This FAQ is about Aggregates and PODs and covers the following material:
- What are Aggregates?
- What are PODs (Plain Old Data)?
- How are they related?
- How and why are they special?
- What changes for C++11?
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How to read:
This article is rather long. If you want to know about both aggregates and POD's (Plain Old Data) take time and read it. If you are interested just in aggregates, read only the first part. If you are interested only in POD's then you must first read the definition, implications, and examples of aggregates and then you may jump to POD's but I would still recommend reading the first part in its entirety. The notion of aggregates is essential for defining POD's. If you find any errors (even minor, including grammar, stylistics, formatting, syntax, etc.) please leave a comment, I'll edit.
What are aggregates and why they are special
Formal definition from the C++ standard (C++03 8.5.1 §1):
So, OK, let's parse this definition. First of all, any array is an aggregate. A class can also be an aggrgate if... wait! nothing is said about structs or unions, can't they be aggregates? Yes, they can. In C++ the term
Now it's time to take a look at some examples:
You get the idea. Now it's time to see how aggregates are special. They, unlike non-aggregate classes, can be initialized with curly braces
if(m == n)
When an object of scalar type (
Examples of array initialization:
Now let's see how aggregate classes can be initialized with braces. Pretty much the same way. Instead of the array elements we will initialize the non-static data members in the order of their appearance in the class definition (they are all public by definition). If there are fewer initializers than members, the rest are value-initialized. If it is impossible to value-initialize one of the members which were not explicitly initialized, we get a compile-time error. If there are more initializers than necessary, we get a compile-time error as well.
In the above example y.c is initialized with 'a', y.x.i1 with 10, y.x.i2 with 20, y.i with 20, y.i with 30 and y.f is value-initialized, that is, initialized with 0.0. The protected static member d is not initialized at all, because it is static.
Aggregate unions are different in that you may initialize only their first member with braces. I think that if you are advanced enough in C++ to even consider using unions (their use may be very dangerous and must be thought of carefully), you could look up the rules for unions in the standard yourself :).
Now that we know what's special about aggregates let's try to understand the restrictions on classes, that is, why they are there. We should understand that memberwise initialization with braces implies that the class is nothing more than the sum of its members. If a user-defined constructor is present, it means that the user needs to do some extra work to initialize the members therefore brace initialization would be incorrect. If virtual functions are present, it means that the class has (on most implementations) a pointer to the so-called vtable of the class, which is set in the constructor, so brace-initialization would be insufficient. You could figure out the rest of the restrictions in a similar manner as an exercise
So much about the aggregates. Now we can define a stricter set of types, to wit, POD's
What are POD's and why they are special
Formal definition from the C++ standard (C++03 9 §4):
Wow, this one's tougher to parse, isn't it? :) Let's leave unions out (on the same grounds as above) and rephrase in a bit clearer way
What does this definition imply? (did I mention POD stands for Plain Old Data ?:)
POD-classes, POD-unions, scalar types, and arrays of such types are collectively called POD-types.
The list goes on and on...
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What changes for C++11?
The standard definition of an aggregate has changed slightly, but it's still pretty much the same:
Ok, what changed?
So, what is an aggregate didn't change much at all. It's still the same basic idea, adapted to the new features.
What about PODs?
PODs went through a lot of changes. Lots of previous rules about PODs were relaxed in this new standard, and the way the definition is provided in the standard was radically changed.
The idea of a POD is to capture basically two distinct properties:
Because of this, the definition has been split into two distinct concepts: trivial classes and standard-layout classes, because these are more useful than POD. The standard now rarely uses the term POD, preferring the more specific trivial and standard-layout concepts.
The new definition basically says that a POD is a class that is both trivial and has standard-layout, and this property must hold recursively for all non-static data members:
Let's go over each of these two properties in detail separately.
Trivial is the first property mentioned above: trivial classes support static initialization.
If a class is trivially copyable (a superset of trivial classes), it is ok to copy its representation over the place with things like
The standard defines a trivial class as follows:
So, what are all those trivial and non-trivial things?
Basically this means that a copy or move constructor is trivial if it is not user-provided, the class has nothing virtual in it, and this property holds recursively for all the members of the class and for the base class.
The definition of a trivial copy/move assignment operator is very similar, simply replacing the word "constructor" with "assignment operator".
A trivial destructor also has a similar definition, with the added constraint that it can't be virtual.
And yet another similar rule exists for trivial default constructors, with the addition that a default constructor is not-trivial if the class has non-static data members with brace-or-equal-initializers, which we've seen above.
Here are some examples to clear everything up:
Standard-layout is the second property. The standard mentions that these are useful for communicating with other languages, and that's because a standard-layout class has the same memory layout of the equivalent C struct or union.
This is another property that must hold recursively for members and all base classes. And as usual, no virtual functions or virtual base classes are allowed. That would make the layout incompatible with C.
A relaxed rule here is that standard-layout classes must have all non-static data members with the same access control. Previously these had to be all public, but now you can make them private or protected, as long as they are all private or all protected.
When using inheritance, only one class in the whole inheritance tree can have non-static data members, and the first non-static data member cannot be of a base class type (this could break aliasing rules), otherwise, it's not a standard-layout class.
This is how the definition goes in the standard text:
And let's see a few examples.
With these new rules a lot more types can be PODs now. And even if a type is not POD, we can take advantage of some of the POD properties separately (if it is only one of trivial or standard-layout).
The standard library has traits to test these properties in the header
That's simple: all non-static data members must all be
The reasoning for them goes to the reasoning for having a distinction between "standard layout" and "not standard layout" at all. Namely, to give the compiler the freedom to choose how to put things into memory. It's not just about vtable pointers.
Back when they standardized C++ in 98, they had to basically predict how people would implement it. While they had quite a bit of implementation experience with various flavors of C++, they weren't certain about things. So they decided to be cautious: give the compilers as much freedom as possible.
That's why the definition of POD in C++98 is so strict. It gave C++ compilers great latitude on member layout for most classes. Basically, POD types were intended to be special cases, something you specifically wrote for a reason.
When C++11 was being worked on, they had a lot more experience with compilers. And they realized that... C++ compiler writers are really lazy. They had all this freedom, but they didn't do anything with it.
The rules of standard layout are more or less codifying common practice: most compilers didn't really have to change much if anything at all to implement them (outside of maybe some stuff for the corresponding type traits).
Now, when it came to
Then there's the fact that it doesn't really hurt the user. If you're making an encapsulated class, odds are good that all of your data members will be
So it's no big loss.
The reason for this one comes back to why they standardized standard layout again: common practice.
There's no common practice when it comes to having two members of an inheritance tree that actually store things. Some put the base class before the derived, others do it the other way. Which way do you order the members if they come from two base classes? And so on. Compilers diverge greatly on these questions.
Also, thanks to the zero/one/infinity rule, once you say you can have two classes with members, you can say as many as you want. This requires adding a lot of layout rules for how to handle this. You have to say how multiple inheritance works, which classes put their data before other classes, etc. That's a lot of rules, for very little material gain.
You can't make everything that doesn't have virtual functions and a default constructor standard layout.
I can't really speak to this one. I'm not educated enough in C++'s aliasing rules to really understand it. But it has something to do with the fact that the base member will share the same address as the base class itself. That is:
And that's probably against C++'s aliasing rules. In some way.
However, consider this: how useful could having the ability to do this ever actually be? Since only one class can have non-static data members, then
So again: no big loss.