Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Someone mentioned it in the IRC, but google doesn't have a good answer.

share|improve this question
add comment

12 Answers

"Slicing" is where you assign an object of a derived class to an instance of a base class, thereby losing part of the information - some of it is "sliced" away.

For example,

class A {
   int foo;
};

class B : public A {
   int bar;
};

So an object of type B has two data members, foo and bar

Then if you were to write this:

B b;

A a = b;

Then the information in b about member bar is lost in a.

share|improve this answer
33  
Very informative, but see stackoverflow.com/questions/274626#274636 for an example of how slicing occurs during method calls (which underscores the danger a little better than the plain assignment example). –  Blair Conrad Nov 8 '08 at 13:53
7  
Interesting. I've been programming in C++ for 15 years and this issue never occurred to me, as I've always passed objects by reference as a matter of efficiency and personal style. Goes to show how good habits can help you. –  Karl Bielefeldt Feb 2 '11 at 3:48
3  
@Felix Thanks but I don't think casting back (since not a pointer arithmetic) will work , A a = b; a is now object of type A which has copy of B::foo. It will be mistake to cast it back now i think. –  user72424 Aug 12 '11 at 12:27
1  
@Hades: I see what you mean, I was considering pointers. You're right, assignment is not casting of course – in fact, a new object is allocated on the stack. Then bar in b is not corrupted at all, simply not copied by the compiler-generated assignment operator, so a is now a completely new object of type A with member a.foo set to the same value as b.foo. –  Felix Dombek Aug 12 '11 at 16:22
2  
@Karl: it does not help in the case of assignment. B& b = xxx; b = someDerivedClass(); still provoke slicing. It is just that usually the problem goes unnoticed. –  Matthieu M. Sep 8 '11 at 17:12
show 6 more comments

If You have a base class A and a derived class B, then You can do the following.

void wantAnA(A myA)
{
   // work with myA
}

B derived;
// work with the object "derived"
wantAnA(derived);

Now the method wantAnA needs a copy of derived. However, the object derived cannot be copied completely, as the class B could invent additional member variables which are not in its base class A.

Therefore, to call wantAnA, the compiler will "slice off" all additional members of the derived class. The result might be an object you did not want to create, because

  • it may be incomplete,
  • it behaves like an A-object (all special behaviour of the class B is lost).
share|improve this answer
2  
+1 great! Now I got aware of slicing using functions/methods –  Viet Jul 19 '12 at 1:19
8  
C++ is not Java! If wantAnA (as its name implies!) wants an A, then that's what it gets. And an instance of A, will, uh, behave like an A. How is that surprising? –  fgp Jan 22 '13 at 16:39
10  
@fgp: It's surprising, because you don't pass an A to the function. –  Black Mar 3 '13 at 7:03
3  
@fgp: The behaviour is similar. However, to the average C++ programmer it might be less obvious. As far as I understood the question, nobody is "complaining". It's just about how the compiler handles the situation. Imho, it is better to avoid slicing at all by passing (const) references. –  Black Apr 7 '13 at 12:13
2  
@ThomasW No, I would not throw out inheritance, but use references. If the signature of wantAnA would be void wantAnA(const A & myA), then there had been not slicing. Instead, a read-only reference to the caller's object is passed. –  Black May 28 '13 at 7:44
show 3 more comments

Most answers here fail to explain what the actual problem with slicing is. They only explain the benign cases of slicing, not the treacherous ones. Assume, like the other answers, that you're dealing with two classes A and B, where B derives (publicly) from A.

In this situation, C++ lets you pass an instance of B to A's assignment operator (and also to the copy constructor). This works because an instance of B can be converted to a const A&, which is what assignment operators and copy-constructors expect their arguments to be.

The benign case

B b;
A a = b;

Nothing bad happens there - you asked for an instance of A which is a copy of B, and that's exactly what you get. Sure, a won't contain some of b's members, but how should it? It's an A, after all, not a B, so it hasn't even heard about these members, let alone would be able to store them.

The treacherous case

B b1;
B b2;
A& a_ref = b2;
a_ref = b1;
//b_2 now contains a mixture of b1 and b2!

You might think that b2 will be a copy of b1 afterwards. But, alas, it's not! If you inspect it, you'll discover that b2 is a Frankensteinian creature, made from some chunks of b1 (the chunks that B inherits from A), and some chunks of b2 (the chunks that only B contains). Ouch!

What happened? Well, C++ by default doesn't treat assignment operators as virtual. Thus, the line a_ref = b1 will call the assignment operator of A, not that of B. This is because for non-virtual functions, the declared type (which is A&) determines which function is called, as opposed to the actual type (which would be B, since a_ref references an instance of B). Now, A's assignment operator obviously knows only about the members declared in A, so it will copy only those, leaving the members added in B unchanged.

A solution

Assigning only to parts of an object usually makes little sense, yet C++ unfortunately provides no built-in way to forbid this. You can, however, roll your own. The first step is making the assignment operator virtual. This will guarantee that it's always the actual type's assignment operator which is called, not the declared type's. The second step is to use dynamic_cast to verify that the assigned object has a compatible type. The third step is to do the actual assignment in a (protected!) member assign(), since B's assign() will probably want to use A's assign() to copy A's members.

class A {
public:
  virtual A& operator= (const A& a) {
    assign(a);
    return *this;
  }

protected:
  void assign(const A& a) {
    // copy members of A from a to this
  }
};

class B : public A {
public:
  virtual B& operator= (const A& a) {
    if (const B* b = dynamic_cast<const B*>(&a))
      assign(*b);
    else
      throw bad_assignment();
    return *this;
  }

protected:
  void assign(const B& b) {
    A::assign(b); // Let A's assign() copy members of A from b to this
    // copy members of B from b to this
  }
};

Note that, for pure convenience, B's operator= covariantly overrides the return type, since it knows that it's returning an instance of B.

share|improve this answer
    
Then the some operations on an object of A are not allowed when the object is of type B. –  curiousguy Jun 29 '13 at 15:05
    
IMHO, the problem is that there are two different kinds of substitutability that may be implied by inheritance: either any derived value may be given to code expecting a base value, or any derived reference may be used as a base reference. I would like to see a language with a type system which addresses both concepts separately. There are many cases where a derived reference should be substitutable for a base reference, but derived instances should not be substitutable for base ones; there are also many cases where instances should be convertible but references should not substitute. –  supercat Aug 12 '13 at 16:11
    
Conceptually, in .NET, if a function returns KeyValuePair<SiameseCat, ToyotaPrius>, one should be able to store that result into a storage location of type KeyValuePair<Animal, Vehicle>, not because an instance of the former is an instance of the latter, but rather because interpreting the return value as a KVP<A,V> would effectively turn it into one. Unfortunately, that would require a separate hierarchy from the normal inheritance one, since a boxed instance of the former type is definitely not equivalent to a boxed instance of the latter. –  supercat Aug 12 '13 at 16:19
1  
I don't understand what is so bad in your "treacherous" case. You stated that you want to: 1) get a reference to an object of class A and 2) cast the object b1 to class A and copy its stuff to a reference of the class A. What is actually wrong here is the proper logic behind the given code. In other words, you took a small image frame (A), placed it over a bigger image (B) and you painted through that frame, complaining later that your bigger image now looks ugly :) But if we just consider that framed area, it looks pretty good, just as the painter wanted, right? :) –  Mladen B. Nov 14 '13 at 13:05
1  
The problem is, differently put, that C++ by default assumes a very strong kind of substitutability - it requires the base class'es operations to workly correctly on subclass instances. And that even for operations which the compiler autogenerated like assignment. So it's not enough to not screw up your own operations in this regard, you also have to explicitly disable the wrong ones generated by the compiler. Or of course, stay away from public inheritance, which usually is a good suggestion anway ;-) –  fgp Nov 16 '13 at 16:31
add comment

Third match in google for "C++ slicing" gives me this Wikipedia article http://en.wikipedia.org/wiki/Object_slicing and this (heated, but the first few posts define the problem) : http://bytes.com/forum/thread163565.html

So it's when you assign an object of a subclass to the super class. The superclass knows nothing of the additional information in the subclass, and hasn't got room to store it, so the additional information gets "sliced off".

If those links don't give enough info for a "good answer" please edit your question to let us know what more you're looking for.

share|improve this answer
add comment

The slicing problem is serious because it can result in memory corruption, and it is very difficult to guarantee a program does not suffer from it. To design it out of the language, classes that support inheritance should be accessible by reference only (not by value). The D programming language has this property.

Consider class A, and class B derived from A. Memory corruption can happen if the A part has a pointer p, and a B instance that points p to B's additional data. Then, when the additional data gets sliced off, p is pointing to garbage.

share|improve this answer
1  
Please explain how the memory corruption can occur. –  foraidt Nov 8 '08 at 12:48
17  
call foo() will call A::foo() after slicing, not B::foo() ... –  Tobi Nov 10 '08 at 12:53
3  
I forgot that the copy ctor will reset the vptr, my mistake. But you can still get corruption if A has a pointer, and B sets that to point into B's section that gets sliced off. –  Walter Bright Nov 11 '08 at 2:21
11  
This problem isn't just limited to slicing. Any classes that contain pointers are going to have dubious behaviour with a default assignment operator and copy-constructor. –  Weeble Feb 11 '09 at 11:54
2  
@Weeble: What makes object slicing worse than general pointer fixups is that to be certain you have prevented slicing from happening, a base class must provide converting constructors for every derived class. (Why? Any derived classes that are missed are susceptible to being picked up by the base class's copy ctor, since Derived is implicitly convertible to Base.) This is obviously counter to the Open-Closed Principle, and a big maintenance burden. –  j_random_hacker Oct 24 '12 at 12:30
show 9 more comments

1. THE DEFINITION OF SLICING PROBLEM

If D is a derived class of the base class B, then you can assign an object of type Derived to a variable (or parameter) of type Base.

EXAMPLE

class Pet
{
 public:
    string name;
};
class Dog : public Pet
{
public:
    string breed;
};

int main()
{   
    Dog dog;
    Pet pet;

    dog.name = "Tommy";
    dog.breed = "Kangal Dog";
    pet = dog;
    cout << pet.breed; //ERROR

Although the above assignment is allowed, the value that is assigned to the variable pet loses its breed field. This is called the slicing problem.

2. HOW TO FIX THE SLICING PROBLEM

To defeat the problem, we use pointers to dynamic variables.

EXAMPLE

Pet *ptrP;
Dog *ptrD;
ptrD = new Dog;         
ptrD->name = "Tommy";
ptrD->breed = "Kangal Dog";
ptrP = ptrD;
cout << ((Dog *)ptrP)->breed; 

In this case, none of the data members or member functions of the dynamic variable being pointed to by ptrD (descendant class object) will be lost. In addition, if you need to use functions, the function must be a virtual function.

share|improve this answer
2  
I understand the "slicing" part, but I don't understand "problem". How is it a problem that some state of dog that isn't part of class Pet (the breed data member) isn't copied in the variable pet? The code is is only interested in the Pet data members - apparently. Slicing is definitely a "problem" if it is unwanted, but I don't see that here. –  curiousguy Feb 18 '12 at 4:18
3  
"((Dog *)ptrP)" I suggest using static_cast<Dog*>(ptrP) –  curiousguy Feb 18 '12 at 4:20
    
I suggest pointing out that you will make the string 'breed' eventually leak memory without a virtual destructor (the destructor of 'string' will not be called) when deleting through 'ptrP'... Why is what you show problematic? The fix is mostly proper class design. The problem in this case is that writing down constructors to control visibility when inheriting is tedious and easily forgotten. You won't get anywhere near the danger zone with your code as there is no polymorphism involved or even mentioned (slicing will truncate your object but not make your program crash, here). –  Dude Oct 18 '12 at 2:58
5  
-1 This completely fails to explain the actual problem. C++ has value semantics, not reference semantics like Java, so this is all entirely to be expected. And the "fix" really is an example of truely horrible C++ code. "Fixing" non-existing problems like this type of slicing by resorting to dynamic allocation is a recipe for buggy code, leaked memory and horrible performance. Note that there are cases where slicing is bad, but this answer failes to point them out. Hint: the trouble starts if you assign through references. –  fgp Jan 22 '13 at 16:35
add comment

The slicing problem in C++ arises from the value semantics of its objects, which remained mostly due to compatibility with C structs. You need to use explicit reference or pointer syntax to achieve "normal" object behavior found in most other languages that do objects, i.e., objects are always passed around by reference.

The short answers is that you slice the object by assigning a derived object to a base object by value, i.e. the remaining object is only a part of the derived object. In order to preserve value semantics, slicing is a reasonable behavior and has its relatively rare uses, which doesn't exist in most other languages. Some people consider it a feature of C++, while many considered it one of the quirks/misfeatures of C++.

share|improve this answer
4  
""normal" object behavior" that's not "normal object behaviour", that's reference semantic. And it relates in no way with C struct, compatibility, or other non-sense the any random OOP priest told you. –  curiousguy Nov 27 '11 at 11:27
2  
@curiousguy Amen, brother. It's sad to see how often C++ get bashed from not being Java, when value semantics is one of the things that makes C++ so insanely powerfull. –  fgp Jan 22 '13 at 16:42
add comment

So ... Why is losing the derived information bad? ... because the author of the derived class may have changed the representation such that slicing off the extra information changes the value being represented by the object. This can happen if the derived class if used to cache a representation that is more efficient for certain operations, but expensive to transform back to the base representation.

Also thought someone should also mention what you should do to avoid slicing... Get a copy of C++ Coding Standards, 101 rules guidlines, and best practices. Dealing with slicing is #54.

It suggests a somewhat sophisticated pattern to fully deal with the issue: have a protected copy constructor, a protected pure virtual DoClone, and a public Clone with an assert which will tell you if a (further) derived class failed to implement DoClone correctly. (The Clone method makes a proper deep copy of the polymorphic object.)

You can also mark the copy constructor on the base explicit which allows for explicit slicing if it is desired.

share|improve this answer
1  
"You can also mark the copy constructor on the base explicit" which does not help at all. –  curiousguy Aug 4 '12 at 22:25
add comment

It seems to me, that slicing isn't so much a problem other than when your own classes and program are poorly architected/designed.

If I pass a subclass object in as a parameter to a method, which takes a parameter of type superclass, I should certainly be aware of that and know the internally, the called method will be working with the superclass (aka baseclass) object only.

It seems to me only the unreasonable expectation that providing a subclass where a baseclass is requested, would somehow result in subclass specific results, would cause slicing to be a problem. Its either poor design in the use of the method or a poor subclass implementation. I'm guessing its usually the result of sacrificing good OOP design in favor of expediency or performance gains.

share|improve this answer
2  
But remember, Minok, that you're NOT passing in a reference of that object. You're passing a NEW copy of that object, but using the base class to copy it in the process. –  Arafangion Dec 22 '10 at 11:06
    
protected copy/assignment on the base class and this problem is solved. –  Dude Oct 18 '12 at 2:51
1  
You're right. Good practice is to use abstract base classes or to restrict the access to copy/assignment. However, it's not so easy to spot once it's there and easy to forget to take care of. Calling virtual methods with sliced *this can make mysterious things happen if you get away without an access violation. –  Dude Oct 18 '12 at 3:06
add comment

OK, I'll give it a try after reading many posts explaining object slicing but not how it becomes problematic.

The vicious scenario that can result in memory corruption is the following:

  • Class provides (accidentally, possibly compiler-generated) assignment on a polymorphic base class.
  • Client copies and slices an instance of a derived class.
  • Client calls a virtual member function that accesses the sliced-off state.
share|improve this answer
add comment
class A 
{ 
    int x; 
};  

class B 
{ 
    B( ) : x(1), c('a') { } 
    int x; 
    char c; 
};  

int main( ) 
{ 
    A a; 
    B b; 
    a = b;     // b.c == 'a' is "sliced" off
    return 0; 
}
share|improve this answer
2  
Would you mind giving some extra details? How does your answer differ from the already posted ones? –  Alexis Pigeon Nov 29 '12 at 12:55
1  
I guess that more explanation wouldn't be bad. –  looper Nov 29 '12 at 12:55
add comment

Find similar answers here:http://sickprogrammersarea.blogspot.in/2014/03/technical-interview-questions-on-c_6.html

Slicing means that the data added by a subclass are discarded when an object of the subclass is passed or returned by value or from a function expecting a base class object.

Explanation: Consider the following class declaration:

           class baseclass
          {
                 ...
                 baseclass & operator =(const baseclass&);
                 baseclass(const baseclass&);
          }
          void function( )
          {
                baseclass obj1=m;
                obj1=m;
          }

As baseclass copy functions don't know anything about the derived only the base part of the derived is copied. This is commonly referred to as slicing.

share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

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