Derived template-class access to base-class member-data
You can use this->
to make clear that you are referring to a member of the class:
void Bar<T>::BarFunc () {
std::cout << this->_foo_arg << std::endl;
}
Alternatively you can also use "using
" in the method:
void Bar<T>::BarFunc () {
using Bar<T>::_foo_arg; // Might not work in g++, IIRC
std::cout << _foo_arg << std::endl;
}
This makes it clear to the compiler that the member name depends on the template parameters so that it searches for the definition of that name in the right places. For more information also see this entry in the C++ Faq Lite.
Here the base class is not a nondependent base class( which means one with a complete type that can be determined without knowing the template arguments), and _foo_arg
is a nondependent name. Standard C++ says that nondependent names are not looked up in dependent base classes.
To correct the code, it suffices to make the name _foo_arg
dependent because dependent names can be looked up only at the time of instantiation, and at that time the exact base specialization that must be explored will be known. For example:
// solution#1
std::cout << this->_foo_arg << std::endl;
An alternative consists in introducing a dependency using a qualified name:
// solution#2
std::cout << Foo<T>::_foo_arg << std::endl;
Care must be taken with this solution, because if the unqualified nondependent name is used to form a virtual function call, then the qualification inhibits the virtual call mechanism and the meaning of the program changes.
And you can bring a name from a dependent base class in the derived class once by using
:
// solution#3
template <class T>
class Bar : public Foo<T> {
public:
...
void BarFunc ();
private:
using Foo<T>::_foo_arg;
};
template <class T>
void Bar<T>::BarFunc () {
std::cout << _foo_arg << std::endl; // works
}
Appears to work fine in Visual C++ 2008. I've added some dummy definitions for the types you mentioned but gave no source for. The rest is exactly as you put it. Then a main function to force BarFunc
to be instantiated and called.
#include <iostream>
class streamable {};
std::ostream &operator<<(std::ostream &os, streamable &s) { return os; }
class foo_arg_t : public streamable {};
class a_arg_t : public streamable {};
class b_arg_t : public streamable {};
template <class T>
class Foo {
public:
Foo (const foo_arg_t foo_arg) : _foo_arg(foo_arg)
{
/* do something for foo */
}
T Foo_T; // either a TypeA or a TypeB - TBD
foo_arg_t _foo_arg;
};
template <class T>
class Bar : public Foo<T> {
public:
Bar (const foo_arg_t bar_arg, const a_arg_t a_arg)
: Foo<T>(bar_arg) // base-class initializer
{
Foo<T>::Foo_T = T(a_arg);
}
Bar (const foo_arg_t bar_arg, const b_arg_t b_arg)
: Foo<T>(bar_arg)
{
Foo<T>::Foo_T = T(b_arg);
}
void BarFunc ();
};
template <class T>
void Bar<T>::BarFunc () {
std::cout << _foo_arg << std::endl;
std::cout << Bar<T>::_foo_arg << std::endl;
}
int main()
{
Bar<a_arg_t> *b = new Bar<a_arg_t>(foo_arg_t(), a_arg_t());
b->BarFunc();
}