Can somebody explain to me, why the first template meta-programming way is going to infinite loop, but the second one runs correctly.

#include <iostream>
using namespace std;

template<int N, int M>
struct commondivs {                                              
  static const int val = (N<M) ? commondivs<N,(M-N)>::val : commondivs<(N-M),M>::val;

template<int N>
struct commondivs<N,N> {
  static const int val = N;

int commondiv(int N, int M){
        return N;
    return (N<M)?commondiv(N,(M-N)):commondiv((N-M),M);     

int main() {

    cout << commondivs<9,6>::val << endl;
    cout << commondiv(9,6) << endl;
    return 0;
  • 3
    Possible duplicate of Replacement for ternary operator in template metaprogramming – L. F. Nov 25 at 15:11
  • 2
    The goal was to used template meta programming. constexpr is not an option. – Exxul Nov 25 at 15:26
  • Added c++98 tag to make explicit that constexpr is not an option. (It was introduced in C++11). That does invalidate existing answers. Exxul, please clarify which C++ version you're limited to. – MSalters Nov 26 at 16:55
  • Sorry I removed the tag. – Exxul Nov 27 at 19:32
(N<M) ? commondivs<N,(M-N)>::val : commondivs<(N-M),M>::val

This line causes instantiation of both commondivs<N,(M-N)>::val and commondivs<(N-M),M>::val, even if the condition is known at compile time and one of the branches will never be taken.

Replace ? : with std::conditional_t, which doesn't have this limitation:

static const int val = std::conditional_t<N < M, commondivs<N,(M-N)>, commondivs<(N-M),M>>::val;

The problem is all the operands of conditional operator will be evaluated, so both commondivs<N,(M-N)> and commondivs<(N-M),M> get instantiated and their val get evaluated and then leads to recursive template instantiation.

You can apply constexpr if and put it in a constexpr static member function.

If the value is true, then statement-false is discarded (if present), otherwise, statement-true is discarded.

template<int N, int M>
struct commondivs {                                              
  constexpr static int get_val() {
    if constexpr (N<M) return commondivs<N,(M-N)>::val; // if true, the else part won't be evaluated
    else return commondivs<(N-M),M>::val;               // vice versa
  static const int val = get_val();


  • Evaluated or just instantiated? – Daniel McLaury Nov 26 at 13:49
  • @DanielMcLaury Evaluated; not just instantiated. – songyuanyao Nov 26 at 13:59
  • The value of ::val has to be generated on both branches sure, but this is still instantiation (of a template with a static const member). Evaluation at run time does not happen ... well, it obviously can't since it never compiles ... – Useless Nov 26 at 17:00

The ternary operator is not like if constexpr: when a compiler sees it, it has to generate code for both branches. In other words, to instantiate a template commondivs<M, N>, a compiler instantiates both templates commondivs<N, M - N> and commondivs<N - M, M>.

In contrast to that, commondiv(N, M - N) and commondiv(N - M, M) are translated into two function calls. Which one is taken, will be decided when the function is actually called.


HolyBlackCat gave a solution with std::conditional_t. Here is another one:

template<int N, int M>
struct commondivs {                                              
    static constexpr int min = (N < M) ? N : M;
    static constexpr int max = (N < M) ? M : N;
    static constexpr int val = commondivs<min, max - min>::val;

template<int N>
struct commondivs<N, N> {
    static constexpr int val = N;

You get infinite recursion because:

static const int val = (N<M) ? commondivs<N,(M-N)>::val : commondivs<(N-M),M>::val;

isn't metatemplate programming at all because ?:, as @Eng says, isn't constexpr.

You want to look at @HolyBlackCat's answer.

  • 1
    It won't help. ?: is not constexpr. – Evg Nov 25 at 15:21
  • No I try it. The same infinite loop. – Exxul Nov 25 at 15:23

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