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Assuming I have a base class A and publicly derived class B, how should I assign A object to the A base class subobject of B?

class A {...};
class B : public A {...};
A a(..);
B b(..);
static_cast<A&>(b) = a; ???

Is that doable without writing assignement operator for B? Are there any potential problems with casting b to A&? Is that standard conformant?

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4  
Why do you want to do this? –  James McNellis Jan 1 '11 at 18:57
    
That's a good question- what would the semantics under such assignment be? –  Kos Jan 1 '11 at 20:31
1  
There are several usage in the MS VC ATL library. –  9dan Jan 1 '11 at 21:09
    
Very common with method only class inheriting data only struct, like database accessor classes. –  9dan Jan 1 '11 at 21:10
    
+1 Plain simple question but has very good reminding point for long time C++ programmers with shallow Object Orient Programing experience. –  9dan Jan 1 '11 at 22:20
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6 Answers 6

up vote 1 down vote accepted

Writing another answer to demonstrate why and how assign a base class object to a derived class object.

struct TimeMachineThing_Data {
..
..
};

class TimeMachineThing : private TimeMachineThing_Data
{
    static std::stack<TimeMachineThing_Data> m_stateHistory;

    void SaveState() {
        m_stateHistory.push_back( static_cast<TimeMachineThing_Data&>(*this) );
    }

    void RestoreState() {
        static_cast<TimeMachineThing_Data&>(*this) = m_stateHistory.front();
        m_stateHistory.pop_front();
    }
};

It's very useful and fully legitimate.

(Here is private inheritance, so only internally TimeMachineThing IS-A TimeMachinetime_Data)


Another one.

struct StructWithHundresField {
  string title;
  string author;
  ...

  StructWithHundresField() {
    ...
  }
};

class EasyResetClass : public StructWithHundresField {
  int not_reset_this_attriute;
public:
  void ResetToInitialStateAtAnyTime() {
    static_cast<StructWithHundresField&>(*this) = StructWithHundresField();
  }
}
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1  
This is rarely a useful pattern, though. Composition should be preferred to private inheritance wherever possible. –  James McNellis Jan 1 '11 at 21:13
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That's a really bad idea. A is the base, B is a derived type. By casting B to an A, you are now using A's assignment operator, which isn't going to touch any of the extra derived data. At the end of that assignment, b is still considered to be of type B, even though it now contains an A. This is the opposite of the way inheritance is meant to be used.

Changing the line to b = reinterpret_cast<B&>(a); would be even worse. Then you would be pretending that a is a B when it's not, and you be reading invalid memory.

If you truly want to do this kind of assignment, you want:

class B : public A {
    B& operator= (const A& a) { ... }
};

Then you can write a function to copy the information from the A, and somehow deal with the extra information in the derived type B, plus this would allow you to simply write:

b = a;
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1  
It's a bad idea, because you're only assigning a portion of your data. I.e. if A has members p, q and B adds member r, when you do the assignment static_cast<A&>(b) = a; you only assign p,q, and leave r untouched. This is most likely not what you want, as it's basically an incomplete assignment. So I could have worded it "This is usually a really bad idea, but if you understand the risks, here's how to do it." –  Tim Jan 1 '11 at 19:34
1  
yes, and it's those added aspects that matter here. Instead of A and B, lets use class Boss : public Employee. If you then do boss1 = employee1;, boss1 is now not really a boss anymore. Definitely still an employee, but not a boss. –  Tim Jan 1 '11 at 19:42
1  
@Tim now feel like understand your reasoning. You probably mistaken assignment with allocation. One can not assign newly created A instance to B reference but one can change A portion of B any time any way. –  9dan Jan 1 '11 at 19:43
2  
I'm not confusing assignment with allocation. I understand that the code works, and doesn't trample memory. I'm saying this is a bad practice, as its results are probably not what you wanted. As I said above, you can do the assignment, leaving the derived members data untouched... but is that really what you want? If you want to set the derived members to a default (or interpolated) value, use the assignment operator above. If you actually want to leave the derived members as-is, go ahead -- just be sure to understand what you're doing, and COMMENT IT for the sake of the maintainer. –  Tim Jan 1 '11 at 19:54
2  
@9dan: A::operator=(a); There is nothing wrong with calling the base class assignment operator from a derived class member function. –  James McNellis Jan 1 '11 at 21:44
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Think for a minute about whether this is a good idea. Remember that if you have B subclassing A, then every B is an A but not every A is a B. For example, every dog is a mammal, but not every mammal is a dog. If you have a concrete B object, trying to set it to an A object isn't mathematically well-defined in most cases. Moreover, in the world of C++, because you B object is statically typed as a B, you can never assign it an object of type A in a way that will make it stop being a B. At best, you're going to overwrite just the A portion of the B object without changing any of the B-specific parts.

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In C++ (as with other OOP languages) inheritance establish Is-A relationship.

That is, if B publicly inherit A, B = A.

You always can cast B instance to A reference without any worry.

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Makes sense. I was only worried about any potential problems with memory layout - I somehow can't find an argument why such assigments have to always work in C++. –  andriej Jan 1 '11 at 19:20
    
-1: @ 9dan it's FALSE. In memory B shall be different than an A. So when doing B = A you only copy a slice of A to a B. Results are unforseable. Polymorphism works through the usage of Pointers and of References only –  Stephane Rolland Jan 1 '11 at 20:46
    
@Stephane What specific word or phrase is FALSE in my answer? If I intended to modify A potion of B's memory, really I could not predict result of the assignment? Did you misunderderstood type equality and data equality? –  9dan Jan 1 '11 at 21:07
1  
@Stephane then How can you use inherited A's method with B instance ?? All A's method must include dynamic_cast thing for the future inheriance ?? Or Do we need static_cast before pass B instance to the function expecting A ?? –  9dan Jan 1 '11 at 21:42
1  
@Stephane So we could use all of A's method with B instance right? And in A's view, B instances are the exactly same with the pure A instance right? That's the IS-A relationship I'm trying to explain. –  9dan Jan 1 '11 at 22:09
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I would say you need an assignment operator that specifically copies an A object to a B object.

In general, it's a good idea to have one any way when copying objects of the same type. But objects of different types make it even more important.

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Everyone should know assignment is a covariant binary operator and therefore cannot work correctly with virtual functions. This is true for most binary operators, but assignment is special because it is part of the C++ language.

If you are using OO, your objects should be uncopyable and always represented by pointers. Uniqueness of object identity is the heart of OO: objects are not values, they have a unique value (their address).

If you are playing with values you should be using the appropriate concepts: functional programming (FP). That's closures (applicative objects), switches, templates, variants, and other stuff.

Try to get a solid understanding of each before mixing them. In general FP subsumes OO so is the general methodology: OO is a special case that in special circumstances delivers safe dynamic dispatch. OO dispatch is linear which means it handles an unbounded set of subtypes but it also applies only to properties (functions with one variant argument, namely the object) and can't work for anything higher order (functions with more than one variant argument). Assignment is just another 2-ary function, hence, it can't be dispatched with virtual functions.

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