same job.

    These days low-end micro-controllers come and go faster than the compiler developers can catch up, so it is not uncommon to work with compilers that use a simple byte-copy loop instead of something optimized for structure assignments. With the move to 32 bit ARM cores this is not true for a large part of embedded developers. There are however a lot of people out there who build products that target obscure 8 and 16 bit micro-controllers.

  • A memcpy tuned for a specific platform may be more optimal than what a compiler can generate. For example on embedded platforms having structures in flash memory is common. Reading from flash is not as slow as writing to it, but it is still a lot slower than a ordinary copy from RAM to RAM. A optimized memcpy function may use DMA or special features from the flash controller to speed up the copy process.

share|improve this answer

On some implementations, the way in which memcpy() is performed may differ from the way in which "normal" structure assignment would be performed, in a manner that may be important in some narrow contexts. For example, one or the other structure operand may be unaligned and the compiler might not know about it (e.g. one memory region might have external linkage and be defined in a module written in a different language that has no means of enforcing alignment). Use of a __packed declaration would be better if a compiler supported such, but not all compilers do.

Another reason for using something other than structure assignment could be that a particular implementation's memcpy might access its operands in a sequence that would work correctly with certain kinds of volatile source or destination, while that implementation's struct assignment might use a different sequence that wouldn't work. This is generally not a good reason to use memcpy, however, since aside from the alignment issue (which memcpy is required to handle correctly in any case) the specifications for memcpy don't promise much about how the operation will be performed. It would be better to use a specially-written routine which performed the operations exactly as required (for example, if the target is a piece of hardware which needs to have 4 bytes of structure data written using four 8-bit writes rather than one 32-bit writes, one should write a routine which does that, rather than hoping that no future version of memcpy decides to "optimize" the operation).

A third reason for using memcpy in some cases would be the fact that compilers will often perform small structure assignments using a direct sequence of loads and stores, rather than using a library routine. On some controllers, the amount of code this requires may vary depending upon where the structures are located in memory, to the point that the load/store sequence may end up being bigger than a memcpy call. For example, on a PICmicro controller with 1Kwords of code space and 192 bytes of RAM, coping a 4-byte structure from bank 1 to bank 0 would take 16 instructions. A memcpy call would take eight or nine (depending upon whether count is an unsigned char or int [with only 192 bytes of RAM total, unsigned char should be more than sufficient!] Note, however, that calling a memcpy-ish routine which assumed a hard-coded size and required both operands be in RAM rather than code space would only require five instructions to call, and that could be reduced to four with the use of a global variable.

share|improve this answer

first version is perfect.
second one may be used for speed (there is no reason for your size).
3rd one is used only if padding is different for target and source.

share|improve this answer
I would guess that the second version would be no faster than the first version with any modern compiler. The first version actually calls memcpy in the implementations that I have seen. –  semaj Jul 27 '11 at 15:20

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.