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Does somebody know, why this compiles??

template< typename TBufferTypeFront, typename TBufferTypeBack = TBufferTypeFront>
class FrontBackBuffer{

public:


  FrontBackBuffer(
    const TBufferTypeFront  front, 
    const TBufferTypeBack back):    ////const reference  assigned to reference???
     m_Front(front),
     m_Back(back)
  {
  };

  ~FrontBackBuffer()
  {};

  TBufferTypeFront m_Front;       ///< The front buffer
  TBufferTypeBack m_Back;         ///< The back buffer

};

int main(){
    int b;
    int a;
    FrontBackBuffer<int&,int&> buffer(a,b); //
    buffer.m_Back = 33;
    buffer.m_Front = 55;
}

I compile with GCC 4.4. Why does it even let me compile this? Shouldn't there be an error that I cannot assign a const reference to a non-const reference?

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Top level const-volatile qualifiers are ignored in function signatures. –  David Rodríguez - dribeas Nov 7 '12 at 16:17
    
AFAIK const reference does not exists. You can only have reference to const object (const int& is valid, int& const does not exists). However this does not resolve your issue here... –  PiotrNycz Nov 7 '12 at 16:21
    
Why are the names of the parameters to the constructor prefixed with m? Doesn't that stand for member? And isn't its purpose to disambiguate member objects from function local and global objects? –  Benjamin Lindley Nov 7 '12 at 16:32
    
m_ stands for member yes, and yes its an error :-) –  Gabriel Nov 7 '12 at 16:58

4 Answers 4

up vote 2 down vote accepted

For the code to do what you want it to do, it would have to read:

  FrontBackBuffer(
    typename std::remove_reference<TBufferTypeFront>::type const&  m_front, 
    typename std::remove_reference<TBufferTypeBack>::type const& m_back):    ////const reference  assigned to reference???
    m_Front(m_front),
    m_Back(m_back)
  {
  };

which has the added "feature" that it turns other types into const references when used to construct FrontBackBuffer.

Now this isn't perfect. This prevents temporary arguments to FrontBackBuffer from being moved, and passes even small cheap to copy types (like char) by reference instead of by value. There are standard C++0x techniques to do this that are a bit awkward to write if you care.

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Would be very interested how that is possible? Thanks for the help!! Was very helpful! –  Gabriel Nov 7 '12 at 17:34
    
The technique is called "perfect forwarding". There is a stack overflow tag for it. I'd advise reading up on it a bunch before trying it: odds are you don't need to know how to do it yet. Here is a question I answered where someone demonstrates a use of perfect forwarding: stackoverflow.com/questions/13160826/… -- read these for more information: stackoverflow.com/questions/tagged/perfect-forwarding –  Yakk Nov 7 '12 at 18:56

When TypeBufferFront is int&, const TBufferTypeFront is equivalent to int& const, where the const is ignored during template substitution, since all references are constant, even if what they refer to is not.

So, when instantiated with int&, your constructor is effectively FrontBackBuffer(int&, int&), which works as given.

This is an example of why many people will use T const instead of const T, to make it clearer how the substitution occurs, as well as allow them to read the cv-qualifiers from right to left.

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So can I understand this as : const int & const -> and the const gets ingnored? –  Gabriel Nov 7 '12 at 17:04
    
@Gabriel: No, the point is that if it were legal, a const int& const is the same as a int const& const a constant reference to a constant integer. During template substitution, int const& const (which is not legal) is reduced to int const& (which is legal). –  Dave S Nov 7 '12 at 17:54

FrontBackBuffer::m_Front is of type TBufferTypeFront which translates to int& in your template instantiation. There is nothing wrong with assigning to an int&.

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There is something wrong with binding an int& to an const int&. Gabriel thinks that the parameters to the constructor are of type const int&, and that's why the question. –  Benjamin Lindley Nov 7 '12 at 16:15

The thing is that if type T is int&, then the type const T is not const int&, but int & const. The illegal top-level const on a reference is ignored in template substitutions and typedef results.

If, on the other hand T is const int, then T& is const int&

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Is this not an akward behaviour, huch, C++ is so hard... –  Gabriel Nov 7 '12 at 17:06
1  
@Gabriel, not so much if you know how to pronounce types. const int & is pronounced as "reference to const int", whereas the illegal int & const would be "const reference to (non-const) int". So if T is "reference to int", then const T is "const reference to int". If T is const int then T& is reference to const int. Hope this was clear –  Armen Tsirunyan Nov 7 '12 at 17:09
    
Thanks, so the strange thing is that T = reference to int = int& yields then "const T" = const int & -> where the const gets ignored and there stands int & .... thats not intuitive isnt it? the understanding comes from a normal code like "const int & a = 2" which is basically the wrong form (right to left: reference to int const = reference to const int)... –  Gabriel Nov 7 '12 at 17:19

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