Let's say I have a class Derived which derives from class Base whereas sizeof(Derived) > sizeof(Base). Now, if one allocates an array of Derived like this:

Base * myArray = new Derived[42];

and then attempts to access the n-th object using


Then this is might likely (but not always) cause undefined behaviour due to accessing Base from an invalid location.

What is the correct term for such an programming error? Should it be considered a case of object slicing?

  • 2
    @Slava That's classic dynamic C-style array. A C-style array is a sequence of objects exposed via a raw pointer to its first element. It doesn't matter how it is allocated. – n. 'pronouns' m. May 5 '16 at 13:05
  • 2
    @n.m. how vector allocates data inside? It is using new[] is it not? But according to you that's programmer's error – Slava May 5 '16 at 13:13
  • 2
    @Slava That's irrelevant to OP's question; please avoid asking here. – edmz May 5 '16 at 13:27
  • 3
    @Slava how vector allocates data inside is not anyone's buiness. It is guaranteed by the standard to work, that's all users need to know. new, if used, is called by the standard library. The standard library is allowed to use stuff whuch is not accessible or not advised for the users of the library. – n. 'pronouns' m. May 5 '16 at 13:42
  • 2
    As a German I suggest Arrayelementsizemismatch as the correct term. Mhmm. Gotta shove a "base" in there somewhere... – sbi May 14 '16 at 8:23

This is not object slicing.

As noted, indexing myArray does not cause object slicing, but results in undefined behavior caused by indexing into an array of Derived as if it were an array of Base.

A kind of "array decay bug".

The bug introduced at the assignment of new Derived[42] to myArray may be a variation of an array decay bug.

In a true instance of this type of bug, there is an actual array:

Derived x[42];
Base *myArray = x;

The problem is introduced because an array of Derived decays into a pointer to Derived with value equal to the address of its first element. The decay allows the pointer assignment to work properly. This decay behavior is inherited from C, which was a language design feature to allow arrays to be "passed by reference".

This leads us to the even worse incarnation of this bug. This feature gives C and C++ semantics for arrays syntax that turn array function arguments into aliases for pointer arguments.

void foo (Base base_array[42]) {

Derived d[42];
foo(d);          // Boom.

However, new[] is actually an overloaded operator that returns a pointer to the beginning of the allocated array object. So it is not a true instance of array decay (even though the array allocator is used). However, the bug symptoms are the same, and the intention of new[] is to get an array of Derived.

Detecting and avoiding the bug.

Use a smart pointer.

This kind of problem can be avoided by using a smart pointer object instead of managing a raw pointer. For example, the analogous coding error with unique_ptr would look like:

std::unique_ptr<Base[]> myArray = new Derived[42];

This would yield a compile time error, because unique_ptrs constructor is explicit

Use a container, and maybe std::reference.

Alternatively, you could avoid using new[], and use std::vector<Derived>. Then, you would have forced yourself to design a different solution for sending this array to framework code that is only Base aware. Possibly, a template function.

void my_framework_code (Base &object) {

template <typename DERIVED>
void my_interface(std::vector<DERIVED> &v) {
    for (...) {

Or, by using std::reference_wrapper<Base>.

std::vector<Derived> v(42);
std::vector<std::reference_wrapper<Base>> myArray(v.begin(), v.end());
|improve this answer|||||
  • If the sizes are the same, it will most likely work. Does the standard have anything to say about that? – sp2danny May 12 '16 at 7:50
  • @sp2danny: Once the array-to-pointer conversion is performed, the Base pointer must be treated as a pointer to a nonarray object. Only a Derived pointer can be treated as a pointer to an array object. Thus, pointer arithmetic on the Base pointer is limited to what is defined for an array of length one. – jxh May 12 '16 at 9:20
  • @jxh So contrary to ruakh's comment on n.m.'s answer, myArray + 0 is NOT undefined behaviour? – jotik May 13 '16 at 6:20
  • @sp2danny: Okay, found n.m.'s citation in C++2014. – jxh May 13 '16 at 18:17

It is not slicing at all, rather it is undefined behavior because you are accessing a Derived object where none exists (unless you get lucky and the sizes line up, in which case it is still UB but might do something useful anyway).

It's a simple case of failed pointer arithmetic.

|improve this answer|||||
  • It's still undefined behaviour even if you "get lucky and the sizes line up". Pointers are pointers, not integers. Technically. :) – Lightness Races in Orbit May 10 '16 at 20:04
  • @LightnessRacesinOrbit: You're right, the way I worded that made it sound like it would be totally valid in that case but it's not. I've updated the answer to reflect that. – John Zwinck May 11 '16 at 1:40

This is not object slicing in any way.

Object slicing is perfectly well defined by the C++ standard. It may be a violation of object-oriented design principles or whatever, but it is not a violation of C++ rules.

This code violates 5.7 [expr.add] paragraph 7:

For addition or subtraction, if the expressions P or Q have type “pointer to cv T”, where T is different from the cv-unqualified array element type, the behavior is undefined. [Note: In particular, a pointer to a base class cannot be used for pointer arithmetic when the array contains objects of a derived class type. —end note].

Array subscript operator is defined to be equivalent to pointer arithmetic, 5.2.1 [expr.sub] paragraph 1:

The expression E1[E2] is identical (by definition) to *((E1)+(E2))

|improve this answer|||||
  • 1
    +1. Interestingly, this implies that even myArray + 0 invokes undefined behavior. I wonder if any compilers currently use that fact for any weird optimizations? – ruakh May 5 '16 at 19:46
  • 1
    @ruakh: They could use it to determine that the dynamic type equals the static type and eliminate virtual function calls. Don't know, if any do though. – MikeMB May 6 '16 at 7:00
  • What do you mean by "Object slicing is perfectly well defined by the C++ standard"? – jotik May 6 '16 at 7:59
  • 2
    @jotik I mean object slicing does not violate any C++ rules. There's no undefined behaviour. – n. 'pronouns' m. May 6 '16 at 8:33
  • @MikeMB nice, that would be an excellent way to hint a compiler at the dynamic type of an object. – Johannes Schaub - litb May 14 '16 at 14:03

This is not a case of slicing, although it is very similar. Slicing is well defined. This is simply undefined behaviour (always, not just likely) due to illegal pointer arithmetic.

|improve this answer|||||

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.