While playing with variadic templates, classes, functions and lambdas, (from here) I found that following code is running with clang++ while not running with g++ :

#include <iostream>
#include <string>
using namespace std;
template <class... F>
struct overload_set : F... 
  overload_set(F... f) : F(f)... {}  
template <class... F>
auto overload(F... f) 
  return overload_set<F...>(f...);   
int main()
    auto func = overload (
        [](int &val) { val *= 2; }, 
        [](string &arg) { arg += arg; }, 
        [](char &c) { c = 'x'; }
    int val = 10;
    string str = "stackoverflow";
    char ch = 's';
    cout << val << " : " << str << " : " << ch << endl;
    cout << val << " : " << str << " : " << ch << endl;
    return 0;

For clang : coliru

For g++ : coliru

g++ is giving ambiguous operator() for func(val), func(str) and func(c). I think the operator() must not be ambiguous, as each one is having different arguments.

What's the problem with g++?

  • 1
    @Niall: it's not really about the lambdas or even variadic templates; even given the simplest struct deriving from bases B1, B2... with different operator()(X&) functions, g++ needs using B1::operator(); using B2::operator(); (see here). – Tony Delroy Oct 28 '15 at 6:40
  • 1
    @TonyD. I'm thinking it is a clang bug - some test indicates there is a difference here in how clang resolves functions from the base classes vs how it resolves the call operator. – Niall Oct 28 '15 at 7:49
  • @Niall gotcha, clang resolves x() differently from x.operator()(). – n. 'pronouns' m. Oct 28 '15 at 8:42
  • This issue was already addressed here – Nikos Athanasiou Oct 28 '15 at 9:44

This has little to do with lambdas, variadic templates, operators or any advanced C++1{xy} stuff. Let's simplify:

struct foo
    void func(int&){}
struct bar
    void func(char&){}

struct test : foo, bar {};

int main()
    test t;
    int i = 1;
    char c = 'a';

This fails to compile in either g++ or clang++. Which is a good thing too, because that's how the language is specified to work.

If we change func to operator(), g++ continues to reject the program but clang++ either accepts or rejects it, depending on how the operator is called:

 t.operator()(c); // rejected
 t(c);            // accepted

Which looks like a clang bug to me.

In order to make the code above compile, a very small change is needed:

struct test : foo, bar {
  using foo::func;
  using bar::func;

Now I have no idea how to make pack expansion work in the using directive, or if it's indeed possible. But there's a workaround:

template <class... F> struct overload_set;

template <> struct overload_set<> {};

template <class F> struct overload_set<F> : F {
  using F::operator();
  overload_set(F f) : F(f) {}

template <class F, class... Fs>
struct overload_set<F, Fs...> : F, overload_set<Fs...>
  overload_set(F f, Fs... fs) : F(f), overload_set<Fs...>(fs...) {}
  using F::operator();
  using overload_set<Fs...>::operator();

With this change your code compiles with both g++ and clang++.

| improve this answer | |
  • 2
    There is a link from the OP's linked blog post that is pretty much this workaround. The blog mentions it as a "industrial-strength version", link here – Niall Oct 28 '15 at 7:47
  • @Niall The industrial version is the one I've seen Yakk among others use (there are variations on the base template, the number of specializations and the use of perfect forwarding) – Nikos Athanasiou Oct 28 '15 at 10:03

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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