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Consider the following variadic function

template <typename Type, typename... Types>
bool f(Type& arg, Types&... args)
    return f(arg) && f(args...);

template <typename Type>
bool f(Type& arg)
    // Do something

If one level of recursion is false, then I suspect that the following will not be executed. Is there a trick to force the recursion on all arguments even if one of them returns false ?

share|improve this question
How about replacing && with &? – fredoverflow Mar 23 '13 at 18:27
up vote 21 down vote accepted

This shouldn't be too hard:

template <typename Type, typename... Types>
bool f(Type& arg, Types&... args)
    bool b1 = f(arg);
    bool b2 = f(args...);
    return b1 && b2;
share|improve this answer
I think just get rid of the second calls to f. – Joseph Mansfield Mar 23 '13 at 15:03
@sftrabbit: Leftover :) Thank you – Andy Prowl Mar 23 '13 at 15:03
See my answer for the benchmark. – Vincent Mar 23 '13 at 18:19

As the debate has evolved in a comparison of the AndyProwl and Alon solution, I've benchmarked the both solution, and the result ... depends of the number of arguments.

Compiling with:

g++-4.7 -std=c++11 -Wall -Wextra -O3 main.cpp -o main -D_FIRST

benchmarks the AndyProwl solution and compiling with :

g++-4.7 -std=c++11 -Wall -Wextra -O3 main.cpp -o main -D_SECOND

benchmarks the Alon solution.

Here is the program of the benchmark for 10 arguments.

#include <iostream>
#include <chrono>

// Function 1 : with &&
template <typename Type>
inline bool f1(const Type& arg)
   return arg;
template <typename Type, typename... Types>
inline bool f1(const Type& arg, const Types&... args)
    bool arg1 = f1(arg);
    bool arg2 = f1(args...);
    return arg1 && arg2;

// Function 2 : with &
template <typename Type>
inline bool f2(const Type& arg)
   return arg;
template <typename Type, typename... Types>
inline bool f2(const Type& arg, const Types&... args)
    return f2(arg) & f2(args...);

// Benchmark
int main(int argc, char* argv[])
    // Variables
    static const unsigned long long int primes[10] = {11, 13, 17, 19, 23, 29, 31, 37, 41, 43};
    static const unsigned long long int nbenchs = 50;
    static const unsigned long long int ntests = 10000000;
    unsigned long long int sum = 0;
    double result = 0;
    double mean = 0;
    std::chrono::high_resolution_clock::time_point t0 = std::chrono::high_resolution_clock::now();

    // Loop of benchmarks
    for (unsigned long long int ibench = 0; ibench < nbenchs; ++ibench) {

        // Initialization
        t0 = std::chrono::high_resolution_clock::now();
        sum = 0;

        // Loop of tests
        for (unsigned long long int itest = 1; itest <= ntests; ++itest) {
#ifdef _FIRST
            sum += f1((itest+sum)%primes[0], (itest+sum)%primes[1], (itest+sum)%primes[2], (itest+sum)%primes[3], (itest+sum)%primes[4], (itest+sum)%primes[5], (itest+sum)%primes[6], (itest+sum)%primes[7], (itest+sum)%primes[8], (itest+sum)%primes[9]);
#ifdef _SECOND
            sum += f2((itest+sum)%primes[0], (itest+sum)%primes[1], (itest+sum)%primes[2], (itest+sum)%primes[3], (itest+sum)%primes[4], (itest+sum)%primes[5], (itest+sum)%primes[6], (itest+sum)%primes[7], (itest+sum)%primes[8], (itest+sum)%primes[9]);

        // Finalization
        result = std::chrono::duration_cast<std::chrono::duration<double>>(std::chrono::high_resolution_clock::now()-t0).count();
        mean += result;
        std::cout<<"time = "<<result<<" (sum = "<<sum<<")"<<std::endl;

    // End
    std::cout<<"mean time = "<<mean/nbenchs<<std::endl;
    return 0;

With 50 benchmarks for each solution with a given number of arguments, the dispersion is very small, and the mean time over these benchmarks is a reliable indicator.

My first benchmark has been with the "right" number of arguments where the Alon solution is faster than the AndyProwl solution.

The final results are here :


So the AndyProwl solution is generally faster than the Alon one. So, now I can validate your answer. But I think that the difference is so small that it's architecture/compiler dependent.


  • AndyProwl+1 for your generally faster solution
  • Alon+1 for your constexpr-ready solution
share|improve this answer
Nice graph, thank you for sharing the information. +1 – Andy Prowl Mar 23 '13 at 18:23
All graphs need error bars – Inverse Mar 28 '13 at 20:38
As I have posted the code, you can run it several times and compute the dispersion. – Vincent Mar 29 '13 at 11:54

You can execute them separately and return a bool expression:

bool b0 = f(arg);
bool b1 = f(args);
return b0 && b1;
share|improve this answer

Without recursion:

template <typename... Types>
bool f(Types&&... args)
  bool r=true;
  (void)std::initializer_list<bool>{(r = f(args)&&r)...};
  return r;
share|improve this answer

There is a much nicer trick, instead of using && between all the functions, just use one &

static_cast<bool>(f(arg)) & static_cast<bool>(f2(args)) ... will run all operations regardless of the result :)

share|improve this answer
This can be fixed with static_cast<bool>. I like this approach since it's more compact than the ones with helper variables. – ipc Mar 23 '13 at 15:11
@Alon: In most cases? Which only means it would be a much more dangerous bug. But OK, you "fixed" it, so I'm taking the -1 back. But it's not "nice" anymore (IMHO). – Daniel Frey Mar 23 '13 at 15:22
I wouldn't call this a "much nicer trick". It just makes the code harder to read, debug, and maintain. @Vincent: Why wouldn't you just use temporary variables? There's no performance penalty, if that's what you're concerned with, and it makes your intent clear. This one doesn't. People who are used to read C++ actually expect to see the short-circuiting when reading a piece of code like this one, because this is the usual behavior and because & is not usual for the logical conjunction. You don't have to accept my answer, just please don't learn from this. – Andy Prowl Mar 23 '13 at 15:40
@Vincent: Doing it this way won't bring you one femtosecond of performance gain, any compiler will just optimize the temporary variables away. And if the compiler is really dumb, then I see it likelier that it will introduce a performance penalty for this version, because of the conversions to bool and the bitwise &. – Andy Prowl Mar 23 '13 at 16:00
@AndyProwl: I will have to check the assembly, but I've just done 4 series of 50 benchmarks on your solution and this one (without the static_cast, as f returns a boolean), and this one is 7.5% faster than yours (g++ 4.7.2 with -O3). – Vincent Mar 23 '13 at 16:22

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