In the following bit of code, pointer values and pointer addresses differ as expected.
But array values and addresses don't!
How can this be?
Output
my_array = 0022FF00
&my_array = 0022FF00
pointer_to_array = 0022FF00
&pointer_to_array = 0022FEFC#include <stdio.h>
int main()
{
char my_array[100] = "some cool string";
printf("my_array = %p\n", my_array);
printf("&my_array = %p\n", &my_array);
char *pointer_to_array = my_array;
printf("pointer_to_array = %p\n", pointer_to_array);
printf("&pointer_to_array = %p\n", &pointer_to_array);
printf("Press ENTER to continue...\n");
getchar();
return 0;
}
Answers;-
The name of an array usually evaluates to the address of the first element of the array, so array and&array have the same value (but different types, so array+1 and &array+1 will not be equal if the array is more than 1 element long).
There are two exceptions to this: when the array name is an operand of sizeof or unary & (address-of), the name refers to the array object itself. Thus sizeof array gives you the size in bytes of the entire array, not the size of a pointer.
For an array defined as T array[size], it will have type T *. When/if you increment it, you get to the next element in the array.
&array evaluates to the same address, but given the same definition, it creates a pointer of the typeT(*)[size] -- i.e., it's a pointer to an array, not to a single element. If you increment this pointer, it'll add the size of the entire array, not the size of a single element. For example, with code like this:
char array[16];
printf("%p\t%p", (void*)&array, (void*)(&array+1));
We can expect the second pointer to be 16 greater than the first (because it's an array of 16 char's). Since %p typically converts pointers in hexadecimal, it might look something like:
0x12341000 0x12341010
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