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I know that structs in .NET do not support inheritance, but its not exactly clear why they are limited in this way.

What technical reason prevents structs from inheriting from other structs?

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3  
I'm not dying for this functionality, but I can think of a few cases when struct inheritance would be useful: you might want to extent a Point2D struct to a Point3D struct with inheritance, you might want to inherit from Int32 to constrain it values between 1 and 100, you might want to create a type-def which is visible across multiple files (the Using typeA = typeB trick has file scope only), etc. –  Juliet Aug 3 '09 at 15:25
4  
You might want to read stackoverflow.com/questions/1082311/…, which explains a bit more about structs and why they should be restricted to a certain size. If you want to use inheritance in a struct then you should probably be using a class. –  Justin Aug 3 '09 at 15:35
1  
And you might want to read stackoverflow.com/questions/1222935/… as it goes in depth why it just couldn't be done in the dotNet platform. They cold have made it the C++ way, with the same problems which can be disastrous for a managed platform. –  Dykam Aug 3 '09 at 16:23

10 Answers 10

up vote 57 down vote accepted

The reason value types can't support inheritance is because of arrays.

The problem is that, for performance and GC reasons, arrays of value types are stored "inline". For example, given new FooType[10] {...}, if FooType is a reference type, 11 instances will be created on the GC heap (one for the array, and 10 for each instance). If FooType is instead a value type, only one instance will be created on the GC heap -- the array itself (as each array value will be stored "inline" with the array).

Now, suppose we had inheritance with value types. When combined with the above "inline storage" behavior of arrays, Bad Things happen, as can be seen in C++: http://www.parashift.com/c++-faq-lite/proper-inheritance.html#faq-21.4

Consider this pseudo-C# code:

struct Base
{
  public int A;
}

struct Derived : Base {
  public int B;
}

void Square(Base[] values)
{
  for (int i = 0; i < values.Length; ++i)
    values [i].A *= 2;
}

Derived[] v = new Derived[2];
Square (v);

By normal conversion rules, a Derived[] is convertible to a Base[] (for better or worse), so if you s/struct/class/g for the above example, it'll compile and run as expected, with no problems. But if Base and Derived are value types, and arrays store values inline, then we have a problem.

We have a problem because Square() doesn't know anything about Derived, it'll use only pointer arithmetic to access each element of the array, incrementing by a constant amount (sizeof(A)). The assembly would be vaguely like:

for (int i = 0; i < values.Length; ++i)
{
    A* value = (A*) (((char*) values) + i*sizeof(A));
    value->A *= 2;
}

(Yes, that's abominable assembly, but the point is that we'll increment through the array at known compile-time constants, without any knowledge that a derived type is being used.)

So, if this actually happened, we'd have memory corruption issues. Specifically, within Square(), values[1].A*=2 would actually be modifying values[0].B!

Try to debug THAT!

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The sensible solution to that problem would be to disallow the cast form Base[] to Detived[]. Just like casting from short[] to int[] is forbidden, although casting from short to int is possible. –  nikie Aug 3 '09 at 16:34
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+answer: the problem with inheritance didn't click with me until you put it in terms of arrays. Another user stated that this problem could be mitigated by "slicing" structs to the appropriate size, but I see slicing as being the cause of more problems than it solves. –  Juliet Aug 3 '09 at 16:50
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At least by preventing struct inheritance we have a separate keyword and can more easily say "structs are special", as opposed to having a "random" limitation in something that works for one set of things (classes) but not for another (structs). I imagine that the struct limitation is far easier to explain ("they're different!"). –  jonp Aug 3 '09 at 16:55
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@jonp: short to int doesn't require a cast. It's an implicit conversion. –  nikie Aug 3 '09 at 17:19
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You're right, that is terrible assembly. In fact, I think you'd need a C compiler to compile it ;) –  Richard Szalay Aug 3 '09 at 17:21

Imagine structs supported inheritance. Then declaring:

BaseStruct a;
InheritedStruct b; //inherits from BaseStruct, added fields, etc.

a = b; //?? expand size during assignment?

would mean struct variables don't have fixed size, and that is why we have reference types.

Even better, consider this:

BaseStruct[] baseArray = new BaseStruct[1000];

baseArray[500] = new InheritedStruct(); //?? morph/resize the array?
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3  
C++ answered this by introducing the concept of 'slicing', so that's a solvable problem. So, why shouldn't struct inheritance be supported? –  jonp Aug 3 '09 at 16:16
1  
Consider arrays of inheritable structs, and remember that C# is a (memory)managed language. Slicing or any similar option would wreak havoc on the fundamentals of the CLR. –  Kenan E. K. Aug 3 '09 at 16:33
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@jonp: Solvable, yes. Desirable? Here's a thought experiment: imagine if you have a base class Vector2D(x, y) and derived class Vector3D(x, y, z). Both classes have a Magnitude property which calculates sqrt(x^2 + y^2) and sqrt(x^2 + y^2 + z^2) respectively. If you write 'Vector3D a = Vector3D(5, 10, 15); Vector2D b = a;', what should 'a.Magnitude == b.Magnitude' return? If we then write 'a = (Vector3D)b', does a.Magnitude have the same value before the assignment as it does after? The .NET designers probably said to themselves, "no, we'll have none of that". –  Juliet Aug 3 '09 at 16:41
1  
Just because a problem can be solved, doesn't mean it should be solved. Sometimes it's just best to avoid situations where the problem arises. –  Dan Diplo Aug 3 '09 at 16:42
    
+1: A Short, elegant and right to the point answer. –  Saeb Amini Oct 8 '11 at 12:52

Structs do not use references (unless they are boxed, but you should try to avoid that) thus polymorphism isn't meaningful since there is no indirection via a reference pointer. Objects normally live on the heap and are referenced via reference pointers, but structs are allocated on the stack (unless they are boxed) or are allocated "inside" the memory occupied by a reference type on the heap.

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5  
one does not need to use polymorphism to take advantage of inheritance –  rmeador Aug 3 '09 at 15:36
    
So, you'd have how many different types of inheritance in .NET? –  John Saunders Aug 3 '09 at 15:50
    
Polymorphism does exist in structs, just consider the difference between calling ToString() when you implement it on a custom struct or when a custom implementation of ToString() does not exist. –  Kenan E. K. Aug 3 '09 at 16:00
    
That's because they all derive from System.Object. It's more the polymorphism of the System.Object type than of structs. –  John Saunders Aug 3 '09 at 16:07
    
Polymorphism could be meaningful with structures used as generic type parameters. Polymorphism works with structs that implement interfaces; the biggest problem with interfaces is that they can't expose byrefs to struct fields. Otherwise, the biggest thing I think would be helpful as far as "inheriting" structs would be a means of having a type (struct or class) Foo that has a field of structure type Bar be able to regard Bar's members as its own, so that a Point3d class could e.g. encapsulate a Point2d xy but refer to the X of that field as either xy.X or X. –  supercat Oct 1 '13 at 20:56

Here's what the docs say:

Structs are particularly useful for small data structures that have value semantics. Complex numbers, points in a coordinate system, or key-value pairs in a dictionary are all good examples of structs. Key to these data structures is that they have few data members, that they do not require use of inheritance or referential identity, and that they can be conveniently implemented using value semantics where assignment copies the value instead of the reference.

Basically, they're supposed to hold simple data and therefore do not have "extra features" such as inheritance. It would probably be technically possible for them to support some limited kind of inheritance (not polymorphism, due to them being on the stack), but I believe it is also a design choice to not support inheritance (as many other things in the .NET languages are.)

On the other hand, I agree with the benefits of inheritance, and I think we all have hit the point where we want our struct to inherit from another, and realize that it's not possible. But at that point, the data structure is probably so advanced that it should be a class anyway.

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4  
That is not the reason why there is no inheritance. –  Dykam Aug 3 '09 at 15:33
4  
Doesn't answer the question. –  Matt Howells Aug 3 '09 at 15:36
    
I believe the inheritance being talked about here is not being able to use two structs where one inherits from the other interchangeably, but re-using and adding to the implementation of one struct to another (i.e. creating a Point3D from a Point2D; you would not be able to use a Point3D instead of a Point2D, but you wouldn't have to reimplement the Point3D entirely from scratch.) That's how I interpreted it anyways... –  Blixt Aug 3 '09 at 15:42
    
In short: it could support inheritance without polymorphism. It doesn't. I believe it's a design choice to help a person choose class over struct when appropriate. –  Blixt Aug 3 '09 at 15:49

Class like inheritance is not possible, as a struct is laid directly on the stack. An inheriting struct would be bigger then it parent, but the JIT doesn't know so, and tries to put too much on too less space. Sounds a little unclear, let's write a example:

struct A {
    int property;
} // sizeof A == sizeof int

struct B : A {
    int childproperty;
} // sizeof B == sizeof int * 2

If this would be possible, it would crash on the following snippet:

void DoSomething(A arg){};

...

B b;
DoSomething(b);

Space is allocated for the sizeof A, not for the sizeof B.

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1  
C++ handles this case just fine, IIRC. The instance of B is sliced to fit in the size of an A. If it's a pure data type, as .NET structs are, then nothing bad will happen. You do run into a bit of a problem with a method that returns an A and you're storing that return value in a B, but that shouldn't be allowed. In short, the .NET designers could have dealt with this if they wanted to, but they didn't for some reason. –  rmeador Aug 3 '09 at 15:44
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For your DoSomething(), there isn't likely to be a problem as (assuming C++ semantics) 'b' would be "sliced" to create an A instance. The problem is with <i>arrays</i>. Consider your existing A and B structs, and a <c>DoSomething(A[] arg){arg[1].property = 1;}</c> method. Since arrays of value types store the values "inline", DoSomething(actual = new B[2]{}) will cause actual[0].childproperty to be set, not actual[1].property. This is bad. –  jonp Aug 3 '09 at 15:47
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@John: I wasn't asserting it was, and I don't think @jonp was either. We were merely mentioning that this problem is old and has been solved, so the .NET designers chose not to support it for some reason other than technical infeasibility. –  rmeador Aug 3 '09 at 15:51
    
It should be noted that the "arrays of derived types" issue isn't new to C++; see parashift.com/c++-faq-lite/proper-inheritance.html#faq-21.4 (Arrays in C++ are evil! ;-) –  jonp Aug 3 '09 at 15:52
    
@John: the solution to "arrays of derived types and base types don't mix" problem is, as usual, Don't Do That. Which is why arrays in C++ are evil (more easily permits memory corruption), and why .NET doesn't support inheritance with value types (compiler and JIT ensure that it can't happen). –  jonp Aug 3 '09 at 15:54

This seems like a very frequent question. I feel like adding that value types are stored "in place" where you declare the variable; apart from implementation details, this means that there is no object header that says something about the object, only the variable knows what kind of data resides there.

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The compiler knows what's there. Referencing C++ this cannot be the answer. –  Henk Holterman Aug 3 '09 at 15:56
    
Where did you infer C++ from? I'd go with saying in-place because that's what matches the behaviour the best, the stack is an implementation detail, to quote an MSDN blog article. –  Cecil Has a Name Aug 3 '09 at 19:57
    
Yes, mentioning C++ was bad, just my train of thought. But aside from the question if runtime info is needed, why shouldn't structs have an 'object header' ? The compiler can mash them up anyway it likes. It could even hide a header on a [Structlayout] struct. –  Henk Holterman Aug 3 '09 at 20:40
    
Because structs are value types, it is not necessary with an object header because the run-time always copies the content as for other value types (a constraint). It wouldn't make sense with a header, because that's what reference-type classes are for :P –  Cecil Has a Name Aug 4 '09 at 6:22

Structs are allocated on the stack. This means the value semantics are pretty much free, and accessing struct members is very cheap. This doesn't prevent polymorphism.

You could have each struct start with a pointer to its virtual function table. This would be a performance issue (every struct would be at least the size of a pointer), but it's doable. This would allow virtual functions.

What about adding fields?

Well, when you allocate a struct on the stack, you allocate a certain amount of space. The required space is determined at compile time (whether ahead of time or when JITting). If you add fields and then assign to a base type:

struct A
{
    public int Integer1;
}

struct B : A
{
    public int Integer2;
}

A a = new B();

This will overwrite some unknown part of the stack.

The alternative is for the runtime to prevent this by only writing sizeof(A) bytes to any A variable.

What happens if B overrides a method in A and references its Integer2 field? Either the runtime throws a MemberAccessException, or the method instead accesses some random data on the stack. Neither of these is permissible.

It's perfectly safe to have struct inheritance, so long as you don't use structs polymorphically, or so long as you don't add fields when inheriting. But these aren't terribly useful.

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Isn't this pretty much what has already been said? -1. –  John Saunders Aug 3 '09 at 22:27
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Almost. Nobody else mentioned the slicing problem in reference to the stack, only in reference to arrays. And nobody else mentioned the available solutions. –  user38001 Aug 3 '09 at 22:29
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All value types in .net are zero-filled on creastion, regardless of their type or what fields they contain. Adding something like a vtable pointer to a struct would require a means of initializing types with non-zero default values. Such a feature might be useful for a variety of purposes, and implementing such a thing for most cases might not be too hard, but nothing close exists in .net. –  supercat May 14 '12 at 14:36

There is a point I would like to correct. Even though the reason structs cannot be inherited is because they live on the stack is the right one, it is at the same a half correct explanation. Structs, like any other value type can live in the stack. Because it will depend on where the variable is declared they will either live in the stack or in the heap. This will be when they are local variables or instance fields respectively.

In saying that, Cecil Has a Name nailed it correctly.

I would like to emphasize this, value types can live on the stack. This doesn't mean they always do so. Local variables, including method parameters, will. All others will not. Nevertheless, it still remains the reason they can't be inherited. :-)

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Structs do support interfaces, so you can do some polymorphic things that way.

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IL is a stack-based language, so calling a method with an argument goes something like this:

  1. Push the argument onto the stack
  2. Call the method.

When the method runs, it pops some bytes off the stack to get its argument. It knows exactly how many bytes to pop off because the argument is either a reference type pointer (always 4 bytes on 32-bit) or it is a value type for which the size is always known exactly.

If it is a reference type pointer then the method looks up the object in the heap and gets its type handle, which points to a method table which handles that particular method for that exact type. If it is a value type, then no lookup to a method table is necessary because value types do not support inheritance, so there is only one possible method/type combination.

If value types supported inheritance then there would be extra overhead in that the particular type of the struct would have to placed on the stack as well as its value, which would mean some sort of method table lookup for the particular concrete instance of the type. This would eliminate the speed and efficiency advantages of value types.

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1  
C++ has solved that, read this answer for the real problem: stackoverflow.com/questions/1222935/… –  Dykam Aug 3 '09 at 16:21

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