First off, you need to understand that the fundamental units of protection in modern OSes are the process and the memory page. Processes are memory protection domains; they are the level at which an OS enforces security policy, and they thus correspond strongly with a running program. (Where they don't, it's either because the program is running in multiple processes or because the program is being shared in some kind of framework; the latter case has the potential to be “security-interesting” but that's 'nother story.) Virtual memory pages are the level at which the hardware applies security rules; every page in a process's memory has attributes that determine what the process can do with the page: whether it can read the page, whether it can write to it, and whether it can execute program code on it (though the third attribute is rather more rarely used than perhaps it should be). Compiled program code is mapped into memory into pages that are both readable and executable, but not writable, whereas the stack should be readable and writable, but not executable. Most memory pages are not readable, writable or executable at all; the OS only lets a process use as many pages as it explicitly asks for, and that's what memory allocation libraries (
malloc() et al.) manage for you.
Provided each stack frame is smaller than a memory page so that, as the program advances through the stack, it writes to each page, the OS (i.e., the privileged part of the runtime) can at least in principle detect stack overflows reliably and terminate the program if that occurs. Basically, all that happens to do this detection is that there is a page that the program cannot write to at the end of the stack; if the program tries to write to it, the memory management hardware traps it and the OS gets a chance to intervene.
The potential problems with this come if the OS can be tricked into not setting such a page or if the stack frames can become so large and sparsely written to that the guard page is jumped over. (Keeping more guard pages would help prevent the second case with little cost; forcing variable-sized stack allocations – e.g.,
alloca() – to always write to the space they allocate before returning control to the program, and so detect a smashed stack, would prevent the first with some cost in terms of speed, though the writes could be reasonably sparse to keep the cost fairly small.)
What are the consequences of this? Well, the OS has to do the right thing with memory management. (@Michael's link illustrates what can happen when it gets that wrong.) But also it is dangerous to let an attacker determine memory allocation sizes where you don't force a write to the whole allocation immediately;
alloca and C99 variable-sized arrays are a particular threat. Moreover, I would be more suspicious of C++ code as that tends to do a lot more stack-based memory allocation; it might be OK, but there's a greater potential for things to go wrong.
Personally, I prefer to keep stack sizes and stack-frame sizes small anyway and do all variable-sized allocations on the heap. In part, this is a legacy of working on some types of embedded system and with code which uses very large numbers of threads, but it does make protecting against stack overflow attacks much simpler; the OS can reliably trap them and all the attacker has then is a denial-of-service (annoying, but rarely fatal). I don't know whether this is a solution for all programmers.
 Typical page sizes: 4kB on 32-bit systems, 16kB on 64-bit systems. Check your system documentation for what it is in your environment.