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Copyright © 2001, 2003, 2004, 2012 Daryle Walker
Distributed under the Boost Software License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
Table of Contents
When developing a class, sometimes a base class needs to be initialized with a member of the current class. As a naïve example:
#include <streambuf> /* for std::streambuf */ #include <ostream> /* for std::ostream */ class fdoutbuf : public std::streambuf { public: explicit fdoutbuf( int fd ); //... }; class fdostream : public std::ostream { protected: fdoutbuf buf; public: explicit fdostream( int fd ) : buf( fd ), std::ostream( &buf ) {} //... };
This is undefined because C++'s initialization order mandates that the base class is initialized before the member it uses. R. Samuel Klatchko developed a way around this by using the initialization order in his favor. Base classes are intialized in order of declaration, so moving the desired member to another base class, that is initialized before the desired base class, can ensure proper initialization.
A custom base class can be made for this idiom:
#include <streambuf> /* for std::streambuf */ #include <ostream> /* for std::ostream */ class fdoutbuf : public std::streambuf { public: explicit fdoutbuf( int fd ); //... }; struct fdostream_pbase { fdoutbuf sbuffer; explicit fdostream_pbase( int fd ) : sbuffer( fd ) {} }; class fdostream : private fdostream_pbase , public std::ostream { typedef fdostream_pbase pbase_type; typedef std::ostream base_type; public: explicit fdostream( int fd ) : pbase_type( fd ), base_type( &sbuffer ) {} //... };
Other projects can use similar custom base classes. The technique is basic enough to make a template, with a sample template class in this library. The main template parameter is the type of the enclosed member. The template class has several (explicit) constructor member templates, which implicitly type the constructor arguments and pass them to the member. The template class uses implicit copy construction and assignment, cancelling them if the enclosed member is non-copyable.
Manually coding a base class may be better if the construction and/or copying needs are too complex for the supplied template class, or if the compiler is not advanced enough to use it.
Since base classes are unnamed, a class cannot have multiple (direct) base classes of the same type. The supplied template class has an extra template parameter, an integer, that exists solely to provide type differentiation. This parameter has a default value so a single use of a particular member type does not need to concern itself with the integer.
#include <type_traits> /* exposition only */ #ifndef BOOST_BASE_FROM_MEMBER_MAX_ARITY #define BOOST_BASE_FROM_MEMBER_MAX_ARITY 10 #endif template < typename MemberType, int UniqueID = 0 > class boost::base_from_member { protected: MemberType member; #if C++11 is in use template< typename ...T > explicit constexpr base_from_member( T&& ...x ) noexcept( std::is_nothrow_constructible<MemberType, T...>::value ); #else base_from_member(); template< typename T1 > explicit base_from_member( T1 x1 ); template< typename T1, typename T2 > base_from_member( T1 x1, T2 x2 ); //... template< typename T1, typename T2, typename T3, typename T4, typename T5, typename T6, typename T7, typename T8, typename T9, typename T10 > base_from_member( T1 x1, T2 x2, T3 x3, T4 x4, T5 x5, T6 x6, T7 x7, T8 x8, T9 x9, T10 x10 ); #endif }; template < typename MemberType, int UniqueID > class base_from_member<MemberType&, UniqueID> { protected: MemberType& member; explicit constexpr base_from_member( MemberType& x ) noexcept; };
The class template has a first template parameter MemberType
representing the type of the based-member. It has a last template parameter
UniqueID
, that is an int
, to differentiate between multiple base
classes that use the same based-member type. The last template parameter has
a default value of zero if it is omitted. The class template has a protected
data member called member
that
the derived class can use for later base classes (or itself).
If the appropriate features of C++11 are present, there will be a single constructor
template. It implements perfect forwarding to the best
constructor call of member
(if any). The constructor template is marked both constexpr
and explicit
. The former will
be ignored if the corresponding inner constructor call (of member
)
does not have the marker. The latter binds the other way; always taking effect,
even when the inner constructor call does not have the marker. The constructor
template propagates the noexcept
status of the inner constructor call. (The constructor template has a trailing
parameter with a default value that disables the template when its signature
is too close to the signatures of the automatically-defined non-template copy-
and/or move-constructors of base_from_member
.)
On earlier-standard compilers, there is a default constructor and several constructor member templates. These constructor templates can take as many arguments (currently up to ten) as possible and pass them to a constructor of the data member.
A specialization for member references offers a single constructor taking a
MemberType&
,
which is the only way to initialize a reference.
Since C++ does not allow any way to explicitly state the template parameters of a templated constructor, make sure that the arguments are already close as possible to the actual type used in the data member's desired constructor. Explicit conversions may be necessary.
The BOOST_BASE_FROM_MEMBER_MAX_ARITY
macro constant specifies the maximum argument length for the constructor templates.
The constant may be overridden if more (or less) argument configurations are
needed. The constant may be read for code that is expandable like the class
template and needs to maintain the same maximum size. (Example code would be
a class that uses this class template as a base class for a member with a flexible
set of constructors.) This constant is ignored when C++11 features are present.
With the starting example, the fdoutbuf
sub-object needs to be encapsulated in a base class that is inheirited before
std::ostream
.
#include <boost/utility/base_from_member.hpp> #include <streambuf> // for std::streambuf #include <ostream> // for std::ostream class fdoutbuf : public std::streambuf { public: explicit fdoutbuf( int fd ); //... }; class fdostream : private boost::base_from_member<fdoutbuf> , public std::ostream { // Helper typedef's typedef boost::base_from_member<fdoutbuf> pbase_type; typedef std::ostream base_type; public: explicit fdostream( int fd ) : pbase_type( fd ), base_type( &member ){} //... };
The base-from-member idiom is an implementation detail, so it should not be
visible to the clients (or any derived classes) of fdostream
.
Due to the initialization order, the fdoutbuf
sub-object will get initialized before the std::ostream
sub-object does, making the former sub-object safe to use in the latter sub-object's
construction. Since the fdoutbuf
sub-object of the final type is the only sub-object with the name member
that name can be used unqualified
within the final class.
The base-from-member class templates should commonly involve only one base-from-member sub-object, usually for attaching a stream-buffer to an I/O stream. The next example demonstrates how to use multiple base-from-member sub-objects and the resulting qualification issues.
#include <boost/utility/base_from_member.hpp> #include <cstddef> /* for NULL */ struct an_int { int y; an_int( float yf ); }; class switcher { public: switcher(); switcher( double, int * ); //... }; class flow_regulator { public: flow_regulator( switcher &, switcher & ); //... }; template < unsigned Size > class fan { public: explicit fan( switcher ); //... }; class system : private boost::base_from_member<an_int> , private boost::base_from_member<switcher> , private boost::base_from_member<switcher, 1> , private boost::base_from_member<switcher, 2> , protected flow_regulator , public fan<6> { // Helper typedef's typedef boost::base_from_member<an_int> pbase0_type; typedef boost::base_from_member<switcher> pbase1_type; typedef boost::base_from_member<switcher, 1> pbase2_type; typedef boost::base_from_member<switcher, 2> pbase3_type; typedef flow_regulator base1_type; typedef fan<6> base2_type; public: system( double x ); //... }; system::system( double x ) : pbase0_type( 0.2 ) , pbase1_type() , pbase2_type( -16, &this->pbase0_type::member.y ) , pbase3_type( x, static_cast<int *>(NULL) ) , base1_type( pbase3_type::member, pbase1_type::member ) , base2_type( pbase2_type::member ) { //... }
The final class has multiple sub-objects with the name member
,
so any use of that name needs qualification by a name of the appropriate base
type. (Using typedef
s ease mentioning
the base types.) However, the fix introduces a new problem when a pointer is
needed. Using the address operator with a sub-object qualified with its class's
name results in a pointer-to-member (here, having a type of an_int
boost::base_from_member<
an_int,
0> :: *
) instead
of a pointer to the member (having a type of an_int
*
). The new problem is fixed by qualifying
the sub-object with this->
and is needed just for pointers, and not for references or values.
There are some argument conversions in the initialization. The constructor
argument for pbase0_type
is
converted from double
to float
. The first constructor argument for pbase2_type
is converted from int
to double
.
The second constructor argument for pbase3_type
is a special case of necessary conversion; all forms of the null-pointer literal
in C++ (except nullptr
from C++11)
also look like compile-time integral expressions, so C++ always interprets
such code as an integer when it has overloads that can take either an integer
or a pointer. The last conversion is necessary for the compiler to call a constructor
form with the exact pointer type used in switcher
's
constructor. (If C++11's nullptr
is used, it still needs a conversion if multiple pointer types can be accepted
in a constructor call but std::nullptr_t
cannot.)
Last revised: April 22, 2020 at 13:38:06 GMT |