In regard to C++ Standard:

  1. Does std::function of GNU Compiler Collection use union data type to cast between different function pointer types (e.g. to convert non-static member function pointer to non-member function pointer)? I think so. EDIT: It uses union data type but no cast is made (type-erasure).
  2. Is it an undefined behavior to cast between different function pointer types (in C++ or C++11 Standard)? I think so.
  3. Is it possible to implement a std::function without using any code which has an undefined behavior? I don't think so. I'm talking about this.

The following is my question:

Do we sometimes have to write code that has undefined behavior according to the C++ Standard (but they have defined behavior for particular C++ compilers such as GCC or MSVC)?

Does it mean that we can't/shouldn't prevent undefined behavior of our C++ codes?

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    I highly doubt std::function cannot be implemented. And I would personally recommend never writing code that is undefined by The Standard, even if a particular platform guarantees a specific behaviour. But it is occasionally useful in that case, though I've yet to be convinced it is necessary. – BoBTFish Jul 9 '14 at 8:23
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    @BoBTFish It depends on the context, and what undefined behavior we're dealing with. There's a lot of necessary functionality which isn't defined in the C++ standard (but is, for example, in Posix, or in the Windows specification). – James Kanze Jul 9 '14 at 8:26
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    Besides everything else, the standard library code is free to exploit whatever platform-specific behavior it wants, all it has to guarantee is that externally it will behave as specified by the standard. So, even if inside the library code there's stuff that is not portable, you are not invoking UB by using it. – Matteo Italia Jul 9 '14 at 8:30
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    No, we don't have to write "codes" with undefined behavior. Codes are things that cryptologists make and break. We write code. If your boss tells you to write code with undefined behaviour, or else, you go ahead and write it. Or you say no and pack your belongings and get escorted out of the campus. Does it make you "have to" write such code? I guess that depends on what you mean by "have to". Standard C++ is Turing-complete so everything is doable without UB. Sometimes one resorts to UB for squeezing that last drop of performance out of the code, but other than that... – n.m. Jul 9 '14 at 8:39
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    "Does std::function of GNU Compiler Collection use union data type to cast between different function pointer types (e.g. to convert non-static member function pointer to non-member function pointer)? I think so." Absolutely not. It uses type erasure. std::function is not a wrapper of a function pointer, it can store function objects with a state. – sbabbi Jul 9 '14 at 8:50

Nobody forces you to write anything, so nobody forces you to write code that invokes UB.

As for the standard library, its code is free to contain any nonportable behavior it wants - heck, it may even be written in another language with the compiler creating the bindings via magical unicorns; all that matters is that it behaves according to specification.

Come to think of it, it's obvious that at some level the standard library will have to go outside the standard - making syscalls, talking with hardware, ... is not even contemplated by the standard, and is often deeply platform-specific. For example, on 64 bit Linux you can perform syscalls with inline assembly (via the sysenter instruction) - the standard does not forbid this, it just doesn't mandate that every platform must behave like this.

As for the specific example, I don't see any UB - the unions there are used as specified by the standard - i.e. reading only from the last member you wrote into (hence the field m_flag).

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    +1 for the magical unicorns creating the standard. – Theolodis Jul 9 '14 at 8:50
  • Thanks, I forgot about how my example has been working (m_flag for first example and function overloading for second example). – M. Sadeq H. E. Jul 9 '14 at 9:57
  1. Why is this ever interesting? It could be implemented in terms of __gnu_cplusplus_builtin_std_function__ for all we know.
  2. No, the standard explicitly permits that.
  3. Definitely yes, with any number of fully standard-conforming techniques.

The rest of the question is ill-posed, addressed in a comment.

Here's a rudimentary mock-up of std::function on the back of an envelope, with no casts or unions or AFAICT anything remotely dangerous. Of course not all features of real std::function either, but that's just a matter of some technical work.

#include <memory>
#include <iostream>
#include <type_traits>

template <typename R, typename ... Args>
struct CallBase
  virtual R operator()(Args... args) = 0;
  virtual ~CallBase() {}

template <typename R, typename ... Args>
struct FunCall : CallBase<R, Args...>
  virtual R operator()(Args... args) { return f(args...); }
  FunCall(R f(Args...)) : f(f) {}

template <typename Obj, typename R, typename ... Args>
struct ObjCall : CallBase<R, Args...>
  virtual R operator()(Args... args) { return o(args...); }
  Obj o;
  ObjCall(Obj o) : o(o) {}

template <typename R, typename ... Args> struct MemFunCall;
template <typename R, typename Cl, typename ... Args>
struct MemFunCall<R, Cl, Args...> : CallBase<R, Cl, Args...>
  typedef typename std::remove_reference<Cl>::type Rcl;
  virtual R operator()(Cl c, Args... args) { return (c.*f)(args...); }
  R (Rcl::*f)(Args...);
  MemFunCall(R (Rcl::*f)(Args...)) : f(f) {}

template <typename Fn> class Function;
template <typename R> struct Function<R()>
  std::unique_ptr<CallBase<R>> fn;
  R operator()() { return (*fn)(); }
  Function(R (*f)()) : fn(new FunCall<R>(f)) {}
  template<typename Obj>
  Function(Obj o) : fn(new ObjCall<Obj, R>(o)) {}

template <typename R, typename Arg1, typename ... Args> 
struct Function<R(Arg1, Args...)>
  std::unique_ptr<CallBase<R, Arg1, Args...>> fn;
  R operator()(Arg1 arg1, Args... args) { return (*fn)(arg1, args...); }
  Function(R (*f)(Arg1 arg1, Args...)) :
    fn(new FunCall<R, Arg1, Args...>(f)) {}
  template<typename T>
  Function(R (T::*f)(Args...)) : 
    fn(new MemFunCall<R, Arg1, Args...>(f)) {}
  template<typename Obj>
  Function(Obj o) : fn(new ObjCall<Obj, R, Arg1, Args...>(o)) {}

struct Foo
  static void bar (int a) { std::cout << "bar " << a << std::endl; }
  int baz (const char* b) { std::cout << "baz " << b << std::endl; return 0; }
  void operator()(double x) { std::cout << "operator() " << x << std::endl; }


int main ()
  Function<void(int)> f1(&Foo::bar);
  Foo foo;
  Function<int(Foo&, const char*)> f2(&Foo::baz);
  f2(foo, "whatever");
  Function<void(double)> f3(foo);
  • But you are using inheritance which has lower performance in comparison to union (no casts!) and function overloading. – M. Sadeq H. E. Jul 15 '14 at 18:16
  • There is not a single word about performance in the question. If you have specific performance goals, state them explicitly. – n.m. Jul 15 '14 at 19:54

Does std::function of GNU Compiler Collection use union data type to cast between different function pointer types (e.g. to convert non-static member function pointer to non-member function pointer)? I think so.

No, it uses type-erasure. It is a kind of variant for function objects.

Is it an undefined behavior to cast between different function pointer types (in C++ or C++11 Standard)? I think so.

It does not have to be, you can cast a function pointer to another function pointer and a member function pointer to another member function pointer.

Is it possible to implement a std::function without using any code which has an undefined behavior? I don't think so. I'm talking about this.

Yes you can, there are plenty examples out there, it is really easy, doing so will teach you a lot about c++:

http://probablydance.com/2013/01/13/a-faster-implementation-of-stdfunction/ https://codereview.stackexchange.com/questions/14730/impossibly-fast-delegate-in-c11 http://avdgrinten.wordpress.com/2013/08/07/c-stdfunction-with-the-speed-of-a-macro/

But, in time, you'll see that the ability to think and model at a high-level is more important than knowing the details of a specific language.


In some rare cases it can be voluntary to exploit an undefined-behavior, that is when all the following conditions are met:

  • you are certain that the code is not supposed to be compiled on other platforms/using other compilers (this happen but is very rare, as you really never know what will happen with your code in the future);
  • you are using a very specific compiler, with a very specific version, with very specific compilation flags targeting one very specific platform (yeah sure...);
  • your compiler, under these conditions, specify in it's documentation what is the behaviour of that specific undefined-behaviour code you have at hand (for example it might call terminate() even if the standard say that it's undefined behaviour, or even do something useful, as it's allowed by undefined-behaviour from the standard point of view);

Basically, if your compiler does document the behavior when the standard says it's undefined-bahaviour, you can rely on it if you are not writting portable code.

Of course compilers, compilation flags, code and target platforms change through time so it's rarely a good idea. The important thing to understand is that C++ standard only define what a cross-platform C++ code is allowed to look like. It doesn't specify more (it don't specify implementation for example) and just specify where it can't specify a portable behavior.

So if you write portable code, or code that follow the standard, you never have to exploit undefined behaviour.

Also, most undefined behaviour are just usage errors that are costly to to check at runtime (like checking array boundaries, you do it if you want but the standard will not force the compilers to do it). Therefore, it might be in some case useful to add checks to avoid an undefined behaviour but it's better to just not allow that code to be written in the beginning. It's one of the reasons strong type checking is helpful with big codebases and also why static analysis is getting a lot of attention these days. They do help prevent even compiling some code that can be checked at compile time that they are going to be problematic.

  • A more interesting historical example for point #3 might be code that performs wrapping computations on signed integers. Many older compilers did in fact explicitly specify that code could legitimately rely upon wrapping behavior, and the compiler would not make any optimizations based upon a presumption that numbers couldn't wrap. – supercat Jul 9 '14 at 17:14

The C++ standard library is part of the implementation. So the C++ standard library may contain source code that would have undefined behaviour if you wrote it in your own user code, but the implementation guarantees that it works as defined by the C++ standard. If it doesn't work as defined, that's not undefined behaviour, that is a bug in the implementation.

Code doesn't just have "undefined behaviour", it has "behaviour that is not defined by the C++ standard". For example, there are tons of Posix functions that are defined by the Posix standard. If your implementation says "this implementation follows the C++ Standard and the Posix Standard", then using Posix functions that don't have behaviour defined by the C++ Standard is fine, because they have defined behaviour on your implementation (possibly not on another that is not Posix compatible).

And you may have heard that undefined behaviour could format your hard drive (and other nasty things). But the other way round, since "formatting hard drives" is not mentioned anywhere in the C++ Standard, if formatting your hard drive is what your program is actually supposed to do, then you will have to do something that is undefined behaviour according to the C++ standard.

Obviously you'd need some pretty good reason to invoke undefined behaviour in your code. Because of the obvious dangers (different behaviours possible, nasty behaviour possible with optimising compilers, huge portability problems), any undefined behaviour without very strong justification is a very bad sign.


Every program using the POSIX API for accessing dynamically linked functions must rely on behaviour undefined by the C++ standard: specifically converting the void* returned by dlsym to a function pointer. Of course, "works as expected" is one way to implement undefined behaviour, and the POSIX standard mandates the cast is well-defined on all compliant platforms.


The very fastest at-face-value implementations of the fast inverse square root involve undefined behaviour. A more compliant implementation may require an additional copy. Given that the raison d'être of the fast inverse square root lies in being fast, this may just qualify as "need" depending on the situation. However, modern optimizers are capable of such sorcery that I wouldn't be surprised if the compliant version was quietly transformed into the optimal form.

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    @Down-voter: I can't improve/correct/delete the answer if you don't say what is wrong with it... – DeveloperInDevelopment Jul 9 '14 at 20:28

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