void _POSIX_API_Initialize(void)
{
/*
* If there are any type size assumptions in the POSIX API, this is
* the appropriate place to place them.
*
* Currently, there are no none type size assumptions.
*/
/*
* Install our API Object Management Table and initialize the
* various managers.
*/
_Objects_Information_table[OBJECTS_POSIX_API] = _POSIX_Objects;
_POSIX_signals_Manager_Initialization();
_POSIX_Threads_Manager_initialization();
_POSIX_Condition_variables_Manager_initialization();
_POSIX_Key_Manager_initialization();
_POSIX_Mutex_Manager_initialization();
_POSIX_Message_queue_Manager_initialization();
_POSIX_Semaphore_Manager_initialization();
_POSIX_Timer_Manager_initialization();
_POSIX_Barrier_Manager_initialization();
_POSIX_RWLock_Manager_initialization();
_POSIX_Spinlock_Manager_initialization();
}
void rtems_initialize_data_structures(void)
{
_System_state_Handler_initialization( FALSE );
_CPU_Initialize();
/*
* Do this as early as possible to ensure no debugging output
* is even attempted to be printed.
*/
_Debug_Manager_initialization();
_API_extensions_Initialization();
_Thread_Dispatch_initialization();
_User_extensions_Handler_initialization();
_ISR_Handler_initialization();
/*
* Initialize the internal support API and allocator Mutex
*/
_Objects_Information_table[OBJECTS_INTERNAL_API] = _Internal_Objects;
_API_Mutex_Initialization( 2 );
_API_Mutex_Allocate( &_RTEMS_Allocator_Mutex );
_API_Mutex_Allocate( &_Once_Mutex );
_Watchdog_Handler_initialization();
_TOD_Handler_initialization();
_Thread_Handler_initialization();
_Scheduler_Handler_initialization();
_SMP_Handler_initialize();
_CPU_set_Handler_initialization();
/* MANAGERS */
/*
* Install our API Object Management Table and initialize the
* various managers.
*/
_Objects_Information_table[OBJECTS_CLASSIC_API] = _RTEMS_Objects;
_RTEMS_tasks_Manager_initialization();
_Semaphore_Manager_initialization();
/*
* Install our API Object Management Table and initialize the
* various managers.
*/
_Objects_Information_table[OBJECTS_POSIX_API] = _POSIX_Objects;
_POSIX_Key_Manager_initialization();
/*
* Discover and initialize the secondary cores in an SMP system.
*/
_SMP_Handler_initialize();
_System_state_Set( SYSTEM_STATE_BEFORE_MULTITASKING );
/*
* No threads should be created before this point!!!
* _Thread_Executing and _Thread_Heir are not set.
*
* At this point all API extensions are in place. After the call to
* _Thread_Create_idle() _Thread_Executing and _Thread_Heir will be set.
*/
_Thread_Create_idle();
/*
* Scheduling can properly occur now as long as we avoid dispatching.
*/
_System_state_Set( SYSTEM_STATE_UP );
_SMP_Request_start_multitasking();
_Thread_Start_multitasking();
/* Add Initialization of the Thread_Dispatch wrapper */
Init__wrap__Thread_Dispatch();
/*
* Now we are back in a non-dispatching critical section
*/
#if defined(RTEMS_SMP)
{
ISR_Level level;
/*
* On SMP we enter _Thread_Handler() with interrupts disabled and
* _Thread_Dispatch() obtained the per-CPU lock for us. We have to
* release it here and set the desired interrupt level of the thread.
*/
Per_CPU_Control *cpu_self = _Per_CPU_Get();
_Assert( cpu_self->thread_dispatch_disable_level == 1 );
_Assert( _ISR_Get_level() != 0 );
cpu_self->thread_dispatch_disable_level = 0;
_Profiling_Thread_dispatch_enable( cpu_self, 0 );
/* For whatever reason, we haven't locked our per cpu yet in the
* Scheduler Simulator. Until this is done, this release is not needed.
*/
/* _Per_CPU_Release( cpu_self ); */
level = _Thread_Executing->Start.isr_level;
_ISR_Set_level( level);
/*
* The thread dispatch level changed from one to zero. Make sure we lose
* no thread dispatch necessary update.
*/
_Thread_Dispatch();
}
#else
_Thread_Enable_dispatch();
#endif
/*
* Print an initial message
*/
check_heir_and_executing();
}