The purpose delete() or free() is to mark the memory, which was allocated to the pointer by new() available again for reuse by the system.
If you see the output of code :
List *a = new List();
cout<<"Address to which 'a' points because of new() : "<<a<<'\n';
cout<<"Address of pointer 'a' itself : "<<&a<<'\n';
List *b = new List();
cout<<"Address to which 'b' points because of new() : "<<b<<'\n';
cout<<"Address of pointer 'b' itself : "<<&b<<'\n';
cout<<"Even after deletion : \n";
cout<<" a points to : "<<a<<'\n';
cout<<" b pointer to : "<<b<<'n';
It is very important you understand the output of this code.
The output is:
Address to which 'a' points because of new() : 0x830d70
Address of pointer 'a' itself : 0x28fefc
Address to which 'b' points because of new() : 0x830d70
Address of pointer 'b' itself : 0x28fef8
Even after deletion :
a points to : 0x830d70
b points to : 0x830d70
As you can see the addresses to which pointer 'a' and 'b' point is same. This is because when delete is called on pointer a, the memory pointed by pointer 'a' is marked available or can be used for next memory allocation requests.
And when new() is called again, the same memory which was allocated for pointer 'a' earlier, is reused again and pointer 'b' points to it.
Because the same memory location is used again, and our program did not request for a any new memory space, the program will have less memory requirements which is good. This is dynamic memory allocation.
Another thing to note is that the address of the two pointers is different. So the pointers have different memory location and that is not reused even if pointer 'a' is deleted and then pointer 'b' is deleted. delete() called on pointer 'a' reclaims the memory to which it is pointing and not of the pointer 'a' itself.
And that is why even after delete() is called for pointer 'a' and pointer 'b', printing them does not throws any exception and terminate the program. delete() has made the memory location pointed by the pointer available for reuse but not has made the contents of pointer NULL or something else. So it still points to that location. And that is printing the contents of pointer before and after delete() is same.
Accessing the pointer by with dereferencing in program for lists, stacks, queues etc. may terminate is program.
But following code does not terminate the program
int *n = new int(1);
The out of above code is '1' in the first line and some garbabe value in the second line.
See the following one :
int *a = new int(1);
int *z = new int(21);
the output of the above is '1' in first line and '21' in the second line.
this is because calling delete() for pointer 'a' marks the pointed memory reusable and that is taken up again and pointer 'z' points to it.
So cout<<*a prints 21 which we had actually assigned to 'z';
It also shows that the pointer name can still be used again even if delete() has been called upon it.