With the C++14 (aka. C++1y) Standard in a state close to being final, programmers must ask themselves about backwards compatibility, and issues related to such.

The question

In the answers of this question it is stated that the Standard has an Appendix dedicated to information regarding changes between revisions.

It would be helpful if these potential issues in the previously mentioned Appendix could be explained, perhaps with the help of any formal documents related to what is mentioned there.

  • According to the Standard: What changes introduced in C++14 can potentially break a program written in C++11?
  • 12
    I think that with the increasing flow of low-quality questions in this site (meta.stackoverflow.com/questions/252506/… , meta.stackoverflow.com/questions/251758/…), everybody just got itchy fingers to downvote and gets overzealous in dismissing questions. This is however a good question and an even greater answer. – bolov Jun 1 '14 at 15:25
  • 1
    @BenVoigt well, a new answer can be posted, or the existing answer can be edited. I think the positive gains from this answer vastly outweighs the negative ones (which I don’t deny they exist). At least for me. – bolov Jun 1 '14 at 15:44
  • @BenVoigt I followed these two questions; (1) and (2). I do however see what you are pointing out, and I see two solutions. Either an edit of the question to reflect that it's asking about the issues raised in the standard, or turning it too a community wiki to prevent excessive posts in the thread (if that happens). – Filip Roséen - refp Jun 1 '14 at 15:51
  • 1
    Pretty much any change at all is a potentially breaking change in any language that has the means (at compile time or at run time) to inspect the capabilities of the standard library. I think it would be more interesting to ask if there is any change between C++11 and C++14 that isn't potentially breaking. If there isn't, then your question is just "What's new in C++14?" (Not that that's not a fair question.) – user743382 Jun 1 '14 at 16:14
  • @BenVoigt Post edited to move away from "list question"-ness, now it should be suitable for stackoverflow. I propose we remove related comments to keep the comment section relevant to the current state of the post. – Filip Roséen - refp Jun 1 '14 at 17:27

Note: In this post I consider a "breaking change" to be either, or both, of;
1. a change that will make legal C++11 ill-formed when compiled as C++14, and;
2. a change that will change the runtime behavior when compiled as C++14, vs C++11.

C++11 vs C++14, what does the Standard say?

The Standard draft (n3797) has a section dedicated for just this kind of information, where it describes the (potentially breaking) differences between one revision of the standard, and another.

This post has used that section, [diff.cpp11], as a base for a semi-elaborate discussion regarding the changes that could affect code written for C++11, but compiled as C++14.

C.3.1] Digit Separators

The digit separator was introduced so that one could, in a more readable manner, write numeric literals and split them up in a way that is more natural way.

int x = 10000000;   // (1)
int y = 10'000'000; // (2), C++14

It's easy to see that (2) is much easier to read than (1) in the above snippet, while both initializers have the same value.

The potential issue regarding this feature is that the single-quote always denoted the start/end of a character-literal in C++11, but in C++14 a single-quote can either be surrounding a character-literal, or used in the previously shown manner (2).

Example Snippet, legal in both C++11 and C++14, but with different behavior.

#define M(x, ...) __VA_ARGS__

int a[] = { M(1'2, 3'4, 5) };

// int a[] = { 5 };        <-- C++11
// int a[] = { 3'4, 5 };   <-- C++14
//                              ^-- semantically equivalent to `{ 34, 5 }`

( Note: More information regarding single-quotes as digit separators can be found in n3781.pdf )

C.3.2] Sized Deallocation

C++14 introduces the opportunity to declare a global overload of operator delete suitable for sized deallocation, something which wasn't possible in C++11.

However, the Standard also mandates that a developer cannot declare just one of the two related functions below, it must declare either none, or both; which is stated in [new.delete.single]p11.

void operator delete (void*) noexcept;
void operator delete (void*, std::size_t) noexcept; // sized deallocation

Further information regarding the potential problem:

Existing programs that redefine the global unsized version do not also define the sized version. When an implementation introduces a sized version, the replacement would be incomplete and it is likely that programs would call the implementation-provided sized deallocator on objects allocated with the programmer-provided allocator.

Note: Quote taken from n3536 - C++ Sized Deallocation

( Note: More of interest is available in the paper titled n3536 - C++ Sized Deallocation, written by Lawrence Crowl )

C.3.3] constexpr member-functions, no longer implicitly const

There are many changes to constexpr in C++14, but the only change that will change semantics between C++11, and C++14 is the constantness of a member-function marked as constexpr.

The rationale behind this change is to allow constexpr member-functions to mutate the object to which they belong, something which is allowed due to the relaxation of constexpr.

struct A { constexpr int func (); };

// struct A { constexpr int func () const; }; <-- C++11
// struct A { constexpr int func ();       }; <-- C++14

Recommended material on this change, and why it is important enough to introduce potential code-breakage:

Example snippet, legal in both C++11 and C++14, but with different behavior

struct Obj {
  constexpr int func (int) {
    return 1;

  constexpr int func (float) const {
    return 2;

Obj const a = {}; 
int const x = a.func (123);

// int const x = 1;   <-- C++11
// int const x = 2;   <-- C++14

C.3.4] Removal of std::gets

std::gets has been removed from the Standard Library because it is considered dangerous.

The implications of this is of course that trying to compile code written for C++11, in C++14, where such a function is used will most likely just fail to compile.

( Note: there are ways of writing code that doesn't fail to compile, and have different behavior, that depends on the removal of std::gets from the Standard Library )

  • 2
    @JonathanWakely std::is_same<decltype(i), std::initializer_list<int>>::value having auto i {1}, will yield true in C++14 too; there has been no change in this aspect. – Filip Roséen - refp Jun 2 '14 at 7:29
  • 4
    Yet another change is the adding std::decay to the implementation of std::common_type. So the code like std::common_type<int&, int&>::type f(int& x){return x;} /*...*/ int x{}; f(x) = 2; becomes invalid. – Constructor Jun 2 '14 at 8:31
  • 3
    The common_type change is a DR, so most vendors will change their C++11 library too (if they haven't done so already) and you won't be able to detect any difference between C++11 and C++14 in that regard. – Jonathan Wakely Jun 2 '14 at 9:56
  • 2
    That last one is already causing problems with C++1y semi-implementations that are a combination of C11 and C++11 headers, where the latter invokes std::gets in the former that no longer exists: stackoverflow.com/q/17775390/560648 – Lightness Races with Monica Jun 2 '14 at 22:17
  • 2
    @Yakk: That isn't a "breaking" change, though. The behavior is correctly varying based on the presence of the feature it's designed to detect. – Ben Voigt Jun 15 '14 at 17:00

Not the answer you're looking for? Browse other questions tagged or ask your own question.