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// file : common/session/custom/session.txx
// copyright : Copyright (c) 2009-2012 Code Synthesis Tools CC
// license : GNU GPL v2; see accompanying LICENSE file
#include <cassert>
template <typename T>
typename session::position<T> session::
insert (odb::database&,
const typename odb::object_traits<T>::id_type& id,
const typename odb::object_traits<T>::pointer_type& obj)
{
typedef odb::object_traits<T> object_traits;
std::shared_ptr<object_map_base>& pm (map_[&typeid (T)]);
if (!pm)
pm.reset (new object_map<T>);
object_map<T>& m (static_cast<object_map<T>&> (*pm));
typename object_map<T>::value_type vt (id, object_state<T> (obj));
std::pair<typename object_map<T>::iterator, bool> r (m.insert (vt));
// We shall never try to re-insert the same object into the cache.
//
assert (r.second);
return position<T> (m, r.first);
}
template <typename T>
void session::
initialize (const position<T>& p)
{
typedef typename odb::object_traits<T>::pointer_type pointer_type;
// Make a copy for change tracking. If our object model had a
// polymorphic hierarchy, then we would have had to use a
// virtual function-based mechanism (e.g., clone()) instead of
// the copy constructor since for a polymorphic hierarchy all
// the derived objects are stored as pointers to the root object.
//
p.pos_->second.orig = pointer_type (new T (*p.pos_->second.obj));
}
template <typename T>
typename odb::object_traits<T>::pointer_type session::
find (odb::database&, const typename odb::object_traits<T>::id_type& id) const
{
typedef typename odb::object_traits<T>::pointer_type pointer_type;
type_map::const_iterator ti (map_.find (&typeid (T)));
if (ti == map_.end ())
return pointer_type ();
const object_map<T>& m (static_cast<const object_map<T>&> (*ti->second));
typename object_map<T>::const_iterator oi (m.find (id));
if (oi == m.end ())
return pointer_type ();
return oi->second.obj;
}
template <typename T>
void session::
erase (odb::database&, const typename odb::object_traits<T>::id_type& id)
{
type_map::iterator ti (map_.find (&typeid (T)));
if (ti == map_.end ())
return;
object_map<T>& m (static_cast<object_map<T>&> (*ti->second));
typename object_map<T>::iterator oi (m.find (id));
if (oi == m.end ())
return;
m.erase (oi);
if (m.empty ())
map_.erase (ti);
}
template <typename T>
void session::object_map<T>::
flush (odb::database& db)
{
for (typename object_map<T>::iterator i (this->begin ()), e (this->end ());
i != e; ++i)
{
const T& obj (*i->second.obj);
if (obj.changed (*i->second.orig))
{
db.update (obj);
i->second.flushed_ = true;
}
}
}
template <typename T>
void session::object_map<T>::
mark ()
{
for (typename object_map<T>::iterator i (this->begin ()), e (this->end ());
i != e; ++i)
{
if (i->second.flushed_)
{
i->second.orig.reset (new T (*i->second.obj));
i->second.flushed_ = false;
}
}
}
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