These are all functionally identical. When you pass an array to a function in C, the array gets implicitly converted to a pointer to the first element of the array. Hence, these three functions will print the same output (that is, the size of a pointer to char
).
void func1(char* str) {
printf("sizeof str: %zu\n", sizeof str);
}
void func2(char str[]) {
printf("sizeof str: %zu\n", sizeof str);
}
void func3(char str[10]) {
printf("sizeof str: %zu\n", sizeof str);
}
This conversion only applies to the first dimension of an array. A char[42][13]
gets converted to a char (*)[13]
, not a char **
.
void func4(char (*str_array)[13]) {
printf("sizeof str_array: %zu\n"
"sizeof str_array[0]: %zu\n", sizeof str_array, sizeof str_array[0]);
}
char (*)[13]
is the type of str_array
. It's how you write "a pointer to an array of 13 char
s". This could have also been written as void func4(char str_array[42][13]) { ... }
, though the 42 is functionally meaningless as you can see by experimenting, passing arrays of different sizes into func4
.
In C99 and C11 (but not C89 or C++), you can pass a pointer to an array of varying size into a function, by passing it's size along with it, and including the size identifier in the [square brackets]
. For example:
void func5(size_t size, char (*str_array)[size]) {
printf("sizeof str_array: %zu\n"
"sizeof str_array[0]: %zu\n", sizeof str_array, sizeof str_array[0]);
}
This declares a pointer to an array of size char
s. Note that you must dereference the pointer before you can access the array. In the example above, sizeof str_array[0]
evaluates to the size of the array, not the size of the first element. As an example, to access the 11th element, use (*str_array)[11]
or str_array[0][11]
.
void func (size_t size, char str[size])
, which might be preferable in some situations. Not possible in C++ though.