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I have a Vector class which represents a 2D vector. It is templated to allow any numerical type to be used for the x and y components. As an example, one of the arithmetic operators I overload is * for multiplying a vector with a scalar:

template <typename T, typename U>
inline const Vector<T> operator*(const Vector<T>& vector, U scalar) {
    return Vector<T>(vector.x * scalar, vector.y * scalar);

(I also have a function with the parameters in the opposite order to allow scalar * Vector in addition to Vector * scalar).

As you can see, I use <T, U> instead of simply <T> so that the scalar doesn't have to be the same type as the Vector. When I didn't do this, surprisingly Vector<double> * int wouldn't compile (I thought the int would automatically widen).

In any case, I don't simply want to return a Vector<T>. I want to mimic the built-in types and return whichever has higher precision, T or U. So for example, Vector<int> * double => Vector<double> while Vector<double> * short => Vector<double>.

Is this possible?

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2 Answers 2

up vote 3 down vote accepted

There are two solutions to this. In Pre C++11 you can write a template like:

template <typename T, typename U>
struct WhatWillItBe {
  typedef T result_t;

template <typename T>
struct WhatWillItBe<T, double> {
  typedef double result_t;

// ... lots more

etc. and write a lot of specialisations, then you can use that to look up the return type, e.g.:

template <typename T, typename U>
inline const Vector<typename WhatWillItBe<T,U>::result_t> operator*(const Vector<T>& vector, U scalar) {
    return Vector<typename WhatWillItBe<T,U>::result_t>(vector.x * scalar, vector.y * scalar);

Alternatively C++11 makes this straightforward, you can write auto for the return type and use -> to specify the return type after the rest of the function:

template <typename T, typename U>
inline auto operator*(const Vector<T>& vector, U scalar) -> Vector<decltype(vector.x*scalar)> {
    return Vector<decltype(vector.x*scalar)>(vector.x * scalar, vector.y * scalar);

Which allows you to use decltype for the return type of a function, setting it based on what would happen for promotion naturally with vector.x * scalar.

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Awesome, wish I could upvote more than once. I keep seeing good applications of the -> return type syntax all the time. –  Seth Carnegie Feb 20 '12 at 21:17
Noting, of course, that in C++11 your return type shouldn't be const, as it inhibits move semantics. –  ildjarn Feb 20 '12 at 21:19
Does clang++ 3.0 support this? –  Mk12 Feb 20 '12 at 21:21
You're right, your last example compiles when I use clang++ -std=c++0x :). –  Mk12 Feb 20 '12 at 21:35
@Mk12 : Effective C++ was written well before C++11; if there's ever a new edition, that recommendation will surely be removed. –  ildjarn Feb 20 '12 at 21:55

You can use common_type or decltype to cook up something that gives you the resulting type; and then you have to create the actual vector:

template <typename A, typename B>
std::vector<typename std::common_type<A, B>::type>
operator*(std::vector<A> const & v, B const & x)
    std::vector<typename std::common_type<A, B>::type> res;
    for (A a : v) res.push_back(a * x);
    return res;

Using decltype, you can get at the result type via:

decltype(std::declval<A>() * std::declval<B>())

For both std::common_type and std::declval you need to #include <type_traits>.

With delayed return types (auto and ->) you can use decltype directly on the function arguments, but using std::declval feels a bit more hygienic, since it doesn't require you to furnish an actual instance of your type (and thus it is applicable even in situations where this isn't possible).

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I'd not see common_type before! That's rather handy. –  Flexo Feb 20 '12 at 21:19
declval also looks handy, +1 –  Seth Carnegie Feb 20 '12 at 21:22
Just by the way, I was talking about my own math Vector class, not std::vector, but this is still a great answer. Unfortunately I get an error when #includeing <type_traits>, so I guess this won't work for me. –  Mk12 Feb 20 '12 at 21:29
It should be noted that this answer requires C++11; if the OP is restricted to C++03 there isn't much of help here. –  ildjarn Feb 20 '12 at 21:30
@Mk12: Those traits are only part of C++11, so add -std=c++0x in GCC, or use MSVS 10 and above. –  Kerrek SB Feb 20 '12 at 21:31

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