Is `std::common_type` associative?

Question

The template class std::common_type calculates a common type to a variadic type list. It is defined using the return type of the ternary operator x:y?z recursively. From that definition it is not obvious to me, whether calculating a std::common_type<X,Y> is associative, i. e. whether

using namespace std;
static_assert( is_same<common_type< X, common_type<Y,Z>::type    >::type,
                       common_type<    common_type<X,Y>::type, Z >::type>::value, "" );

will never throw a compile-time error for all types X, Y and Z for which the is_same<...> expression is valid.

Please note, that I'm NOT asking whether

static_assert( is_same<common_type<X,Y>::type,
                       common_type<Y,X>::type>::value, "" );

will ever fire. It will obviously not. The above is a whole different question.

Please note also, that the specification of std::common_type slightly changed in C++14 and will probably change again in C++17. So the answers may be different for different versions of the standard.

Answer 1

This fails on MinGW-w64(gcc 4.9.1). Also fails on VS2013 and (thanks Baum mit Augen) on gcc5.2 or clang 3.7 with libc++.

#include <type_traits>

using namespace std;

struct Z;
struct X{operator Z();};
struct Y{operator X();};
struct Z{operator Y();};

static_assert( is_same<common_type<X,Y>::type,
                       common_type<Y,X>::type>::value, "" ); // PASS

static_assert( is_same<common_type<X,Z>::type,
                       common_type<Z,X>::type>::value, "" ); // PASS

static_assert( is_same<common_type<Y,Z>::type,
                       common_type<Z,Y>::type>::value, "" ); // PASS

static_assert( is_same<common_type< X, common_type<Y,Z>::type    >::type,
                       common_type<    common_type<X,Y>::type, Z >::type>::value, "" ); // FAIL...

Answer 2

#include <type_traits>

struct T2;
struct T1 {
    T1(){}
    T1(int){}
    operator T2();
};
struct T2 {
    operator int() { return 0; }
};
struct T3 {
    operator int() { return 0; }
};
T1::operator T2() { return T2(); }

using namespace std;
using X = T1;
using Y = T2;
using Z = T3;
int main()
{

    true?T2():T3(); // int
    static_assert(std::is_same<std::common_type_t<T2,
                                                  T3>,
                               int>::value,
                  "Not int");

    true?T1():(true?T2():T3()); // T1
    static_assert(std::is_same<std::common_type_t<T1,
                                                  std::common_type_t<T2,
                                                                     T3>>,
                               T1>::value,
                  "Not T1");

    // -----------------------------------------

    true?T1():T2(); // T2
    static_assert(std::is_same<std::common_type_t<T1,
                                                  T2>,
                               T2>::value,
                  "Not T2");

    true?(true?T1():T2()):T3(); // int
    static_assert(std::is_same<std::common_type_t<std::common_type_t<T1,
                                                                     T2>,
                                                  T3>,
                               int>::value,
                  "Not int");

    // -----------------------------------------

    static_assert( is_same<common_type_t< X, common_type_t<Y,Z>    >,
                           common_type_t<    common_type_t<X,Y>, Z > >::value,
                    "Don't match");
}

Ouch! The mental gymnastics here hurt my head, but I came up with a case that fails to compile, printing "Don't match", with gcc 4.9.2 and with "C++14" (gcc 5.1) on ideone. Now whether or not that is conforming is a different matter...

Now the claim is for class types, std::common_type_t<X, Y> should be either X or Y, but I have coerced std::common_type_t<T2, T3> into converting to int.

Please try with other compilers and let me know what happens!

Answer 3

It's not associative! Here's a program where it fails:

#include <type_traits>

struct Z;
struct X { X(Z); }; // enables conversion from Z to X
struct Y { Y(X); }; // enables conversion from X to Y
struct Z { Z(Y); }; // enables conversion from Y to Z

using namespace std;    
static_assert( is_same<common_type< X, common_type<Y,Z>::type    >::type,
                       common_type<    common_type<X,Y>::type, Z >::type>::value, 
               "std::common_type is not associative." );

The idea is simple: The following diagram shows, what common_type calculates:

    X,Y -> Y
    Y,Z -> Z
    X,Z -> X

The first line is logical, since X can be converted to Y, but not vice versa. The same for the other two lines. Once X and Y are combined and recombined with Z we get Z. On the other hand, combining Y and Z and the combining X with the result gives X. Therefore the results are different.

The fundamental reason for this being possible is that convertibility is not transitive, i. e. if X is convertible to Y and Y convertible to Z it does not follow that X is convertible to Z. If convertibility were transitive, then conversions would work both ways and hence the common_type could not be calculated unambiguously and lead to a compile time error.

This reasoning is independent of the standard version. It applies to C++11, C++14 and the upcoming C++17.