You will want to allocate the space for both the length and the string in the same block of memory. This may be what you intended with your struct, but you have reserved space for only a pointer to the string.
There must be space allocated to contain the characters of the string.
my_string_t * alloc_my_string(char *src)
my_string_t * p = NULL;
int N_chars = strlen(src) + 1;
p = malloc( N_chars + sizeof(my_string_t));
p->num_chars = N_chars;
In my example, to access the pointer to your string, you address the
string member of the
my_string_t * p = alloc_my_string("hello free store.");
printf("String of %d bytes is '%s'\n", p->num_chars, p->string);
Be careful to realize that you are obtaining the pointer for the string as a consequence of allocating space to store the characters. The resource you are allocating is the storage for the characters, the pointer obtained is a reference to the allocated storage.
In my example, the memory allocated is laid out sequentially as follows:
| 00 | 00 | 00 | 11 | 'h'| 'e'| 'l'| 'l'| 'o'| 20 | 'f'| 'r'| 'e'| 'e'| 20 | 's'| 't'| 'o'| 'r'| 'e'| '.'| 00 |
Notice that the value of
p->string is not stored in the allocated memory, it is four bytes from the beginning of the allocated memory, immediately subsequent to the (presumed 32-bit, four-byte) integer.
Your compiler may require that you declare the flexible C array as:
but the version lacking the zero is supposedly C99-compliant.
You can accomplish the equivalent thing with no array member as follows:
char * str_of_mystr2(mystr2 * ms)
return (char *)(ms + 1);
mystr2 * alloc_mystr2(char *src)
mystr2* p = NULL;
size_t N_chars = strlen(src) + 1;
if (N_chars num_chars = (int)N_chars;
printf("String of %d bytes is '%s'\n", p->num_chars, str_of_mystr2 (p));
In this second example, the value equivalent to
p->string is calculated by
str_of_mystr2(). It will have approximately the same value as the first example, depending on how the end of structs are packed by your compiler settings.
While some would suggest tracking the length in a
size_t I would look up some old Dr. Dobb's article on why I disagree. Supporting values greater than INT_MAX is of doubtful value to your program's correctness. By using an int, you can write
assert(p->num_chars >= 0); and have that test something. With an unsigned, you would write the equivalent test something like
assert(p->num_chars < UINT_MAX / 2); As long as you write code which contains checks on run-time data, using a signed type can be useful.
On the other hand, if you are writing a library which handles strings in excess of UINT_MAX / 2 characters, I salute you.