A common compiler optimization is to transform tail-recursive functions into loops, speeding up the execution time and reducing memory (stack) consumption:

int go_to_zero( int n )
    if( n == 0 )
        return 0;
        return go_to_zero( n - 1 );

My question is simple: Is there any performance benefit (i.e. reducing compile time) doing tail-recursive algorithms on template meta-programming?

Here an example:

template<typename... Ts>
struct list {};

template<typename LIST>
struct reverse;

template<typename HEAD , typename... TAIL>
struct reverse<list<HEAD,TAIL...>>
    using result = concat<typename reverse<list<TAIL...>>::result,list<HEAD>>;

struct reverse<list<>>
    using result = list<>;


template<typename INPUT , typename OUTPUT>
struct reverse_impl;

template<typename HEAD , typename... TAIL , tyename... Ts>
struct reverse_impl<list<HEAD,TAIL...>,list<Ts...>>
    using result = typename reverse_impl<list<TAIL...>,list<Ts...,HEAD>>::result;

template<typename... Ts>
struct reverse_impl<list<>,list<Ts...>>
    using result = list<Ts...>;

template<typename LIST>
using reverse = typename reverse_impl<LIST,list<>>::result;
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    what do you mean by performance benefits ? tail recursion and template meta programming don't fall into the same category. Templates are evaluated at compiletime while the function is optimized for runtime.
    – Raxvan
    Mar 17, 2014 at 9:23
  • 2
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    @Raxvan the question is pretty clear: I'm asking for any performance benefit when writting metafunctions in a tail-recursion way instead of other forms of recursion. By performance benefits I mean compilation time reduction and (possibly?) compiler RAM usage reduction. Finally note that tail-recursion and template metaprogramming are very related concepts, because tmp is just a form of functional programming inside C++.
    – Manu343726
    Mar 17, 2014 at 9:32
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    @Raxvan you should read a question properly before judging it! The structure of my question is: 1. (Human friendly) introduction to tail recursion, and its well known performance benefits. 2. tmp related question: Possible benefit of tail-recursion on tmp (Time and compiler resources)
    – Manu343726
    Mar 17, 2014 at 9:35
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    Nice question! I've always used the 1st version, because I never thought of the 2nd one! Just by looking at them, I bet the 2nd is more efficient, simply because it avoids concat so it should require roughly half template instantiations compared to the 1st. But because compiler implementations may be immensely different (e.g. I expect clang to be much faster than gcc on such tasks), I would say that, as always, theoretical discussions on performance without measurements are pointless. Complexity is linear in both cases but this doesn't say much.
    – iavr
    Mar 17, 2014 at 10:07

2 Answers 2


In C++ Template Metaprogramming Appendix C "Compile Time Performance" Abraham and Gurtovoy messured how memoization of template instantiation effects compile time. The book was written in 2005 and I think memoization is better implemented today (I didn't measure). So the question to answer is which implementation can benefit more from memoization. I have edited the code a little bit Version 1 and Version 2. Now it will emit an error when reverse_impl is instantiated, so we can simply count the errors. I reverse 2 lists list<int, short, char> and list<short, char>. Version 1 emits 4 errors and Version 2 emits 7 errors. In this particular case Version 1 benefits from memoization with these two lists (list2 is the tail of list1) and Version 2 doesn't. So I would expect Version 1 is faster.

So it would be best to implement algorithms in terms of other algorithms which are known to benefit from memoization and I think most of them use head recursion.


All the pros and cons of regular vs. tail recursion apply also to the metaprogramming. The difference in this case is that instead of the execution of a compiled program on a target machine, the program is executed in a compiler sand-box and compiles to the target language instead of to the machine language. This process is conceptually not much different from compiling a Java program into a bytecode.

C++ compilers have rather limited allowed depth of template nesting (~hundreds) and if the algorithm grows exponentially, it can be a blocker to usage of regular recursion; tail recursion might help here.

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