I agree that they were most probably looking for variadic templates, but for the sake of it, different approaches that can be taken in C++03:
Using a variant type
Use a container of a variant type. In this case boost::variant
will not work, as it limits the number of types, but you can use boost::any
:
void foo( std::vector< boost::any > args );
Compared to variadic templates, user code will be much more cumbersome, as instead of writting foo( a, b, c, d )
, they will have to manually create the vector upfront. The syntax could be simplified by means of variadic macros (if the compiler supports them) and or helper templated functions to adapt the syntax, but this can quite easily become a mess.
The C way (non-template):
Use the ellipsis notation to write a function that takes an unknown number of arguments (and types):
void foo( type x, ... )
This approach has many shortcommings. The first one is that it is not typesafe, the compiler will not be able to detect that the arguments are the correct number or types, and it is undefined behavior if any of the arguments is a non-POD type, which limits usability from any type to POD types, which might or not be a limiting factor (you can always pass in a pointer to your non-POD object). Overall this is more complex to handle, and much more error prone so it should be avoided.
Not answering the question at all
In very few situations a single function should be able to take an unknown number of arguments of unknown types. Logging and i/o can require this, printf
being such example. But that can be handled in C++ by means of operator overloading (in particular operator<<
) and chaining. In a comment bind
has been suggested, so yes, perfect forwarding in generic code is one such case, bind
, std::thread
...
It think this to be a good answer for an interview, as you can then discuss what the actual need for the function is, and whether there is any better alternative. It can be argued that if at the end you do need a container of a variant type, you can abuse operator overloading to simplify the syntax. Examples of this would be the boost::assign
library, and in those lines you can create a helper argument builder as in:
class args {
public:
args() {}
operator std::vector<boost::any>&() {
return v;
}
template <typename T>
args& operator,( T x ) {
boost::any a = x;
v.push_back( a );
return *this;
}
private:
std::vector<boost::any> v;
};
// usage:
void foo( std::vector<boost::any> a ) {
std::cout << "Received " << a.size() << " arguments" << std::endl;
}
int main() {
foo(( args(), 1, 5.0, "a string", std::vector<int>(5,10) ));
}
Variadic templates
And of course, the best option that is a c++0x compiler that handles variadic templates, that requires no extra boiler plate code, and will make it much simpler to write both user code (directly as a regular function call) and the implementation of the function, whatever it is. As a motivating example, building a vector<boost::any>
with variadic args:
typedef std::vector<boost::any> anyvector_t
// Stop condition, adding nothing at the end
void build_vector_impl( anyvector_t& ) {}
// Intermediate step, add a new argument to the vector and recurse:
template <typename Head, typename... Tail>
void build_vector_impl( anyvector_t& v, Head head, Tail... tail ) {
v.push_back( boost::any(head) );
build_vector_impl( v, tail... );
}
// Syntactic sugar: make it return the vector:
template <typename... Args>
anyvector_t build_vector( Args... args ) {
anyvector_t res;
build_vector_impl( res, args... );
return res;
}
// Test:
int main() {
std::cout << "Number of args: "
<< build_vector( 1, 5, "Hi", std::vector<int>( 5, 10 ) ).size()
<< std::endl;
}