191

Ok, this is really difficult to confess, but I do have a strong temptation at the moment to inherit from std::vector.

I need about 10 customized algorithms for vector and I want them to be directly members of the vector. But naturally I want also to have the rest of std::vector's interface. Well, my first idea, as a law-abiding citizen, was to have an std::vector member in MyVector class. But then I would have to manually reprovide all of the std::vector's interface. Too much to type. Next, I thought about private inheritance, so that instead of reproviding methods I would write a bunch of using std::vector::member's in the public section. This is tedious too actually.

And here I am, I really do think that I can simply inherit publicly from std::vector, but provide a warning in the documentation that this class should not be used polymorphically. I think most developers are competent enough to understand that this shouldn't be used polymorphically anyway.

Is my decision absolutely unjustifiable? If so, why? Can you provide an alternative which would have the additional members actually members but would not involve retyping all of vector's interface? I doubt it, but if you can, I'll just be happy.

Also, apart from the fact that some idiot can write something like

std::vector<int>* p  = new MyVector

is there any other realistic peril in using MyVector? By saying realistic I discard things like imagine a function which takes a pointer to vector ...

Well, I've stated my case. I have sinned. Now it's up to you to forgive me or not :)

  • 9
    So, you basically asking if it's ok to violate a common rule based on the fact that you are just too lazy to re-implement the container's interface? Then no, it is not. See, you can have the best of both worlds if you swallow that bitter pill and do it properly. Don't be that guy. Write robust code. – Jim Brissom Dec 4 '10 at 11:20
  • 7
    Why can't you/don't want to add the functionality you need with non-member functions? To me, that would be the safest thing to do in this scenario. – Simone Dec 4 '10 at 11:25
  • 11
    @Jim: std::vector's interface is quite huge, and when C++1x comes along, it will greatly expand. That's a lot to type and more to expand in a few years. I think this is a good reason to consider inheritance instead of containment - if one follow the premise that those functions should be members (which I doubt). The rule to not to derive from STL containers is that they aren't polymorphic. If you aren't using them that way, it doesn't apply. – sbi Dec 4 '10 at 11:59
  • 9
    The real meat of the question is in the one sentence: "I want them to be directly members of the vector". Nothing else in the question really matters. Why do you "want" this? What is the problem with just providing this functionality as non-members? – jalf Dec 4 '10 at 16:47
  • 8
    @JoshC: "Thou shalt" has always been more common than "thou shall", and it's also the version found in the King James Bible (which is generally what people are alluding to when they write "thou shalt not [...]"). What on Earth would lead you to call it a "misspelling"? – ruakh Dec 28 '14 at 3:27

13 Answers 13

156

Actually, there is nothing wrong with public inheritance of std::vector. If you need this, just do that.

I would suggest doing that only if it is really necessary. Only if you can't do what you want with free functions (e.g. should keep some state).

The problem is that MyVector is a new entity. It means a new C++ developer should know what the hell it is before using it. What's the difference between std::vector and MyVector? Which one is better to use here and there? What if I need to move std::vector to MyVector? May I just use swap() or not?

Do not produce new entities just to make something to look better. These entities (especially, such common) aren't going to live in vacuum. They will live in mixed environment with constantly increased entropy.

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  • 7
    My only counterargument to this is that one must really know what he's doing to do this. For example, do not introduce additional data members into MyVector and then try to pass it in to functions that accept std::vector& or std::vector*. If there's any kind of copy assignment involved using std::vector* or std::vector&, we have slicing issues where the new data members of MyVector will not be copied. The same would be true of calling swap through a base pointer/reference. I tend to think any kind of inheritance hierarchy that risks object slicing is a bad one. – stinky472 Sep 30 '12 at 22:14
  • 13
    std::vector's destructor is not virtual, therefore you should never inherit from it – André Fratelli May 3 '16 at 22:17
  • 2
    I created a class which publicly inherited std::vector for this reason: I had old code with a non-STL vector class, and I wanted to move to STL. I reimplemented the old class as a derived class of std::vector, allowing me to continue using the old function names (e.g., Count() rather than size()) in old code, while writing new code using the std::vector functions. I did not add any data members, therefore std::vector's destructor worked fine for objects created on the heap. – Graham Asher Oct 29 '16 at 12:53
  • 3
    @GrahamAsher If you delete an object through a pointer to base, and the destructor is not virtual, your program is exhibiting undefined behavior. One possible result of undefined behavior is "it worked fine in my tests". Another is that it emails your grandmother your web browsing history. Both are compliant with the C++ standard. It changing from one to the other with point releases of compilers, OSs, or the phase of the moon is also compliant. – Yakk - Adam Nevraumont Jun 11 '19 at 15:24
  • 2
    @GrahamAsher No, whenever you delete any object through a pointer to base without a virtual destructor, that is undefined behavior under the standard. I understand what you think is happening; you just happen to be wrong. "the base class destructor is called, and it works" is one possible symptom (and the most common) of this undefined behavior, because that is the naive machine code that the compiler usually generates. This does not make it safe nor a great idea to do. – Yakk - Adam Nevraumont Jun 11 '19 at 17:18
92

The whole STL was designed in such way that algorithms and containers are separate.

This led to a concept of different types of iterators: const iterators, random access iterators, etc.

Therefore I recommend you to accept this convention and design your algorithms in such way that they won't care about what is the container they're working on - and they would only require a specific type of iterator which they'd need to perform their operations.

Also, let me redirect you to some good remarks by Jeff Attwood.

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63

The main reason for not inheriting from std::vector publicly is an absence of a virtual destructor that effectively prevents you from polymorphic use of descendants. In particular, you are not allowed to delete a std::vector<T>* that actually points at a derived object (even if the derived class adds no members), yet the compiler generally can't warn you about it.

Private inheritance is allowed under these conditions. I therefore recommend using private inheritance and forwarding required methods from the parent as shown below.

class AdVector: private std::vector<double>
{
    typedef double T;
    typedef std::vector<double> vector;
public:
    using vector::push_back;
    using vector::operator[];
    using vector::begin;
    using vector::end;
    AdVector operator*(const AdVector & ) const;
    AdVector operator+(const AdVector & ) const;
    AdVector();
    virtual ~AdVector();
};

You should first consider refactoring your algorithms to abstract the type of container they are operating on and leave them as free templated functions, as pointed out by majority of answerers. This is usually done by making an algorithm accept a pair of iterators instead of container as arguments.

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  • IIUC, the absence of a virtual destructor is only a problem if the derived class allocates resources which must be freed upon destruction. (They wouldn't be freed in a polymorphic use case because a context unknowingly taking ownership of a derived object via pointer to base would only call the base destructor when it is time.) Similar issues arise from other overridden member functions, so care must be taken that the base ones are valid to call. But absent additional resources, are there any other reasons? – Peter - Reinstate Monica Nov 29 '16 at 9:06
  • 2
    vector's allocated storage is not the issue -- after all, vector's destructor would be called all right through a pointer to vector. It's just that the standard forbids deleteing free store objects through a base class expression. The reason is surely that the (de)allocation mechanism may try to infer the size of the memory chunk to free from delete's operand, for example when there are several allocation arenas for objects of certain sizes. This restriction does, afaics, not apply to normal destruction of objects with static or automatic storage duration. – Peter - Reinstate Monica Dec 21 '16 at 11:21
  • @DavisHerring I think we agree there :-). – Peter - Reinstate Monica Sep 20 '17 at 8:18
  • @DavisHerring Ah, I see, you refer to my first comment -- there was an IIUC in that comment, and it ended in a question; I saw later that indeed it is always forbidden. (Basilevs had made a general statement, "effectively prevents", and I wondered about the specific way in which it prevents.) So yes, we agree: UB. – Peter - Reinstate Monica Sep 20 '17 at 14:09
  • @Basilevs That must have been inadvertent. Fixed. – ThomasMcLeod Sep 19 '18 at 13:05
36

If you're considering this, you've clearly already slain the language pedants in your office. With them out of the way, why not just do

struct MyVector
{
   std::vector<Thingy> v;  // public!
   void func1( ... ) ; // and so on
}

That will sidestep all the possible blunders that might come out of accidentally upcasting your MyVector class, and you can still access all the vector ops just by adding a little .v .

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19

What are you hoping to accomplish? Just providing some functionality?

The C++ idiomatic way to do this is to just write some free functions that implement the functionality. Chances are you don't really require a std::vector, specifically for the functionality you're implementing, which means you're actually losing out on reusability by trying to inherit from std::vector.

I would strongly advise you to look at the standard library and headers, and meditate on how they work.

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  • 5
    I'm not convinced. Could you update with some of the proposed code to explain why? – Karl Knechtel Dec 4 '10 at 11:12
  • 6
    @Armen: apart from the aesthetics, are there any good reasons? – snemarch Dec 4 '10 at 11:22
  • 12
    @Armen: Better aesthetics, and greater genericity, would be to provide free front and back functions too. :) (Also consider the example of free begin and end in C++0x and boost.) – UncleBens Dec 4 '10 at 11:37
  • 3
    I still don't what's wrong with free functions. If you don't like the "aesthetics" of the STL, maybe C++ is wrong place for you, aesthetically. And adding some member functions won't fix it, as much other algorithms are still free functions. – Frank Osterfeld Dec 4 '10 at 12:14
  • 17
    It is hard to cache a result of heavy operation in an external algorithm. Suppose you have to calculate a sum of all elements in the vector or to solve a polynomial equation with vector elements as coefficients. Those operations are heavy and laziness would be useful for them. But you can't introduce it without wrapping or inheriting from the container. – Basilevs Dec 5 '10 at 4:48
14

I think very few rules should be followed blindly 100% of the time. It sounds like you've given it quite a lot of thought, and are convinced that this is the way to go. So -- unless someone comes up with good specific reasons not to do this -- I think you should go ahead with your plan.

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  • 9
    Your first sentence is true 100% of the time. :) – Steve Fallows Dec 4 '10 at 15:20
  • 5
    Unfortunately, the second sentence isn't. He hasn't given it a lot of thought. Most of the question is irrelevant. The only part of it that shows his motivation is "I want them to be directly members of the vector". I want. No reason for why this is desirable. Which sounds like he has given it no thought at all. – jalf Dec 4 '10 at 16:52
7

There is no reason to inherit from std::vector unless one wants to make a class that works differently than std::vector, because it handles in its own way the hidden details of std::vector's definition, or unless one has ideological reasons to use the objects of such class in place of std::vector's ones. However, the creators of the standard on C++ did not provide std::vector with any interface (in the form of protected members) that such inherited class could take advantage of in order to improve the vector in a specific way. Indeed, they had no way to think of any specific aspect that might need extension or fine-tune additional implementation, so they did not need to think of providing any such interface for any purpose.

The reasons for the second option can be only ideological, because std::vectors are not polymorphic, and otherwise there is no difference whether you expose std::vector's public interface via public inheritance or via public membership. (Suppose you need to keep some state in your object so you cannot get away with free functions). On a less sound note and from the ideological point of view, it appears that std::vectors are a kind of "simple idea", so any complexity in the form of objects of different possible classes in their place ideologically makes no use.

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4

In practical terms: If you do not have any data members in your derived class, you do not have any problems, not even in polymorphic usage. You only need a virtual destructor if the sizes of the base class and the derived class are different and/or you have virtual functions (which means a v-table).

BUT in theory: From [expr.delete] in the C++0x FCD: In the first alternative (delete object), if the static type of the object to be deleted is different from its dynamic type, the static type shall be a base class of the dynamic type of the object to be deleted and the static type shall have a virtual destructor or the behavior is undefined.

But you can derive privately from std::vector without problems. I have used the following pattern:

class PointVector : private std::vector<PointType>
{
    typedef std::vector<PointType> Vector;
    ...
    using Vector::at;
    using Vector::clear;
    using Vector::iterator;
    using Vector::const_iterator;
    using Vector::begin;
    using Vector::end;
    using Vector::cbegin;
    using Vector::cend;
    using Vector::crbegin;
    using Vector::crend;
    using Vector::empty;
    using Vector::size;
    using Vector::reserve;
    using Vector::operator[];
    using Vector::assign;
    using Vector::insert;
    using Vector::erase;
    using Vector::front;
    using Vector::back;
    using Vector::push_back;
    using Vector::pop_back;
    using Vector::resize;
    ...
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  • 3
    "You only need a virtual destructor if the sizes of the base class and the derived class are different nad/or you have virtual functions (which means a v-table)." This claim is practically correct, but not theoretically – Armen Tsirunyan Dec 4 '10 at 15:09
  • 2
    yep, in principle it is still undefined behavior. – jalf Dec 4 '10 at 16:54
  • If you claim that this is undefined behaviour I would like to see a proof (quotation from the standard). – hmuelner Dec 4 '10 at 17:44
  • 8
    @hmuelner: Unfortunately, Armen and jalf are correct on this one. From [expr.delete] in the C++0x FCD: <quote> In the first alternative (delete object), if the static type of the object to be deleted is different from its dynamic type, the static type shall be a base class of the dynamic type of the object to be deleted and the static type shall have a virtual destructor or the behavior is undefined.</quote> – Ben Voigt Dec 5 '10 at 4:49
  • 1
    Which is funny, because I actually thought the behavior was dependent on the presence of a non-trivial destructor (specifically, that POD classes could be destroyed via a pointer-to-base). – Ben Voigt Dec 5 '10 at 4:57
3

If you follow good C++ style, the absence of virtual function is not the problem, but slicing (see https://stackoverflow.com/a/14461532/877329)

Why is absence of virtual functions not the problem? Because a function should not try to delete any pointer it receives, since it does not have an ownership of it. Therefore, if following strict ownership policies, virtual destructors should not be needed. For example, this is always wrong (with or without virtual destructor):

void foo(SomeType* obj)
    {
    if(obj!=nullptr) //The function prototype only makes sense if parameter is optional
        {
        obj->doStuff();
        }
    delete obj;
    }

class SpecialSomeType:public SomeType
    {
    // whatever 
    };

int main()
    {
    SpecialSomeType obj;
    doStuff(&obj); //Will crash here. But caller does not know that
//  ...
    }

In contrast, this will always work (with or without virtual destructor):

void foo(SomeType* obj)
    {
    if(obj!=nullptr) //The function prototype only makes sense if parameter is optional
        {
        obj->doStuff();
        }
    }

class SpecialSomeType:public SomeType
    {
    // whatever 
    };

int main()
    {
    SpecialSomeType obj;
    doStuff(&obj);
//  The correct destructor *will* be called here.
    }

If the object is created by a factory, the factory should also return a pointer to a working deleter, which should be used instead of delete, since the factory may use its own heap. The caller can get it form of a share_ptr or unique_ptr. In short, do not delete anything you didn't get directly from new.

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2

Yes it's safe as long as you are careful not to do the things that are not safe... I don't think I've ever seen anyone use a vector with new so in practice you'll likely be fine. However, it's not the common idiom in c++....

Are you able to give more information on what the algorithms are?

Sometimes you end up going down one road with a design and then can't see the other paths you might have taken - the fact that you claim to need to vector with 10 new algorithms rings alarm bells for me - are there really 10 general purpose algorithms that a vector can implement, or are you trying to make an object that is both a general purpose vector AND which contains application specific functions?

I'm certainly not saying that you shouldn't do this, it's just that with the information you've given alarm bells are ringing which makes me think that maybe something is wrong with your abstractions and there is a better way to achieve what you want.

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2

I also inherited from std::vector recently, and found it to be very useful and so far I haven't experienced any problems with it.

My class is a sparse matrix class, meaning that I need to store my matrix elements somewhere, namely in an std::vector. My reason for inheriting was that I was a bit too lazy to write interfaces to all the methods and also I am interfacing the class to Python via SWIG, where there is already good interface code for std::vector. I found it much easier to extend this interface code to my class rather than writing a new one from scratch.

The only problem I can see with the approach is not so much with the non-virtual destructor, but rather some other methods, which I would like to overload, such as push_back(), resize(), insert() etc. Private inheritance could indeed be a good option.

Thanks!

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  • 10
    In my experience, the worst long-term damage is often caused by people who try something ill-advised, and "so far haven't experienced (read noticed) any problems with it". – Disillusioned Feb 16 '14 at 7:42
0

Here, let me introduce 2 more ways to do want you want. One is another way to wrap std::vector, another is the way to inherit without giving users a chance to break anything:

  1. Let me add another way of wrapping std::vector without writing a lot of function wrappers.

#include <utility> // For std:: forward
struct Derived: protected std::vector<T> {
    // Anything...
    using underlying_t = std::vector<T>;

    auto* get_underlying() noexcept
    {
        return static_cast<underlying_t*>(this);
    }
    auto* get_underlying() const noexcept
    {
        return static_cast<underlying_t*>(this);
    }

    template <class Ret, class ...Args>
    auto apply_to_underlying_class(Ret (*underlying_t::member_f)(Args...), Args &&...args)
    {
        return (get_underlying()->*member_f)(std::forward<Args>(args)...);
    }
};
  1. Inheriting from std::span instead of std::vector and avoid the dtor problem.
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0

This question is guaranteed to produce breathless pearl-clutching, but in fact there is no defensible reason for avoiding, or "unnecessarily multiplying entities" to avoid, derivation from a Standard container. The simplest, shortest possible expression is clearest, and best.

You do need to exercise all the usual care around any derived type, but there is nothing special about the case of a base from the Standard. Overriding a base member function could be tricky, but that would be unwise to do with any non-virtual base, so there is not much special here. If you were to add a data member, you would need to worry about slicing if the member had to be kept consistent with contents of the base, but again that is the same for any base.

The place where I have found deriving from a standard container particularly useful is to add a single constructor that does precisely the initialization needed, with no chance of confusion or hijacking by other constructors. (I'm looking at you, initialization_list constructors!) Then, you can freely use the resulting object, sliced -- pass it by reference to something expecting the base, move from it to an instance of the base, what have you. There are no edge cases to worry about, unless it would bother you to bind a template argument to the derived class.

A place where this technique will be immediately useful in C++20 is reservation. Where we might have written

  std::vector<T> names; names.reserve(1000);

we can say

  template<typename C> 
  struct reserve_in : C { 
    reserve_in(std::size_t n) { this->reserve(n); }
  };

and then have, even as class members,

  . . .
  reserve_in<std::vector<T>> taken_names{1000};  // 1
  std::vector<T> given_names{reserve_in<std::vector<T>>{1000}}; // 2
  . . .

(according to preference) and not need to write a constructor just to call reserve() on them.

(The reason that reserve_in, technically, needs to wait for C++20 is that prior Standards don't require the capacity of an empty vector to be preserved across moves. That is acknowledged as an oversight, and can reasonably be expected to be fixed as a defect in time for '20. We can also expect the fix to be, effectively, backdated to previous Standards, because all existing implementations actually do preserve capacity across moves; the Standards just haven't required it. The eager can safely jump the gun -- reserving is almost always just an optimization anyway.)

Some would argue that the case of reserve_in is better served by a free function template:

  template<typename C> 
  auto reserve_in(std::size_t n) { C c; c.reserve(n); return c; }

Such an alternative is certainly viable -- and could even, at times, be infinitesimally faster, because of *RVO. But the choice of derivation or free function should be made on its own merits, and not from baseless (heh!) superstition about deriving from Standard components. In the example use above, only the second form would work with the free function; although outside of class context it could be written a little more concisely:

  auto given_names{reserve_in<std::vector<T>>(1000)}; // 2
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