show/hide this revision's text 2 Typo

Follow-up to my previous posting.

Templates are one of the main reasons why C++ fails so abysmally at intellisense, regardless of the IDE used. Because of template specialization, the IDE can never be really sure if a given member exists or not. Consider:

template <typename T>
struct X {
    void foo() { }
};

template <>
struct X<int> { };

typedef int my_int_type;

X<my_int_type> a;
a.|

Not

Now, the cursor is at the indicated position and it's damn hard for the IDE to say at that point if, and what, members a has. For other languages the parsing would be straightforward but for C++, quite a bit of evaluation is needed beforehand.

It gets worse. What if my_int_type were defined inside a class template as well? Now its type would depend on another type argument. And here, even compilers fail.

template <typename T>
struct Y {
    typedef T my_type;
};

X<Y<int>::my_type> b;

After a bit of thinking, a programmer would conclude that this code is the same as the above: Y<int>::my_type resolves to int, therefore b should be the same type as a, right?

Wrong. At the point where the compiler tries to resolve this statement, it doesn't actually know Y<int>::my_type yet! Therefore, it doesn't know that this is a type. It could be something else, e.g. a member function or a field. This might give rise to ambiguities (though not in the present case), therefore the compiler fails. We have to tell it explicitly that we refer to a type name:

X<typename Y<int>::my_type> b;

Now, the code compiles. To see how ambiguities arise from this situation, consider the following code:

Y<int>::my_type(123);

This code statement is perfectly valid and tells C++ to execute the function call to Y<int>::my_type. However, if my_type is not a function but rather a type, this statement would still be valid and perform a special cast (the function-style cast) which is often a constructor invocation. The compiler can't tell which we mean so we have to disambiguate here.
show/hide this revision's text 1

Follow-up to my previous posting.

Templates are one of the main reasons why C++ fails so abysmally at intellisense, regardless of the IDE used. Because of template specialization, the IDE can never be really sure if a given member exists or not. Consider:

template <typename T>
struct X {
    void foo() { }
};

template <>
struct X<int> { };

typedef int my_int_type;

X<my_int_type> a;
a.|

Not, the cursor is at the indicated position and it's damn hard for the IDE to say at that point if, and what, members a has. For other languages the parsing would be straightforward but for C++, quite a bit of evaluation is needed beforehand.

It gets worse. What if my_int_type were defined inside a class template as well? Now its type would depend on another type argument. And here, even compilers fail.

template <typename T>
struct Y {
    typedef T my_type;
};

X<Y<int>::my_type> b;

After a bit of thinking, a programmer would conclude that this code is the same as the above: Y<int>::my_type resolves to int, therefore b should be the same type as a, right?

Wrong. At the point where the compiler tries to resolve this statement, it doesn't actually know Y<int>::my_type yet! Therefore, it doesn't know that this is a type. It could be something else, e.g. a member function or a field. This might give rise to ambiguities (though not in the present case), therefore the compiler fails. We have to tell it explicitly that we refer to a type name:

X<typename Y<int>::my_type> b;

Now, the code compiles. To see how ambiguities arise from this situation, consider the following code:

Y<int>::my_type(123);

This code statement is perfectly valid and tells C++ to execute the function call to Y<int>::my_type. However, if my_type is not a function but rather a type, this statement would still be valid and perform a special cast (the function-style cast) which is often a constructor invocation. The compiler can't tell which we mean so we have to disambiguate here.