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Is malloc deterministic? Say If I have a forked process, that is, a replica of another process, and at some point both of them call the malloc function. Would the address allocated be the same in both processes? Assuming that other parts of execution are also deterministic.

Note: Here, I'm only talking about virtual memory, not physical one.

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7 Answers 7

up vote 22 down vote accepted

There is no reason at all for it to be deterministic, in fact there can be some benefit to it not being deterministic, for example increasing the complexity of exploiting bugs (see also this paper).

This randomness can be helpful at making exploits harder to write. To successfully exploit a buffer overflow you typically need to do two things:

  1. Deliver a payload into a predictable/known memory location
  2. Cause execution to jump to that location

If the memory location is unpredictable making that jump can become quite a lot harder.

The relevant quote from the standard §

The malloc function allocates space for an object whose size is specified by size and whose value is indeterminate

If it were the intention to make it deterministic then that would be clearly stated as such.

Even if it looks deterministic today I wouldn't bet on it remaining so with a newer kernel or a newer libc/GCC version.

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I don't think security has much relevance to the question. Nevertheless, what you wrote about exploiting is correct. –  jweyrich Nov 17 '11 at 17:00
@jweyrich - the C standard explicitly states that it's not deterministic. The fact that it's not deterministic can be useful for implementations in a variety of ways - I used address space randomisation as an obvious modern example, but there are also other less obvious reasons (implementations where there is no such thing as virtual memory springs to mind). –  Flexo Nov 17 '11 at 17:05
I didn't say otherwise. Your answer is ok, though IMO quoting that part of the standard would be the definitive answer. –  jweyrich Nov 17 '11 at 17:13
@SimonRichter - I have to admit I'd always assumed fork() copied all threads, but you're right and the spec is very clear on that too - pubs.opengroup.org/onlinepubs/009695399/functions/fork.html - malloc() isn't async-safe though if I remember correctly which means you can't legally call it in a child after fork() though, since it seems to impose the async-safe requirement on the child after a multithreaded fork(). –  Flexo Nov 17 '11 at 17:53
malloc isn't safe after vfork -- but after a fork is completely fine. –  Simon Richter Nov 17 '11 at 21:09

The C99 spec (at least, in its final public draft) states in 'J.1 Unspecified behavior':

The following are unspecified: ... The order and contiguity of storage allocated by successive calls to the calloc, malloc, and realloc functions (7.20.3).

So it would seem that malloc doesn't have to be deterministic. It therefore isn't safe to assume that it is.

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I don't think you're wrong, but that quotation speaks strictly about contiguity of storage, which has no relation to determinism. An implementation could be deterministic and yet not allocate contiguous memory in successive calls. Or am I wrong? –  jweyrich Nov 17 '11 at 17:06
jweyrich, I agree with you. Determinism has nothing to do with order and contiguity of storage allocated. –  MetallicPriest Nov 17 '11 at 17:26
It speaks about both contiguity and order. So my reading is that the spec specifies no required behaviour for the order of returned storage. So, amongst other things, it doesn't specify that it must be deterministic. A valid implementation therefore may or may not be deterministic. –  Tommy Nov 17 '11 at 17:38

That depends entirely on the malloc implementation. There's no inherent reason why a particular malloc implementation would introduce non-determinism (except possibly as an application fuzzing test, but even then it ought to be disabled by default). For example, Doug Lea's malloc does not use rand(3) or any similar methods in it.

But, since malloc makes calls to the kernel such as sbrk(2) or mmap(2) on Linux or VirtualAlloc on Windows, those system calls may not always be deterministic, even in otherwise identical processes. The kernel may decide to intentionally provide different mmap'ed addresses in different processes for whatever reason.

So for small allocations, which are usually serviced in user space without a system call, it will quite likely be the case that the resulting pointers will be the same after a fork(); large allocations that are serviced by a system a call can be the same.

In general, though, do not depend on it. If you really need identical pointers in separate processes, either create them before forking, or use shared memory and share them appropriately.

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sbrk is deterministic. –  Random832 Nov 17 '11 at 21:01

It depends on the detailed implementations of malloc. A typical malloc implementation (e.g., dlmalloc) used to be deterministic. This is simply because the algorithm itself is deterministic.

However, due to many security attacks such as heap overflow attacks, malloc, that is a heap manager, introduced some randomness in their implementations. (But, its entropy is relatively small because heap managers must consider speed and space) So, it is safe that you should not assume rigorous determinism in a heap managers.

Also, when you fork a process, there are various sources of randomness including ASLR.

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As far as I know, ASLR is not performed on a forked process, only a parent process, or is it? –  MetallicPriest Nov 17 '11 at 16:58
@MetallicPriest: ASLR can't change the stack/heap addresses that already exist when forking, but it can affect future mmap calls used to service malloc requests. –  R.. Nov 18 '11 at 16:29

Yes, it's deterministic to some degree, but not that doesn't necessarily mean it'll given identical results in two forks of a process. For it to ensure identical results in both forks of a process, the fork would have to reproduce the heap (including all free blocks) identically.

One obvious possibility would be address space layout randomization, now practiced in most OSes to improve security. Despite being a fork, the clone of a process may have its address space laid out considerably differently from the original.

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You won't get the same physical address. If you have process A and B each call of malloc returns the address of a free block. The order in which A and B calls malloc is not predictable. But it never happens "in the same moment".

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Technically, if the forked processes both request the same size of block, they should get the same address allocated, but each of those addresses will point to a different physical/real memory location.

Linux uses copy-on-write for fork, so forked children share their parent's memory, until something is changed in either process. At that point the kernel goes through the memory copying sequence to give the forked child it's own dedicated/unique copy of its memory space.

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I am not talking about real memory, only virtual memory. I know about copy-on-write and virtual memory management. –  MetallicPriest Nov 17 '11 at 16:53
"Technically, if the forked processes both request the same size of block, they should get the same address allocated" - That's not true at all - the value of addresses given by malloc is unspecified and often the randomness is introduced by the kernel call itself, not anything in user space, so the libc implementation doesn't have to call rand() or anything crazy like that to make it non-deterministic. –  Flexo Nov 17 '11 at 16:55
malloc is going to try to prevent address space fragmentation and won't allocate blocks at random. But when the kernel maps the process' virtual memory space to physical, THAT mapping can be randomized. –  Marc B Nov 17 '11 at 16:56
@MarcB - malloc is possibly just a call to sbrk or mmap (since we're looking for deterministic we can't safely assume that there will have been sufficient memory left over from a free or previous sbrk/mmap call to handle the request), neither of those calls promise anything more than trying to fulfil the request itself. The new pointer from a call to either of those can sensibly be randomised within the available virtual address space –  Flexo Nov 17 '11 at 17:19

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