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Suppose that I need to store a collection of objects of the same type, but this type can't be defined at compile time. Suppose also that once this type is defined, it never changes. As well known, when the type is not know at compile time, it's possible to store these objects using a container of pointers to their base class, i.e.,

std::vector<Base*> collection;
collection.push_back( new Derived() );

In this way, allocated objects will not be necessarily stored side by side in memory, because in each allocation the new() will return an arbitrary position in memory. Furthermore, there is an extra pointer (vptr) embedded to each object, because the Base class of course needs to be polymorphic.

For this particular case (type is defined once + type never changes), the above solution is not the optimal solution, because, theoretically,

  1. it's not necessary to store the same vptr (sizeof() = pointer size) for each object: all of them points to the same vtable;
  2. it's possible to use contiguous storage locations, since the size of the objects are defined at the beginning of the program and will never change.

Q: Do you guys know a strategy/container/memory allocator/idiom/trick/anything else to overcome those problems?

I think I could do something like this (using the classic Shape example):

struct Triangle_Data {
    double p1[3],p2[3],p3[3];

struct Circle_Data {
    double radius;

struct Shape {
    virtual double area() const = 0;
    virtual char* getData() = 0;
    virtual ~Shape() {}

struct Triangle : public Shape {
    union {
        Triangle_Data tri_data;
        char data[sizeof(Triangle_Data)];
    double area() const { /*...*/ };
    char* getData() { return data; }
    Triangle(char * dat_) {
        std::copy(dat_, dat_+sizeof(Triangle_Data), this->data);

struct Circle : public Shape {
    union {
        Circle_Data circ_data;
        char data[sizeof(Circle_Data)];
    double area() const { /*...*/ };
    char* getData() { return data; }
    Circle(char * dat_) {
        std::copy(dat_, dat_+sizeof(Circle_Data), this->data);

template<class BaseT>
struct Container {
    int n_objects;
    int sizeof_obj;
    std::vector<char> data;
    Container(...arguments here...) : ...init here... {
        data.resize( sizeof_obj * n_objects );
    void push_back(Shape* obj) {
        // copy the content of obj
        for( int i=0; i<sizeof_obj; ++i)
            data.push_back(*(obj.getData() + i));
    char* operator[] (int idx) {
        return data + idx*sizeof_obj;

// usage:
int main() {
    Container<Shape> collection( ..init here.. );
    collection.push_back(new Circle());
    cout << Circle(collection[0]).area() << endl; // horrible, but does it work?

Of course, this approach has a lot of problems with type safety, alignment, etc.. Any suggestion?

Thank you

share|improve this question
If you ask for run-time polymorphism, i.e. virtual functions, you can't avoid paying the price of the vptr (The vtable is unique) –  StoryTeller Apr 7 '13 at 15:01
It would be possible for a language to provide this optimization. C++ does not. –  brian beuning Apr 7 '13 at 15:16
"Base class of course needs to be virtual" There is no such thing as a "virtual" class. There are only polymorphic classes (and virtual bases, which is a completely different thing). /nitpick –  curiousguy Aug 1 at 0:26
@curiousguy Thank you for pointing that out. I just fixed it. –  montefuscolo Aug 2 at 1:31
@StoryTeller "If you ask for run-time polymorphism, i.e. virtual functions, you can't avoid paying the price of the vptr" Knowing that the dynamic type is the same, you could try to avoid it with dirty tricks. –  curiousguy Aug 9 at 3:25

3 Answers 3

up vote 1 down vote accepted

1) it's not necessary to store the same vptr (8 bytes per object?) collection.size() times;

It is not necessary, but objects are independent of one another.

2) it's possible to use contiguous storage locations, since their size are known and equal to each other when their type is defined.

... indeed, if you can store concrete instances you can store them in contiguous memory.

So, what can you do ?

One solution is to not use polymorphic instances, but instead have data and polymorphism separated:

struct IShape {
    virtual ~IShape() {}
    virtual double area() const = 0;

struct Circle {
    float center, radius;

struct IShapeCircle: IShape {
    IShapeCircle(Circle const& c): circle(const_cast<Circle&>(c)) {}
    virtual double area() const { return PI * circle.radius * circle.radius; }

    Circle& circle;

This way, you only create a polymorphic instance when you need it. And for the storage, we can adapt Massimiliano's solution.

struct IShapeVector {
    virtual ~IShapeVector() {}
    std::unique_ptr<IShape> get(size_t i) = 0;
    std::unique_ptr<IShape const> get(size_t i) const = 0;

struct IShapeCircleVector: IShapeVector {
    std::unique_ptr<IShape> get(size_t i) {
        return make_unique<IShapeCircle>(_circles.at(i));
    std::unique_ptr<IShape const> get(size_t i) const {
        return make_unique<IShapeCircle const>(_circles.at(i));

    std::vector<Circle> _circles;

However, you might find that the allocation/deallocation traffic slows you down more than the mere v-ptr.

share|improve this answer
Thank you!!!! I will try to implement this and post the result here. In my case, all allocations are made once. The bottleneck is the loops. My problem with vptrs is because the size of objects is not much bigger then the size of a pointer, thus saving 8 bytes per object is a big deal. –  montefuscolo Apr 7 '13 at 18:17
@montefuscolo: if this is a tight loop, then you might find the allocation/deallocation (hidden behind unique_ptr) to be quite unpleasant. In this case, one solution is to make IShapeCircle "resettable" (by using a pointer instead of a reference), allocate one outside the loop (empty) and then have IShapeVector take an IShape& to be assigned to in get instead of returning a new object: void IShapeVector::assign(IShape& is, size_t i) = 0. Then, void IShapeCircleVector::assign(IShape& is, size_t i) { static_cast<IShapeCircle&>(is).reset(_circles.at(i)); }. –  Matthieu M. Apr 7 '13 at 18:32

it's not necessary to store the same vtable (8 bytes per object?) collection.size() times;

You're not storing vtables at all. You're storing pointers which are of same size whether the objects are polymorphic or not. If the collection has N objects, then it takes N * sizeof(void*) bytes. So the above statement is false.

it's possible to use contiguous storage locations, since their size are known and equal to each other when their type is defined.

This is not clear. If you're talking about the storage maintained by the container, then yes, the storage maintained by std::vector is guaranteed to be contiguous.

share|improve this answer
Oops, I mean vptr, not vtable. About std::vector<Base*>, it's guaranteed to be contiguous only to pointer to Base class, not ot objects. –  montefuscolo Apr 7 '13 at 15:12
@montefuscolo: vptr or vtable, it doesn't matter. You're storing the pointers to the objects, not vptr. –  Nawaz Apr 7 '13 at 15:14
Ok, but each object has a vtpr, and this vtpr are the same for all objects, since all objects are the same type. Thus, why store this vtpr multiple times? is there a way to overcome this? –  montefuscolo Apr 7 '13 at 15:17
@montefuscolo: Alright. In that case, implement your own mechanism to dispatch dynamically, without relying on the compiler and don't use virtual keyword in your class. The mechanism adopted by most compiler uses vptr, which is an implementation detail and therefore is not in your control. If you have virtual, then you will have vptr (in most compilers). –  Nawaz Apr 7 '13 at 15:29
@montefuscolo: (To agree with @Nawaz) If you really are concerned about the vptrs in each instance of a polymorphic class, why are you using virtual? To circumvent the whole "problem", you can instead use compile-time polymorphism and templates. Rolling your own mechanism for dynamic dispatch would be a really big undertaking! –  yzt Apr 7 '13 at 15:43

To address point 2 of your question, if you know that all the objects will be of the same type, and you have this information at run-time, you may think of virtualizing the container and create it with a factory. Just to give a sketch of the idea:

class ShapeContainer {
 /* Virtual base */

class CircleContainer : public ShapeContainer {
/* ... */
    std::vector<Circle> impl_;

class ShapeContainerFactory {
 /* Factory for ShapeContainer derived objects */

int main() {
    ShapeContainer& collection = ShapeContainerFactory.create("Circle");
    collection.push_back( Circle() );

In this case you will be guaranteed to store contiguously not the pointers or references to the polymorphic objects, but the objects themselves.

share|improve this answer
That doesn't solve much, really. Each object will still have a vptr embedded in it... –  StoryTeller Apr 7 '13 at 15:32
@StoryTeller That's the meaning of the premise "To address point 2 of your question..." –  Massimiliano Apr 7 '13 at 15:34
@StoryTeller Yes but the vptr is just a pointer, unless your objects are very light it will not make a huge difference. –  curiousguy Aug 9 at 3:24

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