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At the end of this wikipedia article, in a section "A simple example in C" it is claimed that "the operating system delays real memory allocation until something is written into it". From my experience this is not possible or better put, "not feasible". An OS/Processor does not track each and every memory write. Is the wikipedia article wrong like I suspect ? If not enlighten me.

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I guess when one takes page faults into consideration, than it does make sense in some ways. However, page faults and virtual memory don't fit well with a discussion on memory leaks. I mean is if process allocates 2 pages, writes to one (page one), and then leaks both pages it's still a leak regardless of weather the second page leaks physical memory or not. I guess the section should differentiate between physical memory and virtual memory ? :D

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closed as off topic by Peter O., JE SUIS CHARLIE, Stephan, Ben Carey, Freelancer May 15 '13 at 10:01

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It is written clumsily but is accurate. Virtual memory gets mapped to RAM on demand, the first access to the memory page generates a page fault. –  Hans Passant Apr 16 '11 at 21:06

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Depends on the operating system. On Linux, for example, it actually does work like that. Look up "optimistic memory allocation".

In addition to that, there is the differentiation between virtual memory and physical memory. On most operating systems, you are using virtual memory, so even though you allocate many megabytes worth of memory, the actual physical memory will only be tapped once you write into it (at which point what had been at that location before might get paged back to disk).

There is the "virtual address space" which is basically just "logical" memory that is then later mapped to the physical RAM (or your hard drive, if the memory has been paged out).

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yeh buts thats at a page level. I should have side-stepped the ambiguity =D –  Hassan Syed Apr 16 '11 at 21:52
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You're talking about two different layers here. Memory leaks occur on a higher level, i.e. you allocate a certain amount of virtual bytes and never free them. How they're broken into pages and when is completely irrelevant. –  EboMike Apr 16 '11 at 22:04

You're mistaken.

All the OS has to allocate is virtual memory. You call, say, mmap or break. It creates some virtual address space, and sets the page table entries to cause page faults. You get around to referencing the memory, the page fault happens, and the system goes to do a real memory allocation. Not before.

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I would say the comment is at the very least irrelevant to memory leaks, even if it's not erroneous. There are at least 3 measurements of memory usage:

  • virtual address space consumed
  • commit charge
  • physical memory occupied

Even if memory allocated has not been physically instantiated by a page fault, it's still taking up valuable virtual address space and commit charge.

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Lets say you allocate 1GB of virtual memory and actually only reference and use 0.5GB you still have leaked 0.5GB of your allocated address space. Even if it does not occupy actual real RAM it still requires resources from the memory allocator to manage your allocations (especially when you have allocated lots of small objects). So it still is a memory leak, because (at least on 32bit) you can only allocate an additional 1GB max. instead of 1.5GB and you have no way of releasing it from within your application.

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