Encontré esto en Internet:
#include <utility>
#include <type_traits>
namespace details {
template< typename F, typename Tuple, bool Done, int Total, int... N > struct call_impl {
static void call( F f, Tuple && t ) {
call_impl< F, Tuple, Total == 1 + sizeof...( N ), Total, N..., sizeof...( N ) >::call( f, std::forward< Tuple >( t ) );
}
};
template< typename F, typename Tuple, int Total, int... N > struct call_impl< F, Tuple, true, Total, N... > {
static void call( F f, Tuple && t ) {
f( std::get< N >( std::forward< Tuple >( t ) )... );
}
};
} // namespace details.
template< typename F, typename Tuple > void call( F f, Tuple &&t ) {
//typedef typename std::decay< Tuple >::type ttype;
using ttype = typename std::decay< Tuple >::type;
details::call_impl< F, Tuple, 0 == std::tuple_size< ttype >::value, std::tuple_size< ttype >::value >::call( f, std::forward< Tuple >( t ) );
}
Sirve para desempaquetar una std::tuple
sobre los argumentos de una llamada a función.
La idea es posponer una llamada a función hasta que sea necesario, almacenando los argumentos pasados en una std::tuple
y pudiendo recuperarlos en un momento posterior.
Desafortunadamente, la template
solo trabaja con funciones void
. La estoy intentando adaptar para poder usarla en funciones con cualquier tipo de retorno, pero no lo estoy consiguiendo:
error: no matching function for call to 'call(int (&)(int), std::tuple<int>&)'
...
error: invalid use of incomplete type 'class std::result_of<int (*)(int)>'
#include <tuple>
#include <functional>
#include <type_traits>
#include <iostream>
namespace details {
template< typename RET, typename F, typename Tuple, bool Done, int Total, int... N > struct call_impl {
static RET call( F f, Tuple && t ) {
return call_impl< RET, F, Tuple, Total == 1 + sizeof...( N ), Total, N..., sizeof...( N ) >::call( f, std::forward< Tuple >( t ) );
}
};
template< typename RET, typename F, typename Tuple, int Total, int... N > struct call_impl< RET, F, Tuple, true, Total, N... > {
static RET call( F f, Tuple && t ) {
return f( std::get< N >( std::forward< Tuple >( t ) )... );
}
};
} // namespace details.
template< typename F, typename Tuple, typename RET = typename std::result_of< F >::type > RET call( F f, Tuple &&t ) {
//typedef typename std::decay< Tuple >::type ttype;
using ttype = typename std::decay< Tuple >::type;
return details::call_impl< RET, F, Tuple, 0 == std::tuple_size< ttype >::value, std::tuple_size< ttype >::value >::call( f, std::forward< Tuple >( t ) );
}
int dummy( int );
int main( ) {
auto tp = std::make_tuple( 10 );
auto ret = call( dummy, tp );
std::cout << "Retorno: " << ret << std::endl;
return 0;
}
int dummy( int v ) {
std::cout << "dummy( " << v << " )\n";
return v + 1;
}
Nota: compilado con g++ -Wall -Wextra -std=c++11 -pedantic