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As answer to my last question it was suggested to use, when possible, std::common_type<X,Y>::type in the declaration of automatic return types instead of my original decltype(). However, doing so I ran into problems (using gcc 4.7.0). Consider the following simple code

template<typename> class A;
template<typename X> class A {
  X a[3];
  template <typename> friend class A;
  A(X a0, X a1, X a2) { a[0]=a0; a[1]=a1; a[2]=a2; }
  X operator[](int i) const { return a[i]; }
  X operator*(A const&y) const          // multiplication 0: dot product with self
  { return a[0]*y[0] + a[1]*y[1] + a[2]*y[2]; }
  template<typename Y>
  auto operator*(A<Y> const&y) const -> // multiplication 1: dot product with A<Y>
    typename std::common_type<X,Y>::type
  { return a[0]*y[0] + a[1]*y[1] + a[2]*y[2]; }
  template<typename Y>
  auto operator*(Y s) const ->          // multiplication 2: with scalar
    A<typename std::common_type<X,Y>::type>
  { return A<decltype((*this)[0]*s)>(s*a[0],s*a[1],s*a[2]); }

int main()
  A<double> x(1.2,2.0,-0.4), y(0.2,4.4,5.0);
  A<double> z = x*4;
  auto dot = x*y;           // <-- 
  std::cout<<" x*4="<<z[0]<<' '<<z[1]<<' '<<z[2]<<'\n'
           <<" x*y="<<dot<<'\n';

when USE_DECLTYPE is #defined, the code compiles and runs fine with gcc 4.7.0. But otherwise, the line indicated in main() calls the multiplaction 2, which seems weird if not wrong. Could this possibly be a consequence/side effect of using std::common_type or is it a bug with gcc?

I always thought that the return type has no bearing on which of a multitude of fitting template functions is chosen...

share|improve this question
std::common_type<X, Y> may well make some assumptions about how X ad Y behave, and is defined in C++. decltype on the other hand is a special language feature, and so I feel it would have fewer problems in strange circumstances. I'll have a play with your code and see what happens. – Rook Jun 15 '12 at 17:22
So, having flailed around with GCC4.4 and VS2010 a bit... I've come to the conclusion that I have no idea, but that std::common_type gives significantly nastier compilation errors than decltype when things go wrong. Make of that what you will. – Rook Jun 15 '12 at 18:05
@Rook thanks. I'd like to know what the standard says -- any idea anybody? – Walter Jun 15 '12 at 18:35
@Rook, you should probably get a newer version of GCC if you want to use and give advice on C++11 – Jonathan Wakely Jun 15 '12 at 18:38
up vote 8 down vote accepted

The suggestion to use common_type is bogus.

The problem using decltype you had in your other question was simply a GCC bug.

The problem you have in this question when using common_type is because std::common_type<X, Y>::type tells you the type that you would get from the expression:

condition ? std::declval<X>() : std::declval<Y>()

i.e. what type an X and a Y can both be converted to.

In general that has absolutely nothing to do with the result of x * y, if X and Y have an overloaded operator* that returns a completely different type.

In your specific case, you have the expression x*y where both variables are type A<double>. Overload resolution tries to check each overloaded operator* to see if it's valid. As part of overload resolution it instantiates this member function template:

template<typename Y>
    auto operator*(Y s) const ->
    A<typename std::common_type<X,Y>::type>;

With A<double> substituted for the template parameter Y. That tries to instantiate common_type<double, A<double>> which is not valid, because the expression

condition ? std::declval<double>() : std::declval< A<double> >()

is not valid, because you cannot convert A<double> to double or vice versa, or to any other common type.

The error doesn't happen because that overloaded operator* is called, it happens because the template must be instantiated in order to decide which operator should be called, and the act of instantiating it causes the error. The compiler never gets a far as deciding which operator to call, the error stops it before it gets that far.

So, as I said, the suggestion to use common_type is bogus, it prevents SFINAE from disabling the member function templates that don't match the argument types (formally, SFINAE doesn't work here because the substitution error happens outside the "immediate context" of the template, i.e. it happens inside the definition of common_type not in the function signature, where SFINAE applies.)

It's permitted to specialize std::common_type so it knows about types without implicit conversions, so you could specialize it so that common_type<double, A<double>>::type is valid and produces the type double, like so:

namespace std {
  template<typename T>
    struct common_type<T, A<T>> { typedef T type; };

Doing so would be a very bad idea! What common_type is supposed to give is the answer to "what type can both these types safely be converted to?". The specialization above subverts it to give the answer to "what is the result of multiplying these types?" which is a completely different question! It would be as foolish as specializing is_integral<std::string> to be true.

If you want the answer to "what is the type of a general expression such as expr ?" then use decltype(expr), that's what it's for!

share|improve this answer
ok, std::common_type is not a good idea here. But it shouldn't have any implications for which of the overloaded operator* is chosen, should it? – Walter Jun 15 '12 at 18:43
see my edited answer – Jonathan Wakely Jun 15 '12 at 18:53
excellent! green tick. – Walter Jun 16 '12 at 7:06

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