I have an Animal class with a virtual destructor, and a derived class Cat.

#include <iostream>

struct Animal
    Animal() { std::cout << "Animal constructor" << std::endl; }
    virtual ~Animal() { std::cout << "Animal destructor" << std::endl; }

struct Cat : public Animal
    Cat() { std::cout << "Cat constructor" << std::endl; }
    ~Cat() override { std::cout << "Cat destructor" << std::endl; }

int main()
    const Animal *j = new Cat[1];
    delete[] j;

This gives the output:

Animal constructor
Cat constructor
Animal destructor

I don't understand why is the Cat's destructor not called, when my base class destructor is virtual?

  • 10
    Totally OT, but if a function doesn't have any arguments then you don't need to write anything. Instead of e.g. Cat(void) only Cat() will work. May 15 at 11:24
  • 1
    @463035818_is_not_a_number clang 14.0.3 on macOS reproduces OP's output for me.
    – Botje
    May 15 at 11:26
  • 2
    @Botje I can only reproduce the output with gcc when Animal::~Animal is not virtual (godbolt.org/z/eKndcKGbM) May 15 at 11:26
  • 1
    @463035818_is_not_a_number I changed your first compiler explorer link to x86-64 clang 16.0.0 and got OP's output.
    – Botje
    May 15 at 11:28
  • 2
    (I've answered this, but interesting to note that GCC gets just as confused later if you change the number of cats allocated to 2)
    – Mike Vine
    May 15 at 12:03

7 Answers 7


Note that whilst a Cat is an Animal, an array of Cats is not an array of Animals. In other words, arrays are invariant in C++, not covariant like they are in some other languages.

So you are up-casting this array and this later confuses the compiler. You must do array delete[] in this case on the correct, original, type - Cat*.

Note that you would have similar issues for the same reason if you allocated an array of 2 or more Cats, cast this to an Animal* and then tried to use the second or subsequent Animal.

  • 1
    Typo: down casting -> Upcasting (Downcasting would be Animal -> Cat)
    – Botje
    May 15 at 11:45
  • 4
    std::vector to the rescue May 15 at 11:53
  • Does a tool like CPPCheck see the issue? Can someone point a precise wording, perhaps in cppreference, about why, while storing a derived * as base * is legal, the unexpected delete [] is called?
    – Oersted
    May 15 at 12:11
  • 1
    @AndrewHolmgren en.wikipedia.org/wiki/… May 17 at 13:25
  • 3
    This would become even clearer if you had a data member in Animal and added a second data member to Cat. Since then sizeof(Animal)!=sizeof(Cat), array indexing would be completely off. An array of smart pointers to Animal would work as expected since the destructor would get called for each pointer, and pointers are genuinely polymorphic. May 18 at 2:31

It's Undefined Behaviour in my understanding because of (in Delete,p2, Emphasis mine):

In a single-object delete expression, the value of the operand of delete may be a null pointer value, a pointer value that resulted from a previous non-array new-expression, or a pointer to a base class subobject of an object created by such a new-expression. If not, the behavior is undefined. In an array delete expression, the value of the operand of delete may be a null pointer value or a pointer value that resulted from a previous array new-expression...

Which basically means that for delete[] the type must be the exact one from new[] (no base class sub-objects allowed like delete).

So for the reason that is like this - in my opinion this time is obvious - the implementation needs to know how much is the full object size so it can iterate to the next array element.

I wrote counter arguments for why this could be different - but after some thought (and reading the comments) - I realised that such a solution is solving X-Y problem.

  • 2
    This encourages dangerous behaviour though. If you allow this then you are basically saying Animal* a = new Cat[2]; delete[] a; is ok. This would implicitly imply that a is useful on its own when it very much is not. a[1] is undefined behaviour at this point as array index uses the type (a[i] is defined as (a+i)) which moves on a by sizeof(Animal) bytes and not sizeof(Cat) bytes which it must do. So just avoiding this whole issue by not allowing a to be useful across the board is probably the right thing to do.
    – Mike Vine
    May 16 at 11:07
  • Re "the implementation needs to store the number of array elements anyway": The number of elements may be found dynamically by an end marker. The destructor iterates the array anyway if element destructors are called, so that's not a time loss. The allocated block will probably store a block size, but that may not be the minimum required for the array size (it could always be a power of 2, for example). If the element type does not have a destructor, then the end marker is irrelevant and no iteration at all will take place -- the block can be released right away wholesale. May 17 at 7:17
  • In addition, the first assignment in main does not guarantee in general that the Animal*, pointing to the first element of the array as an Animal would have the same value as the pointer returned by new Cat[], especially if Animal is not the first base class of Cat and EBO did not kick in on the previous ones. So yes, in general, deleting through the converted pointer ought to be UB. Using const auto instead should fix it :-P May 17 at 12:04

I answer to my own comment: https://en.cppreference.com/w/cpp/language/delete (emphasis mine)

For the second (array) form, expression must be a null pointer value or a pointer value previously obtained by an array form of new-expression whose allocation function was not a non-allocating form (i.e. overload (10)). The pointed-to type of expression must be similar to the element type of the array object. If expression is anything else, including if it's a pointer obtained by the non-array form of new-expression, the behavior is undefined.


Informally, two types are similar if, ignoring top-level cv-qualification:

  • they are the same type; or
  • they are both pointers, and the pointed-to types are similar;or
  • they are both pointers to member of the same class, and the types of the pointed-to members are similar; or
  • they are both arrays of the same size or both arrays of unknown bound, and the array element types are similar. (until C++20)
  • they are both arrays of the same size or at least one of them is array of unknown bound, and the array element types are similar.

So far as I understand, inheritance is not similarity...

  • 5
    Inheritance cannot be similarity indeed. Note that the array contains values, not references, and a Cat values is larger than an Animal value, so it won't fit there. That makes the cast from Cat * to Animal * invalid when pointing to an array, but since the type does not indicate it's pointing to an array and for single instance it is valid, the programmer has to mind this.
    – Jan Hudec
    May 16 at 6:07
  • 3
    ah yes - note that if you allocate more than one cat then for example j[1] calculates a wrong address for the second cat, because it uses sizeof(Animal) instead of sizeof(Cat)
    – user253751
    May 16 at 15:01
  • Where do they get the "similarity" idea from? The standard only seems to say "pointer value that resulted from a previous array new-expression". Perhaps there is a constraint or additional remark somewhere which is not cross-referenced from By the way, I must assume that "value" in the standard means "typed value" (and not simply numerical value, or the OP's code would work). But the standard does not define its use of "value" afaics, which may be a defect. May 17 at 7:46
  • @Peter-ReinstateMonica it came from wg21.link/cwg2474
    – Cubbi
    Jun 1 at 21:08
  • @Cubbi Interesting, thanks. As an aside, the definition of "similar" is unintelligible to me. (I assume they mean roughly that cv-qualifications don't matter and that one can omit array bounds, but that's only a qualified guess. Examples would really help here.) Jun 1 at 23:07

My only criticism of the other answers is that they are too tame. Arrays work because the entries all have the same size, so the starting address of the entry with index 5 can be computed easily. Casting array of Derived to array of Base (which is what you are doing here) could have much worse consequences than you have shown. (If the array happens to have only one entry or Derived has no new data members you might be OK.) A[1].method() will probably do something strange because (Base*)(A)+1 is not even the starting address of any object. The method will read the wrong data, and the effect of any change will be highly unpredictable. Any call to a virtual function will use an entirely meaningless vtable pointer, so who knows what 'code' will be executed. Even if that call is not an immediate disaster, you might override a vtable pointer. Destruction of the array will almost certainly delete some meaningless 'pointers'.

Pointer to single object (allocated & deleted without '[]') is fine. You can cast to Base*, dynamic_cast back, and call virtual functions. That's why Ayxan Haqverdili's suggestion works. Array of X should never have anything except objects of run-time type X, and new[] (even new[1]) creates arrays.


Others have explained the issue, but if you want an array of polymorphic objects, you want an array of pointers. Here's one way:

vector<unique_ptr<Animal>> animals;

The Cat's destructor is not called because the pointer J is declared as pointer to a constant Animal. When you delete an array of objects through a pointer to a base class with a virtual destructor the destructor of each derived class object is not called unless the pointer type is of derived class.

So for calling the Cat Destructor. modity the pointer type to

int main()
const Cat* j=new Cat[1];
delete[] j;

Make the Cat destructor also virtual and the code works as expected.

  • 1
    As the destructor of the base class (Animal) is declared virtual, the destructor of the subclass Cat will implicitly be virtual too, as virtual-ness is propagated. May 17 at 21:44
  • 1
    Please read attentively all answers and comments, as the issue is tricky. You'll see that it may "work" but not on all compilers and not in all situations, and rightly so.
    – Oersted
    May 18 at 11:10

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