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I ran into a confusing situation today that I'm hoping someone can explain to me.

I have a C++ program with 4 classes:

  • A Base class that just acts as a common interface,
  • An Enroll class, which subclasses Base and has a pure virtual enroll() method,
  • A Verify class, which also subclasses Base and has a pure virtual verify() method,
  • A Both class that subclasses both Enroll and Verify and provides implementations for enroll() and verify()

Like so:

 class Base {
       Base () { }
       virtual ~Base () { }

 class Enroll : public virtual Base {
       virtual ~Enroll () { }
       virtual void enroll () = 0;

 class Verify : public virtual Base {
       virtual ~Verify () { }
       virtual void verify () = 0;

 class Both : public Enroll, public Verify {
       virtual ~Both () { }

       virtual void enroll () { printf ("Enrolling.\n"); }
       virtual void verify () { printf ("Verifying.\n"); }

Instances of Both are instantiated in a non-member function, which just creates a new Both and returns the pointer:

Both* createInstanceOfBoth () {
   return new Both();

Finally, there's a Registry class that basically just acts as an Enroll/Verify factory. It uses a pair of function pointers to the createInstanceOfBoth() function to provide an instance of Enroll or Verify:

typedef Enroll* (*EnrollGenerator) ();
typedef Verify* (*VerifyGenerator) ();

class Registry {
      Registry () {
          enrollGenerator = (EnrollGenerator)&createInstanceOfBoth;
          verifyGenerator = (VerifyGenerator)&createInstanceOfBoth;              

      Enroll* getEnroll () { return enrollGenerator (); }
      Verify* getVerify () { return verifyGenerator (); }

      EnrollGenerator enrollGenerator;
      VerifyGenerator verifyGenerator;

And here's the problem. When I call getEnroll() on my Registry object and invoke enroll() on the object that's returned, I see the proper, expected output: Enrolling.. But when I call getVerify() and invoke verify() on the object that's returned, the enroll() method is executed again!


int main () {
   Registry registry;
   Enroll *enroller;
   Verify *verifier;

   enroller = registry.getEnroll ();
   verifier = registry.getVerify ();
   enroller->enroll ();
   verifier->verify ();
   return 0;



I've noticed that if I change the order of Enroll and Verify in the declaration of the Both class (class Both : public Verify, public Enroll {...}), the opposite effect will happen:


I've identified a workaround in which, instead of using a single createInstanceOfBoth() function to create my Enroll and Verify objects, I use two differently named functions with the same body but different return types:

Enroll* createInstanceOfEnroll () {
   return new Both();
Verify* createInstanceOfVerify () {
   return new Both();

Then, in the Registry class, I create my function pointers to these functions instead:

Registry () {
    enrollGenerator = &createInstanceOfEnroll;
    verifyGenerator = &createInstanceOfVerify;        

When I run the program now, I get the expected output:


My question is this: why doesn't the first way of doing it work? I suspect that it has something to do with casting createInstanceOfBoth() to a function pointer with a different return type, but I don't fully understand exactly what's happening. I'm fine with using my workaround at the moment, but I'm curious: is there a way of doing this with just the single createInstanceOfBoth() function instead of having to use two identical functions but with different return types?

To save the time and hassle of putting this together into a compilable example, I've posted this code to for download.

share|improve this question
I'm hoping this is an academic curiosity ... – AJG85 Feb 18 '11 at 5:59
Long question, but nicely laid out and easy reading... well done. – Tony D Feb 18 '11 at 6:13
@AJG85: It is. I encountered this sort of tangentially in the course of exploring ways to dynamically instantiate subclasses of Base and even though the production code won't involve anything like this example, it confounded me enough that I couldn't just drop it and move on until I understood what was going on. – RTBarnard Feb 18 '11 at 6:15
Ah well it is an interesting quirk. Sounds like a possible situation where you could use the abstract factory design pattern ... downcasting is worth avoiding as is multiple inheritance except for very specific situations, but that's my personal opinion. – AJG85 Feb 18 '11 at 15:12
up vote 7 down vote accepted

That function pointer cast (treating a function returning Both* as returning Verify* or Enroll*) is incorrect; with multiple inheritance, the different base classes within an object do not necessarily start at the beginning of the object. The function pointer cast is not doing the offsetting operation that is required for the derived-to-base pointer casts from Both* to the base pointer types.

You can have a single createInstanceOfBoth function, but it would need to return Both*; the code that calls it would then do the derived-to-base cast with that result.

share|improve this answer
That makes perfect sense! I've been racking my brain over this little detail for hours, but now that you explain it, it's embarrassingly obvious. Thanks! – RTBarnard Feb 18 '11 at 6:09
Good explanation. "the different base classes within an object do not necessarily start at the beginning of the object" - only one can so that statements a little conservative ;-) – Tony D Feb 18 '11 at 6:11
@Tony: is there a requirement that any of them start at the beginning of the derived object? I believe there is for single inheritance, but am not sure for multiple inheritance. – Jeremiah Willcock Feb 18 '11 at 6:12
that I don't know... I thought you meant there might not be 2+ and was thinking there can't be, but good query whether it need even be 1. I don't see any particular reason the Standard would prohibit a compiler from putting something there, given the virtual functions mean it's not a POD type needing layout compatibility with anything from the C or hardware device world. – Tony D Feb 18 '11 at 6:17

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