______________________________________________________________________

  9   Classes                                          [class]

  ______________________________________________________________________

1 A class is a type.   Its  name  becomes  a  class-name  (_class.name_)
  within its scope.
          class-name:
                  identifier
                  template-id
  Class-specifiers  and elaborated-type-specifiers (_dcl.type.elab_) are
  used to make class-names.  An object of a class consists of a  (possi­
  bly empty) sequence of members and base class objects.
          class-specifier:
                  class-head { member-specificationopt }
          class-head:
                  class-key identifieropt base-clauseopt
                  class-key nested-name-specifier identifier base-clauseopt
          class-key:
                  class
                  struct
                  union

2 A  class-name is inserted into the scope in which it is declared imme­
  diately after the class-name is seen.  The class-name is also inserted
  into  the scope of the class itself.  For purposes of access checking,
  the inserted class name is treated as if it were a public member name.
  A  class-specifier  is  commonly referred to as a class definition.  A
  class is considered defined after the  closing  brace  of  its  class-
  specifier  has  been seen even though its member functions are in gen­
  eral not yet defined.

3 A class with an empty sequence of members and base class objects is an
  empty class.  Complete objects and member subobjects of an empty class
  type  shall have nonzero size.1) [Note: class objects can be assigned,
  passed as arguments to functions, and returned  by  functions  (except
  objects  of  classes  for  which  copying  has  been  restricted;  see
  _class.copy_).  Other plausible operators, such as  equality  compari­
  son, can be defined by the user; see _over.oper_.  ]

4 A  structure is a class defined with the class-key struct; its members
  and   base   classes   (_class.derived_)   are   public   by   default
  (_class.access_).   A  union  is  a  class  defined with the class-key
  union; its members are public by default and it holds  only  one  data
  _________________________
  1) That is, a base class subobject of an empty class type may have ze­
  ro size.

  member at a time (_class.union_).  [Note: aggregates of class type are
  described in _dcl.init.aggr_.  ] A POD-struct2) is an aggregate  class
  that  has  no  non-static data members of type pointer to member, non-
  POD-struct, non-POD-union (or array of such types) or  reference,  and
  has  no  user-defined  copy  assignment  operator  and no user-defined
  destructor.  Similarly, a POD-union is an aggregate union that has  no
  non-static  data  members  of  type pointer to member, non-POD-struct,
  non-POD-union (or array of such types) or reference, and has no  user-
  defined copy assignment operator and no user-defined destructor.

  9.1  Class names                                          [class.name]

1 A class definition introduces a new type.  [Example:
          struct X { int a; };
          struct Y { int a; };
          X a1;
          Y a2;
          int a3;
  declares three variables of three different types.  This implies that
          a1 = a2;        // error: Y assigned to X
          a1 = a3;        // error: int assigned to X
  are type mismatches, and that
          int f(X);
          int f(Y);
  declare  an  overloaded  (_over_) function f() and not simply a single
  function f() twice.  For the same reason,
          struct S { int a; };
          struct S { int a; };  // error, double definition
  is ill-formed because it defines S twice.  ]

2 A class definition introduces the class name into the scope  where  it
  is defined and hides any class, object, function, or other declaration
  of that name in an enclosing scope (_basic.scope_).  If a  class  name
  is declared in a scope where an object, function, or enumerator of the
  same name is also declared, then when both declarations are in  scope,
  the  class  can be referred to only using an elaborated-type-specifier
  (_basic.lookup.elab_).  [Example:
          struct stat {
              // ...
          };
          stat gstat;             // use plain `stat' to
                                  // define variable

          int stat(struct stat*); // redeclare `stat' as function

  _________________________
  2) The acronym POD stands for "plain ol' data."

          void f()
          {
              struct stat* ps;    // `struct' prefix needed
                                  // to name struct stat
              // ...
              stat(ps);           // call stat()
              // ...
          }
     --end    example]    A    declaration    consisting    solely    of
  class-key identifier ;  is  either  a redeclaration of the name in the
  current scope or a forward declaration of the identifier  as  a  class
  name.  It introduces the class name into the current scope.  [Example:
          struct s { int a; };

          void g()
          {
              struct s;               // hide global struct `s'
                                      //  with a local declaration
              s* p;                   // refer to local struct `s'
              struct s { char* p; };  // define local struct `s'
              struct s;               // redeclaration, has no effect
          }
   --end example] [Note: Such declarations allow definition  of  classes
  that refer to each other.  [Example:
          class Vector;

          class Matrix {
              // ...
              friend Vector operator*(Matrix&, Vector&);
          };
          class Vector {
              // ...
              friend Vector operator*(Matrix&, Vector&);
          };
  Declaration  of friends is described in _class.friend_, operator func­
  tions in _over.oper_.  ] ]

3 An elaborated-type-specifier (_dcl.type.elab_) can also be used in the
  declarations of objects and functions.  It differs from a class decla­
  ration in that if a class of the elaborated name is in scope the elab­
  orated name will refer to it.  [Example:
          struct s { int a; };

          void g(int s)
          {
              struct s* p = new struct s;    // global `s'
              p->a = s;                      // local `s'
          }
   --end example]

4 [Note:  The declaration of a class name takes effect immediately after
  the identifier is seen in the  class  definition  or  elaborated-type-
  specifier.  For example,
          class A * A;

  first  specifies  A to be the name of a class and then redefines it as
  the name of a pointer to an object of that class.  This means that the
  elaborated  form  class  A  must  be used to refer to the class.  Such
  artistry with names can be confusing and is best avoided.  ]

5 A typedef-name (_dcl.typedef_) that names a class is a class-name, but
  shall   not   be   used  in  an  elaborated-type-specifier;  see  also
  _dcl.typedef_.

  9.2  Class members                                         [class.mem]
          member-specification:
                  member-declaration member-specificationopt
                  access-specifier : member-specificationopt
          member-declaration:
                  decl-specifier-seqopt member-declarator-listopt ;
                  function-definition ;opt
                  qualified-id ;
                  using-declaration
          member-declarator-list:
                  member-declarator
                  member-declarator-list , member-declarator
          member-declarator:
                  declarator pure-specifieropt
                  declarator constant-initializeropt
                  identifieropt : constant-expression
          pure-specifier:
                   = 0
          constant-initializer:
                   = constant-expression

1 The member-specification in a class definition declares the  full  set
  of members of the class; no member can be added elsewhere.  Members of
  a class are data  members,  member  functions  (_class.mfct_),  nested
  types,  and enumerators.  Data members and member functions are static
  or  nonstatic;  see  _class.static_.    Nested   types   are   classes
  (_class.name_,  _class.nest_) and enumerations (_dcl.enum_) defined in
  the class, and arbitrary types declared as members by use of a typedef
  declaration   (_dcl.typedef_).   The  enumerators  of  an  enumeration
  (_dcl.enum_) defined in the class are member  of  the  class.   Except
  when  used to declare friends (_class.friend_) or to adjust the access
  to a member of a base class (_class.access.dcl_),  member-declarations
  declare  members  of the class, and each such member-declaration shall
  declare at least one member name of the class.  A member shall not  be
  declared twice in the member-specification, except that a nested class
  can be declared and then later defined.

2 A class is considered a completely-defined object type (_basic.types_)
  (or  complete  type)  at the closing } of the class-specifier.  Within
  the class member-specification, the  class  is  regarded  as  complete
  within  function  bodies,  default  arguments  and  constructor  ctor-
  initializers (including such things in nested classes).  Otherwise  it
  is regarded as incomplete within its own class member-specification.

3 [Note:  a  single  name  can  denote several function members provided
  their types are sufficiently different (_over_).  ]

4 A member-declarator can contain  a  constant-initializer  only  if  it
  declares  a  static member (_class.static_) of integral or enumeration
  type, see _class.static.data_.

5 A member can be initialized using  a  constructor;  see  _class.ctor_.
  [Note:  see  clause  _special_  for  a description of constructors and
  other special member functions.  ]

6 A member shall not be auto, extern, or register.

7 The decl-specifier-seq can be omitted in constructor, destructor,  and
  conversion function declarations only.  The member-declarator-list can
  be omitted only after a class-specifier, an enum-specifier, or a decl-
  specifier-seq  of  the form friend elaborated-type-specifier.  A pure-
  specifier shall be used only in the declaration of a virtual  function
  (_class.virtual_).

8 Non-static  (_class.static_)  members  that are class objects shall be
  objects of previously defined classes.   In  particular,  a  class  cl
  shall  not contain an object of class cl, but it can contain a pointer
  or reference to an object of class cl.  When an array is used  as  the
  type of a nonstatic member all dimensions shall be specified.

9 Except  when  used to form a pointer to member (_expr.unary.op_), when
  used in the body of a nonstatic member function of its class or  of  a
  class derived from its class (_class.mfct.nonstatic_), or when used in
  a mem-initializer for a constructor for  its  class  or  for  a  class
  derived  from its class (_class.base.init_), a nonstatic data or func­
  tion member of a class shall only be referred to with the class member
  access syntax (_expr.ref_).

10[Note: the type of a nonstatic member function is an ordinary function
  type, and the type of a nonstatic data member is  an  ordinary  object
  type.   There  are  no  special  member  function types or data member
  types.  ]

11[Example: A simple example of a class definition is
          struct tnode {
              char tword[20];
              int count;
              tnode *left;
              tnode *right;
          };
  which contains an array of twenty  characters,  an  integer,  and  two
  pointers  to similar structures.  Once this definition has been given,
  the declaration
          tnode s, *sp;
  declares s to be a tnode and sp to be a  pointer  to  a  tnode.   With
  these declarations, sp->count refers to the count member of the struc­
  ture to which sp points; s.left refers to the left subtree pointer  of
  the structure s; and s.right->tword[0] refers to the initial character

  of the tword member of the right subtree of s.  ]

12Nonstatic data members of a  (non-union)  class  declared  without  an
  intervening  access-specifier are allocated so that later members have
  higher addresses within a class object.  The order  of  allocation  of
  nonstatic data members separated by an access-specifier is unspecified
  (_class.access.spec_).  Implementation  alignment  requirements  might
  cause  two adjacent members not to be allocated immediately after each
  other; so might requirements for space for managing virtual  functions
  (_class.virtual_) and virtual base classes (_class.mi_).

13If  T  is the name of a class, then each of the following shall have a
  name different from T:

  --every static data member of class T;

  --every member of class T that is itself a type;

  --every enumerator of every member of class T that  is  an  enumerated
    type; and

  --every member of every anonymous union that is a member of class T.

14Two  POD-struct (_class_) types are layout-compatible if they have the
  same number of members, and corresponding members (in order) have lay­
  out-compatible types (_basic.types_).

15Two  POD-union  (_class_) types are layout-compatible if they have the
  same number of members, and corresponding members (in any order)  have
  layout-compatible types (_basic.types_).

  +-------                 BEGIN BOX 1                -------+
  Shouldn't this be the same set of types?
  +-------                  END BOX 1                 -------+

16If  a  POD-union  contains two or more POD-structs that share a common
  initial sequence, and if the POD-union object currently  contains  one
  of  these  POD-structs,  it is permitted to inspect the common initial
  part of any of them.  Two POD-structs share a common initial  sequence
  if  corresponding  members have layout-compatible types (and, for bit-
  fields, the same widths) for a sequence of one or  more  initial  mem­
  bers.

17A  pointer  to  a POD-struct object, suitably converted, points to its
  initial member (or if that member is a bit-field, then to the unit  in
  which  it  resides)  and  vice versa.  [Note: There might therefore be
  unnamed padding within a POD-struct object, but not at its  beginning,
  as necessary to achieve appropriate alignment.  ]

  9.3  Member functions                                     [class.mfct]

1 Functions  declared  in  the  definition  of  a class, excluding those
  declared with a friend specifier (_class.friend_), are  called  member
  functions  of that class.  A member function may be declared static in
  which  case  it  is  a   static   member   function   of   its   class
  (_class.static_);  otherwise  it is a nonstatic member function of its
  class (_class.mfct.nonstatic_, _class.this_).

2 A member function may be defined (_dcl.fct.def_) in its class  defini­
  tion,  in which case it is an inline member function (_dcl.fct.spec_),
  or it may be defined outside of its class definition if it has already
  been declared but not defined in its class definition.  A member func­
  tion definition that appears outside of  the  class  definition  shall
  appear  in  a  namespace scope enclosing the class definition.  Except
  for member function definitions that appear outside of a class defini­
  tion, and except for explicit specializations of template member func­
  tions (_temp.spec_) appearing outside of the class definition, a  mem­
  ber function shall not be redeclared.

3 An  inline  member  function (whether static or nonstatic) may also be
  defined outside of its class definition provided either  its  declara­
  tion  in  the  class definition or its definition outside of the class
  definition declares the function as inline.  [Note:  member  functions
  of a class in namespace scope have external linkage.  Member functions
  of a local class (_class.local_) have no linkage.   See  _basic.link_.
  ]

4 There  shall be at most one definition of a non-inline member function
  in a program; no diagnostic is required.  There may be more  than  one
  inline  member  function definition in a program.  See _basic.def.odr_
  and _dcl.fct.spec_.

5 If the definition of a member function is lexically outside its  class
  definition,  the  member function name shall be qualified by its class
  name using the :: operator.  [Note: a name used in a  member  function
  definition (that is, in the parameter-declaration-clause including the
  default arguments (_dcl.fct.default_), or in the member function body,
  or,  for  a  constructor function (_class.ctor_), in a mem-initializer
  expression  (_class.base.init_))  is  looked  up   as   described   in
  _basic.lookup_.  ] [Example:
          struct X {
                  typedef int T;
                  static T count;
                  void f(T);
          };
          void X::f(T t = count) { }
  The member function f of class X is defined in global scope; the nota­
  tion X::f specifies that the function f is a member of class X and  in
  the  scope of class X.  In the function definition, the parameter type
  T refers to the typedef member T declared in class X and  the  default
  argument  count  refers  to  the  static data member count declared in
  class X.  ]

6 A static local variable in a member function always refers to the same
  object, whether or not the member function is inline.

7 Member  functions  may be mentioned in friend declarations after their
  class has been defined.

8 Member functions of a local class shall be  defined  inline  in  their
  class definition, if they are defined at all.

9 [Note:  a  member  function  can be declared (but not defined) using a
  typedef for a  function  type.   The  resulting  member  function  has
  exactly the same type as it would have if the function declarator were
  provided explicitly, see _dcl.fct_.  For example,
          typedef void fv(void);
          typedef void fvc(void) const;
          struct S {
                  fv memfunc1;  // equivalent to: void memfunc1(void);
                  void memfunc2();
                  fvc memfunc3; // equivalent to: void memfunc3(void) const;
          };
          fv  S::* pmfv1 = &S::memfunc1;
          fv  S::* pmfv2 = &S::memfunc2;
          fvc S::* pmfv3 = &S::memfunc3;
  Also see _temp.arg_.  ]

  9.3.1  Nonstatic member functions               [class.mfct.nonstatic]

1 A nonstatic member function may be called for an object of  its  class
  type,  or  for an object of a class derived (_class.derived_) from its
  class  type,  using  the  class  member  access  syntax   (_expr.ref_,
  _over.match.call_).   A  nonstatic  member function may also be called
  directly   using    the    function    call    syntax    (_expr.call_,
  _over.match.call_)

  --from within the body of a member function of its class or of a class
    derived from its class, or

  --from a mem-initializer (_class.base.init_) for a constructor for its
    class or for a class derived from its class.

  If  a  nonstatic  member function of a class X is called for an object
  that is not of type X, or of a type derived from X,  the  behavior  is
  undefined.

2 When an id-expression (_expr.prim_) that is not part of a class member
  access syntax (_expr.ref_) and not used to form a  pointer  to  member
  (_expr.unary.op_)  is  used in the body of a nonstatic member function
  of class X or used in the mem-initializer for a constructor  of  class
  X, if name lookup (_basic.lookup.unqual_) resolves the name in the id-
  expression to a nonstatic nontype member of class X or of a base class
  of  X,  the  id-expression  is  transformed into a class member access
  expression (_expr.ref_) using (*this) (_class.this_) as  the  postfix-
  expression  to  the  left  of  the  .  operator.  The member name then
  refers to the member of the object for which the function  is  called.

  Similarly  during  name  lookup,  when an unqualified-id (_expr.prim_)
  used in the definition of a member function for class X resolves to  a
  static  member, an enumerator or a nested type of class X or of a base
  class of X, the unqualified-id  is  transformed  into  a  qualified-id
  (_expr.prim_)  in  which  the nested-name-specifier names the class of
  the member function.  [Example:
          struct tnode {
                  char tword[20];
                  int count;
                  tnode *left;
                  tnode *right;
                  void set(char*, tnode* l, tnode* r);
          };
          void tnode::set(char* w, tnode* l, tnode* r)
          {
                  count = strlen(w)+1;
                  if (sizeof(tword)<=count)
                          perror("tnode string too long");
                  strcpy(tword,w);
                  left = l;
                  right = r;
          }
          void f(tnode n1, tnode n2)
          {
                  n1.set("abc",&n2,0);
                  n2.set("def",0,0);
          }
  In the body of the member function tnode::set, the member names tword,
  count,  left,  and  right refer to members of the object for which the
  function is called.  Thus,  in  the  call  n1.set("abc",&n2,0),  tword
  refers  to  n1.tword,  and in the call n2.set("def",0,0), it refers to
  n2.tword.  The functions strlen, error, and strcpy are not members  of
  the class tnode and should be declared elsewhere.3) ]

3 A  nonstatic member function may be declared const, volatile, or const
  volatile.  These cv-qualifiers affect the type  of  the  this  pointer
  (_class.this_).  They also affect the function type (_dcl.fct_) of the
  member function; a member function declared const is  a  const  member
  function,  a  member  function  declared volatile is a volatile member
  function and a member function declared  const  volatile  is  a  const
  volatile member function.  [Example:
          struct X {
                  void g() const;
                  void h() const volatile;
          };
  X::g  is  a  const member function and X::h is a const volatile member
  function.  ]

4 A nonstatic member function may be declared virtual  (_class.virtual_)
  or pure virtual (_class.abstract_).
  _________________________
  3) See, for example, <cstring> (_lib.c.strings_).

  9.3.2  The this pointer                                   [class.this]

1 In the body of a nonstatic (_class.mfct_) member function, the keyword
  this is a non-lvalue expression whose value  is  the  address  of  the
  object for which the function is called.  The type of this in a member
  function of a class X is X*.   If  the  member  function  is  declared
  const,  the  type  of  this  is  const  X*,  if the member function is
  declared volatile, the type of this is volatile X*, and if the  member
  function  is  declared  const  volatile,  the  type  of  this is const
  volatile X*.

2 In a const member function, the  object  for  which  the  function  is
  called  is  accessed  through  a const access path; therefore, a const
  member function shall not modify the object and  its  non-static  data
  members.  [Example:
          struct s {
              int a;
              int f() const;
              int g() { return a++; }
              int h() const { return a++; } // error
          };

          int s::f() const { return a; }
  The  a++  in the body of s::h is ill-formed because it tries to modify
  (a part of) the object for  which  s::h()  is  called.   This  is  not
  allowed in a const member function because this is a pointer to const;
  that is, *this has const type.  ]

3 Similarly, volatile semantics (_dcl.type.cv_) apply in volatile member
  functions when accessing the object and its non-static data members.

4 A  cv-qualified  member function can be called on an object-expression
  (_expr.ref_) only if the object-expression is as cv-qualified or less-
  cv-qualified than the member function.  [Example:
          void k(s& x, const s& y)
          {
              x.f();
              x.g();
              y.f();
              y.g();      // error
          }
  The  call  y.g() is ill-formed because y is const and s::g() is a non-
  const member function, that is,  s::g()  is  less-qualified  than  the
  object-expression y.  ]

5 Constructors  (_class.ctor_)  and destructors (_class.dtor_) shall not
  be declared const, volatile or const volatile.  [Note: However,  these
  functions  can  be  invoked  to  create  and  destroy objects with cv-
  qualified types, see (_class.ctor_) and (_class.dtor_).  ]

  9.4  Static members                                     [class.static]

1 A data or function member of a class may be declared static in a class
  definition, in which case it is a static member of the class.

2 A static member s of class X may be referred to using the qualified-id
  expression X::s; it is not necessary to use the  class  member  access
  syntax  (_expr.ref_) to refer to a static member.  A static member may
  be referred to using the class member access syntax, in which case the
  object-expression is always evaluated.  [Example:
          class process {
          public:
                  static void reschedule();
          };
          process& g();
          void f()
          {
                  process::reschedule(); // ok: no object necessary
                  g().reschedule();      // g() is called
          }
    --end  example]  A  static member may be referred to directly in the
  scope  of  its  class  or  in   the   scope   of   a   class   derived
  (_class.derived_)  from  its class; in this case, the static member is
  referred to as if a qualified-id expression was used, with the nested-
  name-specifier  of  the qualified-id naming the class scope from which
  the static member is referenced.  [Example:
          int g();
          struct X {
                  static int g();
          };
          struct Y : X {
                  static int i;
          };
          int Y::i = g(); // equivalent to Y::g();
   --end example]

3 If an unqualified-id (_expr.prim_) is used  in  the  definition  of  a
  static  member  following  the member's declarator-id, and name lookup
  (_basic.lookup.unqual_) finds that  the  unqualified-id  refers  to  a
  static member, enumerator, or nested type of the member's class (or of
  a base class of the member's class), the unqualified-id is transformed
  into  a  qualified-id  expression  in  which the nested-name-specifier
  names the class scope from which the member is referenced.  The  defi­
  nition of a static member shall not use directly the names of the non­
  static members of its class or of a base class of its class (including
  as  operands of the sizeof operator).  The definition of a static mem­
  ber may only refer  to  these  members  to  form  pointer  to  members
  (_expr.unary.op_) or with the class member access syntax (_expr.ref_).

4 Static  members   obey   the   usual   class   member   access   rules
  (_class.access_).

  9.4.1  Static member functions                     [class.static.mfct]

1 [Note:  the  rules  described  in  _class.mfct_ apply to static member
  functions.  ]

2 [Note:  a  static  member  function  does  not  have  a  this  pointer
  (_class.this_).   ]  A  static  member  function shall not be virtual.
  There shall not be a static and a nonstatic member function  with  the
  same name and the same parameter types (_over.load_).  A static member
  function shall not be declared const, volatile, or const volatile.

  9.4.2  Static data members                         [class.static.data]

1 A static data member is not part of the subobjects of a class.   There
  is  only one copy of a static data member shared by all the objects of
  the class.

2 The declaration of a static data member in its class definition is not
  a  definition and may be of an incomplete type other than cv-qualified
  void.  A definition shall be provided for the static data member in  a
  namespace scope enclosing the member's class definition.  In the defi­
  nition at namespace scope, the name of the static data member shall be
  qualified  by  its  class name using the :: operator.  The initializer
  expression in the definition of a static data member is in  the  scope
  of its class (_basic.scope.class_).  [Example:
          class process {
                  static process* run_chain;
                  static process* running;
          };
          process* process::running = get_main();
          process* process::run_chain = running;
  The static data member run_chain of class process is defined in global
  scope; the  notation  process::run_chain  specifies  that  the  member
  run_chain  is a member of class process and in the scope of class pro­
  cess.  In the static data member definition, the  initializer  expres­
  sion refers to the static data member running of class process.  ]

3 [Note: once the static data member has been defined, it exists even if
  no objects of its class have been created.  [Example: in  the  example
  above, run_chain and running exist even if no objects of class process
  are created by the program.  ] ]

4 If a static data member is of  const  integral  or  const  enumeration
  type,  its declaration in the class definition can specify a constant-
  initializer  which  shall   be   an   integral   constant   expression
  (_expr.const_).   In that case, the member can appear in integral con­
  stant expressions within its scope.  The member shall still be defined
  in  a  namespace  scope  and the definition of the member in namespace
  scope shall not contain an initializer.

5 There shall be exactly one definition of a static  data  member  in  a
  program;  no  diagnostic  is  required;  see _basic.def.odr_.  Unnamed
  classes and classes contained directly or  indirectly  within  unnamed

  classes shall not contain static data members.  [Note: this is because
  there is no mechanism to provide the definitions for such static  data
  members.  ]

6 Static  data members of a class in namespace scope have external link­
  age (_basic.link_).  A local class shall not have static data members.

7 Static  data  members  are initialized and destroyed exactly like non-
  local objects (_basic.start.init_, _basic.start.term_).

8 A static data member shall not be mutable (_dcl.stc_).

  9.5  Unions                                              [class.union]

1 In a union, at most one of the data members can be active at any time,
  that is, the value of at most one of the data members can be stored in
  a union at any time.  The size of a union is sufficient to contain the
  largest  of  its data members.  Each data member is allocated as if it
  were the sole member of a struct.  A union can have  member  functions
  (including    constructors   and   destructors),   but   not   virtual
  (_class.virtual_) functions.  A union shall not have base classes.   A
  union  shall not be used as a base class.  An object of a class with a
  non-trivial default constructor  (_class.ctor_),  a  non-trivial  copy
  constructor  (_class.copy_),  a non-trivial destructor (_class.dtor_),
  or a non-trivial copy assignment operator  (_over.ass_,  _class.copy_)
  cannot be a member of a union, nor can an array of such objects.  If a
  union contains a static data member, or a member  of  reference  type,
  the program is ill-formed.

2 A union of the form
          union { member-specification } ;
  is  called an anonymous union; it defines an unnamed object of unnamed
  type.  The member-specification  of  an  anonymous  union  shall  only
  define non-static data members.  The names of the members of an anony­
  mous union shall be distinct from the names of any other entity in the
  scope  in  which  the anonymous union is declared.  For the purpose of
  name look up, after the anonymous union definition, the members of the
  anonymous  union  are  considered to have been defined in the scope in
  which the anonymous union is declared.  [Example:
          void f()
          {
              union { int a; char* p; };
              a = 1;
              // ...
              p = "Jennifer";
              // ...
          }
  Here a and p are used like ordinary (nonmember) variables,  but  since
  they are union members they have the same address.  ]

3 Anonymous unions declared at namespace scope shall be declared static.
  Anonymous unions declared at block scope shall be  declared  with  any
  storage  class  allowed for a block-scope variable, or with no storage

  class.  A storage class is not allowed in a declaration of  an  anony­
  mous  union  in a class scope.  An anonymous union shall not have pri­
  vate or protected members (_class.access_).  An anonymous union  shall
  not have function members.

4 A union for which objects or pointers are declared is not an anonymous
  union.  [Example:
          union { int aa; char* p; } obj, *ptr = &obj;
          aa = 1;       // error
          ptr->aa = 1;  // ok
  The assignment to plain aa is ill formed since the member name is  not
  visible  outside  the  union,  and  even if it were visible, it is not
  associated with any particular object.   ]  [Note:  Initialization  of
  unions   with   no   user-declared   constructors   is   described  in
  (_dcl.init.aggr_).  ]

  9.6  Bit-fields                                            [class.bit]

1 A member-declarator of the form
          identifieropt : constant-expression
  specifies a bit-field; its length is set off from the  bit-field  name
  by  a  colon.   The bit-field attribute is not part of the type of the
  class member.  The constant-expression shall be an integral  constant-
  expression  with a value greater than or equal to zero.  Allocation of
  bit-fields within a class object is implementation-defined.  Alignment
  of  bit-fields  is implementation-defined.  Bit-fields are packed into
  some addressable allocation unit.  [Note: bit-fields straddle  alloca­
  tion  units  on  some  machines  and  not  on  others.  Bit-fields are
  assigned right-to-left on some machines, left-to-right on others.  ]

2 A declaration for a bit-field that omits the  identifier  declares  an
  unnamed  bit-field.   Unnamed bit-fields are not members and cannot be
  initialized.  [Note: an unnamed bit-field is  useful  for  padding  to
  conform  to  externally-imposed  layouts.   ]  As  a  special case, an
  unnamed bit-field with a width of zero specifies alignment of the next
  bit-field  at  an  allocation  unit  boundary.  Only when declaring an
  unnamed bit-field may the constant-expression  be  a  value  equal  to
  zero.

3 A  bit-field  shall  not  be  a static member.  A bit-field shall have
  integral or enumeration type (_basic.fundamental_).  It is implementa­
  tion-defined  whether a plain (neither explicitly signed nor unsigned)
  char, wchar_t, short, int or long bit-field is signed or unsigned.   A
  bool  value  can  successfully be stored in a bit-field of any nonzero
  size.  The address-of operator & shall not be applied to a  bit-field,
  so  there  are no pointers to bit-fields.  A non-const reference shall
  not be bound to a bit-field (_dcl.init.ref_).  [Note: if the  initial­
  izer  for  a  reference of type const T& is an lvalue that refers to a
  bit-field, the reference is bound to a temporary initialized  to  hold
  the  value  of  the  bit-field; the reference is not bound to the bit-
  field directly.  See _dcl.init.ref_.  ]

4 If the value true or false is stored into a bit-field of type bool  of
  any  size (including a one bit bit-field), the original bool value and

  the value of the bit-field shall compare equal.  If the  value  of  an
  enumerator is stored into a bit-field of the same enumeration type and
  the number of bits in the bit-field is large enough to  hold  all  the
  values of that enumeration type, the original enumerator value and the
  value of the bit-field shall compare equal.  [Example:
          enum BOOL { f=0, t=1 };
          struct A {
                  BOOL b:1;
          };
          A a;
          void f() {
                  a.b = t;
                  if (a.b == t) // shall yield true
                  { /* ... */ }
          }
   --end example]

  9.7  Nested class declarations                            [class.nest]

1 A class can be defined within another class.  A class  defined  within
  another is called a nested class.  The name of a nested class is local
  to its enclosing class.  The nested class  is  in  the  scope  of  its
  enclosing  class.   Except by using explicit pointers, references, and
  object names, declarations in a nested class can use only type  names,
  static members, and enumerators from the enclosing class.  [Example:
          int x;
          int y;

          class enclose {
          public:
              int x;
              static int s;
              class inner {
                  void f(int i)
                  {
                      int a = sizeof(x); // error: refers to enclose::x
                      x = i;   // error: assign to enclose::x
                      s = i;   // ok: assign to enclose::s
                      ::x = i; // ok: assign to global x
                      y = i;       // ok: assign to global y
                  }
                  void g(enclose* p, int i)
                  {
                      p->x = i;   // ok: assign to enclose::x
                  }
              };
          };

          inner* p = 0;   // error `inner' not in scope
   --end example]

2 Member  functions  and  static  data  members of a nested class can be
  defined in a namespace scope enclosing the definition of their  class.
  [Example:

          class enclose {
          public:
              class inner {
                  static int x;
                  void f(int i);
              };
          };
          int enclose::inner::x = 1;

          void enclose::inner::f(int i) { /* ... */ }
   --end example]

3 If  class  X  is defined in a namespace scope, a nested class Y may be
  declared in class X and later defined in the definition of class X  or
  be  later  defined  in  a  namespace scope enclosing the definition of
  class X.  [Example:
          class E {
              class I1;      // forward declaration of nested class
              class I2;
              class I1 {};  // definition of nested class
          };
          class E::I2 {};   // definition of nested class
   --end example]

4 Like a member function, a  friend  function  (_class.friend_)  defined
  within  a nested class is in the lexical scope of that class; it obeys
  the same rules for name binding as a static member  function  of  that
  class  (_class.static_) and has no special access rights to members of
  an enclosing class.

  9.8  Local class declarations                            [class.local]

1 A class can be defined within a function definition; such a  class  is
  called  a  local  class.   The  name  of a local class is local to its
  enclosing scope.  The local class is in the  scope  of  the  enclosing
  scope.   Declarations in a local class can use only type names, static
  variables, extern variables and functions, and  enumerators  from  the
  enclosing scope.  [Example:
          int x;
          void f()
          {
              static int s ;
              int x;
              extern int g();

              struct local {
                  int g() { return x; }    // error: `x' is auto
                  int h() { return s; }    // ok
                  int k() { return ::x; }  // ok
                  int l() { return g(); }  // ok
              };
              // ...
          }

          local* p = 0;   // error: `local' not in scope
   --end example]

2 An  enclosing  function  has no special access to members of the local
  class; it obeys the usual access rules (_class.access_).  Member func­
  tions of a local class shall be defined within their class definition,
  if they are defined at all.

3 If class X is a local class a nested class Y may be declared in  class
  X  and  later defined in the definition of class X or be later defined
  in the same scope as the definition of class X.  A class nested within
  a local class is a local class.

4 A local class shall not have static data members.

  9.9  Nested type names                             [class.nested.type]

1 Type  names obey exactly the same scope rules as other names.  In par­
  ticular, type names defined within a class definition cannot  be  used
  outside their class without qualification.  [Example:
          class X {
          public:
              typedef int I;
              class Y { /* ... */ };
              I a;
          };

          I b;     // error
          Y c;     // error
          X::Y d;  // ok
          X::I e;  // ok
   --end example]