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livetrax/libs/gtkmm2/gtk/gtkmm/object.cc
Taybin Rutkin d09f6b3016 Initial revision
git-svn-id: svn://localhost/trunk/ardour2@4 d708f5d6-7413-0410-9779-e7cbd77b26cf
2005-05-13 20:47:18 +00:00

408 lines
13 KiB
C++

// Generated by gtkmmproc -- DO NOT MODIFY!
#include <gtkmm/object.h>
#include <gtkmm/private/object_p.h>
/* $Id$ */
/* Copyright 1998-2002 The gtkmm Development Team
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Library General Public
* License as published by the Free Software Foundation; either
* version 2 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
* Library General Public License for more details.
*
* You should have received a copy of the GNU Library General Public
* License along with this library; if not, write to the Free
* Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <glibmm/quark.h>
#include <gtk/gtkobject.h>
namespace Gtk
{
Object::Object(const Glib::ConstructParams& construct_params)
:
Glib::Object(construct_params)
{
gobject_disposed_ = false;
_init_unmanage(); //We don't like the GTK+ default memory management - we want to be in control._)
}
Object::Object(GtkObject* castitem)
:
Glib::Object((GObject*) castitem)
{
gobject_disposed_ = false;
_init_unmanage(); //We don't like the GTK+ default memory management - we want to be in control.
}
void Object::_init_unmanage(bool /* is_toplevel = false */)
{
//GTKMM_LIFECYCLE
if(gobject_)
{
//Glib::Object::Object has already stored a pointer to this C++ instance in the underlying C instance,
//and connected a callback which will, in turn, call our destroy_notify_(),
//so will will know if GTK+ disposes of the underlying instance.
// Most GTK+ objects are floating, by default. This means that the container widget controls their lifetime.
// We'll change this:
if(GTK_OBJECT_FLOATING (gobject_)) //Top-level Windows and Dialogs can not be manag()ed, so there is no need to do this.
{
GLIBMM_DEBUG_REFERENCE(this, gobject_);
g_object_ref(gobject_); //Increase ref by 1 so that it doesn't get deleted when we sink() it (sink()ing does an unref)
gtk_object_sink((GtkObject*)gobject_); //Stops it from being floating - we will make this optional ( see Gtk::manage() ),
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("gtkmm after sink: C++ instance: %p, C instance: %p, refcount=%d\n", (void*)(Glib::ObjectBase*)this, (void*)gobject_, G_OBJECT(gobject_)->ref_count);
g_warning(" c instance gtype: %s\n", G_OBJECT_TYPE_NAME(gobject_));
#endif
referenced_ = true; //Not managed.
}
else
{
//This widget is already not floating. It's probably already been added to a GTK+ container, and has just had Glib::wrap() called on it.
//It's not floating because containers call gtk_object_sink() on child widgets to take control of them.
//We just ref() it so that we can unref it later.
//GLIBMM_DEBUG_REFERENCE(this, gobject_);
//g_object_ref(gobject_);
//Alternatively, it might be a top-level window (e.g. a Dialog). We would then be doing one too-many refs(),
//We do an extra unref() in Window::_destroy_c_instance() to take care of that.
referenced_ = false; //Managed. We should not try to unfloat GtkObjects that we did not instantiate.
}
}
}
void Object::_destroy_c_instance()
{
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("Gtk::Object::_destroy_c_instance() this=%10X, gobject_=%10X\n", this, gobject_);
if(gobject_)
g_warning(" gtypename: %s\n", G_OBJECT_TYPE_NAME(gobject_));
#endif
cpp_destruction_in_progress_ = true;
// remove our hook.
GtkObject* object = gobj();
if (object)
{
g_assert(GTK_IS_OBJECT(object));
disconnect_cpp_wrapper();
//Unfortunately this means that our dispose callback will not be called, because the qdata has been removed.
//So we'll connect the callback again, just so that gobject_disposed_ gets set for use later in this same method.
//See below:
//This probably isn't a problem now:
//If we are killing the C++ instance before the C instance, then this might lead to strange behaviour.
//If this is a problem, then you'll have to use a managed() object, which will die only upon GTK+'s request.
//We can't do anything with the gobject_ if it's already been disposed.
//This prevents us from unref-ing it again, or destroying it again after GTK+ has told us that it has been disposed.
if (!gobject_disposed_)
{
if(referenced_)
{
//It's not manage()ed so we just unref to destroy it
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("final unref: gtypename: %s, refcount: %d\n", G_OBJECT_TYPE_NAME(object), ((GObject*)object)->ref_count);
#endif
//Because we called disconnect_cpp_wrapper() our dispose callback will not be called, because the qdata has been removed.
//So we'll connect a callback again, just so that gobject_disposed_ gets set for use later in this same method.
gulong connection_id_destroy = g_signal_connect (object, "destroy", G_CALLBACK (&callback_destroy_), this);
GLIBMM_DEBUG_UNREFERENCE(this, object);
g_object_unref(object);
if(!gobject_disposed_) //or if(g_signal_handler_is_connected(object, connection_id_destroy))
g_signal_handler_disconnect(object, connection_id_destroy);
//destroy_notify() should have been called after the final g_object_unref() or gtk_object_destroy(), so gobject_disposed_ should now be true.
//If the C instance still isn't dead then insist, by calling gtk_object_destroy().
//This is necessary because even a manage()d widget is refed when added to a container.
// <danielk> That's simply not true. But references might be taken elsewhere,
// and gtk_object_destroy() just tells everyone "drop your refs, please!".
if (!gobject_disposed_)
{
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("Gtk::Object::_destroy_c_instance(): Calling gtk_object_destroy(): gobject_=%10X, gtypename=%s\n", object, G_OBJECT_TYPE_NAME(object));
#endif
g_assert(GTK_IS_OBJECT(object));
gtk_object_destroy(object); //Container widgets can respond to this.
}
}
else
{
//It's manag()ed, but the coder decided to delete it before deleting its parent.
//That should be OK because the Container can respond to that.
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("Gtk::Object::_destroy_c_instance(): Calling gtk_object_destroy(): gobject_=%10X\n", gobject_);
#endif
if (!gobject_disposed_)
{
g_assert(GTK_IS_OBJECT(object));
gtk_object_destroy(object);
}
}
}
//Glib::Object::~Object() will not g_object_unref() it too. because gobject_ is now 0.
}
}
Object::~Object()
{
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("Gtk::Object::~Object() gobject_=%10X\n", gobject_);
#endif
//This has probably been called already from Gtk::Object::_destroy(), which is called from derived destructors.
_destroy_c_instance();
}
void Object::disconnect_cpp_wrapper()
{
//GTKMM_LIFECYCLE:
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("Gtk::Object::disconnect_cpp_wrapper() this=%10X, gobject_=%10X\n", this, gobject_);
if(gobject_)
g_warning(" gtypename: %s\n", G_OBJECT_TYPE_NAME(gobject_));
#endif
if(gobj())
{
//Prevent gtk vfuncs and default signal handlers from calling our instance methods:
g_object_steal_qdata((GObject*)gobj(), Glib::quark_); //It will no longer be possible to get the C++ instance from the C instance.
//Allow us to prevent generation of a new C++ wrapper during destruction:
g_object_set_qdata((GObject*)gobj(), Glib::quark_cpp_wrapper_deleted_, (gpointer)true);
//Prevent C++ instance from using GTK+ object:
gobject_ = 0;
//TODO: Disconnect any signals, using gtk methods.
//We'll have to keep a record of all the connections.
}
}
void Object::destroy_notify_()
{
//Overriden.
//GTKMM_LIFECYCLE
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("Gtk::Object::destroy_notify_: this=%10X, gobject_=%10X\n", this, gobject_);
if(gobject_)
g_warning(" gtypename=%s\n", G_OBJECT_TYPE_NAME(gobject_));
#endif
//Remember that it's been disposed (which only happens once):
//This also stops us from destroying it again in the destructor when it calls destroy_().
gobject_disposed_ = true;
if(!cpp_destruction_in_progress_) //This function might have been called as a side-effect of destroy() when it called gtk_object_destroy().
{
if (!referenced_) //If it's manage()ed.
{
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("Gtk::Object::destroy_notify_: before delete this.\n");
#endif
delete this; //Free the C++ instance.
}
else //It's not managed, but the C gobject_ just died before the C++ instance..
{
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("Gtk::Object::destroy_notify_: setting gobject_ to 0\n");
#endif
gobject_ = 0;
}
}
}
void Object::destroy_()
{
//Called from destructors.
//GTKMM_LIFECYCLE
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("Gtk::Object::destroy_(): gobject_: %10X\n", gobject_);
if(gobject_)
g_warning(" gtypename: %s\n", G_OBJECT_TYPE_NAME(gobject_));
#endif
if ( !cpp_destruction_in_progress_ ) //see comment below.
{
//Prevent destroy_notify_() from running as a possible side-effect of gtk_object_destroy.
//We can't predict whether destroy_notify_() will really be run, so we'll disconnect the C++ instance here.
cpp_destruction_in_progress_ = true;
//destroy the C instance:
_destroy_c_instance();
}
//The C++ destructor will be reached later. This function was called by a destructor.
}
void Object::set_manage()
{
//GTKMM_LIFECYCLE
//This object will not be unref()ed by gtkmm, though it could be destroyed if the coder deletes the C++ instance early.
//This method is overriden in Gtk::Window because they can not be manage()ed.
if (!referenced_) return; //It's already managed.
// remove our reference
if (gobject_->ref_count >= 1) //This should only happen just after creation. We don't use "==1" because GtkButton starts with a refcount of 2 when using a mnemonic.
{
//g_warning("Object::set_manage(), making object floating: %s\n", G_OBJECT_TYPE_NAME(gobject_));
// Cowardly refuse to remove last reference make floating instead. //TODO: What does that comment mean?
#ifdef GLIBMM_DEBUG_REFCOUNTING
g_warning("Object::set_manage(): setting GTK_FLOATING: gobject_ = %p", (void*) gobj());
g_warning(" gtypename=%s\n", G_OBJECT_TYPE_NAME(gobj()));
#endif
GTK_OBJECT_SET_FLAGS(gobj(), GTK_FLOATING);
}
else
{
g_warning("Object::set_manage(). Refcount seems to be 0. %s\n", G_OBJECT_TYPE_NAME(gobject_));
//DEF_GLIBMM_DEBUG_UNREF(this, gobj())
//g_object_unref(gobj());
}
//g_warning("Object::set_manage(): end: %s", G_OBJECT_TYPE_NAME(gobject_));
//g_warning(" refcount=%d", G_OBJECT(gobj())->ref_count);
referenced_ = false;
}
void Object::callback_destroy_(GObject*, void* data) //static
{
//This is only used for a short time, then disconnected.
Object* cppObject = static_cast<Object*>(data);
if(cppObject) //This will be 0 if the C++ destructor has already run.
{
cppObject->gobject_disposed_ = true;
}
}
bool Object::is_managed_() const
{
return !referenced_;
}
} // namespace Gtk
namespace
{
} // anonymous namespace
namespace Glib
{
Gtk::Object* wrap(GtkObject* object, bool take_copy)
{
return dynamic_cast<Gtk::Object *> (Glib::wrap_auto ((GObject*)(object), take_copy));
}
} /* namespace Glib */
namespace Gtk
{
/* The *_Class implementation: */
const Glib::Class& Object_Class::init()
{
if(!gtype_) // create the GType if necessary
{
// Glib::Class has to know the class init function to clone custom types.
class_init_func_ = &Object_Class::class_init_function;
// This is actually just optimized away, apparently with no harm.
// Make sure that the parent type has been created.
//CppClassParent::CppObjectType::get_type();
// Create the wrapper type, with the same class/instance size as the base type.
register_derived_type(gtk_object_get_type());
// Add derived versions of interfaces, if the C type implements any interfaces:
}
return *this;
}
void Object_Class::class_init_function(void* g_class, void* class_data)
{
BaseClassType *const klass = static_cast<BaseClassType*>(g_class);
CppClassParent::class_init_function(klass, class_data);
}
Glib::ObjectBase* Object_Class::wrap_new(GObject* o)
{
return manage(new Object((GtkObject*)(o)));
}
/* The implementation: */
Object::CppClassType Object::object_class_; // initialize static member
GType Object::get_type()
{
return object_class_.init().get_type();
}
GType Object::get_base_type()
{
return gtk_object_get_type();
}
Glib::PropertyProxy<void*> Object::property_user_data()
{
return Glib::PropertyProxy<void*>(this, "user-data");
}
Glib::PropertyProxy_ReadOnly<void*> Object::property_user_data() const
{
return Glib::PropertyProxy_ReadOnly<void*>(this, "user-data");
}
} // namespace Gtk