1 ------------------------------------------------------------------------------
3 -- GNAT RUN-TIME LIBRARY (GNARL) COMPONENTS --
5 -- S Y S T E M . T A S K I N G . S T A G E S --
9 -- Copyright (C) 1992-2014, Free Software Foundation, Inc. --
11 -- GNARL is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. --
18 -- As a special exception under Section 7 of GPL version 3, you are granted --
19 -- additional permissions described in the GCC Runtime Library Exception, --
20 -- version 3.1, as published by the Free Software Foundation. --
22 -- You should have received a copy of the GNU General Public License and --
23 -- a copy of the GCC Runtime Library Exception along with this program; --
24 -- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see --
25 -- <http://www.gnu.org/licenses/>. --
27 -- GNARL was developed by the GNARL team at Florida State University. --
28 -- Extensive contributions were provided by Ada Core Technologies, Inc. --
30 ------------------------------------------------------------------------------
33 -- Turn off polling, we do not want ATC polling to take place during tasking
34 -- operations. It causes infinite loops and other problems.
36 pragma Partition_Elaboration_Policy
(Concurrent
);
37 -- This package only implements the concurrent elaboration policy. This pragma
38 -- will enforce it (and detect conflicts with user specified policy).
41 with Ada
.Unchecked_Deallocation
;
43 with System
.Interrupt_Management
;
44 with System
.Tasking
.Debug
;
45 with System
.Address_Image
;
46 with System
.Task_Primitives
;
47 with System
.Task_Primitives
.Operations
;
48 with System
.Tasking
.Utilities
;
49 with System
.Tasking
.Queuing
;
50 with System
.Tasking
.Rendezvous
;
51 with System
.OS_Primitives
;
52 with System
.Secondary_Stack
;
53 with System
.Storage_Elements
;
54 with System
.Restrictions
;
55 with System
.Standard_Library
;
56 with System
.Traces
.Tasking
;
57 with System
.Stack_Usage
;
59 with System
.Soft_Links
;
60 -- These are procedure pointers to non-tasking routines that use task
61 -- specific data. In the absence of tasking, these routines refer to global
62 -- data. In the presence of tasking, they must be replaced with pointers to
63 -- task-specific versions. Also used for Create_TSD, Destroy_TSD, Get_Current
64 -- _Excep, Finalize_Library_Objects, Task_Termination, Handler.
66 with System
.Tasking
.Initialization
;
67 pragma Elaborate_All
(System
.Tasking
.Initialization
);
68 -- This insures that tasking is initialized if any tasks are created
70 package body System
.Tasking
.Stages
is
72 package STPO
renames System
.Task_Primitives
.Operations
;
73 package SSL
renames System
.Soft_Links
;
74 package SSE
renames System
.Storage_Elements
;
75 package SST
renames System
.Secondary_Stack
;
81 use Task_Primitives
.Operations
;
85 use System
.Traces
.Tasking
;
87 -----------------------
88 -- Local Subprograms --
89 -----------------------
92 Ada
.Unchecked_Deallocation
(Ada_Task_Control_Block
, Task_Id
);
94 procedure Trace_Unhandled_Exception_In_Task
(Self_Id
: Task_Id
);
95 -- This procedure outputs the task specific message for exception
98 procedure Task_Wrapper
(Self_ID
: Task_Id
);
99 pragma Convention
(C
, Task_Wrapper
);
100 -- This is the procedure that is called by the GNULL from the new context
101 -- when a task is created. It waits for activation and then calls the task
102 -- body procedure. When the task body procedure completes, it terminates
105 -- The Task_Wrapper's address will be provided to the underlying threads
106 -- library as the task entry point. Convention C is what makes most sense
107 -- for that purpose (Export C would make the function globally visible,
108 -- and affect the link name on which GDB depends). This will in addition
109 -- trigger an automatic stack alignment suitable for GCC's assumptions if
112 -- "Vulnerable_..." in the procedure names below means they must be called
113 -- with abort deferred.
115 procedure Vulnerable_Complete_Task
(Self_ID
: Task_Id
);
116 -- Complete the calling task. This procedure must be called with
117 -- abort deferred. It should only be called by Complete_Task and
118 -- Finalize_Global_Tasks (for the environment task).
120 procedure Vulnerable_Complete_Master
(Self_ID
: Task_Id
);
121 -- Complete the current master of the calling task. This procedure
122 -- must be called with abort deferred. It should only be called by
123 -- Vulnerable_Complete_Task and Complete_Master.
125 procedure Vulnerable_Complete_Activation
(Self_ID
: Task_Id
);
126 -- Signal to Self_ID's activator that Self_ID has completed activation.
127 -- This procedure must be called with abort deferred.
129 procedure Abort_Dependents
(Self_ID
: Task_Id
);
130 -- Abort all the direct dependents of Self at its current master nesting
131 -- level, plus all of their dependents, transitively. RTS_Lock should be
132 -- locked by the caller.
134 procedure Vulnerable_Free_Task
(T
: Task_Id
);
135 -- Recover all runtime system storage associated with the task T. This
136 -- should only be called after T has terminated and will no longer be
139 -- For tasks created by an allocator that fails, due to an exception, it is
140 -- called from Expunge_Unactivated_Tasks.
142 -- Different code is used at master completion, in Terminate_Dependents,
143 -- due to a need for tighter synchronization with the master.
145 ----------------------
146 -- Abort_Dependents --
147 ----------------------
149 procedure Abort_Dependents
(Self_ID
: Task_Id
) is
153 -- Each task C will take care of its own dependents, so there is no
154 -- need to worry about them here. In fact, it would be wrong to abort
155 -- indirect dependents here, because we can't distinguish between
156 -- duplicate master ids. For example, suppose we have three nested
157 -- task bodies T1,T2,T3. And suppose T1 also calls P which calls Q (and
158 -- both P and Q are task masters). Q will have the same master id as
159 -- Master_of_Task of T3. Previous versions of this would abort T3 when
160 -- Q calls Complete_Master, which was completely wrong.
165 P
:= C
.Common
.Parent
;
168 if C
.Master_of_Task
= Self_ID
.Master_Within
then
170 (Debug
.Trace
(Self_ID
, "Aborting", 'X', C
));
171 Utilities
.Abort_One_Task
(Self_ID
, C
);
172 C
.Dependents_Aborted
:= True;
176 C
:= C
.Common
.All_Tasks_Link
;
179 Self_ID
.Dependents_Aborted
:= True;
180 end Abort_Dependents
;
186 procedure Abort_Tasks
(Tasks
: Task_List
) is
188 Utilities
.Abort_Tasks
(Tasks
);
195 -- Note that locks of activator and activated task are both locked here.
196 -- This is necessary because C.Common.State and Self.Common.Wait_Count have
197 -- to be synchronized. This is safe from deadlock because the activator is
198 -- always created before the activated task. That satisfies our
199 -- in-order-of-creation ATCB locking policy.
201 -- At one point, we may also lock the parent, if the parent is different
202 -- from the activator. That is also consistent with the lock ordering
203 -- policy, since the activator cannot be created before the parent.
205 -- Since we are holding both the activator's lock, and Task_Wrapper locks
206 -- that before it does anything more than initialize the low-level ATCB
207 -- components, it should be safe to wait to update the counts until we see
208 -- that the thread creation is successful.
210 -- If the thread creation fails, we do need to close the entries of the
211 -- task. The first phase, of dequeuing calls, only requires locking the
212 -- acceptor's ATCB, but the waking up of the callers requires locking the
213 -- caller's ATCB. We cannot safely do this while we are holding other
214 -- locks. Therefore, the queue-clearing operation is done in a separate
215 -- pass over the activation chain.
217 procedure Activate_Tasks
(Chain_Access
: Activation_Chain_Access
) is
218 Self_ID
: constant Task_Id
:= STPO
.Self
;
221 Next_C
, Last_C
: Task_Id
;
222 Activate_Prio
: System
.Any_Priority
;
224 All_Elaborated
: Boolean := True;
227 -- If pragma Detect_Blocking is active, then we must check whether this
228 -- potentially blocking operation is called from a protected action.
230 if System
.Tasking
.Detect_Blocking
231 and then Self_ID
.Common
.Protected_Action_Nesting
> 0
233 raise Program_Error
with "potentially blocking operation";
237 (Debug
.Trace
(Self_ID
, "Activate_Tasks", 'C'));
239 Initialization
.Defer_Abort_Nestable
(Self_ID
);
241 pragma Assert
(Self_ID
.Common
.Wait_Count
= 0);
243 -- Lock RTS_Lock, to prevent activated tasks from racing ahead before
244 -- we finish activating the chain.
248 -- Check that all task bodies have been elaborated
250 C
:= Chain_Access
.T_ID
;
253 if C
.Common
.Elaborated
/= null
254 and then not C
.Common
.Elaborated
.all
256 All_Elaborated
:= False;
259 -- Reverse the activation chain so that tasks are activated in the
260 -- same order they're declared.
262 Next_C
:= C
.Common
.Activation_Link
;
263 C
.Common
.Activation_Link
:= Last_C
;
268 Chain_Access
.T_ID
:= Last_C
;
270 if not All_Elaborated
then
272 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
273 raise Program_Error
with "Some tasks have not been elaborated";
276 -- Activate all the tasks in the chain. Creation of the thread of
277 -- control was deferred until activation. So create it now.
279 C
:= Chain_Access
.T_ID
;
281 if C
.Common
.State
/= Terminated
then
282 pragma Assert
(C
.Common
.State
= Unactivated
);
284 P
:= C
.Common
.Parent
;
289 (if C
.Common
.Base_Priority
< Get_Priority
(Self_ID
)
290 then Get_Priority
(Self_ID
)
291 else C
.Common
.Base_Priority
);
293 System
.Task_Primitives
.Operations
.Create_Task
294 (C
, Task_Wrapper
'Address,
296 (C
.Common
.Compiler_Data
.Pri_Stack_Info
.Size
),
297 Activate_Prio
, Success
);
299 -- There would be a race between the created task and the creator
300 -- to do the following initialization, if we did not have a
301 -- Lock/Unlock_RTS pair in the task wrapper to prevent it from
305 C
.Common
.State
:= Activating
;
308 P
.Awake_Count
:= P
.Awake_Count
+ 1;
309 P
.Alive_Count
:= P
.Alive_Count
+ 1;
311 if P
.Common
.State
= Master_Completion_Sleep
and then
312 C
.Master_of_Task
= P
.Master_Within
314 pragma Assert
(Self_ID
/= P
);
315 P
.Common
.Wait_Count
:= P
.Common
.Wait_Count
+ 1;
318 for J
in System
.Tasking
.Debug
.Known_Tasks
'Range loop
319 if System
.Tasking
.Debug
.Known_Tasks
(J
) = null then
320 System
.Tasking
.Debug
.Known_Tasks
(J
) := C
;
321 C
.Known_Tasks_Index
:= J
;
326 if Global_Task_Debug_Event_Set
then
327 Debug
.Signal_Debug_Event
328 (Debug
.Debug_Event_Activating
, C
);
331 C
.Common
.State
:= Runnable
;
337 -- No need to set Awake_Count, State, etc. here since the loop
338 -- below will do that for any Unactivated tasks.
342 Self_ID
.Common
.Activation_Failed
:= True;
346 C
:= C
.Common
.Activation_Link
;
349 if not Single_Lock
then
353 -- Close the entries of any tasks that failed thread creation, and count
354 -- those that have not finished activation.
356 Write_Lock
(Self_ID
);
357 Self_ID
.Common
.State
:= Activator_Sleep
;
359 C
:= Chain_Access
.T_ID
;
363 if C
.Common
.State
= Unactivated
then
364 C
.Common
.Activator
:= null;
365 C
.Common
.State
:= Terminated
;
367 Utilities
.Cancel_Queued_Entry_Calls
(C
);
369 elsif C
.Common
.Activator
/= null then
370 Self_ID
.Common
.Wait_Count
:= Self_ID
.Common
.Wait_Count
+ 1;
374 P
:= C
.Common
.Activation_Link
;
375 C
.Common
.Activation_Link
:= null;
379 -- Wait for the activated tasks to complete activation. It is
380 -- unsafe to abort any of these tasks until the count goes to zero.
383 exit when Self_ID
.Common
.Wait_Count
= 0;
384 Sleep
(Self_ID
, Activator_Sleep
);
387 Self_ID
.Common
.State
:= Runnable
;
394 -- Remove the tasks from the chain
396 Chain_Access
.T_ID
:= null;
397 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
399 if Self_ID
.Common
.Activation_Failed
then
400 Self_ID
.Common
.Activation_Failed
:= False;
401 raise Tasking_Error
with "Failure during activation";
405 -------------------------
406 -- Complete_Activation --
407 -------------------------
409 procedure Complete_Activation
is
410 Self_ID
: constant Task_Id
:= STPO
.Self
;
413 Initialization
.Defer_Abort_Nestable
(Self_ID
);
419 Vulnerable_Complete_Activation
(Self_ID
);
425 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
427 -- ??? Why do we need to allow for nested deferral here?
429 if Runtime_Traces
then
430 Send_Trace_Info
(T_Activate
);
432 end Complete_Activation
;
434 ---------------------
435 -- Complete_Master --
436 ---------------------
438 procedure Complete_Master
is
439 Self_ID
: constant Task_Id
:= STPO
.Self
;
442 (Self_ID
.Deferral_Level
> 0
443 or else not System
.Restrictions
.Abort_Allowed
);
444 Vulnerable_Complete_Master
(Self_ID
);
451 -- See comments on Vulnerable_Complete_Task for details
453 procedure Complete_Task
is
454 Self_ID
: constant Task_Id
:= STPO
.Self
;
458 (Self_ID
.Deferral_Level
> 0
459 or else not System
.Restrictions
.Abort_Allowed
);
461 Vulnerable_Complete_Task
(Self_ID
);
463 -- All of our dependents have terminated, never undefer abort again
471 -- Compiler interface only. Do not call from within the RTS. This must be
472 -- called to create a new task.
474 procedure Create_Task
476 Size
: System
.Parameters
.Size_Type
;
477 Task_Info
: System
.Task_Info
.Task_Info_Type
;
479 Relative_Deadline
: Ada
.Real_Time
.Time_Span
;
480 Domain
: Dispatching_Domain_Access
;
481 Num_Entries
: Task_Entry_Index
;
482 Master
: Master_Level
;
483 State
: Task_Procedure_Access
;
484 Discriminants
: System
.Address
;
485 Elaborated
: Access_Boolean
;
486 Chain
: in out Activation_Chain
;
488 Created_Task
: out Task_Id
)
491 Self_ID
: constant Task_Id
:= STPO
.Self
;
493 Base_Priority
: System
.Any_Priority
;
495 Base_CPU
: System
.Multiprocessors
.CPU_Range
;
497 use type System
.Multiprocessors
.CPU_Range
;
499 pragma Unreferenced
(Relative_Deadline
);
500 -- EDF scheduling is not supported by any of the target platforms so
501 -- this parameter is not passed any further.
504 -- If Master is greater than the current master, it means that Master
505 -- has already awaited its dependent tasks. This raises Program_Error,
506 -- by 4.8(10.3/2). See AI-280. Ignore this check for foreign threads.
508 if Self_ID
.Master_of_Task
/= Foreign_Task_Level
509 and then Master
> Self_ID
.Master_Within
511 raise Program_Error
with
512 "create task after awaiting termination";
515 -- If pragma Detect_Blocking is active must be checked whether this
516 -- potentially blocking operation is called from a protected action.
518 if System
.Tasking
.Detect_Blocking
519 and then Self_ID
.Common
.Protected_Action_Nesting
> 0
521 raise Program_Error
with "potentially blocking operation";
524 pragma Debug
(Debug
.Trace
(Self_ID
, "Create_Task", 'C'));
527 (if Priority
= Unspecified_Priority
528 then Self_ID
.Common
.Base_Priority
529 else System
.Any_Priority
(Priority
));
531 -- Legal values of CPU are the special Unspecified_CPU value which is
532 -- inserted by the compiler for tasks without CPU aspect, and those in
533 -- the range of CPU_Range but no greater than Number_Of_CPUs. Otherwise
534 -- the task is defined to have failed, and it becomes a completed task
537 if CPU
/= Unspecified_CPU
538 and then (CPU
< Integer (System
.Multiprocessors
.CPU_Range
'First)
540 CPU
> Integer (System
.Multiprocessors
.Number_Of_CPUs
))
542 raise Tasking_Error
with "CPU not in range";
544 -- Normal CPU affinity
547 -- When the application code says nothing about the task affinity
548 -- (task without CPU aspect) then the compiler inserts the value
549 -- Unspecified_CPU which indicates to the run-time library that
550 -- the task will activate and execute on the same processor as its
551 -- activating task if the activating task is assigned a processor
555 (if CPU
= Unspecified_CPU
556 then Self_ID
.Common
.Base_CPU
557 else System
.Multiprocessors
.CPU_Range
(CPU
));
560 -- Find parent P of new Task, via master level number. Independent
561 -- tasks should have Parent = Environment_Task, and all tasks created
562 -- by independent tasks are also independent. See, for example,
563 -- s-interr.adb, where Interrupt_Manager does "new Server_Task". The
564 -- access type is at library level, so the parent of the Server_Task
565 -- is Environment_Task.
569 if P
.Master_of_Task
<= Independent_Task_Level
then
570 P
:= Environment_Task
;
572 while P
/= null and then P
.Master_of_Task
>= Master
loop
573 P
:= P
.Common
.Parent
;
577 Initialization
.Defer_Abort_Nestable
(Self_ID
);
580 T
:= New_ATCB
(Num_Entries
);
583 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
584 raise Storage_Error
with "Cannot allocate task";
587 -- RTS_Lock is used by Abort_Dependents and Abort_Tasks. Up to this
588 -- point, it is possible that we may be part of a family of tasks that
592 Write_Lock
(Self_ID
);
594 -- Now, we must check that we have not been aborted. If so, we should
595 -- give up on creating this task, and simply return.
597 if not Self_ID
.Callable
then
598 pragma Assert
(Self_ID
.Pending_ATC_Level
= 0);
599 pragma Assert
(Self_ID
.Pending_Action
);
601 (Chain
.T_ID
= null or else Chain
.T_ID
.Common
.State
= Unactivated
);
605 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
607 -- ??? Should never get here
609 pragma Assert
(False);
610 raise Standard
'Abort_Signal;
613 Initialize_ATCB
(Self_ID
, State
, Discriminants
, P
, Elaborated
,
614 Base_Priority
, Base_CPU
, Domain
, Task_Info
, Size
, T
, Success
);
620 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
621 raise Storage_Error
with "Failed to initialize task";
624 if Master
= Foreign_Task_Level
+ 2 then
626 -- This should not happen, except when a foreign task creates non
627 -- library-level Ada tasks. In this case, we pretend the master is
628 -- a regular library level task, otherwise the run-time will get
629 -- confused when waiting for these tasks to terminate.
631 T
.Master_of_Task
:= Library_Task_Level
;
634 T
.Master_of_Task
:= Master
;
637 T
.Master_Within
:= T
.Master_of_Task
+ 1;
639 for L
in T
.Entry_Calls
'Range loop
640 T
.Entry_Calls
(L
).Self
:= T
;
641 T
.Entry_Calls
(L
).Level
:= L
;
644 if Task_Image
'Length = 0 then
645 T
.Common
.Task_Image_Len
:= 0;
648 T
.Common
.Task_Image
(1) := Task_Image
(Task_Image
'First);
650 -- Remove unwanted blank space generated by 'Image
652 for J
in Task_Image
'First + 1 .. Task_Image
'Last loop
653 if Task_Image
(J
) /= ' '
654 or else Task_Image
(J
- 1) /= '('
657 T
.Common
.Task_Image
(Len
) := Task_Image
(J
);
658 exit when Len
= T
.Common
.Task_Image
'Last;
662 T
.Common
.Task_Image_Len
:= Len
;
665 -- Note: we used to have code here to initialize T.Commmon.Domain, but
666 -- that is not needed, since this is initialized in System.Tasking.
671 -- The CPU associated to the task (if any) must belong to the
672 -- dispatching domain.
674 if Base_CPU
/= System
.Multiprocessors
.Not_A_Specific_CPU
676 (Base_CPU
not in T
.Common
.Domain
'Range
677 or else not T
.Common
.Domain
(Base_CPU
))
679 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
680 raise Tasking_Error
with "CPU not in dispatching domain";
683 -- To handle the interaction between pragma CPU and dispatching domains
684 -- we need to signal that this task is being allocated to a processor.
685 -- This is needed only for tasks belonging to the system domain (the
686 -- creation of new dispatching domains can only take processors from the
687 -- system domain) and only before the environment task calls the main
688 -- procedure (dispatching domains cannot be created after this).
690 if Base_CPU
/= System
.Multiprocessors
.Not_A_Specific_CPU
691 and then T
.Common
.Domain
= System
.Tasking
.System_Domain
692 and then not System
.Tasking
.Dispatching_Domains_Frozen
694 -- Increase the number of tasks attached to the CPU to which this
695 -- task is being moved.
697 Dispatching_Domain_Tasks
(Base_CPU
) :=
698 Dispatching_Domain_Tasks
(Base_CPU
) + 1;
701 -- Create TSD as early as possible in the creation of a task, since it
702 -- may be used by the operation of Ada code within the task.
704 SSL
.Create_TSD
(T
.Common
.Compiler_Data
);
705 T
.Common
.Activation_Link
:= Chain
.T_ID
;
708 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
710 if Runtime_Traces
then
711 Send_Trace_Info
(T_Create
, T
);
716 (Self_ID
, "Created task in " & T
.Master_of_Task
'Img, 'C', T
));
723 function Current_Master
return Master_Level
is
725 return STPO
.Self
.Master_Within
;
732 procedure Enter_Master
is
733 Self_ID
: constant Task_Id
:= STPO
.Self
;
735 Self_ID
.Master_Within
:= Self_ID
.Master_Within
+ 1;
738 (Self_ID
, "Enter_Master ->" & Self_ID
.Master_Within
'Img, 'M'));
741 -------------------------------
742 -- Expunge_Unactivated_Tasks --
743 -------------------------------
745 -- See procedure Close_Entries for the general case
747 procedure Expunge_Unactivated_Tasks
(Chain
: in out Activation_Chain
) is
748 Self_ID
: constant Task_Id
:= STPO
.Self
;
750 Call
: Entry_Call_Link
;
755 (Debug
.Trace
(Self_ID
, "Expunge_Unactivated_Tasks", 'C'));
757 Initialization
.Defer_Abort_Nestable
(Self_ID
);
760 -- Experimentation has shown that abort is sometimes (but not always)
761 -- already deferred when this is called.
763 -- That may indicate an error. Find out what is going on
767 pragma Assert
(C
.Common
.State
= Unactivated
);
769 Temp
:= C
.Common
.Activation_Link
;
771 if C
.Common
.State
= Unactivated
then
775 for J
in 1 .. C
.Entry_Num
loop
776 Queuing
.Dequeue_Head
(C
.Entry_Queues
(J
), Call
);
777 pragma Assert
(Call
= null);
782 Initialization
.Remove_From_All_Tasks_List
(C
);
785 Vulnerable_Free_Task
(C
);
791 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
792 end Expunge_Unactivated_Tasks
;
794 ---------------------------
795 -- Finalize_Global_Tasks --
796 ---------------------------
799 -- We have a potential problem here if finalization of global objects does
800 -- anything with signals or the timer server, since by that time those
801 -- servers have terminated.
803 -- It is hard to see how that would occur
805 -- However, a better solution might be to do all this finalization
806 -- using the global finalization chain.
808 procedure Finalize_Global_Tasks
is
809 Self_ID
: constant Task_Id
:= STPO
.Self
;
815 (Int
: System
.Interrupt_Management
.Interrupt_ID
) return Character;
816 pragma Import
(C
, State
, "__gnat_get_interrupt_state");
817 -- Get interrupt state for interrupt number Int. Defined in init.c
819 Default
: constant Character := 's';
820 -- 's' Interrupt_State pragma set state to System (use "default"
824 if Self_ID
.Deferral_Level
= 0 then
826 -- In principle, we should be able to predict whether abort is
827 -- already deferred here (and it should not be deferred yet but in
828 -- practice it seems Finalize_Global_Tasks is being called sometimes,
829 -- from RTS code for exceptions, with abort already deferred.
831 Initialization
.Defer_Abort_Nestable
(Self_ID
);
833 -- Never undefer again
836 -- This code is only executed by the environment task
838 pragma Assert
(Self_ID
= Environment_Task
);
840 -- Set Environment_Task'Callable to false to notify library-level tasks
841 -- that it is waiting for them.
843 Self_ID
.Callable
:= False;
845 -- Exit level 2 master, for normal tasks in library-level packages
849 -- Force termination of "independent" library-level server tasks
853 Abort_Dependents
(Self_ID
);
855 if not Single_Lock
then
859 -- We need to explicitly wait for the task to be terminated here
860 -- because on true concurrent system, we may end this procedure before
861 -- the tasks are really terminated.
863 Write_Lock
(Self_ID
);
865 -- If the Abort_Task signal is set to system, it means that we may
866 -- not have been able to abort all independent tasks (in particular,
867 -- Server_Task may be blocked, waiting for a signal), in which case, do
868 -- not wait for Independent_Task_Count to go down to 0. We arbitrarily
869 -- limit the number of loop iterations; if an independent task does not
870 -- terminate, we do not want to hang here. In that case, the thread will
871 -- be terminated when the process exits.
873 if State
(System
.Interrupt_Management
.Abort_Task_Interrupt
) /= Default
875 for J
in 1 .. 10 loop
876 exit when Utilities
.Independent_Task_Count
= 0;
878 -- We used to yield here, but this did not take into account low
879 -- priority tasks that would cause dead lock in some cases (true
883 (Self_ID
, 0.01, System
.OS_Primitives
.Relative
,
884 Self_ID
.Common
.State
, Ignore_1
, Ignore_2
);
888 -- ??? On multi-processor environments, it seems that the above loop
889 -- isn't sufficient, so we need to add an additional delay.
892 (Self_ID
, 0.01, System
.OS_Primitives
.Relative
,
893 Self_ID
.Common
.State
, Ignore_1
, Ignore_2
);
901 -- Complete the environment task
903 Vulnerable_Complete_Task
(Self_ID
);
905 -- Handle normal task termination by the environment task, but only
906 -- for the normal task termination. In the case of Abnormal and
907 -- Unhandled_Exception they must have been handled before, and the
908 -- task termination soft link must have been changed so the task
909 -- termination routine is not executed twice.
911 SSL
.Task_Termination_Handler
.all (Ada
.Exceptions
.Null_Occurrence
);
913 -- Finalize all library-level controlled objects
915 if not SSL
."=" (SSL
.Finalize_Library_Objects
, null) then
916 SSL
.Finalize_Library_Objects
.all;
919 -- Reset the soft links to non-tasking
921 SSL
.Abort_Defer
:= SSL
.Abort_Defer_NT
'Access;
922 SSL
.Abort_Undefer
:= SSL
.Abort_Undefer_NT
'Access;
923 SSL
.Lock_Task
:= SSL
.Task_Lock_NT
'Access;
924 SSL
.Unlock_Task
:= SSL
.Task_Unlock_NT
'Access;
925 SSL
.Get_Jmpbuf_Address
:= SSL
.Get_Jmpbuf_Address_NT
'Access;
926 SSL
.Set_Jmpbuf_Address
:= SSL
.Set_Jmpbuf_Address_NT
'Access;
927 SSL
.Get_Sec_Stack_Addr
:= SSL
.Get_Sec_Stack_Addr_NT
'Access;
928 SSL
.Set_Sec_Stack_Addr
:= SSL
.Set_Sec_Stack_Addr_NT
'Access;
929 SSL
.Check_Abort_Status
:= SSL
.Check_Abort_Status_NT
'Access;
930 SSL
.Get_Stack_Info
:= SSL
.Get_Stack_Info_NT
'Access;
932 -- Don't bother trying to finalize Initialization.Global_Task_Lock
933 -- and System.Task_Primitives.RTS_Lock.
935 end Finalize_Global_Tasks
;
941 procedure Free_Task
(T
: Task_Id
) is
942 Self_Id
: constant Task_Id
:= Self
;
945 if T
.Common
.State
= Terminated
then
947 -- It is not safe to call Abort_Defer or Write_Lock at this stage
949 Initialization
.Task_Lock
(Self_Id
);
952 Initialization
.Finalize_Attributes
(T
);
953 Initialization
.Remove_From_All_Tasks_List
(T
);
956 Initialization
.Task_Unlock
(Self_Id
);
958 System
.Task_Primitives
.Operations
.Finalize_TCB
(T
);
961 -- If the task is not terminated, then mark the task as to be freed
964 T
.Free_On_Termination
:= True;
968 ---------------------------
969 -- Move_Activation_Chain --
970 ---------------------------
972 procedure Move_Activation_Chain
973 (From
, To
: Activation_Chain_Access
;
974 New_Master
: Master_ID
)
976 Self_ID
: constant Task_Id
:= STPO
.Self
;
981 (Debug
.Trace
(Self_ID
, "Move_Activation_Chain", 'C'));
983 -- Nothing to do if From is empty, and we can check that without
992 Initialization
.Defer_Abort_Nestable
(Self_ID
);
994 -- Loop through the From chain, changing their Master_of_Task fields,
995 -- and to find the end of the chain.
998 C
.Master_of_Task
:= New_Master
;
999 exit when C
.Common
.Activation_Link
= null;
1000 C
:= C
.Common
.Activation_Link
;
1003 -- Hook From in at the start of To
1005 C
.Common
.Activation_Link
:= To
.all.T_ID
;
1006 To
.all.T_ID
:= From
.all.T_ID
;
1008 -- Set From to empty
1010 From
.all.T_ID
:= null;
1012 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
1013 end Move_Activation_Chain
;
1019 -- The task wrapper is a procedure that is called first for each task body
1020 -- and which in turn calls the compiler-generated task body procedure.
1021 -- The wrapper's main job is to do initialization for the task. It also
1022 -- has some locally declared objects that serve as per-task local data.
1023 -- Task finalization is done by Complete_Task, which is called from an
1024 -- at-end handler that the compiler generates.
1026 procedure Task_Wrapper
(Self_ID
: Task_Id
) is
1027 use type SSE
.Storage_Offset
;
1028 use System
.Standard_Library
;
1029 use System
.Stack_Usage
;
1031 Bottom_Of_Stack
: aliased Integer;
1033 Task_Alternate_Stack
:
1034 aliased SSE
.Storage_Array
(1 .. Alternate_Stack_Size
);
1035 -- The alternate signal stack for this task, if any
1037 Use_Alternate_Stack
: constant Boolean := Alternate_Stack_Size
/= 0;
1038 -- Whether to use above alternate signal stack for stack overflows
1040 Secondary_Stack_Size
:
1041 constant SSE
.Storage_Offset
:=
1042 Self_ID
.Common
.Compiler_Data
.Pri_Stack_Info
.Size
*
1043 SSE
.Storage_Offset
(Parameters
.Sec_Stack_Percentage
) / 100;
1045 Secondary_Stack
: aliased SSE
.Storage_Array
(1 .. Secondary_Stack_Size
);
1046 for Secondary_Stack
'Alignment use Standard
'Maximum_Alignment;
1047 -- Actual area allocated for secondary stack. Note that it is critical
1048 -- that this have maximum alignment, since any kind of data can be
1051 Secondary_Stack_Address
: System
.Address
:= Secondary_Stack
'Address;
1052 -- Address of secondary stack. In the fixed secondary stack case, this
1053 -- value is not modified, causing a warning, hence the bracketing with
1054 -- Warnings (Off/On). But why is so much *more* bracketed???
1056 SEH_Table
: aliased SSE
.Storage_Array
(1 .. 8);
1057 -- Structured Exception Registration table (2 words)
1059 procedure Install_SEH_Handler
(Addr
: System
.Address
);
1060 pragma Import
(C
, Install_SEH_Handler
, "__gnat_install_SEH_handler");
1061 -- Install the SEH (Structured Exception Handling) handler
1063 Cause
: Cause_Of_Termination
:= Normal
;
1064 -- Indicates the reason why this task terminates. Normal corresponds to
1065 -- a task terminating due to completing the last statement of its body,
1066 -- or as a result of waiting on a terminate alternative. If the task
1067 -- terminates because it is being aborted then Cause will be set
1068 -- to Abnormal. If the task terminates because of an exception
1069 -- raised by the execution of its task body, then Cause is set
1070 -- to Unhandled_Exception.
1072 EO
: Exception_Occurrence
;
1073 -- If the task terminates because of an exception raised by the
1074 -- execution of its task body, then EO will contain the associated
1075 -- exception occurrence. Otherwise, it will contain Null_Occurrence.
1077 TH
: Termination_Handler
:= null;
1078 -- Pointer to the protected procedure to be executed upon task
1081 procedure Search_Fall_Back_Handler
(ID
: Task_Id
);
1082 -- Procedure that searches recursively a fall-back handler through the
1083 -- master relationship. If the handler is found, its pointer is stored
1084 -- in TH. It stops when the handler is found or when the ID is null.
1086 ------------------------------
1087 -- Search_Fall_Back_Handler --
1088 ------------------------------
1090 procedure Search_Fall_Back_Handler
(ID
: Task_Id
) is
1092 -- A null Task_Id indicates that we have reached the root of the
1093 -- task hierarchy and no handler has been found.
1098 -- If there is a fall back handler, store its pointer for later
1101 elsif ID
.Common
.Fall_Back_Handler
/= null then
1102 TH
:= ID
.Common
.Fall_Back_Handler
;
1104 -- Otherwise look for a fall back handler in the parent
1107 Search_Fall_Back_Handler
(ID
.Common
.Parent
);
1109 end Search_Fall_Back_Handler
;
1111 -- Start of processing for Task_Wrapper
1114 pragma Assert
(Self_ID
.Deferral_Level
= 1);
1117 (Self_ID
, Self_ID
.Common
.Parent
, Self_ID
.Master_of_Task
);
1119 -- Assume a size of the stack taken at this stage
1121 if not Parameters
.Sec_Stack_Dynamic
then
1122 Self_ID
.Common
.Compiler_Data
.Sec_Stack_Addr
:=
1123 Secondary_Stack
'Address;
1124 SST
.SS_Init
(Secondary_Stack_Address
, Integer (Secondary_Stack
'Last));
1127 if Use_Alternate_Stack
then
1128 Self_ID
.Common
.Task_Alternate_Stack
:= Task_Alternate_Stack
'Address;
1131 -- Set the guard page at the bottom of the stack. The call to unprotect
1132 -- the page is done in Terminate_Task
1134 Stack_Guard
(Self_ID
, True);
1136 -- Initialize low-level TCB components, that cannot be initialized by
1137 -- the creator. Enter_Task sets Self_ID.LL.Thread.
1139 Enter_Task
(Self_ID
);
1141 -- Initialize dynamic stack usage
1143 if System
.Stack_Usage
.Is_Enabled
then
1145 Guard_Page_Size
: constant := 16 * 1024;
1146 -- Part of the stack used as a guard page. This is an OS dependent
1147 -- value, so we need to use the maximum. This value is only used
1148 -- when the stack address is known, that is currently Windows.
1150 Small_Overflow_Guard
: constant := 12 * 1024;
1151 -- Note: this used to be 4K, but was changed to 12K, since
1152 -- smaller values resulted in segmentation faults from dynamic
1155 Big_Overflow_Guard
: constant := 64 * 1024 + 8 * 1024;
1156 Small_Stack_Limit
: constant := 64 * 1024;
1157 -- ??? These three values are experimental, and seem to work on
1158 -- most platforms. They still need to be analyzed further. They
1159 -- also need documentation, what are they and why does the logic
1160 -- differ depending on whether the stack is large or small???
1162 Pattern_Size
: Natural :=
1163 Natural (Self_ID
.Common
.
1164 Compiler_Data
.Pri_Stack_Info
.Size
);
1165 -- Size of the pattern
1167 Stack_Base
: Address
;
1168 -- Address of the base of the stack
1171 Stack_Base
:= Self_ID
.Common
.Compiler_Data
.Pri_Stack_Info
.Base
;
1173 if Stack_Base
= Null_Address
then
1175 -- On many platforms, we don't know the real stack base
1176 -- address. Estimate it using an address in the frame.
1178 Stack_Base
:= Bottom_Of_Stack
'Address;
1180 -- Also reduce the size of the stack to take into account the
1181 -- secondary stack array declared in this frame. This is for
1182 -- sure very conservative.
1184 if not Parameters
.Sec_Stack_Dynamic
then
1186 Pattern_Size
- Natural (Secondary_Stack_Size
);
1189 -- Adjustments for inner frames
1191 Pattern_Size
:= Pattern_Size
-
1192 (if Pattern_Size
< Small_Stack_Limit
1193 then Small_Overflow_Guard
1194 else Big_Overflow_Guard
);
1196 -- Reduce by the size of the final guard page
1198 Pattern_Size
:= Pattern_Size
- Guard_Page_Size
;
1203 (Self_ID
.Common
.Analyzer
,
1204 Self_ID
.Common
.Task_Image
(1 .. Self_ID
.Common
.Task_Image_Len
),
1205 Natural (Self_ID
.Common
.Compiler_Data
.Pri_Stack_Info
.Size
),
1206 SSE
.To_Integer
(Stack_Base
),
1209 Fill_Stack
(Self_ID
.Common
.Analyzer
);
1213 -- We setup the SEH (Structured Exception Handling) handler if supported
1216 Install_SEH_Handler
(SEH_Table
'Address);
1218 -- Initialize exception occurrence
1220 Save_Occurrence
(EO
, Ada
.Exceptions
.Null_Occurrence
);
1222 -- We lock RTS_Lock to wait for activator to finish activating the rest
1223 -- of the chain, so that everyone in the chain comes out in priority
1226 -- This also protects the value of
1227 -- Self_ID.Common.Activator.Common.Wait_Count.
1232 if not System
.Restrictions
.Abort_Allowed
then
1234 -- If Abort is not allowed, reset the deferral level since it will
1235 -- not get changed by the generated code. Keeping a default value
1236 -- of one would prevent some operations (e.g. select or delay) to
1237 -- proceed successfully.
1239 Self_ID
.Deferral_Level
:= 0;
1242 if Global_Task_Debug_Event_Set
then
1243 Debug
.Signal_Debug_Event
(Debug
.Debug_Event_Run
, Self_ID
);
1247 -- We are separating the following portion of the code in order to
1248 -- place the exception handlers in a different block. In this way,
1249 -- we do not call Set_Jmpbuf_Address (which needs Self) before we
1250 -- set Self in Enter_Task
1252 -- Call the task body procedure
1254 -- The task body is called with abort still deferred. That
1255 -- eliminates a dangerous window, for which we had to patch-up in
1258 -- During the expansion of the task body, we insert an RTS-call
1259 -- to Abort_Undefer, at the first point where abort should be
1262 Self_ID
.Common
.Task_Entry_Point
(Self_ID
.Common
.Task_Arg
);
1263 Initialization
.Defer_Abort_Nestable
(Self_ID
);
1266 -- We can't call Terminate_Task in the exception handlers below,
1267 -- since there may be (e.g. in the case of GCC exception handling)
1268 -- clean ups associated with the exception handler that need to
1269 -- access task specific data.
1271 -- Defer abort so that this task can't be aborted while exiting
1273 when Standard
'Abort_Signal =>
1274 Initialization
.Defer_Abort_Nestable
(Self_ID
);
1276 -- Update the cause that motivated the task termination so that
1277 -- the appropriate information is passed to the task termination
1278 -- procedure. Task termination as a result of waiting on a
1279 -- terminate alternative is a normal termination, although it is
1280 -- implemented using the abort mechanisms.
1282 if Self_ID
.Terminate_Alternative
then
1285 if Global_Task_Debug_Event_Set
then
1286 Debug
.Signal_Debug_Event
1287 (Debug
.Debug_Event_Terminated
, Self_ID
);
1292 if Global_Task_Debug_Event_Set
then
1293 Debug
.Signal_Debug_Event
1294 (Debug
.Debug_Event_Abort_Terminated
, Self_ID
);
1299 -- ??? Using an E : others here causes CD2C11A to fail on Tru64
1301 Initialization
.Defer_Abort_Nestable
(Self_ID
);
1303 -- Perform the task specific exception tracing duty. We handle
1304 -- these outputs here and not in the common notification routine
1305 -- because we need access to tasking related data and we don't
1306 -- want to drag dependencies against tasking related units in the
1307 -- the common notification units. Additionally, no trace is ever
1308 -- triggered from the common routine for the Unhandled_Raise case
1309 -- in tasks, since an exception never appears unhandled in this
1310 -- context because of this handler.
1312 if Exception_Trace
= Unhandled_Raise
then
1313 Trace_Unhandled_Exception_In_Task
(Self_ID
);
1316 -- Update the cause that motivated the task termination so that
1317 -- the appropriate information is passed to the task termination
1318 -- procedure, as well as the associated Exception_Occurrence.
1320 Cause
:= Unhandled_Exception
;
1322 Save_Occurrence
(EO
, SSL
.Get_Current_Excep
.all.all);
1324 if Global_Task_Debug_Event_Set
then
1325 Debug
.Signal_Debug_Event
1326 (Debug
.Debug_Event_Exception_Terminated
, Self_ID
);
1330 -- Look for a task termination handler. This code is for all tasks but
1331 -- the environment task. The task termination code for the environment
1332 -- task is executed by SSL.Task_Termination_Handler.
1338 Write_Lock
(Self_ID
);
1340 if Self_ID
.Common
.Specific_Handler
/= null then
1341 TH
:= Self_ID
.Common
.Specific_Handler
;
1343 -- Look for a fall-back handler following the master relationship
1344 -- for the task. As specified in ARM C.7.3 par. 9/2, "the fall-back
1345 -- handler applies only to the dependent tasks of the task". Hence,
1346 -- if the terminating tasks (Self_ID) had a fall-back handler, it
1347 -- would not apply to itself, so we start the search with the parent.
1349 Search_Fall_Back_Handler
(Self_ID
.Common
.Parent
);
1358 -- Execute the task termination handler if we found it
1362 TH
.all (Cause
, Self_ID
, EO
);
1366 -- RM-C.7.3 requires all exceptions raised here to be ignored
1373 if System
.Stack_Usage
.Is_Enabled
then
1374 Compute_Result
(Self_ID
.Common
.Analyzer
);
1375 Report_Result
(Self_ID
.Common
.Analyzer
);
1378 Terminate_Task
(Self_ID
);
1381 --------------------
1382 -- Terminate_Task --
1383 --------------------
1385 -- Before we allow the thread to exit, we must clean up. This is a delicate
1386 -- job. We must wake up the task's master, who may immediately try to
1387 -- deallocate the ATCB from the current task WHILE IT IS STILL EXECUTING.
1389 -- To avoid this, the parent task must be blocked up to the latest
1390 -- statement executed. The trouble is that we have another step that we
1391 -- also want to postpone to the very end, i.e., calling SSL.Destroy_TSD.
1392 -- We have to postpone that until the end because compiler-generated code
1393 -- is likely to try to access that data at just about any point.
1395 -- We can't call Destroy_TSD while we are holding any other locks, because
1396 -- it locks Global_Task_Lock, and our deadlock prevention rules require
1397 -- that to be the outermost lock. Our first "solution" was to just lock
1398 -- Global_Task_Lock in addition to the other locks, and force the parent to
1399 -- also lock this lock between its wakeup and its freeing of the ATCB. See
1400 -- Complete_Task for the parent-side of the code that has the matching
1401 -- calls to Task_Lock and Task_Unlock. That was not really a solution,
1402 -- since the operation Task_Unlock continued to access the ATCB after
1403 -- unlocking, after which the parent was observed to race ahead, deallocate
1404 -- the ATCB, and then reallocate it to another task. The call to
1405 -- Undefer_Abort in Task_Unlock by the "terminated" task was overwriting
1406 -- the data of the new task that reused the ATCB. To solve this problem, we
1407 -- introduced the new operation Final_Task_Unlock.
1409 procedure Terminate_Task
(Self_ID
: Task_Id
) is
1410 Environment_Task
: constant Task_Id
:= STPO
.Environment_Task
;
1411 Master_of_Task
: Integer;
1412 Deallocate
: Boolean;
1415 Debug
.Task_Termination_Hook
;
1417 if Runtime_Traces
then
1418 Send_Trace_Info
(T_Terminate
);
1421 -- Since GCC cannot allocate stack chunks efficiently without reordering
1422 -- some of the allocations, we have to handle this unexpected situation
1423 -- here. Normally we never have to call Vulnerable_Complete_Task here.
1425 if Self_ID
.Common
.Activator
/= null then
1426 Vulnerable_Complete_Task
(Self_ID
);
1429 Initialization
.Task_Lock
(Self_ID
);
1435 Master_of_Task
:= Self_ID
.Master_of_Task
;
1437 -- Check if the current task is an independent task If so, decrement
1438 -- the Independent_Task_Count value.
1440 if Master_of_Task
= Independent_Task_Level
then
1442 Utilities
.Independent_Task_Count
:=
1443 Utilities
.Independent_Task_Count
- 1;
1446 Write_Lock
(Environment_Task
);
1447 Utilities
.Independent_Task_Count
:=
1448 Utilities
.Independent_Task_Count
- 1;
1449 Unlock
(Environment_Task
);
1453 -- Unprotect the guard page if needed
1455 Stack_Guard
(Self_ID
, False);
1457 Utilities
.Make_Passive
(Self_ID
, Task_Completed
=> True);
1458 Deallocate
:= Self_ID
.Free_On_Termination
;
1464 pragma Assert
(Check_Exit
(Self_ID
));
1466 SSL
.Destroy_TSD
(Self_ID
.Common
.Compiler_Data
);
1467 Initialization
.Final_Task_Unlock
(Self_ID
);
1469 -- WARNING: past this point, this thread must assume that the ATCB has
1470 -- been deallocated, and can't access it anymore (which is why we have
1471 -- saved the Free_On_Termination flag in a temporary variable).
1474 Free_Task
(Self_ID
);
1477 if Master_of_Task
> 0 then
1486 function Terminated
(T
: Task_Id
) return Boolean is
1487 Self_ID
: constant Task_Id
:= STPO
.Self
;
1491 Initialization
.Defer_Abort_Nestable
(Self_ID
);
1498 Result
:= T
.Common
.State
= Terminated
;
1505 Initialization
.Undefer_Abort_Nestable
(Self_ID
);
1509 ----------------------------------------
1510 -- Trace_Unhandled_Exception_In_Task --
1511 ----------------------------------------
1513 procedure Trace_Unhandled_Exception_In_Task
(Self_Id
: Task_Id
) is
1514 procedure To_Stderr
(S
: String);
1515 pragma Import
(Ada
, To_Stderr
, "__gnat_to_stderr");
1517 use System
.Soft_Links
;
1518 use System
.Standard_Library
;
1520 function To_Address
is new
1521 Ada
.Unchecked_Conversion
1522 (Task_Id
, System
.Task_Primitives
.Task_Address
);
1524 Excep
: constant Exception_Occurrence_Access
:=
1525 SSL
.Get_Current_Excep
.all;
1528 -- This procedure is called by the task outermost handler in
1529 -- Task_Wrapper below, so only once the task stack has been fully
1530 -- unwound. The common notification routine has been called at the
1531 -- raise point already.
1533 -- Lock to prevent unsynchronized output
1535 Initialization
.Task_Lock
(Self_Id
);
1536 To_Stderr
("task ");
1538 if Self_Id
.Common
.Task_Image_Len
/= 0 then
1540 (Self_Id
.Common
.Task_Image
(1 .. Self_Id
.Common
.Task_Image_Len
));
1544 To_Stderr
(System
.Address_Image
(To_Address
(Self_Id
)));
1545 To_Stderr
(" terminated by unhandled exception");
1546 To_Stderr
((1 => ASCII
.LF
));
1547 To_Stderr
(Exception_Information
(Excep
.all));
1548 Initialization
.Task_Unlock
(Self_Id
);
1549 end Trace_Unhandled_Exception_In_Task
;
1551 ------------------------------------
1552 -- Vulnerable_Complete_Activation --
1553 ------------------------------------
1555 -- As in several other places, the locks of the activator and activated
1556 -- task are both locked here. This follows our deadlock prevention lock
1557 -- ordering policy, since the activated task must be created after the
1560 procedure Vulnerable_Complete_Activation
(Self_ID
: Task_Id
) is
1561 Activator
: constant Task_Id
:= Self_ID
.Common
.Activator
;
1564 pragma Debug
(Debug
.Trace
(Self_ID
, "V_Complete_Activation", 'C'));
1566 Write_Lock
(Activator
);
1567 Write_Lock
(Self_ID
);
1569 pragma Assert
(Self_ID
.Common
.Activator
/= null);
1571 -- Remove dangling reference to Activator, since a task may outlive its
1574 Self_ID
.Common
.Activator
:= null;
1576 -- Wake up the activator, if it is waiting for a chain of tasks to
1577 -- activate, and we are the last in the chain to complete activation.
1579 if Activator
.Common
.State
= Activator_Sleep
then
1580 Activator
.Common
.Wait_Count
:= Activator
.Common
.Wait_Count
- 1;
1582 if Activator
.Common
.Wait_Count
= 0 then
1583 Wakeup
(Activator
, Activator_Sleep
);
1587 -- The activator raises a Tasking_Error if any task it is activating
1588 -- is completed before the activation is done. However, if the reason
1589 -- for the task completion is an abort, we do not raise an exception.
1592 if not Self_ID
.Callable
and then Self_ID
.Pending_ATC_Level
/= 0 then
1593 Activator
.Common
.Activation_Failed
:= True;
1599 -- After the activation, active priority should be the same as base
1600 -- priority. We must unlock the Activator first, though, since it
1601 -- should not wait if we have lower priority.
1603 if Get_Priority
(Self_ID
) /= Self_ID
.Common
.Base_Priority
then
1604 Write_Lock
(Self_ID
);
1605 Set_Priority
(Self_ID
, Self_ID
.Common
.Base_Priority
);
1608 end Vulnerable_Complete_Activation
;
1610 --------------------------------
1611 -- Vulnerable_Complete_Master --
1612 --------------------------------
1614 procedure Vulnerable_Complete_Master
(Self_ID
: Task_Id
) is
1617 CM
: constant Master_Level
:= Self_ID
.Master_Within
;
1618 T
: aliased Task_Id
;
1620 To_Be_Freed
: Task_Id
;
1621 -- This is a list of ATCBs to be freed, after we have released all RTS
1622 -- locks. This is necessary because of the locking order rules, since
1623 -- the storage manager uses Global_Task_Lock.
1625 pragma Warnings
(Off
);
1626 function Check_Unactivated_Tasks
return Boolean;
1627 pragma Warnings
(On
);
1628 -- Temporary error-checking code below. This is part of the checks
1629 -- added in the new run time. Call it only inside a pragma Assert.
1631 -----------------------------
1632 -- Check_Unactivated_Tasks --
1633 -----------------------------
1635 function Check_Unactivated_Tasks
return Boolean is
1637 if not Single_Lock
then
1641 Write_Lock
(Self_ID
);
1643 C
:= All_Tasks_List
;
1644 while C
/= null loop
1645 if C
.Common
.Activator
= Self_ID
and then C
.Master_of_Task
= CM
then
1649 if C
.Common
.Parent
= Self_ID
and then C
.Master_of_Task
= CM
then
1652 if C
.Common
.State
= Unactivated
then
1659 C
:= C
.Common
.All_Tasks_Link
;
1664 if not Single_Lock
then
1669 end Check_Unactivated_Tasks
;
1671 -- Start of processing for Vulnerable_Complete_Master
1675 (Debug
.Trace
(Self_ID
, "V_Complete_Master(" & CM
'Img & ")", 'C'));
1677 pragma Assert
(Self_ID
.Common
.Wait_Count
= 0);
1679 (Self_ID
.Deferral_Level
> 0
1680 or else not System
.Restrictions
.Abort_Allowed
);
1682 -- Count how many active dependent tasks this master currently has, and
1683 -- record this in Wait_Count.
1685 -- This count should start at zero, since it is initialized to zero for
1686 -- new tasks, and the task should not exit the sleep-loops that use this
1687 -- count until the count reaches zero.
1689 -- While we're counting, if we run across any unactivated tasks that
1690 -- belong to this master, we summarily terminate them as required by
1694 Write_Lock
(Self_ID
);
1696 C
:= All_Tasks_List
;
1697 while C
/= null loop
1699 -- Terminate unactivated (never-to-be activated) tasks
1701 if C
.Common
.Activator
= Self_ID
and then C
.Master_of_Task
= CM
then
1703 -- Usually, C.Common.Activator = Self_ID implies C.Master_of_Task
1704 -- = CM. The only case where C is pending activation by this
1705 -- task, but the master of C is not CM is in Ada 2005, when C is
1706 -- part of a return object of a build-in-place function.
1708 pragma Assert
(C
.Common
.State
= Unactivated
);
1711 C
.Common
.Activator
:= null;
1712 C
.Common
.State
:= Terminated
;
1713 C
.Callable
:= False;
1714 Utilities
.Cancel_Queued_Entry_Calls
(C
);
1718 -- Count it if directly dependent on this master
1720 if C
.Common
.Parent
= Self_ID
and then C
.Master_of_Task
= CM
then
1723 if C
.Awake_Count
/= 0 then
1724 Self_ID
.Common
.Wait_Count
:= Self_ID
.Common
.Wait_Count
+ 1;
1730 C
:= C
.Common
.All_Tasks_Link
;
1733 Self_ID
.Common
.State
:= Master_Completion_Sleep
;
1736 if not Single_Lock
then
1740 -- Wait until dependent tasks are all terminated or ready to terminate.
1741 -- While waiting, the task may be awakened if the task's priority needs
1742 -- changing, or this master is aborted. In the latter case, we abort the
1743 -- dependents, and resume waiting until Wait_Count goes to zero.
1745 Write_Lock
(Self_ID
);
1748 exit when Self_ID
.Common
.Wait_Count
= 0;
1750 -- Here is a difference as compared to Complete_Master
1752 if Self_ID
.Pending_ATC_Level
< Self_ID
.ATC_Nesting_Level
1753 and then not Self_ID
.Dependents_Aborted
1756 Abort_Dependents
(Self_ID
);
1760 Abort_Dependents
(Self_ID
);
1762 Write_Lock
(Self_ID
);
1766 (Debug
.Trace
(Self_ID
, "master_completion_sleep", 'C'));
1767 Sleep
(Self_ID
, Master_Completion_Sleep
);
1771 Self_ID
.Common
.State
:= Runnable
;
1774 -- Dependents are all terminated or on terminate alternatives. Now,
1775 -- force those on terminate alternatives to terminate, by aborting them.
1777 pragma Assert
(Check_Unactivated_Tasks
);
1779 if Self_ID
.Alive_Count
> 1 then
1781 -- Consider finding a way to skip the following extra steps if there
1782 -- are no dependents with terminate alternatives. This could be done
1783 -- by adding another count to the ATCB, similar to Awake_Count, but
1784 -- keeping track of tasks that are on terminate alternatives.
1786 pragma Assert
(Self_ID
.Common
.Wait_Count
= 0);
1788 -- Force any remaining dependents to terminate by aborting them
1790 if not Single_Lock
then
1794 Abort_Dependents
(Self_ID
);
1796 -- Above, when we "abort" the dependents we are simply using this
1797 -- operation for convenience. We are not required to support the full
1798 -- abort-statement semantics; in particular, we are not required to
1799 -- immediately cancel any queued or in-service entry calls. That is
1800 -- good, because if we tried to cancel a call we would need to lock
1801 -- the caller, in order to wake the caller up. Our anti-deadlock
1802 -- rules prevent us from doing that without releasing the locks on C
1803 -- and Self_ID. Releasing and retaking those locks would be wasteful
1804 -- at best, and should not be considered further without more
1805 -- detailed analysis of potential concurrent accesses to the ATCBs
1806 -- of C and Self_ID.
1808 -- Count how many "alive" dependent tasks this master currently has,
1809 -- and record this in Wait_Count. This count should start at zero,
1810 -- since it is initialized to zero for new tasks, and the task should
1811 -- not exit the sleep-loops that use this count until the count
1814 pragma Assert
(Self_ID
.Common
.Wait_Count
= 0);
1816 Write_Lock
(Self_ID
);
1818 C
:= All_Tasks_List
;
1819 while C
/= null loop
1820 if C
.Common
.Parent
= Self_ID
and then C
.Master_of_Task
= CM
then
1823 pragma Assert
(C
.Awake_Count
= 0);
1825 if C
.Alive_Count
> 0 then
1826 pragma Assert
(C
.Terminate_Alternative
);
1827 Self_ID
.Common
.Wait_Count
:= Self_ID
.Common
.Wait_Count
+ 1;
1833 C
:= C
.Common
.All_Tasks_Link
;
1836 Self_ID
.Common
.State
:= Master_Phase_2_Sleep
;
1839 if not Single_Lock
then
1843 -- Wait for all counted tasks to finish terminating themselves
1845 Write_Lock
(Self_ID
);
1848 exit when Self_ID
.Common
.Wait_Count
= 0;
1849 Sleep
(Self_ID
, Master_Phase_2_Sleep
);
1852 Self_ID
.Common
.State
:= Runnable
;
1856 -- We don't wake up for abort here. We are already terminating just as
1857 -- fast as we can, so there is no point.
1859 -- Remove terminated tasks from the list of Self_ID's dependents, but
1860 -- don't free their ATCBs yet, because of lock order restrictions, which
1861 -- don't allow us to call "free" or "malloc" while holding any other
1862 -- locks. Instead, we put those ATCBs to be freed onto a temporary list,
1863 -- called To_Be_Freed.
1865 if not Single_Lock
then
1869 C
:= All_Tasks_List
;
1871 while C
/= null loop
1873 -- If Free_On_Termination is set, do nothing here, and let the
1874 -- task free itself if not already done, otherwise we risk a race
1875 -- condition where Vulnerable_Free_Task is called in the loop below,
1876 -- while the task calls Free_Task itself, in Terminate_Task.
1878 if C
.Common
.Parent
= Self_ID
1879 and then C
.Master_of_Task
>= CM
1880 and then not C
.Free_On_Termination
1883 P
.Common
.All_Tasks_Link
:= C
.Common
.All_Tasks_Link
;
1885 All_Tasks_List
:= C
.Common
.All_Tasks_Link
;
1888 T
:= C
.Common
.All_Tasks_Link
;
1889 C
.Common
.All_Tasks_Link
:= To_Be_Freed
;
1895 C
:= C
.Common
.All_Tasks_Link
;
1901 -- Free all the ATCBs on the list To_Be_Freed
1903 -- The ATCBs in the list are no longer in All_Tasks_List, and after
1904 -- any interrupt entries are detached from them they should no longer
1907 -- Global_Task_Lock (Task_Lock/Unlock) is locked in the loop below to
1908 -- avoid a race between a terminating task and its parent. The parent
1909 -- might try to deallocate the ACTB out from underneath the exiting
1910 -- task. Note that Free will also lock Global_Task_Lock, but that is
1911 -- OK, since this is the *one* lock for which we have a mechanism to
1912 -- support nested locking. See Task_Wrapper and its finalizer for more
1916 -- The check "T.Common.Parent /= null ..." below is to prevent dangling
1917 -- references to terminated library-level tasks, which could otherwise
1918 -- occur during finalization of library-level objects. A better solution
1919 -- might be to hook task objects into the finalization chain and
1920 -- deallocate the ATCB when the task object is deallocated. However,
1921 -- this change is not likely to gain anything significant, since all
1922 -- this storage should be recovered en-masse when the process exits.
1924 while To_Be_Freed
/= null loop
1926 To_Be_Freed
:= T
.Common
.All_Tasks_Link
;
1928 -- ??? On SGI there is currently no Interrupt_Manager, that's why we
1929 -- need to check if the Interrupt_Manager_ID is null.
1931 if T
.Interrupt_Entry
and then Interrupt_Manager_ID
/= null then
1933 Detach_Interrupt_Entries_Index
: constant Task_Entry_Index
:= 1;
1934 -- Corresponds to the entry index of System.Interrupts.
1935 -- Interrupt_Manager.Detach_Interrupt_Entries. Be sure
1936 -- to update this value when changing Interrupt_Manager specs.
1938 type Param_Type
is access all Task_Id
;
1940 Param
: aliased Param_Type
:= T
'Access;
1943 System
.Tasking
.Rendezvous
.Call_Simple
1944 (Interrupt_Manager_ID
, Detach_Interrupt_Entries_Index
,
1949 if (T
.Common
.Parent
/= null
1950 and then T
.Common
.Parent
.Common
.Parent
/= null)
1951 or else T
.Master_of_Task
> Library_Task_Level
1953 Initialization
.Task_Lock
(Self_ID
);
1955 -- If Sec_Stack_Addr is not null, it means that Destroy_TSD
1956 -- has not been called yet (case of an unactivated task).
1958 if T
.Common
.Compiler_Data
.Sec_Stack_Addr
/= Null_Address
then
1959 SSL
.Destroy_TSD
(T
.Common
.Compiler_Data
);
1962 Vulnerable_Free_Task
(T
);
1963 Initialization
.Task_Unlock
(Self_ID
);
1967 -- It might seem nice to let the terminated task deallocate its own
1968 -- ATCB. That would not cover the case of unactivated tasks. It also
1969 -- would force us to keep the underlying thread around past termination,
1970 -- since references to the ATCB are possible past termination.
1972 -- Currently, we get rid of the thread as soon as the task terminates,
1973 -- and let the parent recover the ATCB later.
1975 -- Some day, if we want to recover the ATCB earlier, at task
1976 -- termination, we could consider using "fat task IDs", that include the
1977 -- serial number with the ATCB pointer, to catch references to tasks
1978 -- that no longer have ATCBs. It is not clear how much this would gain,
1979 -- since the user-level task object would still be occupying storage.
1981 -- Make next master level up active. We don't need to lock the ATCB,
1982 -- since the value is only updated by each task for itself.
1984 Self_ID
.Master_Within
:= CM
- 1;
1986 Debug
.Master_Completed_Hook
(Self_ID
, CM
);
1987 end Vulnerable_Complete_Master
;
1989 ------------------------------
1990 -- Vulnerable_Complete_Task --
1991 ------------------------------
1993 -- Complete the calling task
1995 -- This procedure must be called with abort deferred. It should only be
1996 -- called by Complete_Task and Finalize_Global_Tasks (for the environment
1999 -- The effect is similar to that of Complete_Master. Differences include
2000 -- the closing of entries here, and computation of the number of active
2001 -- dependent tasks in Complete_Master.
2003 -- We don't lock Self_ID before the call to Vulnerable_Complete_Activation,
2004 -- because that does its own locking, and because we do not need the lock
2005 -- to test Self_ID.Common.Activator. That value should only be read and
2006 -- modified by Self.
2008 procedure Vulnerable_Complete_Task
(Self_ID
: Task_Id
) is
2011 (Self_ID
.Deferral_Level
> 0
2012 or else not System
.Restrictions
.Abort_Allowed
);
2013 pragma Assert
(Self_ID
= Self
);
2015 (Self_ID
.Master_Within
in
2016 Self_ID
.Master_of_Task
+ 1 .. Self_ID
.Master_of_Task
+ 3);
2017 pragma Assert
(Self_ID
.Common
.Wait_Count
= 0);
2018 pragma Assert
(Self_ID
.Open_Accepts
= null);
2019 pragma Assert
(Self_ID
.ATC_Nesting_Level
= 1);
2021 pragma Debug
(Debug
.Trace
(Self_ID
, "V_Complete_Task", 'C'));
2027 Write_Lock
(Self_ID
);
2028 Self_ID
.Callable
:= False;
2030 -- In theory, Self should have no pending entry calls left on its
2031 -- call-stack. Each async. select statement should clean its own call,
2032 -- and blocking entry calls should defer abort until the calls are
2033 -- cancelled, then clean up.
2035 Utilities
.Cancel_Queued_Entry_Calls
(Self_ID
);
2038 if Self_ID
.Common
.Activator
/= null then
2039 Vulnerable_Complete_Activation
(Self_ID
);
2046 -- If Self_ID.Master_Within = Self_ID.Master_of_Task + 2 we may have
2047 -- dependent tasks for which we need to wait. Otherwise we just exit.
2049 if Self_ID
.Master_Within
= Self_ID
.Master_of_Task
+ 2 then
2050 Vulnerable_Complete_Master
(Self_ID
);
2052 end Vulnerable_Complete_Task
;
2054 --------------------------
2055 -- Vulnerable_Free_Task --
2056 --------------------------
2058 -- Recover all runtime system storage associated with the task T. This
2059 -- should only be called after T has terminated and will no longer be
2062 -- For tasks created by an allocator that fails, due to an exception, it
2063 -- is called from Expunge_Unactivated_Tasks.
2065 -- For tasks created by elaboration of task object declarations it is
2066 -- called from the finalization code of the Task_Wrapper procedure.
2068 procedure Vulnerable_Free_Task
(T
: Task_Id
) is
2070 pragma Debug
(Debug
.Trace
(Self
, "Vulnerable_Free_Task", 'C', T
));
2077 Initialization
.Finalize_Attributes
(T
);
2084 System
.Task_Primitives
.Operations
.Finalize_TCB
(T
);
2085 end Vulnerable_Free_Task
;
2087 -- Package elaboration code
2090 -- Establish the Adafinal softlink
2092 -- This is not done inside the central RTS initialization routine
2093 -- to avoid with'ing this package from System.Tasking.Initialization.
2095 SSL
.Adafinal
:= Finalize_Global_Tasks
'Access;
2097 -- Establish soft links for subprograms that manipulate master_id's.
2098 -- This cannot be done when the RTS is initialized, because of various
2099 -- elaboration constraints.
2101 SSL
.Current_Master
:= Stages
.Current_Master
'Access;
2102 SSL
.Enter_Master
:= Stages
.Enter_Master
'Access;
2103 SSL
.Complete_Master
:= Stages
.Complete_Master
'Access;
2104 end System
.Tasking
.Stages
;