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I have a data structure made of nested STL containers:

typedef std::map<Solver::EnumValue, double> SmValueProb;
typedef std::map<Solver::VariableReference, Solver::EnumValue> SmGuard;
typedef std::map<SmGuard, SmValueProb> SmTransitions;
typedef std::map<Solver::EnumValue, SmTransitions> SmMachine;

This form of the data is only used briefly in my program, and there's not much behavior that makes sense to attach to these types besides simply storing their data. However, the compiler (VC++2010) complains that the resulting names are too long.

Redefining the types as subclasses of the STL containers with no further elaboration seems to work:

typedef std::map<Solver::EnumValue, double> SmValueProb;
class SmGuard : public std::map<Solver::VariableReference, Solver::EnumValue> { };
class SmTransitions : public std::map<SmGuard, SmValueProb> { };
class SmMachine : public std::map<Solver::EnumValue, SmTransitions> { };

Recognizing that the STL containers aren't intended to be used as a base class, is there actually any hazard in this scenario?

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3 Answers 3

up vote 8 down vote accepted

There is one hazard: if you call delete on a pointer to a base class with no virtual destructor, you have Undefined Behavior. Otherwise, you are fine.

At least that's the theory. In practice, in the MSVC ABI or the Itanium ABI (gcc, Clang, icc, ...) delete on a base class with no virtual destructor (-Wdelete-non-virtual-dtor with gcc and clang, providing the class has virtual methods) only results in a problem if your derived class adds non-static attributes with non-trivial destructor (eg. a std::string).

In your specific case, this seems fine... but...

... you might still want to encapsulate (using Composition) and expose meaningful (business-oriented) methods. Not only will it be less hazardous, it will also be easier to understand than it->second.find('x')->begin()...

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Yes there is:

std::map<Solver::VariableReference, Solver::EnumValue>* x = new SmGuard;
delete x;

results in undefined behavior.

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This is one of the controversial point of C++ vs "inheritance based classical OOP".

There are two aspect that must be taken in consideration:

  • a typedef is introduce another name for a same type: std::map<Solver::EnumValue, double> and SmValueProb are -at all effect- the exact same thing and cna be used interchangably.
  • a class introcuce a new type that is (by principle) unrelated with anything else.

Class relation are defined by the way the class is "made up", and what lets implicit operations and conversion to be possible with other types.

Outside of specific programming paradigms (like OOP, that associate to the concept of "inhritance" and "is-a" relation) inheritance, implicit constructors, implicit casts, and so on, all do a same thing: let a type to be used across the interface of another type, thus defining a network of possible operations across different types. This is (generally speaking) "polymorphism".

Various programming paradigms exist about saying how such a network should be structured each attempting to optimize a specific aspect of programming, like the representation or runtime-replacable objects (classical OOP), the representation of compile-time replacable objects (CRTP), the use of genreric algorithial function for different types (Generic programming), teh use of "pure function" to express algorithm composition (functional and lambda "captures").

All of them dictates some "rules" about how language "features" must be used, since -being C++ multiparadigm- non of its features satisfy alone the requirements of the paradigm, letting some dirtiness open.

As Luchian said, inheriting a std::map will not produce a pure OOP replaceable type, since a delete over a base-pointer will not know how to destroy the derived part, being the destructor not virtual by design.

But -in fact- this is just a particular case: also pbase->find will not call your own eventually overridden find method, being std::map::find not virtual. (But this is not undefined: it is very well defined to be most likely not what you intend).

The real question is another: is "classic OOP substitution principle" important in your design or not? In other word, are you going to use your classes AND their bases each other interchangeably, with functions just taking a std::map* or std::map& parameter, pretending those function to call std::map functions resulting in calls to your methods?

  • If yes, inheritance is NOT THE WAY TO GO. There are no virtual methods in std::map, hence runtime polymorphism will not work.
  • If no, that is: you're just writing your own class reusing both std::map behavior and interface, with no intention of interchange their usage (in particular, you are not allocating your own classes with new and deletinf them with delete applyed to an std::map pointer), providing just a set of functions taking yourclass& or yourclass* as parameters, that that's perfectly fine. It may even be better than a typedef, since your function cannot be used with a std::map anymore, thus separating the functionalities.

The alternative can be "encapsulation": that is: make the map and explicit member of your class letting the map accessible as a public member, or making it a private member with an accessor function, or rewriting yourself the map interface in your class. You gat finally an unrelated type with tha same interface an its own behavior. At the cost to rewrite the entire interface of something that may have hundredths of methods.


To anyone thinking about the danger of the missing of vitual dtor, note tat encapluating with public visibility won't solve the problem:

class myclass: public std::map<something...>

std::map<something...>* p = new myclass;
delete p;

is UB excatly like

class myclass
   std::map<something...> mp;

std::map<something...>* p = &((new myclass)->mp);
delete p;

The second sample has the same mistake as the first, it is just less common: they both pretend to use a pointer to a partial object to operate on the entire one, with nothing in the partial object letting you able to know what the "containing one" is.

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I completely disagree on the same. It is completely forbidden (no valid usecase) to call delete on a class member, while it can work to call delete on a pointer to a base class, depending on the circumstances. The latter is also much easier to do accidentally because of the subtyping relationship. –  Matthieu M. Nov 26 '12 at 9:36
@MatthieuM.: If you "completly disagree", why then you explain exactly my same concept? I said that the "conceptual mistake" is the same. Not that the "code" or "usecase" etc. is the same. And btw. there are library out there (MFC and WxWidget to name a few) with functions returning pointers to... embedded members. calling delete on those pointer (not knowing where they come from) is the same problem of calling delete on a base pointer you don't know where it comes from. –  Emilio Garavaglia Nov 26 '12 at 9:55
@MatthieuM. Btw. it is not "forbidden": it compiles regularly. It's just UB. Hence the same (or am I missing something in comparing "UB" against "UB" ??) –  Emilio Garavaglia Nov 26 '12 at 10:03
My point is not that you cannot obtain a pointer to a data-member, my point is that calling delete on a pointer to a data-member is fundamentally broken while calling delete on a pointer to base-class is generally works (esp. with a virtual destructor). This is why I consider the two usecases completely different. (note: if it was not obvious, I am not arguing against your answer, only against the Note part) –  Matthieu M. Nov 26 '12 at 10:45
@MatthieuM. Your assertion "calling delete on a pointer to a data-member is fundamentally broken while calling delete on a pointer to base-class generally works (esp. with a virtual destructor)." is POV. I can say -with exactly same meaning- "calling delete on a base never works but with a virtual dtor". Hence, with equal POV arguing the virtual dtor to be a special case (the dtor is not vrtual if you don't make it as such). The fact that dtor are virtual in OOP objects, does not mean that inheritance is for OOP only. –  Emilio Garavaglia Nov 26 '12 at 11:55

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