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/* -*- C++ -*- */
// $Id$
// Thread_Manager.i
#if !defined(ACE_USE_ONE_SHOT_AT_THREAD_EXIT)
ACE_INLINE
ACE_At_Thread_Exit::ACE_At_Thread_Exit()
: td_(0),
was_applied_(0),
is_owner_(1)
{
}
ACE_INLINE int
ACE_At_Thread_Exit::was_applied() const
{
return was_applied_;
}
ACE_INLINE int
ACE_At_Thread_Exit::was_applied(int applied)
{
was_applied_ = applied;
if (was_applied_)
td_ = 0;
return was_applied_;
}
ACE_INLINE int
ACE_At_Thread_Exit::is_owner() const
{
return is_owner_;
}
ACE_INLINE int
ACE_At_Thread_Exit::is_owner(int owner)
{
is_owner_ = owner;
return is_owner_;
}
ACE_INLINE void
ACE_At_Thread_Exit::do_apply()
{
if (!this->was_applied_ && this->is_owner_)
{
td_->at_pop();
}
}
ACE_INLINE
ACE_At_Thread_Exit::~ACE_At_Thread_Exit()
{
this->do_apply();
}
ACE_INLINE
ACE_At_Thread_Exit_Func::ACE_At_Thread_Exit_Func (
void* object,
ACE_CLEANUP_FUNC func,
void* param
)
: object_(object),
func_(func),
param_(param)
{
}
ACE_INLINE
ACE_At_Thread_Exit_Func::~ACE_At_Thread_Exit_Func()
{
this->do_apply();
}
ACE_INLINE void
ACE_At_Thread_Exit_Func::apply()
{
func_(object_, param_);
}
#endif /* ! ACE_USE_ONE_SHOT_AT_THREAD_EXIT */
ACE_INLINE
ACE_Thread_Descriptor_Base::ACE_Thread_Descriptor_Base (void)
: thr_id_ (ACE_OS::NULL_thread),
thr_handle_ (ACE_OS::NULL_hthread),
grp_id_ (0),
thr_state_ (ACE_THR_IDLE),
task_ (0)
{
}
ACE_INLINE
ACE_Thread_Descriptor_Base::~ACE_Thread_Descriptor_Base (void)
{
}
ACE_INLINE int
ACE_Thread_Descriptor_Base::operator==(const ACE_Thread_Descriptor_Base &rhs) const
{
return ACE_OS::thr_cmp (this->thr_handle_, rhs.thr_handle_) == 0
&& ACE_OS::thr_equal (this->thr_id_, rhs.thr_id_) == 0;
}
ACE_INLINE int
ACE_Thread_Descriptor_Base::operator!=(const ACE_Thread_Descriptor_Base &rhs) const
{
return !(*this == rhs);
}
ACE_INLINE ACE_Task_Base *
ACE_Thread_Descriptor_Base::task (void)
{
ACE_TRACE ("ACE_Thread_Descriptor_Base::task");
return this->task_;
}
// Group ID.
ACE_INLINE int
ACE_Thread_Descriptor_Base::grp_id (void)
{
ACE_TRACE ("ACE_Thread_Descriptor_Base::grp_id");
return grp_id_;
}
// Current state of the thread.
ACE_INLINE ACE_Thread_State
ACE_Thread_Descriptor_Base::state (void)
{
ACE_TRACE ("ACE_Thread_Descriptor_Base::state");
return thr_state_;
}
// Unique thread id.
ACE_INLINE ACE_thread_t
ACE_Thread_Descriptor::self (void)
{
ACE_TRACE ("ACE_Thread_Descriptor::self");
return this->thr_id_;
}
// Unique kernel-level thread handle.
ACE_INLINE void
ACE_Thread_Descriptor::self (ACE_hthread_t &handle)
{
ACE_TRACE ("ACE_Thread_Descriptor::self");
handle = this->thr_handle_;
}
// Get the thread creation
ACE_INLINE long
ACE_Thread_Descriptor::flags (void) const
{
ACE_TRACE ("ACE_Thread_Descriptor::flag");
return flags_;
}
#if !defined(ACE_USE_ONE_SHOT_AT_THREAD_EXIT)
ACE_INLINE void
ACE_Thread_Descriptor::log_msg_cleanup(ACE_Log_Msg* log_msg)
{
log_msg_ = log_msg;
}
#endif /* !ACE_USE_ONE_SHOT_AT_THREAD_EXIT */
// Set the <next_> pointer
ACE_INLINE void
ACE_Thread_Descriptor::set_next (ACE_Thread_Descriptor *td)
{
ACE_TRACE ("ACE_Thread_Descriptor::set_next");
this->next_ = td;
}
// Get the <next_> pointer
ACE_INLINE ACE_Thread_Descriptor *
ACE_Thread_Descriptor::get_next (void)
{
ACE_TRACE ("ACE_Thread_Descriptor::flag");
return ACE_static_cast (ACE_Thread_Descriptor *, this->next_);
}
// Set the exit status.
ACE_INLINE void *
ACE_Thread_Control::status (void *s)
{
ACE_TRACE ("ACE_Thread_Control::status");
return this->status_ = s;
}
// Get the exit status.
ACE_INLINE void *
ACE_Thread_Control::status (void)
{
ACE_TRACE ("ACE_Thread_Control::status");
return this->status_;
}
// Returns the current <Thread_Manager>.
ACE_INLINE ACE_Thread_Manager *
ACE_Thread_Control::thr_mgr (void)
{
ACE_TRACE ("ACE_Thread_Control::thr_mgr");
return this->tm_;
}
// Atomically set a new <Thread_Manager> and return the old
// <Thread_Manager>.
ACE_INLINE ACE_Thread_Manager *
ACE_Thread_Control::thr_mgr (ACE_Thread_Manager *tm)
{
ACE_TRACE ("ACE_Thread_Control::thr_mgr");
ACE_Thread_Manager *o_tm = this->tm_;
this->tm_ = tm;
return o_tm;
}
ACE_INLINE ACE_Thread_Descriptor *
ACE_Thread_Manager::thread_desc_self (void)
{
// This method must be called with lock held.
// Try to get it from cache.
ACE_Thread_Descriptor *desc = ACE_LOG_MSG->thr_desc ();
#if 1
ACE_ASSERT (desc != 0);
// Thread descriptor should always get cached.
#else
if (desc == 0)
{
ACE_thread_t id = ACE_OS::thr_self ();
desc = this->find_thread (id);
// Thread descriptor adapter might not have been put into the
// list yet.
if (desc != 0)
// Update the TSS cache.
ACE_LOG_MSG->thr_desc (desc);
}
#endif
return desc;
}
// Return the unique ID of the thread.
ACE_INLINE ACE_thread_t
ACE_Thread_Manager::thr_self (void)
{
ACE_TRACE ("ACE_Thread_Manager::thr_self");
return ACE_Thread::self ();
}
ACE_INLINE ACE_Task_Base *
ACE_Thread_Manager::task (void)
{
ACE_TRACE ("ACE_Thread_Manager::task");
ACE_Thread_Descriptor *td = this->thread_desc_self () ;
if (td == 0)
return 0;
else
return td->task ();
}
ACE_INLINE int
ACE_Thread_Manager::open (size_t)
{
// Currently no-op.
return 0;
}
#if !defined(ACE_USE_ONE_SHOT_AT_THREAD_EXIT)
ACE_INLINE int
ACE_Thread_Manager::at_exit (ACE_At_Thread_Exit* at)
{
return this->thread_desc_self ()->at_exit (at);
}
ACE_INLINE int
ACE_Thread_Manager::at_exit (ACE_At_Thread_Exit& at)
{
return this->thread_desc_self ()->at_exit (at);
}
#endif /* !ACE_USE_ONE_SHOT_AT_THREAD_EXIT */
ACE_INLINE int
ACE_Thread_Manager::at_exit (void *object,
ACE_CLEANUP_FUNC cleanup_hook,
void *param)
{
return this->thread_desc_self ()->at_exit (object,
cleanup_hook,
param);
}
ACE_INLINE void
ACE_Thread_Manager::wait_on_exit (int do_wait)
{
this->automatic_wait_ = do_wait;
}
ACE_INLINE int
ACE_Thread_Manager::wait_on_exit (void)
{
return this->automatic_wait_;
}
ACE_INLINE int
ACE_Thread_Manager::register_as_terminated (ACE_Thread_Descriptor *td)
{
#if defined (VXWORKS)
ACE_UNUSED_ARG (td);
#else /* ! VXWORKS */
ACE_Thread_Descriptor_Base *tdb;
ACE_NEW_RETURN (tdb, ACE_Thread_Descriptor_Base (*td), -1);
this->terminated_thr_list_.insert_tail (tdb);
#endif /* ! VXWORKS */
return 0;
}
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