This question is out of pure curiosity. I recently learnt that it is very important to delete memory space if it is dynamically allocated in the Heap. My question, is it possible to delete the dynamically allocated memory space using a different C++ program (from the one with which the memory space was created) if the address of the memory space is known?

Here's an example:


#include <iostream>
using namespace std;

int main() {
    int *a = new int;
    cout << a;
    int foo;
    cin >> foo;  // for blocking the program from closing.
    return 0;

Output for CODE01.CPP (say)



#include <iostream>
using namespace std;

int main() {
    int *a = (int*)0x7c1640;
    delete a;
    return 0;

Will this work? If I first run code01.cpp and then immediately code02.cpp will the memory in the Heap get deleted?

  • 2
    To be clear, in CODE01 the memory will be cleared when the program ends. If your object had a destructor, it might not clean up properly. But in this case, you are dealing with an int so it doesn't matter. If you are concerned about memory, allocated memory is always freed when the program ends. – François Andrieux Oct 11 at 15:08
  • 4
    then you learned it wrong. once the program terminates all memory is handed back to the OS – formerlyknownas_463035818 Oct 11 at 15:10
  • 6
    A modern OS will give you a separate virtual address space for each process. The addresses are meaningless across processes. – drescherjm Oct 11 at 15:12
  • 1
    @MarekR I don't see why this is too broad? Just make an answer which states that the memory space is not shared. This is a fine question. – ruohola Oct 11 at 15:14
  • 3
    Common modern desktop platform do not support this capability. There are old platforms (that are not in common use today) which could do that (e.g., old Amiga with OS allocated memory blocks, old Mac with cooperative memory chunk management). There may be modern embedded platforms that also might provide that capability (executable overlays and shared memory pool). – Eljay Oct 11 at 15:29

Any modern OS will create a separate virtual address space for both of the programs. Thus the address you are printing in code01.cpp is only relevant for that program and you cannot access the address space from code02.cpp.

So to answer your immediate question: running cpp02.cpp will not affect the state of the still running cpp01.cpp in any way.


One of the jobs assigned to opeating systems is the insure that one process can not harm another one. This mean preventing one process from affecting the memory used by another one directly in any way.

There are several mechanisms for this but they all defeat the idea

"If I know the value of a pointer used in that process, then I can do something to it's memory from this processes."

because that is exactly what the OS is suppose to prevent.

That said many OSs provide special channels (intended for interprocess communication) that you could abuse to allow something similar. But you'd have to work at it,and the details depend on the OS.

  • Even if you were to be able to work around the OS memory protection, the two processes would still be using their own C++ heap with their own control structures. Freeing to the wrong process heap would be disaster. – Mark Ransom Oct 11 at 15:30
  • To make it work you'd have to implement your own "heap" management seaprate from the new/delete mechanism of the language. Say both processes memory-map a common file, then use the memory for an object store. In that context "pointers" are file-offsets. As I say, you'd have to work at it, but in that context you could make process B responsible for releasing an object inserted by process A. – dmckee Oct 11 at 15:34

The short answer, on most modern operating systems, is no. Most operating systems use virtual memory which means 0x7c1640 in program A is not necessarily 0x7c1640 in program B. In order for this to be possible, you would have to write a custom OS for this with no memory protection, at which point any program can overwrite any other program, which is a major security vulnerability.

A related question offers the diagram below of how virtual addresses are occupied. Each program gets a fake memory address the OS translates, so each program gets a different heap and cannot interact with each other through memory directly, at least on a common virtual memory system.

Process memory allocation

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