I ran into this design problem. Here's the story:

I have a base class that defines a few methods like this:

virtual double & f(double x);

The base class will call one of them to ask for the reference to some data in subclass when answering some queries. The problem is, these f methods return an optional piece of data in subclass. In other words, depending on the subclass, what f is asking to return may not exist at all. The logic in the base class can guarantee that it will not call such f() on a subclass when it doesn't exist, so in principle this subclass doesn't need to implement this method, but I don't want to make the method pure virtual because the subclass needs to be instantiable regardless. Inconveniently the return type of f needs to be reference so I can't simply return some junk value.

So basically I'm looking for a "elegant" way to return a dummy reference, that will not be called anyway if the program works correctly, but ideally would help debugging by catching mistake calls. The signature of f is important for readability so ideally I don't want to change it.

I suppose I can declare a dummy static double DATA_NOT_EXIST variable in the class and return it, but it looks a bit ugly. Any better ideas? What's your favorite way to return a "null" reference when you have to?

Thanks in advance.


I want to keep these methods in base class, although they do seem better off declared in subclasses instead, because the base class is trying to handle some logic that's not applicable to all subclasses (is this itself a bad design?). Something like this: the base class represents a mouse, and the optional data in the subclasses represent left/middle/right buttons. Any particular subclass may not have certain buttons, but anyway the base class still handles button clicks, with the assumption that there may or may not be buttons.

Edit: Here's some source code to illustrate what I mean to do. In base class:

#include <cassert>
struct Base
  double & basef(int x)
    assert(x >= 0 && x < 20);
    if (x < 10) return f1(x);
    else return f2(x);
  virtual double & f1(int x);
  virtual double & f2(int x);

struct Sub1 : Base
  double & f1(int x) { return a[x]; }
  double & f2(int x) { return b[x - 10]; }
  double a[10];
  double b[10];

struct Sub2 : Base
  double & f1(int x) { return a[x]; }
  double & f2(int x) { /* nothing to return here! */ }
  double a[10];
  • 2
    Why not just put these functions in a subclass? If they cannot be implemented in every subclass then they have no place being in the superclass (in general). – Mankarse Oct 9 '12 at 4:16
  • Overall, your design seems flawed, but if you can't change it, the best thing to do would probably be to just assert(false) in the subclasses where f should never be called. – Mankarse Oct 9 '12 at 4:22
  • They need to be called by a base class dispatcher. That dispatcher has to be in the base class. Think of the base class as representing something like a mouse, and the optional data as e.g. left/middle/right button. Not all mouses have all keys, but it still makes better sense to assume such common scheme in the base class and let the base class handle the key clicks. – fang Oct 9 '12 at 4:23
  • 1
    I see your point (or at least, I think I do). You have two reasonable options -- 1) move f into a subclass, and then explicitly downcast when you are sure that it will be available (this is equivalent to what you are already doing, but it makes it clearer that this is how the code works), 2) figure out what the common interface is, and put the "dispatching" code (or whatever) in the subclass (perhaps with a common implementation as a free function somewhere). – Mankarse Oct 9 '12 at 4:29
  • Thanks for the suggestions. I don't think I can go with (1) because even if which data is available is known, it is still unknown which subclass to down cast to because there will be many subclasses. Could you elaborate on (2) please? – fang Oct 9 '12 at 4:35

You have several options, none require you introduce undefined behavior into your program by dereferencing null pointers as has been suggested by two answers now.

1) Throw an exception. Take away the unpredictability and make it part of your design:

// default implementation in base class
virtual double& f2(int x)
    throw std::runtime_error("No value defined");

2) Use boost::optional<double&>:

// default implementation in base class
virtual boost::optional<double&> f2(int x)
    return boost::optional<double&>();

// call-site
auto value = x->f2(0);
if (value)

3) Use double* (poor-man's boost::optional):

// default implementation in base class
virtual double* f2(int x)
    return nullptr;

// same call-site as before

4) Fundamentally change the design to avoid the situation.

All of these are better solutions because they're reliable and predictable.

  • Could you quickly explain what boost is doing behind the scene in (2)? – fang Oct 10 '12 at 1:48
  • @fang: Basically number three, actually, when the T in boost::optional<T> is a reference type. – GManNickG Oct 10 '12 at 2:36
double& Dummy() { return *(double*)nullptr; }

If your compiler is smart enough to realize that this is a nullptr access and warns about it, try using another value that is likely to cause a crash, like anything <4096 (reasonably modern systems should have the first memory page completely offlimits to catch nullpointer dereferences), ~0 or something similar, or make the pointer a global variable.

Of course, I would usually do something like

double& Dummy() { ASSERT(false); }

and only return the reference if the compiler doesn't know about functions that don't return.

  • This is the same as a downvoted and deleted answer on this question. Do not introduce undefined behavior into your program to solve a problem. – GManNickG Oct 9 '12 at 14:10
  • @GManNickG: Is it actually UB? I suspect it might only be UB if the reference is actually accessed during a particular execution (similar to how you're allowed to write ((struct foo *) NULL)->somefield if all you actually do is apply sizeof to it), but I'm not sure. If so, and if no execution ever actually accesses it when the ref is NULL, then no UB would arise. – j_random_hacker Oct 9 '12 at 14:29
  • 1
    @j_random_hacker: Standard-wise, it's intended to be UB, though last I looked it was an active issue of whether this should be UB: int* i = nullptr; *i;, since it doesn't do anything with the value. The sizeof example is okay because the argument to sizeof is explicitly specified to be non-evaluated. Regardless, yes, if the code is never run then there is no UB, but the point is if you're going to run code in a bad situation, why make it worse by doing something unpredictable or ill-defined? Just throw an exception. – GManNickG Oct 9 '12 at 15:05

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