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Maybe a naive question, but...

Confirm or deny:

The existence of memory for objects/variables of automatic and static storage duration is determined compile-time and there is absolutely zero chance that the program will fail runtime because there wasn't enough memory for an automatic object.

Naturally, when the constructor of an automatic object performs dynamic allocations and such allocation fails, we consider this to be a failure on dynamic allocation, and not automatic.

share|improve this question
While it can be confirmed at compile time for static objects, it cannot be done for automatic ones, because it depends on program logic. – ruslik Dec 7 '10 at 17:25
The way this question is worded sure sounds like homework/exam question, but I can't believe someone with 8k rep would be asking SO to do his homework. :) I'm curious where it came from though. – R.. Dec 7 '10 at 17:26
@R.. It came like this: When you try to allocate an automatic array which is too large you get a compile error, but when you try to allocate a large dynamic array you get a runtime error. So I thought, is it possible that I get a runtime error for the former case even if the compilation succeeds :) – Armen Tsirunyan Dec 7 '10 at 17:29
@Armen: do you expect compile error for this: int f(){int t=f();};? – ruslik Dec 7 '10 at 17:34
@ruslik: No, I most certainly do not. Though I will most likely get a warning – Armen Tsirunyan Dec 7 '10 at 17:36
up vote 13 down vote accepted

Two words : Stack Overflow. :P

share|improve this answer
I have to say, I couldn't believe this answer had two upvotes. And then I made it three. – Billy ONeal Dec 7 '10 at 17:08
Don't miss the link. [:P] – Prasoon Saurav Dec 7 '10 at 17:09
@Parasoon: I didn't lol. – Billy ONeal Dec 7 '10 at 17:10
@Prasoon: HOW could I have forgoten about that?! :) – Armen Tsirunyan Dec 7 '10 at 17:17
@Prasoon: Sorry for the mispelling. I'll schedule an appointment get the foot removed from my mouth next week :) – Billy ONeal Dec 7 '10 at 17:18

Automatic allocation can certainly fail - this is usually known as a stack overflow. You see this quite often when someone tries to have a vary large array as a local variable. Unbounded (or not-bounded-enough) recursion can also cause this.

What you can't really do in a platform independent way is detect automatic allocation failure and handle it.

share|improve this answer
+1 for pointing out common causes of a stack overflow. – Billy ONeal Dec 7 '10 at 17:08
"Detect automatic allocation failure and handle it" and this includes that you can't portably predict it. The program int main() { int a = 1; int b = 2; return a + b;} wouldn't be strictly conforming, since it relies on behavior that can vary between implementations (specifically, that there's enough stack available for two ints), except that formally it isn't varying behavior, because the standard doesn't mention the issue at all. Instead, it's beyond the scope of the standard whether any program works, aborts somehow at runtime, or trashes the heap. – Steve Jessop Dec 7 '10 at 17:45

On systems with overcommit (e.g. Linux in the default configuration), it's even possible for objects of static storage duration to result in failure at runtime. At program startup, these objects will exist in either copy-on-write zero-pages (if they were uninitialized) or copy-on-write mappings of the on-disk executable file. Upon the first attempt to write to them, a page fault will happen and the kernel will make a local modifiable copy for your process. If the kernel was careless and did not reserve as much memory as it committed to the process, this could fail, and the result will be the dreaded OOM-killer.

No robust system has this problem, and the Linux behavior can be fixed by:

echo "2" > /proc/sys/vm/overcommit_memory
share|improve this answer
+1: Nonstandard behavior, brought to you by Linux! Thank you for making it impossible to create a conforming C implementation using default settings. *Bill installs BSD. – Billy ONeal Dec 7 '10 at 19:23
I'm pretty sure overcommit is traditional BSD behavior too, but I may be wrong. I just don't know the different BSD's well enough to comment so I didn't mention them. – R.. Dec 7 '10 at 20:02

Not true. An automatic allocation can cause a stack overflow, which causes instant process termination on most architectures/platforms of which I am aware.

Also, it's possible the program cannot allocate enough space for your static variables from the underlying platform, in which case the program will still fail, but it will fail before main is called.

share|improve this answer
If you're lucky it causes instant termination. If you're unlucky, it clobbers other portions of memory and gives the attacker root. :-) Fortunately the latter only happens in practice if you allocate insanely large (many kb) objects on the stack, but unsafe use of C99 VLA's can lead to this. – R.. Dec 7 '10 at 17:19
@R. Hmm.... not sure how other platforms handle this. On Win32 at least it terminates the process. On other boxes it might not. – Billy ONeal Dec 7 '10 at 17:20
@Billy: if each call only increases stack usage by a few kb, you'll hit a guard page and the process will get terminated. But what if a single call grows the stack by 2gb? Unless the compiler generates special code to check for this (and slows down all sane functions that don't need it) the stack pointer will just end up in the middle of some other memory, and your function will happily clobber that memory. – R.. Dec 7 '10 at 17:46
@R..: I think that technically it would only have to slow down functions which in total move the stack pointer by more than the size of the guard region (presuming that the compiler knows that, or perhaps the page size as a minimum), or which use VLAs, alloca, or similar. One could argue that such functions aren't entirely sane to begin with, or anyway that a performance hit on those things (by default, could be disabled by a compiler option) is worth it given how tricky they are to use safely. – Steve Jessop Dec 7 '10 at 18:15
Indeed. I think the best way is: whenever moving the stack pointer by more than PAGE_SIZE, move it in increments of PAGE_SIZE and write one word after each step. Then you're guaranteed to hit a guard page. – R.. Dec 7 '10 at 18:22

Simple counterexample:

#include <string.h>

int main()
    int huge[0x1FFFFFFF]; // Specific size doesn't matter;
                          // it just has to be bigger than the stack.

    memset(huge, 0, sizeof(huge) / sizeof(int));

    return 0;
share|improve this answer
Stack frame size is usually unlimited. Total size of the stack itself though, is usually the limiting factor. – Billy ONeal Dec 7 '10 at 17:10
This won't compile will it? – Armen Tsirunyan Dec 7 '10 at 17:11
@Armen: It will. I'll change it to something that will compile exactly... – nmichaels Dec 7 '10 at 17:12
@Armen: It should compile, but fail spectacularly at runtime. (Though it's possible the compiler looked at it and said "Are you loony?") If you try to compile this on a 32 bit machine it will fail because 2 billion integers is larger than the entire memory space of the machine (by about 2x). – Billy ONeal Dec 7 '10 at 17:12
@Armen: There, now it will compile all by itself. – nmichaels Dec 7 '10 at 17:13


#include <iostream>

using namespace std;

class A
    A() { p = new int[0xFFFFFFFF]; }

    int* p;

static A g_a;

int main()
    cout << "Why do I never get called?" << endl;
share|improve this answer
You missed the last sentence of the OP's question. "Naturally, when the constructor of an automatic object performs dynamic allocations and such allocation fails, we consider this to be a failure on dynamic allocation, and not automatic." EDIT: And using namespace std; needs to die! :P – Billy ONeal Dec 7 '10 at 17:13
using namespace std; in simple examples is hardly a problem. It makes the example more readable than having std:: everywhere. Granted, in this example, it doesn't really matter since I'm only using 1 cout statement (and one that never gets run since the failure happens before it). Additionally, his question was regarding creation of static variables. I used new, but you could just as easily created the member variable as int p[0x7FFFFFFF] to get the same effect. In either case, it results in a stack overflow. – Zac Howland Dec 7 '10 at 17:20
@Zac: 1. I think it makes code less readable. When you're calling the standard library, it should be obvious at the call site. 2. No, neither the member variable nor the call to new result in a stack overflow. The first case will probably fail because the static storage space will be exhausted. The call to new fails because the heap is exhausted. Neither allocation touches the stack. Ever. – Billy ONeal Dec 7 '10 at 19:35
@Billy 1. That is a religious discussion that could go on until Judgement Day, so suffice it to say, to each their own. 2. You forget the full text of the stack overflow error: stack overruns heap. That is, if you allocate too much heap space, it will intersect your stack space (same with the static storage space), thus, in either case it results in the same problem: you are allocating too much memory in any given pot of memory and corrupting the other pots. – Zac Howland Dec 8 '10 at 15:15
@Zac: That's simply not true. The simplification "stack grows one way, heap grows the other" is not true on most real machines, because most real machines have virtual memory. Yes, you've got memory bounds being overrun, but that does not make it a stack overflow. Only automatic variables are stored on the stack, and you have no automatic variables there. – Billy ONeal Dec 8 '10 at 15:23

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