41

Consider the following snippet:

#include <array>
int main() {
  using huge_type = std::array<char, 20*1024*1024>;
  huge_type t;
}

Obviously it would crash on most of platforms, because the default stack size is usually less than 20MB.

Now consider the following code:

#include <array>
#include <vector>

int main() {
  using huge_type = std::array<char, 20*1024*1024>;
  std::vector<huge_type> v(1);
}

Surprisingly it also crashes! The traceback (with one of the recent libstdc++ versions) leads to include/bits/stl_uninitialized.h file, where we can see the following lines:

typedef typename iterator_traits<_ForwardIterator>::value_type _ValueType;
std::fill(__first, __last, _ValueType());

The resizing vector constructor must default-initialize the elements, and this is how it's implemented. Obviously, _ValueType() temporary crashes the stack.

The question is whether it's a conforming implementation. If yes, it actually means that the use of a vector of huge types is quite limited, isn't it?

  • One should not store huge objects in a array type. Doing so potentially requires a very large region of contigious memory that may not be present. Instead, have a vector of pointers (std::unique_ptr typically) so that you don't place such a high demand on your memory. – NathanOliver Jan 6 at 20:31
  • 2
    Just memory. There are C++ implementations running that don't use virtual memory. – NathanOliver Jan 6 at 20:36
  • 3
    Which compiler, btw? I can't reproduce with VS 2019 (16.4.2) – ChrisMM Jan 6 at 20:50
  • 3
    From looking at the libstdc++ code, this implementation is only used if the element type is trivial and copy assignable and if the default std::allocator is used. – walnut Jan 6 at 20:54
  • 1
    @Damon As I mentioned above it seems to only be used for trivial types with the default allocator, so there shouldn't be any observable difference. – walnut Jan 6 at 23:52
17

There is no limit on how much automatic storage any std API uses.

They could all require 12 terabytes of stack space.

However, that API only requires Cpp17DefaultInsertable, and your implementation creates an extra instance over what is required by the constructor. Unless it is gated behind detecting the object is trivially ctorable and copyable, that implementation looks illegal.

  • 7
    From looking at the libstdc++ code, this implementation is only used if the element type is trivial and copy assignable and if the default std::allocator is used. I am not sure why this special case is made in the first place. – walnut Jan 6 at 20:54
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    @walnut Which means the compiler is free to as-if not actually create that temporary object; I'm guessing there is a decent chance on an optimized build it doesn't get created? – Yakk - Adam Nevraumont Jan 7 at 14:05
  • 3
    Yes, I guess it could, but for large elements GCC doesn't seem to. Clang with libstdc++ does optimize out the temporary, but it seems only if the vector size passed to the constructor is a compile-time constant, see godbolt.org/z/-2ZDMm. – walnut Jan 7 at 17:33
8
huge_type t;

Obviously it would crash on most of platforms ...

I dispute the assumption of "most". Since the memory of the huge object is never used, the compiler can completely ignore it and never allocate the memory in which case there would be no crash.

The question is whether it's a conforming implementation.

The C++ standard doesn't limit stack use, or even acknowledge the existence of a stack. So, yes it conforms to the standard. But one could consider this to be a quality of implementation issue.

it actually means that the use of a vector of huge types is quite limited, isn't it?

That appears to be the case with libstdc++. The crash was not reproduced with libc++ (using clang), so it seems that this is not limitation in the language, but rather only in that particular implementation.

  • 6
    "won't necessarily crash despite overflowing of stack because the allocated memory is never accessed by the program" — if the stack is used in any way after this (e.g. to call a function), this will crash even on the over-committing platforms. – Ruslan Jan 7 at 7:56
  • Any platform on which this does not crash (assuming the object isn't successfully allocated) is vulnerable to Stack Clash. – user253751 Jan 7 at 17:51
  • @user253751 It would be optimistic to assume that most platforms / programs aren't vulnerable. – eerorika Jan 7 at 18:03
  • I think overcommit only applies to the heap, not the stack. The stack has a fixed upper bound on its size. – Jonathan Wakely 2 days ago
  • @JonathanWakely You're right. It appears that the reason why it doesn't crash is because the compiler never allocates the object that is unused. – eerorika 2 days ago
4

I'm not a language lawyer nor a C++ standard expert, but cppreference.com says:

explicit vector( size_type count, const Allocator& alloc = Allocator() );

Constructs the container with count default-inserted instances of T. No copies are made.

Perhaps I'm misunderstanding "default-inserted," but I would expect:

std::vector<huge_type> v(1);

to be equivalent to

std::vector<huge_type> v;
v.emplace_back();

The latter version shouldn't create a stack copy but construct a huge_type directly in the vector's dynamic memory.

I can't authoritatively say that what you're seeing is non-compliant, but it's certainly not what I would expect from a quality implementation.

  • 3
    As I mentioned in a comment on the question, libstdc++ only uses this implementation for trivial types with copy assignment and std::allocator, so there should be no observable difference between inserting directly into the vectors memory and creating an intermediate copy. – walnut Jan 6 at 23:55
  • @walnut: Right, but the huge stack allocation and the performance impact of init and copy are still things I wouldn't expect from a high-quality implementation. – Adrian McCarthy Jan 7 at 18:32
  • 2
    Yes, I agree. I think this was an oversight in the implementation. My point was only that it doesn't matter in terms of standard compliance. – walnut Jan 7 at 18:36
  • IIRC you also need copyability or movability for emplace_back but not for just creating a vector. Which means you can have vector<mutex> v(1) but not vector<mutex> v; v.emplace_back(); For something like huge_type you might still have an allocation and move operation more with the second version. Neither should create temporary objects. – dyp Jan 7 at 21:25
  • 1
    @IgorR. vector::vector(size_type, Allocator const&) requires (Cpp17)DefaultInsertable – dyp Jan 10 at 9:53

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