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Is there any way to double the precision returned by multiply (to avoid overflow)?

template<class T> class MyClass {
     T multiply (T a, T b) { return a * b; }
}

Something like:

long T multiply (T a, T b) { return a * b; }

So that whether 'int', 'long', or 'double' was given, a 'long int', 'long long', or 'long double' would be returned from multiply.

This is a general question. I'm working around it by using a double internally. But my question is whether there is any mechanism to promote a type to its "long" variant in C++?

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It's probably better to just use long long as your T if you want to avoid overflow. –  Pubby Mar 7 '13 at 23:10
4  
long is not a qualifier that can be applied to a type name; long int is an indivisible type name that happens to be spelled with the two keywords long and int. –  Keith Thompson Mar 7 '13 at 23:11
    
I don't understand why you want to use "long T". T is a template parameter and it can be whatever primitive type or instance of object you want to be, as you long * operator is override. In some case you can cast T to long. –  user1929959 Mar 7 '13 at 23:12
3  
Also, keep in mind that there's no guarantee that the long version of a type is any larger than the normal one. long and long long are both 64 bits on my system, for instance. –  duskwuff Mar 7 '13 at 23:15
    
@AndyProwl: Uhm... what? Maybe because it won't compile? You cannot add long (or unsigned), to a type. –  David Rodríguez - dribeas Mar 7 '13 at 23:17

2 Answers 2

up vote 13 down vote accepted

A possible solution is to define your own type trait:

template<typename T>
struct add_long { typedef T type; };

template<>
struct add_long<int> { typedef long int type; };

template<>
struct add_long<double> { typedef long double type; };

template<>
struct add_long<long int> { typedef long long int type; };

// And so on...

This is how you would use it in your class:

template<class T>
class MyClass {
public:
    typedef typename add_long<T>::type longT;
    longT multiply (longT a, longT b) { return a * b; }
};

And here is a small test:

#include <type_traits>

int main()
{
    MyClass<int> m;
    auto l = m.multiply(2, 3);
    static_assert(std::is_same<decltype(l), long int>::value, "Error!");
}
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3  
Depending on expected use, you might want to omit type from the generic template, or otherwise ensure that you get a compilation error if you try this with with a type that doesn't have a longer version and therefore will overflow anyway. For safety, you could then define the specializations with int8_t -> int16_t, int16_t -> int32_t and int32_t -> int64_t to ensure that you really are increasing the size at each stage. Ofc that's slightly less portable since those are optional types, but on the systems the code doesn't port to multiply can overflow, which is best avoided. –  Steve Jessop Mar 7 '13 at 23:21
1  
@SteveJessop: The unsigned part is covered by the "and so on" comment ;-) –  Andy Prowl Mar 7 '13 at 23:24
1  
Dont you want a and b to still be T? –  Loki Astari Mar 8 '13 at 0:06
1  
@SteveJessop: an extremely useful suggestion that I've combined with Andy's original answer in my solution. Your comment is right-on and I hope it is up-voted more to draw more attention to it. –  Brent Foust Mar 8 '13 at 5:50
2  
@Rubistro Then if a and b are still T, don't forget to cast them (or at least one of them) to longT before multiplying, as otherwise the multiplication will be upcast to the larger type after overflowing. –  Christian Rau Mar 8 '13 at 8:33

@Andy has the right answer, which works quite well. But for those who want a compile-time error if MyClass is instantiated with a type for which there is no 'long' value, I've combined it with @SteveJessop's excellent comment to give the following solution:

// --- Machinery to support double-precision 'T' to avoid overflow in method 'multiply' ---
// Note: uncomment typedef if don't want compile-time errors 
// when no "long" type exists
// ----
template<typename T>
struct add_long { /*typedef T type;*/ };

template<> struct add_long<int8_t>   { typedef int16_t  type; };
template<> struct add_long<int16_t>  { typedef int32_t  type; };
template<> struct add_long<int32_t>  { typedef int64_t  type; };
template<> struct add_long<uint8_t>  { typedef uint16_t type; };
template<> struct add_long<uint16_t> { typedef uint32_t type; };
template<> struct add_long<uint32_t> { typedef uint64_t type; };

template<> struct add_long<float>    { typedef double        type; };
template<> struct add_long<double>   { typedef long double   type; };

Example usage of 'longT':

template<class T> class MyClass
{
    // Note: a compiler error on the next line means that 
    //       class T has no double-precision type defined above.
    typedef typename add_long<T>::type longT;
public:
    longT multiply (T a, T b) { return longT(a) * b; }
}

Example Usage of MyClass:

MyClass<float> my;
printf("result = %lf\n", my.multiply(3.4e38, 3.4e38));
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What about the lonely long int between all those intX_ts? What if std::int32_t is typedefed to long int? –  Christian Rau Mar 8 '13 at 8:37
    
@ChristianRau: good catch. That was left over and has been removed. –  Brent Foust Mar 8 '13 at 20:25

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