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.

  • 2
    Will you accept a case where (X,(Y,Z)) has a common type, but (X,Y), and hence (X,Y),Z, does not? Or do you want them both to resolve to a type, but different ones. 'Cause I'm pretty stuck trying to construct a case for the latter, and strongly suspect it isn't possible; any two chains of conversions will cause an ambiguity.
    – BoBTFish
    Dec 22, 2015 at 11:36
  • It's certainly the case that the static_assertion can fail to compile, because there is no common type. I assume the question is asking about the case where all the common_type types are valid, but is_same is false. Dec 22, 2015 at 11:40
  • @JonathanWakely Thanks for the hint. Fixed the question. Dec 22, 2015 at 11:57
  • Apparently you can make it not-associative. But that doesn't matter, if it not associative it is because there is a logical inconsistency in your design. It would be like defining operator== in a way that is not consistent with logic.
    – alfC
    Dec 22, 2015 at 14:07
  • I assumed this was more of an academic interest, but either way, I disagree with "that doesn't matter... there is a logical inconsistency in your design" because (in the general sense) associativity is not always desired, and substitution failure can be. I can at least think of a tangential counter-example to the operator== argument: a double cast down to a float may equal another float, but a float cast up to a double can easily fail equality. (Using this impl. warrants documentation, but casting both to LCM (float here) or both to GCM (double here) to enforce assoc. is edge case spackle.)
    – John P
    Oct 28, 2017 at 14:59

3 Answers 3


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...
  • 2
    Also fails with gcc5.2 and clang 3.7 with libc++.
    – Baum mit Augen
    Dec 22, 2015 at 12:21
  • Also fails on clang 3.8.0 and gcc 7.0.0 (snapshot) Jul 18, 2016 at 21:40
#include <type_traits>

struct T2;
struct T1 {
    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
                  "Not int");

    true?T1():(true?T2():T3()); // T1
                  "Not T1");

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

    true?T1():T2(); // T2
                  "Not T2");

    true?(true?T1():T2()):T3(); // int
                  "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!

  • 1
    Also fires with clang3.7 + libc++.
    – Baum mit Augen
    Dec 22, 2015 at 12:25
  • fires with mingw-w64 too. VS2013 triggers all of them (and some other errors) except the "Not T2" one. Granted, VS is not know for its conformity to the Standard... Dec 22, 2015 at 12:47
  • My interpretation of the standard suggests that the second case is ill-formed because int and T1 can convert to each other. This makes them ineligible to be operands 2 and 3 of operator:? Dec 22, 2015 at 12:52
  • 4
    @RichardHodges int converts to T1. T1 doesn't convert to int (one-user-defined-conversion-only rule).
    – T.C.
    Dec 22, 2015 at 13:05

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.

  • Yes, but I have philosophical concerns about three categories than can be mapped into each other but only cyclically. I would say that is not associative in the language but it should be, in the same sense that operator== should be implemented in a way that T a = b; assert(a == b);
    – alfC
    Dec 22, 2015 at 14:04

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge that you have read and understand our privacy policy and code of conduct.

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