Template factorial function without template specialization

I don't understand the following behavior.

The following code, aimed at computing the factorial at compile time, doesn't even compile:

#include <iostream>
using namespace std;
template<int N>
int f() {
if (N == 1) return 1; // we exit the recursion at 1 instead of 0
return N*f<N-1>();
}
int main() {
cout << f<5>() << endl;
return 0;
}

and throws the following error:

...\$ g++ factorial.cpp && ./a.out
factorial.cpp: In instantiation of ‘int f() [with int N = -894]’:
factorial.cpp:7:18:   recursively required from ‘int f() [with int N = 4]’
factorial.cpp:7:18:   required from ‘int f() [with int N = 5]’
factorial.cpp:15:16:   required from here
factorial.cpp:7:18: fatal error: template instantiation depth exceeds maximum of 900 (use ‘-ftemplate-depth=’ to increase the maximum)
7 |   return N*f<N-1>();
|            ~~~~~~^~
compilation terminated.

whereas, upon adding the specialization for N == 0 (which the template above doesn't even reach),

template<>
int f<0>() {
cout << "Hello, I'm the specialization.\n";
return 1;
}

the code compiles and give the correct output of, even if the specialization is never used:

...\$ g++ factorial.cpp && ./a.out
120
• If it can potentially be called, it needs to exist. – Jesper Juhl Aug 28 at 18:30
• In this case constexpr int f(int N); (Or consteval in c++20) would also work. – Artyer Aug 28 at 18:33
• Sidenote: What would be the result of f<-1>()? As it is meaningless, I'd prefer unsigned int as template parameter. We wouldn't prevent anybody from writing f<-1> (would be converted to huge integer anyway), but at least we'd express right from the start that we actually expect non-negative values only... – Aconcagua Aug 28 at 19:10
• You've gotten an excellent answer that I cannot usefully add to. I just want to state that this is one of the reasons constexpr was created. – Omnifarious Aug 28 at 19:24
• To be mathematically complete: Factorial of 0 is defined as 1, so you should have if constexpr(N == 0) return 1; else ... – Aconcagua Aug 31 at 7:16

The issue here is that your if statement is a run time construct. When you have

int f() {
if (N == 1) return 1; // we exit the recursion at 1 instead of 0
return N*f<N-1>();
}

the f<N-1> is instantiated as it may be called. Even though the if condition will stop it from calling f<0>, the compiler still has to instantiate it since it is part of the function. That means it instantiates f<4>, which instantiates f<3>, which instantiates f<2>, and on and on it will go forever.

The Pre C++17 way to stop this is to use a specialization for 0 which breaks that chain. Starting in C++17 with constexpr if, this is no longer needed. Using

int f() {
if constexpr (N == 1) return 1; // we exit the recursion at 1 instead of 0
else return N*f<N-1>();
}

guarantees that return N*f<N-1>(); won't even exist in the 1 case, so you don't keep going down the instantiation rabbit hole.

The problem is that f<N>() always instantiates f<N-1>() whether that if branch is taken or not. Unless properly terminated, that would create infinite recursion at compile time (i.e. it would attempt instantiating F<0>, then f<-1>, then f<-2> and so on). Obviously you should terminate that recursion somehow.

Apart from constexpr solution and specialization suggested by NathanOliver, you may terminate the recursion explicitly:

template <int N>
inline int f()
{
if (N <= 1)
return 1;
return N * f<(N <= 1) ? N : N - 1>();
}

Mind, this solution is rather poor (the same terminal condition must be repeated twice), I'm writing this answer merely to show that there are always more ways to solve the problem :- )