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C++ Pointers vs Arrays
Pointers and arrays are strongly related. In fact, pointers and arrays are interchangeable in many cases. For example, a pointer that points to the beginning of an array can access that array by using either pointer arithmetic or array-style indexing. Consider the following program −
#include <iostream>
using namespace std;
const int MAX = 3;
int main () {
int var[MAX] = {10, 100, 200};
int *ptr;
// let us have array address in pointer.
ptr = var;
for (int i = 0; i < MAX; i++) {
cout << "Address of var[" << i << "] = ";
cout << ptr << endl;
cout << "Value of var[" << i << "] = ";
cout << *ptr << endl;
// point to the next location
ptr++;
}
return 0;
}
When the above code is compiled and executed, it produces result something as follows −
Address of var[0] = 0xbfa088b0 Value of var[0] = 10 Address of var[1] = 0xbfa088b4 Value of var[1] = 100 Address of var[2] = 0xbfa088b8 Value of var[2] = 200
However, pointers and arrays are not completely interchangeable. For example, consider the following program −
#include <iostream>
using namespace std;
const int MAX = 3;
int main () {
int var[MAX] = {10, 100, 200};
for (int i = 0; i < MAX; i++) {
*var = i; // This is a correct syntax
var++; // This is incorrect.
}
return 0;
}
It is perfectly acceptable to apply the pointer operator * to var but it is illegal to modify var value. The reason for this is that var is a constant that points to the beginning of an array and can not be used as l-value.
Because an array name generates a pointer constant, it can still be used in pointer-style expressions, as long as it is not modified. For example, the following is a valid statement that assigns var[2] the value 500 −
*(var + 2) = 500;
Above statement is valid and will compile successfully because var is not changed.