Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I understand the well-known example of creating a compile-time factorial calculation with templates such that recursive runtime calculations are not necessary. In such an example, all the required values for the calculations are known at compile time.

But I ran across this other example for using templates to calculate the power of a number, and I just don't get how this is an optimization over a similar runtime recursive function:

template<int n>
inline int power(const int& m) { return power<n-1>(m)*m;}

template<>
inline int power<1>(const int& m) { return m;}

template<>
inline int power<0>(const int& m) { return 1;}

cout << power<3>(m)<<endl;

Obviously, m cannot be known at compile time in this example. So at run time, a series of calculations will still be performed that result in essentially the same thing as m*m*m, right?

Is their a clear advantage to a template like this? Perhaps I am just not seeing it.

share|improve this question
    
This is just a syntactic sugar to perform a runtime calculation. Personally I don't see any performance gain. –  iammilind May 25 '13 at 10:14
1  
One possibility is that constant folding allows inline depth reduction to the point you end up with a single constant and a simple assignment –  Captain Obvlious May 25 '13 at 10:18

2 Answers 2

up vote 3 down vote accepted

You can get the advantage of template metaprogramming only if you know the X and Y both at compile time. The example code:

template<unsigned int X, unsigned int N>
struct Power { static const unsigned int value = X * Power<X,N-1>::value; };

template<unsigned int X>
struct Power<X,0> { static const unsigned int value = 1; };

Usage: Power<X,Y>::value to determine the X^Y.
Demo.

In your posted code (which happens to use templates but not meta-programming!), only the Y is known at compile time and X is passed as runtime parameter. Which means the result also will be calculated at runtime and we have to rely on compiler based optimizations. Better to use std::pow(..) in such cases.

share|improve this answer
    
Fascinating! I assume the term "metaprogramming" only applies to situations when you are completely avoiding runtime cost for a particular task? hence why this term does not apply to my example but does apply to your example? –  OpenLearner May 25 '13 at 11:49
    
@Fellowshee, yes in the context of template metaprogramming (TMP) you shouldn't have runtime cost. In your example you are relying on the parameter m, which is passed at runtime. In my example we are having a compile time constant value. A good test is to use the answer of any code calculation as template argument e.g. template<int N> struct X {};; if the code X< {your calculation} > x; compiles fine than you have used TMP, otherwise not. For example, with my code X<Power<5,4>::value> x; compiles fine. –  iammilind May 25 '13 at 13:01

The difference is that this code must be instantiated at compile time, probably giving the optimiser better chance to notice that it's just a long sequence of multiplications.

It's really mainly guesswork about the optimiser implementation. It might be better at inlining different template instantiations (because that's how templates are often used) than at inlining recursion (where it needs to discover the stop condition statically) or unrolling loops.

share|improve this answer
    
Thanks; compared to the factorial example that probably everyone knows, that factorial is indeed calculated entirely a compile time such that no runtime calculation of the factorial is necessary, in which case there is a much more obvious benefit to the template, is that plausible? –  OpenLearner May 25 '13 at 10:20
    
@Fellowshee The factorial can also only be computed at compile time if it's factorial of a compile-time value. Just as you could modify this function template to compute power of compile-time values only. –  Angew May 25 '13 at 10:26

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

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