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Can someone tell me when are literal classes needed in C++?
I am getting a little confused from constexpr constructors, constexpr members, and I can't see what the point is. I'd like to see some practical use of it.

Also I'd want to know if a set member function needs to be constexpr, i.e.:

constexpr void set_num(int a) { num = a; }
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You can't modify a compile-time object. –  Vaughn Cato Jan 13 '13 at 20:52
@VaughnCato I'd like to know which part of my question are you referring to. Thanks –  TGO Jan 13 '13 at 20:54
It appeared that your set_num member was trying to modify a member of a class. If set_num is declared constexpr, then the object can't be modified, so your assignment wouldn't be valid. –  Vaughn Cato Jan 13 '13 at 20:58
I haven't come across a particular case where I would use constexpr instances of classes, but I don't use constexprs much anyway. In principle, you would create a class when you want to group several related constexpr values and functions together. –  Vaughn Cato Jan 13 '13 at 21:20
@VaughnCato, you're right that a constexpr member function can't modify the object, but that's like any other const member function, not because the object is a "compile-time object". You can have mutable objects of literal types. –  Jonathan Wakely Jan 14 '13 at 0:36

3 Answers 3

up vote 6 down vote accepted

In C++03 this object has dynamic initialization

struct Data {
  int i;
  int j;
Data init_data();  // calculate something
const Data data = init_data();

i.e. when the program starts, before main runs, the function will be called and the object gets initialized.

In C++11 the object can have constant initialization, a form of static initialization, meaning that its value is set at compile-time and it's initialized before the program begins. This is useful to avoid the static initialization order fiasco among other things. To ensure the type gets constant initialization it must be initialized by a constant expression, so must have a constexpr constructor and any functions called in the full expression must be constexpr functions.

The type Data is trivial so its implicitly-declared constructors are constexpr constructors, so to make the global data undergo constant initialization we just need to make init_data() be a constexpr function:

struct Data {
  int i;
  int j;
constexpr Data init_data();  // calculate something
constexpr Data data = init_data();

The advantage of a literal type is that such types can be used in other constant expressions i.e. in contexts that require compile-time constants. So now that we have our data object as a compile-time constant, we can use it in other constant expressions e.g. to initialize other compile-time constants:

const int i = ::data.i;

And we can use the Data type for a static data member with an in-class initializer:

struct MoreData {
  static constexpr Data zerozero = Data{};  // OK, Data is a literal type

If Data wasn't a literal type we would have to write:

struct MoreData {
  static const Data zerozero;

// in moredata.cc
const Data MoreData::zerozero = Data{};

And then code which only sees the header doesn't know the value of MoreData::zerozero and can't use it in compile-time optimisations.

So the advantage of the "literal type" rules is that they allow you to define new class types that can be used in constant expressions. In C++03 only very few types, such as integers, could be used in constant expressions, e.g. integer literals such as 1 or 0x23 or compile-time constants of integer type. In C++11 you can write you own types which can have moderately complicated logic in their constructors (anything that can be expressed in a constexpr function) but can still be used as a compile-time constant.

Also I'd want to know if a set member function needs to be constexpr, i.e.

A constexpr member function is a special case of a const member function, so it can't modify (non-mutable) members of the type. A setter function, which modifies the object, can't be const.

To be a literal type a class must follow some rules including having at least one constexpr constructor. That doesn't mean all objects of that type must be constexpr constants, it just means that objects of that type can be constexpr constants if they are declared as such and are initialized using one of the class' constexpr constructors. To use the Data example again, most objects in your program would not be constants:

Data d = { 0, 1 };
d.i = d.i + 5;

So if you added a setter, a function which modifies the object, then it would only make sense to use it on non-const objects of that type, and like any other functions which modifies the type it should not be

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Perfect! Very concise and clear. Thank you! –  TGO Jan 15 '13 at 21:41

constexpr fixes a problem in C++98 when using numeric limits. Before C++11 an expression such as


can not be used as integral constant, although it is almost equal to macro INT_MAX. with C++11, such an expression is declared as constexpr so that, for example, you can use it to declare arrays or in compile-time computations (metaprogramming):

std::array<float,std::numeric_limits<short>::max()> a;
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While indeed constexpr in everyday use makes the most sense for such constant return functions, this is of course only half the truth about constexpr and its usage and implications (and only half an answer to the actual question). –  Christian Rau Jan 14 '13 at 11:57

A big advantage of constexpr classes is that they may be put into .ro data which can lead to executable size reductions and performance boosts. Esp. for geometric types e.g. or similar 'simple' types this is very neat as you could also get rid of "magic" numbers. See e.g. https://www.kdab.com/kdab-contributions-to-qt-5-0-part-4/.

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