So, here is a quick trick to make this work, without manually constructing objects. Instead, I created a Deferred<T>
template that represents an object in automatic storage whose construction is deferred (and possibly never occurs).
The buff
in Deferred
should be replaced with a union
, because that will handle alignment issues (assuming you have C++11 features to support that). Asserts that constructed
is true when you call get()
is probably a good idea.
Once you have constructed your object, you can implicitly cast your Deferred<T>
to a T&
, then use that T&
as an alias to the deferred-constructed T
.
In theory, you could do away with the constructed
bool
if you could prove that it would always be constructed, but I'd advise against it. Other than that, this should be nearly as efficient as you can pull it off. And with the C++11 union
case, it might even be standards compliant.
Oh yes, and it should be enhanced with perfect forwarding.
#include <utility>
// does not handle alignment issues:
template<typename T>
struct Deferred {
Deferred():constructed(false) {}
operator T&() { return get(); }
T& get() { return *reinterpret_cast<T*>(&buff[0]); }
template<typename... Args>
T& construct( Args... args ) {
new(&buff[0]) T(args...);
constructed = true;
return get();
}
~Deferred() {
if (constructed) {
get().~T();
}
}
private:
bool constructed;
char buff[sizeof(T)];
};
#include <iostream>
struct Object {
bool is_int;
Object( int x ):is_int(true) {}
Object( double d ):is_int(false) {}
~Object() {
std::cout << "~Object("<<is_int<<") destroyed\n";
}
};
enum which_test {
as_int,
as_double,
do_not,
};
void test(which_test v) {
std::cout << v << "\n";
Deferred<Object> o;
if(v==as_int) {
o.construct( 7 );
} else if (v==as_double) {
o.construct( 7.0 );
} else {
}
}
int main() {
test(as_int);
test(as_double);
test(do_not);
}