/usr/include/glibmm-2.4/glibmm/object.h is in libglibmm-2.4-dev 2.46.3-1.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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#ifndef _GLIBMM_OBJECT_H
#define _GLIBMM_OBJECT_H
/* Copyright 2002 The gtkmm Development Team
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free
* Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
//X11 defines DestroyNotify and some other non-prefixed stuff, and it's too late to change that now,
//so let's give people a clue about the compilation errors that they will see:
#ifdef DestroyNotify
# error "X11/Xlib.h seems to have been included before this header. Due to some commonly-named macros in X11/Xlib.h, it may only be included after any glibmm, gdkmm, or gtkmm headers."
#endif
#include <glibmmconfig.h>
#include <glibmm/objectbase.h>
#include <glibmm/wrap.h>
#include <glibmm/quark.h>
#include <glibmm/refptr.h>
#include <glibmm/utility.h> /* Could be private, but that would be tedious. */
#include <glibmm/containerhandle_shared.h> /* Because its specializations may be here. */
#include <glibmm/value.h>
#include <glib.h> /* for G_GNUC_NULL_TERMINATED */
#ifndef DOXYGEN_SHOULD_SKIP_THIS
extern "C"
{
typedef struct _GObject GObject;
typedef struct _GObjectClass GObjectClass;
}
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
namespace Glib
{
#ifndef DOXYGEN_SHOULD_SKIP_THIS
class Class;
class Object_Class;
class GSigConnectionNode;
/* ConstructParams::ConstructParams() takes a varargs list of properties
* and values, like g_object_new() does. This list will then be converted
* to a GParameter array, for use with g_object_newv(). No overhead is
* involved, since g_object_new() is just a wrapper around g_object_newv()
* as well.
*
* The advantage of an auxiliary ConstructParams object over g_object_new()
* is that the actual construction is always done in the Glib::Object ctor.
* This allows for neat tricks like easy creation of derived custom types,
* without adding special support to each ctor of every class.
*
* The comments in object.cc and objectbase.cc should explain in detail
* how this works.
*/
class ConstructParams
{
public:
const Glib::Class& glibmm_class;
unsigned int n_parameters;
GParameter* parameters;
explicit ConstructParams(const Glib::Class& glibmm_class_);
ConstructParams(const Glib::Class& glibmm_class_, const char* first_property_name, ...)
G_GNUC_NULL_TERMINATED; // warn if called without a trailing NULL pointer
~ConstructParams() noexcept;
// The copy constructor is semantically required by the C++ compiler
// (since g++ 3.4) to be able to create temporary instances, depending
// on the usage context. Apparently the compiler will actually optimize
// away the copy, though. See bug #132300.
ConstructParams(const ConstructParams& other);
private:
// no copy assignment
ConstructParams& operator=(const ConstructParams&);
};
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
class GLIBMM_API Object : virtual public ObjectBase
{
public:
#ifndef DOXYGEN_SHOULD_SKIP_THIS
typedef Object CppObjectType;
typedef Object_Class CppClassType;
typedef GObject BaseObjectType;
typedef GObjectClass BaseClassType;
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
// noncopyable
Object(const Object&) = delete;
Object& operator=(const Object&) = delete;
Object(Object&& src) noexcept;
Object& operator=(Object&& src) noexcept;
protected:
Object(); //For use by C++-only sub-types.
explicit Object(const Glib::ConstructParams& construct_params);
explicit Object(GObject* castitem);
virtual ~Object() noexcept; //It should only be deleted by the callback.
public:
//static RefPtr<Object> create(); //You must reimplement this in each derived class.
#ifndef DOXYGEN_SHOULD_SKIP_THIS
static GType get_type() G_GNUC_CONST;
static GType get_base_type() G_GNUC_CONST;
#endif
//GObject* gobj_copy(); //Give a ref-ed copy to someone. Use for direct struct access.
// Glib::Objects contain a list<Quark, pair<void*, DestroyNotify> >
// to store run time data added to the object at run time.
//TODO: Use slots instead:
void* get_data(const QueryQuark &key);
void set_data(const Quark &key, void* data);
typedef void (*DestroyNotify) (gpointer data);
void set_data(const Quark &key, void* data, DestroyNotify notify);
void remove_data(const QueryQuark& quark);
// same as remove without notifying
void* steal_data(const QueryQuark& quark);
// convenience functions
//template <class T>
//void set_data_typed(const Quark& quark, const T& data)
// { set_data(quark, new T(data), delete_typed<T>); }
//template <class T>
//T& get_data_typed(const QueryQuark& quark)
// { return *static_cast<T*>(get_data(quark)); }
#ifndef DOXYGEN_SHOULD_SKIP_THIS
private:
friend class Glib::Object_Class;
static CppClassType object_class_;
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
// Glib::Object can not be dynamic because it lacks a float state.
//virtual void set_manage();
};
//For some (proably, more spec-compliant) compilers, these specializations must
//be next to the objects that they use.
#ifndef GLIBMM_CAN_USE_DYNAMIC_CAST_IN_UNUSED_TEMPLATE_WITHOUT_DEFINITION
# ifndef DOXYGEN_SHOULD_SKIP_THIS /* hide the specializations */
namespace Container_Helpers
{
/** Partial specialization for pointers to GObject instances.
* @ingroup ContHelpers
* The C++ type is always a Glib::RefPtr<>.
*/
template <class T>
struct TypeTraits< Glib::RefPtr<T> >
{
typedef Glib::RefPtr<T> CppType;
typedef typename T::BaseObjectType * CType;
typedef typename T::BaseObjectType * CTypeNonConst;
static CType to_c_type (const CppType& ptr) { return Glib::unwrap(ptr); }
static CType to_c_type (CType ptr) { return ptr; }
static CppType to_cpp_type(CType ptr)
{
//return Glib::wrap(ptr, true);
//We copy/paste the wrap() implementation here,
//because we can not use a specific Glib::wrap(CType) overload here,
//because that would be "dependent", and g++ 3.4 does not allow that.
//The specific Glib::wrap() overloads don't do anything special anyway.
GObject* cobj = (GObject*)const_cast<CTypeNonConst>(ptr);
return Glib::RefPtr<T>( dynamic_cast<T*>(Glib::wrap_auto(cobj, true /* take_copy */)) );
//We use dynamic_cast<> in case of multiple inheritance.
}
static void release_c_type(CType ptr)
{
GLIBMM_DEBUG_UNREFERENCE(0, ptr);
g_object_unref(ptr);
}
};
//This confuses the SUN Forte compiler, so we ifdef it out:
# ifdef GLIBMM_HAVE_DISAMBIGUOUS_CONST_TEMPLATE_SPECIALIZATIONS
/** Partial specialization for pointers to const GObject instances.
* @ingroup ContHelpers
* The C++ type is always a Glib::RefPtr<>.
*/
template <class T>
struct TypeTraits< Glib::RefPtr<const T> >
{
typedef Glib::RefPtr<const T> CppType;
typedef const typename T::BaseObjectType * CType;
typedef typename T::BaseObjectType * CTypeNonConst;
static CType to_c_type (const CppType& ptr) { return Glib::unwrap(ptr); }
static CType to_c_type (CType ptr) { return ptr; }
static CppType to_cpp_type(CType ptr)
{
//return Glib::wrap(ptr, true);
//We copy/paste the wrap() implementation here,
//because we can not use a specific Glib::wrap(CType) overload here,
//because that would be "dependent", and g++ 3.4 does not allow that.
//The specific Glib::wrap() overloads don't do anything special anyway.
GObject* cobj = (GObject*)(ptr);
return Glib::RefPtr<const T>( dynamic_cast<const T*>(Glib::wrap_auto(cobj, true /* take_copy */)) );
//We use dynamic_cast<> in case of multiple inheritance.
}
static void release_c_type (CType ptr)
{
GLIBMM_DEBUG_UNREFERENCE(0, ptr);
g_object_unref(const_cast<CTypeNonConst>(ptr));
}
};
# endif /* GLIBMM_HAVE_DISAMBIGUOUS_CONST_TEMPLATE_SPECIALIZATIONS */
} //namespace Container_Helpers
template <class T, class PtrT> inline
PtrT Value_Pointer<T,PtrT>::get_(Glib::Object*) const
{
return dynamic_cast<T*>(get_object());
}
/** Partial specialization for RefPtr<> to Glib::Object.
* @ingroup glibmmValue
*/
template <class T>
class Value< Glib::RefPtr<T> > : public ValueBase_Object
{
public:
typedef Glib::RefPtr<T> CppType;
typedef typename T::BaseObjectType* CType;
static GType value_type() { return T::get_base_type(); }
void set(const CppType& data) { set_object(data.operator->()); }
CppType get() const { return Glib::RefPtr<T>::cast_dynamic(get_object_copy()); }
};
//The SUN Forte Compiler has a problem with this:
# ifdef GLIBMM_HAVE_DISAMBIGUOUS_CONST_TEMPLATE_SPECIALIZATIONS
/** Partial specialization for RefPtr<> to const Glib::Object.
* @ingroup glibmmValue
*/
template <class T>
class Value< Glib::RefPtr<const T> > : public ValueBase_Object
{
public:
typedef Glib::RefPtr<const T> CppType;
typedef typename T::BaseObjectType* CType;
static GType value_type() { return T::get_base_type(); }
void set(const CppType& data) { set_object(const_cast<T*>(data.operator->())); }
CppType get() const { return Glib::RefPtr<T>::cast_dynamic(get_object_copy()); }
};
# endif /* GLIBMM_HAVE_DISAMBIGUOUS_CONST_TEMPLATE_SPECIALIZATIONS */
# endif /* DOXYGEN_SHOULD_SKIP_THIS */
#endif /* GLIBMM_CAN_USE_DYNAMIC_CAST_IN_UNUSED_TEMPLATE_WITHOUT_DEFINITION */
} // namespace Glib
#endif /* _GLIBMM_OBJECT_H */
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