I wanted to use memcpy to do a 'type agnostic swap' in an array which might contain arbitrary types. Why does it require a const src pointer?

I wrote my own version instead:

void copyBytes(char *x, char *y, int howMany){
  int i;
  for(i = 0; i<howMany; i++){
    *(x+i) = *(y+i);

Is there something wrong with my version?

  • 5
    const * isn't a restriction on *, it's a relaxation. – user541686 Sep 23 '13 at 0:03
  • 2
    It doesn't require a const pointer - you can pass in non-const sources just fine. But because of that const modifier — basically a promise not to modify the source — you're able to pass in const sources, which would otherwise trigger warnings or errors, since the compiler would assume they might be modified. – Paul Roub Sep 23 '13 at 0:04
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    A non-const pointer can be implicitly converted to a const pointer (const is a promise not to modify it), but the reverse is not possible. If the caller has a const pointer it means that it promised not to modify it, so, not to break this promise, changing it to a non-const pointer is not allowed. – Matteo Italia Sep 23 '13 at 0:43

Is there something wrong with my version?

I'd say so. Here's a critique.

void copyBytes(char *x, char *y, int howMany)

First of all your pointers are char *, which means any pointer type other than char * needs to be explicitly converted. You should be using void *, to which pointer types are implicitly converted.

uint16_t a, b;

copyBytes(&a, &b, sizeof(a));  // &a and &b are uint16_t*, not char*.

Second, the source, y, is not const, which means you will get warnings if you pass a const source.

char buf[512];
const char str[] = "Hello world";  // Contents of string are constant.
copyBytes(buf, str, sizeof(str));  // With your code, this produces a warning.

Third, howMany is signed, meaning you can pass a negative value.

I would recommend a signature like this (incidentally this is very similar to memcpy):

void copyBytes(void *x, const void *y, size_t howMany)

A fourth critique ... libc's memcpy is likely to be much better optimized, using larger-than-byte units, platform-specific performance tricks (example: inline assembly, SSE on x86), etc. There's also memmove which has better specified behavior when the buffers overlap.

In conclusion: It's fine to write these routines yourself for learning purposes, but you're usually much better off with the C library.


"Require"? "Require" is a wrong word. memcpy doesn't require a const src pointer. It allows a const src pointer. Allowing a const src pointer is a weaker specification then requiring a non-const src pointer. It extends the applicability of the function, not restricts it.

Requiring a non-const src pointer would restrict the applicability of memcpy - you wouldn't be able to pass pointers to const data to your function (unless you use an ugly cast). Why would you introduce such a requirement? memcpy does not modify the src data, so it is perfectly logical to allows constant data to be used as src for memcpy. This is why memcpy declares the src pointer as const.

The word "require" is actually applies to your version in this case. Your version requires non-const pointer as src pointer. And because of that additional (and completely unnecesary) requirement, your version is less applicable than memcpy. For example

const char src_data[3] = { 1, 2, 3 };
char dst_data[3];

memcpy(dst_data, src_data, sizeof dst_data);    // Works
copyBytes(dst_data, src_data, sizeof dst_data); // Doesn't even compile

Function memcpy doesn't modify source memory. That means it doesn't require a non-const pointer, it allows a const pointer as well as a non-const pointer. This is not a restriction on the parameter nor on the applicability of the function. You may pass any valid data pointer in there.

This is called an implicit conversion by compiler. In your particular case with const it is "Qualification conversion".

unqualified type can be converted to const

Opposite implicit conversion from a const pointer to a pointer is not allowed. Note word "implicit" here. That means func(void *pointer) is more restrictive than func(void const *pointer).

If you omit const qualifier you leverage compiler imposed type safety. Compiler will warn you or others that it won't be a good idea to pass a const pointer in.

If you use const qualifier in a function declaration you make a promise that you won't modify data there. This is a good hint to a programmer and improves readability of your code. However, this is a promise only. A bad function may violate the promise by casting out const-ness inside the function body. This is technically possible but bad.

  • 1
    Not quite any pointer. You may pass any pointer to an object to memcpy. Passing a pointer to a function to memcpy is not defined. – Eric Postpischil Sep 23 '13 at 0:47
  • 1
    @EricPostpischil Well, yes. Then, in the same spirit, we need to say "any valid data pointer". – dmitri Sep 23 '13 at 4:22

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