1

When I define:

char ch_array[50];
  1. What's the difference between &ch_array[0] and ch_array?

  2. What if I define like this?

    char *ch_array = (char *) malloc(sizeof(char)*50);
    

    The problem actually comes from when I use (&ch_array + 128) vs. &ch_array[128], when bcopy(&ch_array + 128, buf, 128);.

  3. I got a segementation fault here, but no fault using bcopy(&ch_array[128], buf, 128);, why? Does it have anything to do with the location where the array is stored?

2
  • 2
    Your subject and question is different. &ch_array + 128 is nonsensical.
    – leppie
    Apr 28, 2013 at 17:54
  • 1
    Don't ask three questions in one. Apr 28, 2013 at 18:37

3 Answers 3

5

the problem actually comes from when I use (&ch_array + 128) vs. &ch_array[128], when bcopy(&ch_array + 128, buf, 128);

ch_array is an array (an array of 50 char, to be precise). &ch_array[0] is a pointer to char, a pointer to ch_array's initial element.

In most contexts, the array name is converted to a pointer to its initial element, but one of the exceptions(1) is when it is the operand of the address operator &.

Thus &ch_array is a pointer to an array of 50 char, and

&ch_array + 128

is adds 128 * sizeof(char[50]) to the address of ch_array. By what we have been given in the question, the addition invokes undefined behaviour, but in practice, usually you will obtain an address 128*50 = 6400 bytes from the start of ch_array.

&ch_array[128] on the other hand, is a pointer to the 128-th element of the array ch_array (that doesn't exist, so it's more undefined behaviour), 128 bytes from the start of ch_array.


If you define it

char *ch_array = (char *) malloc(sizeof(char)*50);

then ch_array is a pointer to char, and it also has the same value as &ch_array[0], but in contrast to the above, there is no conversion involved.

Then, &ch_array is a char**, and &ch_array + 128 would be - without the undefined behaviour that is invoked since ch_array is not an element of a sufficiently large char* array - a char** pointing to a place 128 * sizeof(char*) bytes behind where ch_array is stored.


(1) The exceptions are when an expression of type "array of T" is the operand of the sizeof or address (&) operators, and when it is a string literal used to initialise a char array, or a wide string literal used to initialise a wide character array.

2
  • The _Alignof exception doesn't actually exist (that's an error in the N1570 draft of the C11 standard, fixed in the final standard). The _Alignof operator does not take an expression as an operand. Apr 28, 2013 at 18:23
  • My mistake. In the third question, I actually defined ch_array[256] Apr 30, 2013 at 8:16
1
bcopy(&ch_array[128], buf, 128);

is equivalent to

bcopy(ch_array+128, buf, 128);

but

bcopy(&ch_array+128, buf, 128);

is something entirely different.

-1

First of all, ch_array and &ch_array are different, whichever definition of ch_array you use. ch_array and &ch_array[0] are almost synonymns, though ocassionally the compiler chokes on ch_array but accepts &ch_array[0]. ch_array and &ch_array[0] are both of type char *. &ch_array is of type char **.

ch_array + 128 is a synonymn for &ch_array[128]. It's not a synonymn for &ch_array[128]. The former mean 128 bytes into ch_array. The latter means 128 char pointers after the address of ch_array, which is likely to be somewhere kind of random; in your case it's not even part of your address space.

Second of all, if you really did define ch_array[50] and then access the 128th element, you are asking for a SEGV there too.

1
  • 1
    -1 ch_array is not of type char* it is of type char[50]. In most contexts it is converted to char* but that is not the same thing. Apr 28, 2013 at 18:40

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