Suppose there's a structure
struct Thing {
int a;
bool b;
};
and I get a pointer to member b of that structure, say as parameter of some function:
void some_function (bool * ptr) {
Thing * thing = /* ?? */;
}
How do I get a pointer to the containing object? Most importantly: Without violating some rule in the standard, that is I want standard defined behaviour, not undefined nor implementation defined behaviour.
As side note: I know that this circumvents type safety.
If you are sure that the pointer is really pointing to the member b in the structure, like if someone did
Thing t;
some_function(&t.b);
Then you should be able to use the offsetof macro to get a pointer to the structure:
std::size_t offset = offsetof(Thing, b);
Thing* thing = reinterpret_cast<Thing*>(reinterpret_cast<char*>(ptr) - offset);
Note that if the pointer ptr doesn't actually point to the Thing::b member, then the above code will lead to undefined behavior if you use the pointer thing.
char* is completely safe and canonical way for this kind of pointer arithmetic.
Nov 23 '15 at 11:55
int8_t can't even exist because addresses and sizeof stuff... everything fine.
Nov 23 '15 at 11:57
int8_t, it's defined to be a byte which char might not be” — no, you’ve got that completely the wrong way round. Use char here, int8_t is wrong.
Nov 23 '15 at 13:42
offsetof has undefined behavior for non-standard-layout types (C++11). In practice it often still works as expected.
offsetof is actually a C feature, not a C++ one, and the C++ specification explicitly says it is undefined on classes which aren’t standard layout. See also std::is_standard_layout, offsetof, and the Standard Layout section of the non-static data members page on cppreference.
void some_function (bool * ptr) {
Thing * thing = (Thing*)(((char*)ptr) - offsetof(Thing,b));
}
I think there is no UB.
X* get_ptr(bool* b){
static typename std::aligned_storage<sizeof(X),alignof(X)>::type buffer;
X* p=static_cast<X*>(static_cast<void*>(&buffer));
ptrdiff_t const offset=static_cast<char*>(static_cast<void*>(&p->b))-static_cast<char*>(static_cast<void*>(&buffer));
return static_cast<X*>(static_cast<void*>(static_cast<char*>(static_cast<void*>(b))-offset));
}
First, we create some static storage that could hold an X. Then we get the address of the X object that could exist in the buffer, and the address of the b element of that object.
Casting back to char*, we can thus get the offset of the bool within the buffer, which we can then use to adjust a pointer to a real bool back to a pointer to the containing X.
buffer as static typename std::aligned_storage<sizeof(X),alignof(X)>::type? Also, is there a reason to static_cast through void* instead of simply reinterpret_casting directly to char* and X*?
reinterpret_cast, as the mapping is ill-specified. static_cast has a defined mapping.
Mar 20 '17 at 20:22
reinterpret_cast for pointers is well defined. I don’t like that this reserves the extra space, but otherwise it seems good. I am very slightly worried about the offset not being the same between this X and the one for the argument one, but if the compiler does that (I can’t find any evidence it can’t, for non-standard-layout, but I doubt any do), I’m not sure there’s any way to get around it.
My proposal is derived from the @Rod answer in Offset from member pointer without temporary instance, and the similar @0xbadf00d's one in Offset of pointer to member.
I started imagining a form of offset driving the implementation of a pointer to a class data member, later confirmed by the post in question and the tests i've made.
I'm not a C++ practitioner so sorry for the brevity.
#include <iostream>
#include <cstddef>
using namespace std;
struct Thing {
int a;
bool b;
};
template<class T, typename U>
std::ptrdiff_t member_offset(U T::* mem)
{
return
( &reinterpret_cast<const char&>(
reinterpret_cast<const T*>( 1 )->*mem )
- reinterpret_cast<const char*>( 1 ) );
}
template<class T, typename U>
T* get_T_from_data_member_pointer (U * ptr, U T::*pU) {
return reinterpret_cast<T*> (
reinterpret_cast<char*>(ptr)
- member_offset(pU));
}
int main()
{
Thing thing;
thing.b = false;
bool * ptr = &thing.b;
bool Thing::*pb = &Thing::b;
std::cout << "Thing object address accessed from Thing test object lvalue; value is: "
<< &thing << "!\n";
std::cout << "Thing object address derived from pointer to class member; value is: "
<< get_T_from_data_member_pointer(ptr, &Thing::b) << "!\n";
}
1 as a pointer actually standards-compliant, or could it have alignment issues or something? I actually think you aren’t allowed to convert any int to a pointer unless that value was calculated from a limited set of operations from a pointer originally, although it might be that you just aren’t allowed to dereference that. Although I did think many times when looking into this that I wish C++ provided by default a T* operator-(U*, U T::*) for all types T and U.
gcc provided that as an extension, since I’m pretty sure it actually stores pointer-to-data-member variables as a ptrdiff_t (refspecs.linuxfoundation.org/cxxabi-1.86.html).
reainterpret_cast issues, if i remember correctly from my old study of C++98. But the conversion is tricky because it's only a way to deduce a displacement, given that the class data member pointer is realized with an offset/displacement. It's just giving the base for compute a pointer arithmetic, nothing to dereference. Correct me if i'm wrong. The @Rod answer is pointing out how that particular convoluted syntax (char reference, at first, and then taking the address) is due to compiler warnings in the line of your observations.
Thingpointer from abooladdress. Why don't you pass the Thing address/pointer to your function?offsetofcan be undefined. You’ve probably moved on from this since November 2015, but if it’s still relevant and a non-offsetofanswer turns up, I suggest you implement it. Fortunately, for an allocator, you don’t need to return a pointer. You can return any pointer-like structure which satisfiesNullablePointerandRandomAccessIteratorandtypedefit topointer.