505

alloca() allocates memory on the stack rather than on the heap, as in the case of malloc(). So, when I return from the routine the memory is freed. So, actually this solves my problem of freeing up dynamically allocated memory. Freeing of memory allocated through malloc() is a major headache and if somehow missed leads to all sorts of memory problems.

Why is the use of alloca() discouraged in spite of the above features?

11
  • 53
    Just a quick note. Although this function can be found in most compilers it is not required by the ANSI-C standard and therefore could limit portability. Another thing is, that you must not! free() the pointer you get and it's freed automatically after you exit the function.
    – merkuro
    Jun 19, 2009 at 16:38
  • 12
    Also, a function with alloca() won't be inlined if declared as such.
    – Justicle
    Jun 23, 2009 at 0:29
  • 2
    @Justicle, can you provide some explanation? I'm very curious what's behind this behaviour
    – migajek
    Aug 1, 2010 at 20:35
  • 71
    Forget all the noise about portability, no need to call free (which is obviously an advantage), non-ability to inline it (obviously heap allocations are very much heavier) and etc. The only reason to avoid alloca is for large sizes. That is, wasting tons of stack memory is not a good idea, plus you have a chance of a stack overflow. If this is the case - consider using malloca / freea
    – valdo
    Nov 2, 2011 at 12:23
  • 15
    Another positive aspect of alloca is that the stack cannot be fragmented like the heap. This could prove useful for hard real-time run-forever style applications, or even safety critical applications, since the WCRU can then be statically analyzed without resorting to custom memory pools with their own set of problems (no temporal locality, sub-optimal resource use).
    – Andreas
    May 17, 2018 at 6:51

24 Answers 24

341

The answer is right there in the man page (at least on Linux):

RETURN VALUE The alloca() function returns a pointer to the beginning of the allocated space. If the allocation causes stack overflow, program behaviour is undefined.

Which isn't to say it should never be used. One of the OSS projects I work on uses it extensively, and as long as you're not abusing it (alloca'ing huge values), it's fine. Once you go past the "few hundred bytes" mark, it's time to use malloc and friends, instead. You may still get allocation failures, but at least you'll have some indication of the failure instead of just blowing out the stack.

21
  • 49
    So there's really no problem with it that you wouldn't also have with declaring large arrays?
    – T.E.D.
    Jun 19, 2009 at 16:32
  • 127
    @Sean: Yes, stack overflow risk is the reason given, but that reason is a bit silly. Firstly because (as Vaibhav says) large local arrays cause exactly the same problem, but are not nearly as vilified. Also, recursion can just as easily blow the stack. Sorry but I'm -1ing you to hopefully counter the prevailing idea that the reason given in the man page is justified. Jun 27, 2010 at 13:22
  • 61
    My point is that the justification given in the man page makes no sense, since alloca() is exactly as "bad" as those other things (local arrays or recursive functions) that are considered kosher. Jun 30, 2010 at 1:44
  • 52
    @ninjalj: Not by highly experienced C/C++ programmers, but I do think many people who fear alloca() do not have the same fear of local arrays or recursion (in fact many people who will shout down alloca() will praise recursion because it "looks elegant"). I agree with Shaun's advice ("alloca() is fine for small allocations") but I disagree with the mindset that frames alloca() as uniquely evil among the 3 -- they are equally dangerous! Aug 2, 2010 at 5:33
  • 43
    Note: Given Linux's "optimistic" memory allocation strategy, you very likely won't get any indication of a heap-exhaustion failure... instead malloc() will return you a nice non-NULL pointer, and then when you try to actually access the address space it points to, your process (or some other process, unpredictably) will get killed by the OOM-killer. Of course this is a "feature" of Linux rather than a C/C++ issue per se, but it's something to keep in mind when debating whether alloca() or malloc() is "safer". :) Jul 28, 2013 at 2:53
274

One of the most memorable bugs I had was to do with an inline function that used alloca. It manifested itself as a stack overflow (because it allocates on the stack) at random points of the program's execution.

In the header file:

void DoSomething() {
   wchar_t* pStr = alloca(100);
   //......
}

In the implementation file:

void Process() {
   for (i = 0; i < 1000000; i++) {
     DoSomething();
   }
}

So what happened was the compiler (Microsoft VC++ 6) inlined DoSomething function and all the stack allocations were happening inside Process() function and thus blowing the stack up. In my defence (and I wasn't the one who found the issue; I had to go and cry to one of the senior developers when I couldn't fix it), it wasn't straight alloca, it was one of ATL string conversion macros.

So the lesson is - do not use alloca in functions that you think might be inlined.

16
  • 148
    Interesting. But wouldn't that qualify as a compiler bug? After all, the inlining changed the behaviour of the code (it delayed the freeing of the space allocated using alloca).
    – sleske
    Oct 17, 2010 at 18:55
  • 87
    Apparently, at least GCC will take this into account: "Note that certain usages in a function definition can make it unsuitable for inline substitution. Among these usages are: use of varargs, use of alloca, [...]". gcc.gnu.org/onlinedocs/gcc/Inline.html
    – sleske
    Oct 17, 2010 at 18:57
  • 183
    What compiler were you smoking? Nov 16, 2011 at 21:34
  • 28
    What I don't understand is why the compiler does not make good use of the scope to determine that allocas in subscope are more or less "freed": stack pointer could come back to its point before entering the scope, like what is done when returning from function (couldn't it?)
    – moala
    May 16, 2012 at 12:18
  • 29
    I've downvoted, but the answer is well written: I agree with others you're faulting alloca for what is a clearly a compiler bug. The compiler has made a faulty assumption in an optimization it should not have made. Working around a compiler bug is fine, but I wouldn't fault anything for it but the compiler. Sep 6, 2018 at 19:02
108

Old question but nobody mentioned that it should be replaced by variable length arrays.

char arr[size];

instead of

char *arr=alloca(size);

It's in the standard C99 and existed as compiler extension in many compilers.

10
  • 7
    It's mentioned by Jonathan Leffler on a comment to Arthur Ulfeldt's answer.
    – ninjalj
    Aug 1, 2010 at 22:31
  • 5
    Indeed, but it shows also how easy it is missed, as I hadn't seen it despite reading all responses before posting. Aug 2, 2010 at 9:50
  • 10
    One note -- those are variable length arrays, not dynamic arrays. The latter are resizable and usually implemented on the heap.
    – Tim Čas
    Dec 9, 2012 at 16:42
  • 6
    Linus Torvalds doesn't like VLAs in the Linux kernel. As of version 4.20 Linux should be almost VLA free. Jan 10, 2019 at 15:18
  • 6
    Unfortunately, there are compilers out there (Keil for ARM) that implement VLA on the heap by silently linking malloc() into the code. That's a major annoyance, as you never know where the memory is allocated and I don't know whether tehy correctly call free() afterwards.
    – opt12
    Sep 19, 2019 at 13:09
76

alloca() is very useful if you can't use a standard local variable because its size would need to be determined at runtime and you can absolutely guarantee that the pointer you get from alloca() will NEVER be used after this function returns.

You can be fairly safe if you

  • do not return the pointer, or anything that contains it.
  • do not store the pointer in any structure allocated on the heap
  • do not let any other thread use the pointer

The real danger comes from the chance that someone else will violate these conditions sometime later. With that in mind it's great for passing buffers to functions that format text into them :)

9
  • 19
    The VLA (variable length array) feature of C99 supports dynamically sized local variables without explicitly requiring alloca() to be used. Jun 22, 2009 at 23:57
  • 2
    neato! found more info in section '3.4 Variable Length Array' of programmersheaven.com/2/Pointers-and-Arrays-page-2 Jun 23, 2009 at 0:15
  • 3
    But that is not different from handling with pointers to local variables. They can be fooled around with as well...
    – glglgl
    Oct 18, 2012 at 7:28
  • 3
    @Jonathan Leffler one thing you can do with alloca but you can't do with VLA is using restrict keyword with them. Like this: float* restrict heavily_used_arr = alloca(sizeof(float)*size); instead of float heavily_used_arr[size]. It might help some compilers (gcc 4.8 in my case) to optimize the assembly even if size is a compilation constant. See my question about it: stackoverflow.com/questions/19026643/using-restrict-with-arrays Oct 1, 2013 at 23:29
  • @JonathanLeffler A VLA is local to the block that contains it. On the other hand, alloca() allocates memory that lasts until the end of the function. This means that there appears to be no straightforward, convenient translation to VLA of f() { char *p; if (c) { /* compute x */ p = alloca(x); } else { p = 0; } /* use p */ }. If you think it is possible to automatically translate uses of alloca to uses of VLA but require more than a comment to describe how, I can make this a question. Mar 24, 2014 at 9:40
46

As noted in this newsgroup posting, there are a few reasons why using alloca can be considered difficult and dangerous:

  • Not all compilers support alloca.
  • Some compilers interpret the intended behaviour of alloca differently, so portability is not guaranteed even between compilers that support it.
  • Some implementations are buggy.
7
  • 30
    One thing I saw mentioned on that link which is not elsewhere on this page is that a function that uses alloca() requires separate registers for holding the stack pointer and frame pointer. On x86 CPUs >= 386, the stack pointer ESP can be used for both, freeing up EBP -- unless alloca() is used. Jun 27, 2010 at 13:30
  • 16
    Another good point on that page is that unless the compiler's code generator handles it as a special case, f(42, alloca(10), 43); could crash due to possibility that the stack pointer is adjusted by alloca() after at least one of the arguments is pushed on it. Jun 27, 2010 at 13:38
  • 4
    The linked post appears to be written by John Levine-- the dude who wrote "Linkers and Loaders", I would trust whatever he says.
    – user318904
    Aug 13, 2011 at 6:06
  • 3
    The linked post is a reply to a posting by John Levine.
    – A. Wilcox
    Dec 29, 2014 at 5:07
  • 14
    Bear in mind, a lot has changed since 1991. All modern C compilers (even in 2009) have to handle alloca as a special case; it's an intrinsic rather than an ordinary function, and may not even call a function. So, the alloca-in-parameter issue (which arose in K&R C from the 1970's) should not be a problem now. More detail in a comment I made on Tony D's answer
    – greggo
    May 2, 2017 at 17:45
32

One issue is that it isn't standard, although it's widely supported. Other things being equal, I'd always use a standard function rather than a common compiler extension.

27

still alloca use is discouraged, why?

I don't perceive such a consensus. Lots of strong pros; a few cons:

  • C99 provides variable length arrays, which would often be used preferentially as the notation's more consistent with fixed-length arrays and intuitive overall
  • many systems have less overall memory/address-space available for the stack than they do for the heap, which makes the program slightly more susceptible to memory exhaustion (through stack overflow): this may be seen as a good or a bad thing - one of the reasons the stack doesn't automatically grow the way heap does is to prevent out-of-control programs from having as much adverse impact on the entire machine
  • when used in a more local scope (such as a while or for loop) or in several scopes, the memory accumulates per iteration/scope and is not released until the function exits: this contrasts with normal variables defined in the scope of a control structure (e.g. for {int i = 0; i < 2; ++i) { X } would accumulate alloca-ed memory requested at X, but memory for a fixed-sized array would be recycled per iteration).
  • modern compilers typically do not inline functions that call alloca, but if you force them then the alloca will happen in the callers' context (i.e. the stack won't be released until the caller returns)
  • a long time ago alloca transitioned from a non-portable feature/hack to a Standardised extension, but some negative perception may persist
  • the lifetime is bound to the function scope, which may or may not suit the programmer better than malloc's explicit control
  • having to use malloc encourages thinking about the deallocation - if that's managed through a wrapper function (e.g. WonderfulObject_DestructorFree(ptr)), then the function provides a point for implementation clean up operations (like closing file descriptors, freeing internal pointers or doing some logging) without explicit changes to client code: sometimes it's a nice model to adopt consistently
    • in this pseudo-OO style of programming, it's natural to want something like WonderfulObject* p = WonderfulObject_AllocConstructor(); - that's possible when the "constructor" is a function returning malloc-ed memory (as the memory remains allocated after the function returns the value to be stored in p), but not if the "constructor" uses alloca
      • a macro version of WonderfulObject_AllocConstructor could achieve this, but "macros are evil" in that they can conflict with each other and non-macro code and create unintended substitutions and consequent difficult-to-diagnose problems
    • missing free operations can be detected by ValGrind, Purify etc. but missing "destructor" calls can't always be detected at all - one very tenuous benefit in terms of enforcement of intended usage; some alloca() implementations (such as GCC's) use an inlined macro for alloca(), so runtime substitution of a memory-usage diagnostic library isn't possible the way it is for malloc/realloc/free (e.g. electric fence)
  • some implementations have subtle issues: for example, from the Linux manpage:

    On many systems alloca() cannot be used inside the list of arguments of a function call, because the stack space reserved by alloca() would appear on the stack in the middle of the space for the function arguments.


I know this question is tagged C, but as a C++ programmer I thought I'd use C++ to illustrate the potential utility of alloca: the code below (and here at ideone) creates a vector tracking differently sized polymorphic types that are stack allocated (with lifetime tied to function return) rather than heap allocated.

#include <alloca.h>
#include <iostream>
#include <vector>

struct Base
{
    virtual ~Base() { }
    virtual int to_int() const = 0;
};

struct Integer : Base
{
    Integer(int n) : n_(n) { }
    int to_int() const { return n_; }
    int n_;
};

struct Double : Base
{
    Double(double n) : n_(n) { }
    int to_int() const { return -n_; }
    double n_;
};

inline Base* factory(double d) __attribute__((always_inline));

inline Base* factory(double d)
{
    if ((double)(int)d != d)
        return new (alloca(sizeof(Double))) Double(d);
    else
        return new (alloca(sizeof(Integer))) Integer(d);
}

int main()
{
    std::vector<Base*> numbers;
    numbers.push_back(factory(29.3));
    numbers.push_back(factory(29));
    numbers.push_back(factory(7.1));
    numbers.push_back(factory(2));
    numbers.push_back(factory(231.0));
    for (std::vector<Base*>::const_iterator i = numbers.begin();
         i != numbers.end(); ++i)
    {
        std::cout << *i << ' ' << (*i)->to_int() << '\n';
        (*i)->~Base();   // optionally / else Undefined Behaviour iff the
                         // program depends on side effects of destructor
    }
}
7
  • 2
    Let me rephrase: This is a very good answer. Up to the point where I think you're suggesting that people use a sort of a counter-pattern.
    – einpoklum
    Jul 18, 2015 at 9:36
  • 1
    The comment from the linux manpage is very old and, I'm pretty sure, obsolete. All modern compilers know what alloca() is, and won't trip over their shoelaces like that. In old K&R C, (1) all functions used frame pointers (2) All function calls were {push args on stack}{call func}{add #n,sp}. alloca was a lib function that would just bump the stack up, the compiler didn't even know about that happening. (1) and (2) are not true any more so alloca can't work that way (now it's an intrinsic). In old C, calling alloca in the middle of pushing args would obviously break those assumptions too.
    – greggo
    May 2, 2017 at 17:31
  • 9
    Regarding the example, I'd be generally concerned about something that requires always_inline to avoid memory corruption....
    – greggo
    May 2, 2017 at 17:33
  • 1
    Uses placement new to return an alloca buffer. If the function ends up not inlined you trash the stack. Your code is undefined.
    – Joshua
    Sep 25, 2019 at 1:05
  • 1
    if anyone gonna read this: modern C++ style for allocating on stack is via allocator - create it and make all vectors and "new" be directed through it Jul 22, 2020 at 7:25
22

Lots of interesting answers to this "old" question, even some relatively new answers, but I didn't find any that mention this....

When used properly and with care, consistent use of alloca() (perhaps application-wide) to handle small variable-length allocations (or C99 VLAs, where available) can lead to lower overall stack growth than an otherwise equivalent implementation using oversized local arrays of fixed length. So alloca() may be good for your stack if you use it carefully.

I found that quote in.... OK, I made that quote up. But really, think about it....

@j_random_hacker is very right in his comments under other answers: Avoiding the use of alloca() in favor of oversized local arrays does not make your program safer from stack overflows (unless your compiler is old enough to allow inlining of functions that use alloca() in which case you should upgrade, or unless you use alloca() inside loops, in which case you should... not use alloca() inside loops).

I've worked on desktop/server environments and embedded systems. A lot of embedded systems don't use a heap at all (they don't even link in support for it), for reasons that include the perception that dynamically allocated memory is evil due to the risks of memory leaks on an application that never ever reboots for years at a time, or the more reasonable justification that dynamic memory is dangerous because it can't be known for certain that an application will never fragment its heap to the point of false memory exhaustion. So embedded programmers are left with few alternatives.

alloca() (or VLAs) may be just the right tool for the job.

I've seen time & time again where a programmer makes a stack-allocated buffer "big enough to handle any possible case". In a deeply nested call tree, repeated use of that (anti-?)pattern leads to exaggerated stack use. (Imagine a call tree 20 levels deep, where at each level for different reasons, the function blindly over-allocates a buffer of 1024 bytes "just to be safe" when generally it will only use 16 or less of them, and only in very rare cases may use more.) An alternative is to use alloca() or VLAs and allocate only as much stack space as your function needs, to avoid unnecessarily burdening the stack. Hopefully when one function in the call tree needs a larger-than-normal allocation, others in the call tree are still using their normal small allocations, and the overall application stack usage is significantly less than if every function blindly over-allocated a local buffer.

But if you choose to use alloca()...

Based on other answers on this page, it seems that VLAs should be safe (they don't compound stack allocations if called from within a loop), but if you're using alloca(), be careful not to use it inside a loop, and make sure your function can't be inlined if there's any chance it might be called within another function's loop.

4
  • 3
    I agree with this point. The dangerous of alloca() is true, but the same can be said to memory leaks with malloc() (why not use a GC then? one might argue). alloca() when used with care can be really useful to decrease the stack size. Feb 2, 2017 at 15:44
  • 1
    Another good reason not to use dynamic memory, especially in embedded: it's more complicated than sticking to the stack. Using dynamic memory requires special procedures and data structures, whereas on the stack it's (to simplify things) a matter of adding/subtracting a higher number from stackpointer.
    – tehftw
    Sep 17, 2018 at 6:31
  • Sidenote: The "using a fixed buffer[MAX_SIZE]" example highlights why overcommit memory policy works so well. Programs allocate memory they may never touch except at the limits of their buffer length. So it's fine that Linux (and other OS's) don't actually assign a page of memory until its first used (as opposed to malloc'd). If the buffer is larger than one page, the program may only use the first page, and not waste the rest of the physical memory. Jun 23, 2019 at 3:46
  • 1
    @KatasticVoyage Unless MAX_SIZE is greater than (or at least equal to) the size of your system's virtual memory page size, your argument doesn't hold water. Also on embedded systems without virtual memory (many embedded MCU's don't have MMU's), the overcommit memory policy may be good from an "ensure your program will run in all situations" standpoint, but that assurance comes with the price that your stack size must be likewise allocated to support that overcommit memory policy. On some embedded systems, that's a price that some manufacturers of low-cost products aren't willing to pay. Sep 5, 2019 at 18:09
19

All of the other answers are correct. However, if the thing you want to alloc using alloca() is reasonably small, I think that it's a good technique that's faster and more convenient than using malloc() or otherwise.

In other words, alloca( 0x00ffffff ) is dangerous and likely to cause overflow, exactly as much as char hugeArray[ 0x00ffffff ]; is. Be cautious and reasonable and you'll be fine.

19

I don't think anyone has mentioned this: Use of alloca in a function will hinder or disable some optimizations that could otherwise be applied in the function, since the compiler cannot know the size of the function's stack frame.

For instance, a common optimization by C compilers is to eliminate use of the frame pointer within a function, frame accesses are made relative to the stack pointer instead; so there's one more register for general use. But if alloca is called within the function, the difference between sp and fp will be unknown for part of the function, so this optimization cannot be done.

Given the rarity of its use, and its shady status as a standard function, compiler designers quite possibly disable any optimization that might cause trouble with alloca, if would take more than a little effort to make it work with alloca.

UPDATE: Since variable-length local arrays have been added to C, and since these present very similar code-generation issues to the compiler as alloca, I see that 'rarity of use and shady status' does not apply to the underlying mechanism; but I would still suspect that use of either alloca or VLA tends to compromise code generation within a function that uses them. I would welcome any feedback from compiler designers.

2
  • 2
    > I would still suspect that use of either alloca or VLA tends to compromise code generation I would think that use of alloca requires a frame pointer, because the stack pointer moves in ways that are not obvious at compile time. alloca can be called in a loop to keep grabbing more stack memory, or with a run-time calculated size, etc. If there is a frame pointer, generated code has a stable reference to locals and the stack pointer can do whatever it wants; it is not used.
    – Kaz
    Jun 12, 2020 at 18:17
  • 7
    If the alternative to VLA or alloca is to invoke malloc and free, the function may be more efficient with their use, even if it makes framing required.
    – Kaz
    Jul 9, 2020 at 15:02
14

Everyone has already pointed out the big thing which is potential undefined behavior from a stack overflow but I should mention that the Windows environment has a great mechanism to catch this using structured exceptions (SEH) and guard pages. Since the stack only grows as needed, these guard pages reside in areas that are unallocated. If you allocate into them (by overflowing the stack) an exception is thrown.

You can catch this SEH exception and call _resetstkoflw to reset the stack and continue on your merry way. Its not ideal but it's another mechanism to at least know something has gone wrong when the stuff hits the fan. *nix might have something similar that I'm not aware of.

I recommend capping your max allocation size by wrapping alloca and tracking it internally. If you were really hardcore about it you could throw some scope sentries at the top of your function to track any alloca allocations in the function scope and sanity check this against the max amount allowed for your project.

Also, in addition to not allowing for memory leaks alloca does not cause memory fragmentation which is pretty important. I don't think alloca is bad practice if you use it intelligently, which is basically true for everything. :-)

2
  • 1
    The problem is, that alloca() can demand so much space, that the stackpointer lands in the heap. With that, a attacker who can control the size for alloca() and the data that goes into that buffer can overwrite the heap (which is very bad). Nov 2, 2018 at 18:50
  • 1
    SEH is a Windows-only thing. That's great if you only care about your code running on Windows, but if your code needs to be cross-platform (or if you're writing code that only runs on a non-Windows platform), then you can't rely on having SEH.
    – George
    Jun 11, 2020 at 13:00
13

One pitfall with alloca is that longjmp rewinds it.

That is to say, if you save a context with setjmp, then alloca some memory, then longjmp to the context, you may lose the alloca memory. The stack pointer is back where it was and so the memory is no longer reserved; if you call a function or do another alloca, you will clobber the original alloca.

To clarify, what I'm specifically referring to here is a situation whereby longjmp does not return out of the function where the alloca took place! Rather, a function saves context with setjmp; then allocates memory with alloca and finally a longjmp takes place to that context. That function's alloca memory is not all freed; just all the memory that it allocated since the setjmp. Of course, I'm speaking about an observed behavior; no such requirement is documented of any alloca that I know.

The focus in the documentation is usually on the concept that alloca memory is associated with a function activation, not with any block; that multiple invocations of alloca just grab more stack memory which is all released when the function terminates. Not so; the memory is actually associated with the procedure context. When the context is restored with longjmp, so is the prior alloca state. It's a consequence of the stack pointer register itself being used for allocation, and also (necessarily) saved and restored in the jmp_buf.

Incidentally, this, if it works that way, provides a plausible mechanism for deliberately freeing memory that was allocated with alloca.

I have run into this as the root cause of a bug.

9
  • 7
    That's what it's supposed to do though - longjmp goes back and makes it so the program forgets about everything that happened in the stack: all the variables, function calls etc. And alloca is just like an array on the stack, so it's expected they will be clobbered like everything else on the stack.
    – tehftw
    Sep 17, 2018 at 6:37
  • 6
    man alloca gave the following sentence: "Because the space allocated by alloca() is allocated within the stack frame, that space is automatically freed if the function return is jumped over by a call to longjmp(3) or siglongjmp(3).". So it is documented that memory allocated with alloca gets clobbered after a longjmp.
    – tehftw
    Sep 17, 2018 at 6:40
  • 1
    @tehftw The situation described occurs without a function return being jumped over by longjmp. The target function has not yet returned. It has done setjmp, alloca and then longjmp. The longjmp may rewind the alloca state back to what it was at setjmp time. That is to say, the pointer moved by alloca suffers from the same problem as a local variable that has not been marked volatile!
    – Kaz
    Sep 17, 2018 at 14:37
  • 7
    I don't understand why it would be supposed to be unexpected. When you setjmp then alloca, and then longjmp, it's normal that allocawould be rewinded. The whole point of longjmp is to get back to the state that was saved at setjmp!
    – tehftw
    Sep 17, 2018 at 17:38
  • 2
    It seems to me that it proves that setjmp/longjmp are dangerous beasts.
    – Yongwei Wu
    Jul 22, 2020 at 8:06
10

Here's why:

char x;
char *y=malloc(1);
char *z=alloca(&x-y);
*z = 1;

Not that anyone would write this code, but the size argument you're passing to alloca almost certainly comes from some sort of input, which could maliciously aim to get your program to alloca something huge like that. After all, if the size isn't based on input or doesn't have the possibility to be large, why didn't you just declare a small, fixed-size local buffer?

Virtually all code using alloca and/or C99 vlas has serious bugs which will lead to crashes (if you're lucky) or privilege compromise (if you're not so lucky).

25
  • 1
    The world may never know. :( That said, I'm hoping you could clarify a question I have about alloca. You said that nearly all code that uses it has a bug, but I was planning on using it; I'd normally ignore such a claim, but coming from you I won't. I'm writing a virtual machine and I'd like to allocate variables that don't escape from the function on the stack, instead of dynamically, because of the enormous speed-up. Is there an alternate approach that has the same performance characteristics? I know I can get close with memory pools, but that still isn't as cheap. What would you do?
    – GManNickG
    May 26, 2011 at 2:33
  • 7
    *0=9; is not valid C. As for testing the size you pass to alloca, test it against what? There's no way to know the limit, and if you're just going to test it against a tiny fixed known-safe size (e.g. 8k) you might as well just use a fixed-size array on the stack. Nov 17, 2011 at 3:07
  • 7
    The trouble with your "either the size is known to be small enough or it's input-dependent and thus could be arbitrarily large" argument as I see it is that it applies just as strongly to recursion. A practical compromise (for both cases) is to assume that if the size is bounded by small_constant * log(user_input) then we probably have enough memory. Apr 16, 2012 at 3:00
  • 1
    Indeed, you have identified the ONE case where VLA/alloca is useful: recursive algorithms where the max space needed at any call frame could be as large as N, but where the sum of the space needed at all recursion levels is N or some function of N that does not grow quickly. Apr 16, 2012 at 5:17
  • 1
    There's no way to know the limit -- Stack can be explicitly set[1], so it can be known, it's just not very practical. 1 - pthread_attr_setstack
    – bestsss
    Jun 11, 2014 at 11:08
9

alloca () is nice and efficient... but it is also deeply broken.

  • broken scope behavior (function scope instead of block scope)
  • use inconsistant with malloc (alloca()-ted pointer shouldn't be freed, henceforth you have to track where you pointers are coming from to free() only those you got with malloc())
  • bad behavior when you also use inlining (scope sometimes goes to the caller function depending if callee is inlined or not).
  • no stack boundary check
  • undefined behavior in case of failure (does not return NULL like malloc... and what does failure means as it does not check stack boundaries anyway...)
  • not ansi standard

In most cases you can replace it using local variables and majorant size. If it's used for large objects, putting them on the heap is usually a safer idea.

If you really need it C you can use VLA (no vla in C++, too bad). They are much better than alloca() regarding scope behavior and consistency. As I see it VLA are a kind of alloca() made right.

Of course a local structure or array using a majorant of the needed space is still better, and if you don't have such majorant heap allocation using plain malloc() is probably sane. I see no sane use case where you really really need either alloca() or VLA.

6
  • I don't see the reason for the downvote (without any comment, by the way)
    – gd1
    Feb 25, 2015 at 18:39
  • 1
    Only names have scope. alloca doesn't create a name, only a memory range, which has lifetime.
    – curiousguy
    Oct 27, 2015 at 6:27
  • @curiousguy: you're merely playing with words. For automatic variables I could as well speak of lifetime of the underlying memory as it match the scope of the name. Anyway the trouble is not how we call it, but the instability of the lifetime/scope of memory returned by alloca and the exceptional behavior.
    – kriss
    Oct 27, 2015 at 8:53
  • 4
    I wish alloca had had a corresponding "freea", with a specification that calling "freea" would undo the effects of the "alloca" that created the object and all subsequent ones, and a requirement that storage 'alloca'ed within a fucntion must be 'freea'ed within it as well. That would have made it possible for nearly all implementations to support alloca/freea in a compatible fashion, would have eased the inlining issues, and generally made things a lot cleaner.
    – supercat
    Mar 31, 2016 at 22:15
  • 4
    @supercat — I wish so too. For that reason (and more), I use an abstraction layer (mostly macros and inline functions) so that I don't ever call alloca or malloc or free directly. I say things like {stack|heap}_alloc_{bytes,items,struct,varstruct} and {stack|heap}_dealloc. So, heap_dealloc just calls free and stack_dealloc is a no-op. This way, the stack allocations can easily be downgraded to heap allocations, and the intentions are more clear as well. Apr 1, 2016 at 15:09
8

alloca is not worse than a variable-length array (VLA), but it's riskier than allocating on the heap.

On x86 (and most often on ARM), the stack grows downwards, and that brings with it a certain amount of risk: if you accidentally write beyond the block allocated with alloca (due to a buffer overflow for example), then you will overwrite the return address of your function, because that one is located "above" on the stack, i.e. after your allocated block.

_alloca block on the stack

The consequence of this is two-fold:

  1. The program will crash spectacularly and it will be impossible to tell why or where it crashed (stack will most likely unwind to a random address due to the overwritten frame pointer).

  2. It makes buffer overflow many times more dangerous, since a malicious user can craft a special payload which would be put on the stack and can therefore end up executed.

In contrast, if you write beyond a block on the heap you "just" get heap corruption. The program will probably terminate unexpectedly but will unwind the stack properly, thereby reducing the chance of malicious code execution.

0
7

Processes only have a limited amount of stack space available - far less than the amount of memory available to malloc().

By using alloca() you dramatically increase your chances of getting a Stack Overflow error (if you're lucky, or an inexplicable crash if you're not).

1
  • 5
    That depends very much on the application. It is not unusual for a memory-limited embedded application to have a stack size larger than the heap (if there even IS a heap).
    – EBlake
    Mar 4, 2020 at 21:20
7

A place where alloca() is especially dangerous than malloc() is the kernel - kernel of a typical operating system has a fixed sized stack space hard-coded into one of its header; it is not as flexible as the stack of an application. Making a call to alloca() with an unwarranted size may cause the kernel to crash. Certain compilers warn usage of alloca() (and even VLAs for that matter) under certain options that ought to be turned on while compiling a kernel code - here, it is better to allocate memory in the heap that is not fixed by a hard-coded limit.

2
  • 8
    alloca() is no more dangerous than int foo[bar]; where bar is some arbitrary integer. Aug 25, 2015 at 23:20
  • 3
    @ToddLehman That's correct, and for that exact reason we've banned VLAs in the kernel for several years, and have been VLA-free since 2018 :-)
    – Chris Down
    Apr 25, 2020 at 11:33
5

Sadly the truly awesome alloca() is missing from the almost awesome tcc. Gcc does have alloca().

  1. It sows the seed of its own destruction. With return as the destructor.

  2. Like malloc() it returns an invalid pointer on fail which will segfault on modern systems with a MMU (and hopefully restart those without).

  3. Unlike auto variables you can specify the size at run time.

It works well with recursion. You can use static variables to achieve something similar to tail recursion and use just a few others pass info to each iteration.

If you push too deep you are assured of a segfault (if you have an MMU).

Note that malloc() offers no more as it returns NULL (which will also segfault if assigned) when the system is out of memory. I.e. all you can do is bail or just try to assign it any way.

To use malloc() I use globals and assign them NULL. If the pointer is not NULL I free it before I use malloc().

You can also use realloc() as general case if want copy any existing data. You need to check pointer before to work out if you are going to copy or concatenate after the realloc().

3.2.5.2 Advantages of alloca

4
  • 5
    Actually the alloca spec does not say it returns an invalid pointer on fail (stack overflow) it says it has undefined behavior... and for malloc it says it returns NULL, not a random invalid pointer (OK, Linux optimistic memory implementation makes that useless).
    – kriss
    Sep 2, 2014 at 10:04
  • @kriss Linux may kill your process, but at least it doesn't venture into undefined behaviour
    – craig65535
    Oct 6, 2017 at 7:25
  • @craig65535: the expression undefined behavior usually means that that behavior isn't defined by C or C++ specification. Not in any way that it will be random or unstable on any given OS or compiler. Therefore it's meaningless to associate UB with the name of an OS like "Linux" or "Windows". It has nothing to do with it.
    – kriss
    Oct 7, 2017 at 7:06
  • I was trying to say that malloc returning NULL, or in the case of Linux, a memory access killing your process, is preferable to the undefined behaviour of alloca. I think I must have misread your first comment.
    – craig65535
    Oct 7, 2017 at 18:19
3

Actually, alloca is not guaranteed to use the stack. Indeed, the gcc-2.95 implementation of alloca allocates memory from the heap using malloc itself. Also that implementation is buggy, it may lead to a memory leak and to some unexpected behavior if you call it inside a block with a further use of goto. Not, to say that you should never use it, but some times alloca leads to more overhead than it releaves frome.

1
  • 1
    It sounds as if gcc-2.95 broke alloca and probably can't be safely used for programs that require alloca. How would it have cleaned up the memory when longjmp is used to abandon frames that did alloca? When would anyone use gcc 2.95 today?
    – Kaz
    Sep 18, 2018 at 2:20
2

In my opinion, alloca(), where available, should be used only in a constrained manner. Very much like the use of "goto", quite a large number of otherwise reasonable people have strong aversion not just to the use of, but also the existence of, alloca().

For embedded use, where the stack size is known and limits can be imposed via convention and analysis on the size of the allocation, and where the compiler cannot be upgraded to support C99+, use of alloca() is fine, and I've been known to use it.

When available, VLAs may have some advantages over alloca(): The compiler can generate stack limit checks that will catch out-of-bounds access when array style access is used (I don't know if any compilers do this, but it can be done), and analysis of the code can determine whether the array access expressions are properly bounded. Note that, in some programming environments, such as automotive, medical equipment, and avionics, this analysis has to be done even for fixed size arrays, both automatic (on the stack) and static allocation (global or local).

On architectures that store both data and return addresses/frame pointers on the stack (from what I know, that's all of them), any stack allocated variable can be dangerous because the address of the variable can be taken, and unchecked input values might permit all sorts of mischief.

Portability is less of a concern in the embedded space, however it is a good argument against use of alloca() outside of carefully controlled circumstances.

Outside of the embedded space, I've used alloca() mostly inside logging and formatting functions for efficiency, and in a non-recursive lexical scanner, where temporary structures (allocated using alloca() are created during tokenization and classification, then a persistent object (allocated via malloc()) is populated before the function returns. The use of alloca() for the smaller temporary structures greatly reduces fragmentation when the persistent object is allocated.

2

Why no one mentions this example introduced by GNU documention?

https://www.gnu.org/software/libc/manual/html_node/Advantages-of-Alloca.html

Nonlocal exits done with longjmp (see Non-Local Exits) automatically free the space allocated with alloca when they exit through the function that called alloca. This is the most important reason to use alloca

Suggest reading order 1->2->3->1:

  1. https://www.gnu.org/software/libc/manual/html_node/Advantages-of-Alloca.html
  2. Intro and Details from Non-Local Exits
  3. Alloca Example
1

I don't think that anybody has mentioned this, but alloca also has some serious security issues not necessarily present with malloc (though these issues also arise with any stack based arrays, dynamic or not). Since the memory is allocated on the stack, buffer overflows/underflows have much more serious consequences than with just malloc.

In particular, the return address for a function is stored on the stack. If this value gets corrupted, your code could be made to go to any executable region of memory. Compilers go to great lengths to make this difficult (in particular by randomizing address layout). However, this is clearly worse than just a stack overflow since the best case is a SEGFAULT if the return value is corrupted, but it could also start executing a random piece of memory or in the worst case some region of memory which compromises your program's security.

0

IMO the biggest risk with alloca and variable length arrays is it can fail in a very dangerous manner if the allocation size is unexpectedly large.

Allocations on the stack typically have no checking in user code.

Modern operating systems will generally put a guard page in place below* to detect stack overflow. When the stack overflows the kernel may either expand the stack or kill the process. Linux expanded this guard region in 2017 to be significantly large than a page, but it's still finite in size.

So as a rule it's best to avoid allocating more than a page on the stack before making use of the previous allocations. With alloca or variable length arrays it's easy to end up allowing an attacker to make arbitrary size allocations on the stack and hence skip over any guard page and access arbitrary memory.

* on most widespread systems today the stack grows downwards.

4
  • I've heard that explanation many times, but it doesn't make any sense to me. Calling any function can "fail in a very dangerous manner", especially if that function is recursive or uses a lot of stack memory. Jan 27, 2022 at 1:52
  • A recursive function (that uses a normal amount of stack space per recursion level) will allocate stack space gradually, so it will hit the guard page and trigger stack expansion or stack overflow handling.
    – plugwash
    Jan 27, 2022 at 11:57
  • A function that allocates a fixed large amount of space on the stack is indeed a risk, but it's still IMO less of a risk than alloca/VLA because if it was going to cause memory violations it would likely cause them during development.
    – plugwash
    Jan 27, 2022 at 11:59
  • Whereas with alloca/VLA you can have a function that normally allocates an appropriate amount of space on the stack, but can be manipulated by an attacker to access locations at arbitrary offsets from the stack.
    – plugwash
    Jan 27, 2022 at 12:01
-1

Most answers here largely miss the point: there's a reason why using _alloca() is potentially worse than merely storing large objects in the stack.

The main difference between automatic storage and _alloca() is that the latter suffers from an additional (serious) problem: the allocated block is not controlled by the compiler, so there's no way for the compiler to optimize or recycle it.

Compare:

while (condition) {
    char buffer[0x100]; // Chill.
    /* ... */
}

with:

while (condition) {
    char* buffer = _alloca(0x100); // Bad!
    /* ... */
}

The problem with the latter should be obvious.

7
  • Do you have any practical examples demonstrating the difference between VLA and alloca (yes, I do say VLA, because alloca is more than just creator of statically-sized arrays)?
    – Ruslan
    Apr 29, 2017 at 15:33
  • There are use cases for the second one, which the first doesn't support. I may want to have 'n' records after the loop is done running 'n' times - perhaps in a linked-list or tree; this data structure then being disposed of when the function eventually returns. Which is not to say I would code anything that way :-)
    – greggo
    Jan 18, 2018 at 19:20
  • 2
    And I would say that "compiler can't control it" is because that's the way that alloca() is defined; modern compilers know what alloca is, and treat it specially; it's not just a library function like it was in the 80's. C99 VLAs are basically alloca with block scope (and better typing). Not any more or less control, just conforming to different semantics.
    – greggo
    Jan 18, 2018 at 19:28
  • @greggo: If you're the downvoter, I would gladly hear why you think my answer is not useful.
    – alecov
    Jan 18, 2018 at 20:16
  • In C, recycling is not the task of the compiler, instead it is the task of the c library (free() ). alloca() is freed on return.
    – peterh
    Dec 10, 2019 at 13:16

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