43

Consider:

template <typename T>
class Base
{
    public:
        static const bool ZEROFILL = true;
        static const bool NO_ZEROFILL = false;
}

template <typename T>
class Derived : public Base<T>
{
    public: 
        Derived( bool initZero = NO_ZEROFILL );    // NO_ZEROFILL is not visible
        ~Derived();
}

I am not able compile this with GCC g++ 3.4.4 (cygwin).

Prior to converting these to class templates, they were non-generic and the derived class was able to see the base class's static members. Is this loss of visibility in a requirement of the C++ spec or is there a syntax change that I need to employ?

I understand that each instantiation of Base<T> will have it's own static member "ZEROFILL" and "NO_ZEROFILL", that Base<float>::ZEROFILL and Base<double>::ZEROFILL are different variables, but i don't really care; the constant is there for readability of the code. I wanted to use a static constant because that is more safe in terms of name conflicts rather than a macro or global.

1
  • Because of the two-phase name lookup (which not all compilers use by default). There are 4 solutions to this problem: 1) Use the prefix Base<T>::NO_ZEROFILL, 2) Use the prefix this->NO_ZEROFILL, 3) Add a statement using Base<T>::NO_ZEROFILL, 4) Use a global compiler switch that enables the permissive mode. The pros & cons of these solutions are described in stackoverflow.com/questions/50321788/… May 14 '18 at 13:33
48

That's two-phase lookup for you.

Base<T>::NO_ZEROFILL (all caps identifiers are boo, except for macros, BTW) is an identifier that depends on T.
Since, when the compiler first parses the template, there's no actual type substituted for T yet, the compiler doesn't "know" what Base<T> is. So it cannot know any identifiers you assume to be defined in it (there might be a specialization for some Ts that the compiler only sees later) and you cannot omit the base class qualification from identifiers defined in the base class.

That's why you have to write Base<T>::NO_ZEROFILL (or this->NO_ZEROFILL). That tells the compiler that NO_ZEROFILL is something in the base class, which depends on T, and that it can only verify it later, when the template is instantiated. It will therefore accept it without trying to verify the code.
That code can only be verified later, when the template is instantiated by supplying an actual parameter for T.

12
  • 1
    aw, you beat me to it by 20 seconds. +1
    – jalf
    Aug 6 '09 at 16:15
  • 1
    @jalf: So for once, I'm the first. :^> Feel free to improve on it.
    – sbi
    Aug 6 '09 at 16:17
  • 2
    Interesting. Do inherited non-static members then require the same qualification? i.e. Base<T>::memberFunction() Aug 6 '09 at 16:25
  • 2
    @ceshirekow: Yes, basically everything behind a ::, where there's something depending on a template parameter before the ::, is "dependent", and this is one of the issues arising from this. (See for an explanation of why the typename is necessary sometimes, if you want to learn more about this. It has the same reason and you'll find good explanations everywhere.)
    – sbi
    Aug 6 '09 at 16:32
  • 1
    @sbi: Are you sure this is called 2-phase lookup? I always thought that term was just for argument dependent lookup. Do you have a reference in the standard for that? Aug 6 '09 at 17:12
29

The problem you have encountered is due to name lookup rules for dependent base classes. 14.6/8 has:

When looking for the declaration of a name used in a template definition, the usual lookup rules (3.4.1, 3.4.2) are used for nondependent names. The lookup of names dependent on the template parameters is postponed until the actual template argument is known (14.6.2).

(This is not really "2-phase lookup" - see below for an explanation of that.)

The point about 14.6/8 is that as far as the compiler is concerned NO_ZEROFILL in your example is an identifier and is not dependent on the template parameter. It is therefore looked up as per the normal rules in 3.4.1 and 3.4.2.

This normal lookup doesn't search inside Base<T> and so NO_ZEROFILL is simply an undeclared identifier. 14.6.2/3 has:

In the definition of a class template or a member of a class template, if a base class of the class template depends on a template-parameter, the base class scope is not examined during unqualified name lookup either at the point of definition of the class template or member or during an instantiation of the class template or member.

When you qualify NO_ZEROFILL with Base<T>:: in essence you are changing it from being a non dependent name to a dependent one and when you do that you delay its lookup until the template is instantiated.

Side note: What is 2-phase lookup:

void bar (int);

template <typename T>
void foo (T const & t) {
  bar (t);
}


namespace NS
{
  struct A {};
  void bar (A const &);
}


int main ()
{
  NS::A a;
  foo (a);
}

The above example is compiled as follows. The compiler parses the function body of foo and see that there is a call to bar which has a dependent argument (ie. one that is dependent on the template parameter). At this point the compiler looks up bar as per 3.4.1 and this is the "phase 1 lookup". The lookup will find the function void bar (int) and that is stored with the dependent call until later.

When the template is then instantiated (as a result of the call from main), the compiler then performs an additional lookup in the scope of the argument, this is the "phase 2 lookup". This case that results in finding void NS::bar(A const &).

The compiler has two overloads for bar and it selects between them, in the above case calling void NS::bar(A const &).

4
  • 4
    +1, nice explanation :) Too bad you seem to have stopped answering on stackoverflow. I loved your elaborative and intensive discussions. Dec 14 '10 at 13:35
  • It's nice to be missed! I hope to get back to answering questions in the near future. Dec 14 '10 at 13:59
  • @RichardCorden I'm not fully understanding your side note to illustrate the "2-phase lookup". As my understanding, the function name bar in the function body of foo is a dependent name, because its parameter is type-dependent. Shouldn't the name lookup of bar in foo also be postponed until the actual template argument is known? Actually, clang++ 3.8.1 doesn't yield any error about the name lookup even if I comment out the line void bar (int);. So I doubt the "phase 1 lookup" for bar is actually performed.
    – Carousel
    Aug 29 '16 at 13:09
  • @Carousel As the name is dependent an error is not expected during phase 1 lookup. Try the following: Add a new template overload above foo(T const &), template <typename T> void bar (T);. Change the overload in namespace NS have the same signature: template <typename T> void bar (T);. Phase 1 lookup finds 2 overloads for bar, and phase 2 finds NS::bar. The compiler is unable to select a best match between the bar(T) functions. Now move the global bar(T) below foo. The code will compile successfully because phase 1 only finds bar(int). Aug 30 '16 at 10:31
1

Seems to compile ok in vs 2008. Have you tried:

public:
    Derived( bool initZero = Base<T>::NO_ZEROFILL );
3
  • 5
    Actually, VC doesn't do two-phase lookup. That's why it compiles there. And that's why it is a bad idea to create a template lib using VC -- you'll have a lot of stuff to fix when you need it on any other compiler.
    – sbi
    Aug 6 '09 at 16:16
  • the fixes are generally fairly trivial though. It's mostly a matter of inserting a lot of typename's, and fixing the occasional 2-phase lookup.
    – jalf
    Aug 6 '09 at 17:13
  • 3
    @jalf: That's true except where it isn't. Among others, I've run into very nasty inter-dependency problems that weren't discovered with VC because VC would only really parse the template when it was instantiated -- and by then all dependent entities were in scope. During the first parse in a proper two-phase lookup, this fell to pieces and it took quite a while and a liberal sprinkling of the programmer's universal cure (indirection) to untangle the mess. The code was a lot harder to understand after that, and it would probably have been designed differently had the problem been known earlier.
    – sbi
    Aug 8 '09 at 11:46
0

Try this program

#include<iostream>
using namespace std;
template <class T> class base{
public:
T x;
base(T a){x=a;}
virtual T get(void){return x;}
};
template <class T>
class derived:public base<T>{
public:
derived(T a):base<T>(a){}
T get(void){return this->x+2;}
};
int main(void){
base<int> ob1(10);
cout<<ob1.get()<<endl;
derived<float> ob(10);
cout<<ob.get();
return 0;
}

in the T get(void){return this->x+2;} line u can also use the scope resolution (::) operator. for example, try replace the line with

T get(void){return base<T>::x+2;}
1
  • 1
    Please properly format your code. Explanation on why code works and where the problem in the original code is, is usually a good thing too.
    – stefan
    Apr 14 '15 at 7:26

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