URL
https://opencores.org/ocsvn/openrisc/openrisc/trunk
Subversion Repositories openrisc
[/] [openrisc/] [trunk/] [gnu-stable/] [gcc-4.5.1/] [gcc/] [ada/] [s-taenca.adb] - Rev 826
Compare with Previous | Blame | View Log
------------------------------------------------------------------------------ -- -- -- GNAT RUN-TIME LIBRARY (GNARL) COMPONENTS -- -- -- -- S Y S T E M . T A S K I N G . E N T R Y _ C A L L S -- -- -- -- B o d y -- -- -- -- Copyright (C) 1992-2009, Free Software Foundation, Inc. -- -- -- -- GNARL is free software; you can redistribute it and/or modify it under -- -- terms of the GNU General Public License as published by the Free Soft- -- -- ware Foundation; either version 3, or (at your option) any later ver- -- -- sion. GNAT is distributed in the hope that it will be useful, but WITH- -- -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY -- -- or FITNESS FOR A PARTICULAR PURPOSE. -- -- -- -- As a special exception under Section 7 of GPL version 3, you are granted -- -- additional permissions described in the GCC Runtime Library Exception, -- -- version 3.1, as published by the Free Software Foundation. -- -- -- -- You should have received a copy of the GNU General Public License and -- -- a copy of the GCC Runtime Library Exception along with this program; -- -- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see -- -- <http://www.gnu.org/licenses/>. -- -- -- -- GNARL was developed by the GNARL team at Florida State University. -- -- Extensive contributions were provided by Ada Core Technologies, Inc. -- -- -- ------------------------------------------------------------------------------ with System.Task_Primitives.Operations; with System.Tasking.Initialization; with System.Tasking.Protected_Objects.Entries; with System.Tasking.Protected_Objects.Operations; with System.Tasking.Queuing; with System.Tasking.Utilities; with System.Parameters; with System.Traces; package body System.Tasking.Entry_Calls is package STPO renames System.Task_Primitives.Operations; use Parameters; use Task_Primitives; use Protected_Objects.Entries; use Protected_Objects.Operations; use System.Traces; -- DO NOT use Protected_Objects.Lock or Protected_Objects.Unlock -- internally. Those operations will raise Program_Error, which -- we are not prepared to handle inside the RTS. Instead, use -- System.Task_Primitives lock operations directly on Protection.L. ----------------------- -- Local Subprograms -- ----------------------- procedure Lock_Server (Entry_Call : Entry_Call_Link); -- This locks the server targeted by Entry_Call -- -- This may be a task or a protected object, depending on the target of the -- original call or any subsequent requeues. -- -- This routine is needed because the field specifying the server for this -- call must be protected by the server's mutex. If it were protected by -- the caller's mutex, accessing the server's queues would require locking -- the caller to get the server, locking the server, and then accessing the -- queues. This involves holding two ATCB locks at once, something which we -- can guarantee that it will always be done in the same order, or locking -- a protected object while we hold an ATCB lock, something which is not -- permitted. Since the server cannot be obtained reliably, it must be -- obtained unreliably and then checked again once it has been locked. -- -- If Single_Lock and server is a PO, release RTS_Lock -- -- This should only be called by the Entry_Call.Self. -- It should be holding no other ATCB locks at the time. procedure Unlock_Server (Entry_Call : Entry_Call_Link); -- STPO.Unlock the server targeted by Entry_Call. The server must -- be locked before calling this. -- -- If Single_Lock and server is a PO, take RTS_Lock on exit. procedure Unlock_And_Update_Server (Self_ID : Task_Id; Entry_Call : Entry_Call_Link); -- Similar to Unlock_Server, but services entry calls if the -- server is a protected object. -- -- If Single_Lock and server is a PO, take RTS_Lock on exit. procedure Check_Pending_Actions_For_Entry_Call (Self_ID : Task_Id; Entry_Call : Entry_Call_Link); -- This procedure performs priority change of a queued call and dequeuing -- of an entry call when the call is cancelled. If the call is dequeued the -- state should be set to Cancelled. Call only with abort deferred and -- holding lock of Self_ID. This is a bit of common code for all entry -- calls. The effect is to do any deferred base priority change operation, -- in case some other task called STPO.Set_Priority while the current task -- had abort deferred, and to dequeue the call if the call has been -- aborted. procedure Poll_Base_Priority_Change_At_Entry_Call (Self_ID : Task_Id; Entry_Call : Entry_Call_Link); pragma Inline (Poll_Base_Priority_Change_At_Entry_Call); -- A specialized version of Poll_Base_Priority_Change, that does the -- optional entry queue reordering. Has to be called with the Self_ID's -- ATCB write-locked. May temporarily release the lock. --------------------- -- Check_Exception -- --------------------- procedure Check_Exception (Self_ID : Task_Id; Entry_Call : Entry_Call_Link) is pragma Warnings (Off, Self_ID); use type Ada.Exceptions.Exception_Id; procedure Internal_Raise (X : Ada.Exceptions.Exception_Id); pragma Import (C, Internal_Raise, "__gnat_raise_with_msg"); E : constant Ada.Exceptions.Exception_Id := Entry_Call.Exception_To_Raise; begin -- pragma Assert (Self_ID.Deferral_Level = 0); -- The above may be useful for debugging, but the Florist packages -- contain critical sections that defer abort and then do entry calls, -- which causes the above Assert to trip. if E /= Ada.Exceptions.Null_Id then Internal_Raise (E); end if; end Check_Exception; ------------------------------------------ -- Check_Pending_Actions_For_Entry_Call -- ------------------------------------------ procedure Check_Pending_Actions_For_Entry_Call (Self_ID : Task_Id; Entry_Call : Entry_Call_Link) is begin pragma Assert (Self_ID = Entry_Call.Self); Poll_Base_Priority_Change_At_Entry_Call (Self_ID, Entry_Call); if Self_ID.Pending_ATC_Level < Self_ID.ATC_Nesting_Level and then Entry_Call.State = Now_Abortable then STPO.Unlock (Self_ID); Lock_Server (Entry_Call); if Queuing.Onqueue (Entry_Call) and then Entry_Call.State = Now_Abortable then Queuing.Dequeue_Call (Entry_Call); Entry_Call.State := (if Entry_Call.Cancellation_Attempted then Cancelled else Done); Unlock_And_Update_Server (Self_ID, Entry_Call); else Unlock_Server (Entry_Call); end if; STPO.Write_Lock (Self_ID); end if; end Check_Pending_Actions_For_Entry_Call; ----------------- -- Lock_Server -- ----------------- procedure Lock_Server (Entry_Call : Entry_Call_Link) is Test_Task : Task_Id; Test_PO : Protection_Entries_Access; Ceiling_Violation : Boolean; Failures : Integer := 0; begin Test_Task := Entry_Call.Called_Task; loop if Test_Task = null then -- Entry_Call was queued on a protected object, or in transition, -- when we last fetched Test_Task. Test_PO := To_Protection (Entry_Call.Called_PO); if Test_PO = null then -- We had very bad luck, interleaving with TWO different -- requeue operations. Go around the loop and try again. if Single_Lock then STPO.Unlock_RTS; STPO.Yield; STPO.Lock_RTS; else STPO.Yield; end if; else if Single_Lock then STPO.Unlock_RTS; end if; Lock_Entries (Test_PO, Ceiling_Violation); -- ??? -- The following code allows Lock_Server to be called when -- cancelling a call, to allow for the possibility that the -- priority of the caller has been raised beyond that of the -- protected entry call by Ada.Dynamic_Priorities.Set_Priority. -- If the current task has a higher priority than the ceiling -- of the protected object, temporarily lower it. It will -- be reset in Unlock. if Ceiling_Violation then declare Current_Task : constant Task_Id := STPO.Self; Old_Base_Priority : System.Any_Priority; begin if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Current_Task); Old_Base_Priority := Current_Task.Common.Base_Priority; Current_Task.New_Base_Priority := Test_PO.Ceiling; System.Tasking.Initialization.Change_Base_Priority (Current_Task); STPO.Unlock (Current_Task); if Single_Lock then STPO.Unlock_RTS; end if; -- Following lock should not fail Lock_Entries (Test_PO); Test_PO.Old_Base_Priority := Old_Base_Priority; Test_PO.Pending_Action := True; end; end if; exit when To_Address (Test_PO) = Entry_Call.Called_PO; Unlock_Entries (Test_PO); if Single_Lock then STPO.Lock_RTS; end if; end if; else STPO.Write_Lock (Test_Task); exit when Test_Task = Entry_Call.Called_Task; STPO.Unlock (Test_Task); end if; Test_Task := Entry_Call.Called_Task; Failures := Failures + 1; pragma Assert (Failures <= 5); end loop; end Lock_Server; --------------------------------------------- -- Poll_Base_Priority_Change_At_Entry_Call -- --------------------------------------------- procedure Poll_Base_Priority_Change_At_Entry_Call (Self_ID : Task_Id; Entry_Call : Entry_Call_Link) is begin if Self_ID.Pending_Priority_Change then -- Check for ceiling violations ??? Self_ID.Pending_Priority_Change := False; -- Requeue the entry call at the new priority. We need to requeue -- even if the new priority is the same than the previous (see ACATS -- test cxd4006). STPO.Unlock (Self_ID); Lock_Server (Entry_Call); Queuing.Requeue_Call_With_New_Prio (Entry_Call, STPO.Get_Priority (Self_ID)); Unlock_And_Update_Server (Self_ID, Entry_Call); STPO.Write_Lock (Self_ID); end if; end Poll_Base_Priority_Change_At_Entry_Call; -------------------- -- Reset_Priority -- -------------------- procedure Reset_Priority (Acceptor : Task_Id; Acceptor_Prev_Priority : Rendezvous_Priority) is begin pragma Assert (Acceptor = STPO.Self); -- Since we limit this kind of "active" priority change to be done -- by the task for itself, we don't need to lock Acceptor. if Acceptor_Prev_Priority /= Priority_Not_Boosted then STPO.Set_Priority (Acceptor, Acceptor_Prev_Priority, Loss_Of_Inheritance => True); end if; end Reset_Priority; ------------------------------ -- Try_To_Cancel_Entry_Call -- ------------------------------ procedure Try_To_Cancel_Entry_Call (Succeeded : out Boolean) is Entry_Call : Entry_Call_Link; Self_ID : constant Task_Id := STPO.Self; use type Ada.Exceptions.Exception_Id; begin Entry_Call := Self_ID.Entry_Calls (Self_ID.ATC_Nesting_Level)'Access; -- Experimentation has shown that abort is sometimes (but not -- always) already deferred when Cancel_xxx_Entry_Call is called. -- That may indicate an error. Find out what is going on. ??? pragma Assert (Entry_Call.Mode = Asynchronous_Call); Initialization.Defer_Abort_Nestable (Self_ID); if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Self_ID); Entry_Call.Cancellation_Attempted := True; if Self_ID.Pending_ATC_Level >= Entry_Call.Level then Self_ID.Pending_ATC_Level := Entry_Call.Level - 1; end if; Entry_Calls.Wait_For_Completion (Entry_Call); STPO.Unlock (Self_ID); if Single_Lock then STPO.Unlock_RTS; end if; Succeeded := Entry_Call.State = Cancelled; Initialization.Undefer_Abort_Nestable (Self_ID); -- Ideally, abort should no longer be deferred at this point, so we -- should be able to call Check_Exception. The loop below should be -- considered temporary, to work around the possibility that abort -- may be deferred more than one level deep ??? if Entry_Call.Exception_To_Raise /= Ada.Exceptions.Null_Id then while Self_ID.Deferral_Level > 0 loop System.Tasking.Initialization.Undefer_Abort_Nestable (Self_ID); end loop; Entry_Calls.Check_Exception (Self_ID, Entry_Call); end if; end Try_To_Cancel_Entry_Call; ------------------------------ -- Unlock_And_Update_Server -- ------------------------------ procedure Unlock_And_Update_Server (Self_ID : Task_Id; Entry_Call : Entry_Call_Link) is Called_PO : Protection_Entries_Access; Caller : Task_Id; begin if Entry_Call.Called_Task /= null then STPO.Unlock (Entry_Call.Called_Task); else Called_PO := To_Protection (Entry_Call.Called_PO); PO_Service_Entries (Self_ID, Called_PO, False); if Called_PO.Pending_Action then Called_PO.Pending_Action := False; Caller := STPO.Self; if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Caller); Caller.New_Base_Priority := Called_PO.Old_Base_Priority; Initialization.Change_Base_Priority (Caller); STPO.Unlock (Caller); if Single_Lock then STPO.Unlock_RTS; end if; end if; Unlock_Entries (Called_PO); if Single_Lock then STPO.Lock_RTS; end if; end if; end Unlock_And_Update_Server; ------------------- -- Unlock_Server -- ------------------- procedure Unlock_Server (Entry_Call : Entry_Call_Link) is Caller : Task_Id; Called_PO : Protection_Entries_Access; begin if Entry_Call.Called_Task /= null then STPO.Unlock (Entry_Call.Called_Task); else Called_PO := To_Protection (Entry_Call.Called_PO); if Called_PO.Pending_Action then Called_PO.Pending_Action := False; Caller := STPO.Self; if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Caller); Caller.New_Base_Priority := Called_PO.Old_Base_Priority; Initialization.Change_Base_Priority (Caller); STPO.Unlock (Caller); if Single_Lock then STPO.Unlock_RTS; end if; end if; Unlock_Entries (Called_PO); if Single_Lock then STPO.Lock_RTS; end if; end if; end Unlock_Server; ------------------------- -- Wait_For_Completion -- ------------------------- procedure Wait_For_Completion (Entry_Call : Entry_Call_Link) is Self_Id : constant Task_Id := Entry_Call.Self; begin -- If this is a conditional call, it should be cancelled when it -- becomes abortable. This is checked in the loop below. if Parameters.Runtime_Traces then Send_Trace_Info (W_Completion); end if; Self_Id.Common.State := Entry_Caller_Sleep; -- Try to remove calls to Sleep in the loop below by letting the caller -- a chance of getting ready immediately, using Unlock & Yield. -- See similar action in Wait_For_Call & Timed_Selective_Wait. if Single_Lock then STPO.Unlock_RTS; else STPO.Unlock (Self_Id); end if; if Entry_Call.State < Done then STPO.Yield; end if; if Single_Lock then STPO.Lock_RTS; else STPO.Write_Lock (Self_Id); end if; loop Check_Pending_Actions_For_Entry_Call (Self_Id, Entry_Call); exit when Entry_Call.State >= Done; STPO.Sleep (Self_Id, Entry_Caller_Sleep); end loop; Self_Id.Common.State := Runnable; Utilities.Exit_One_ATC_Level (Self_Id); if Parameters.Runtime_Traces then Send_Trace_Info (M_Call_Complete); end if; end Wait_For_Completion; -------------------------------------- -- Wait_For_Completion_With_Timeout -- -------------------------------------- procedure Wait_For_Completion_With_Timeout (Entry_Call : Entry_Call_Link; Wakeup_Time : Duration; Mode : Delay_Modes; Yielded : out Boolean) is Self_Id : constant Task_Id := Entry_Call.Self; Timedout : Boolean := False; use type Ada.Exceptions.Exception_Id; begin -- This procedure waits for the entry call to be served, with a timeout. -- It tries to cancel the call if the timeout expires before the call is -- served. -- If we wake up from the timed sleep operation here, it may be for -- several possible reasons: -- 1) The entry call is done being served. -- 2) There is an abort or priority change to be served. -- 3) The timeout has expired (Timedout = True) -- 4) There has been a spurious wakeup. -- Once the timeout has expired we may need to continue to wait if the -- call is already being serviced. In that case, we want to go back to -- sleep, but without any timeout. The variable Timedout is used to -- control this. If the Timedout flag is set, we do not need to -- STPO.Sleep with a timeout. We just sleep until we get a wakeup for -- some status change. -- The original call may have become abortable after waking up. We want -- to check Check_Pending_Actions_For_Entry_Call again in any case. pragma Assert (Entry_Call.Mode = Timed_Call); Yielded := False; Self_Id.Common.State := Entry_Caller_Sleep; -- Looping is necessary in case the task wakes up early from the timed -- sleep, due to a "spurious wakeup". Spurious wakeups are a weakness of -- POSIX condition variables. A thread waiting for a condition variable -- is allowed to wake up at any time, not just when the condition is -- signaled. See same loop in the ordinary Wait_For_Completion, above. if Parameters.Runtime_Traces then Send_Trace_Info (WT_Completion, Wakeup_Time); end if; loop Check_Pending_Actions_For_Entry_Call (Self_Id, Entry_Call); exit when Entry_Call.State >= Done; STPO.Timed_Sleep (Self_Id, Wakeup_Time, Mode, Entry_Caller_Sleep, Timedout, Yielded); if Timedout then if Parameters.Runtime_Traces then Send_Trace_Info (E_Timeout); end if; -- Try to cancel the call (see Try_To_Cancel_Entry_Call for -- corresponding code in the ATC case). Entry_Call.Cancellation_Attempted := True; if Self_Id.Pending_ATC_Level >= Entry_Call.Level then Self_Id.Pending_ATC_Level := Entry_Call.Level - 1; end if; -- The following loop is the same as the loop and exit code -- from the ordinary Wait_For_Completion. If we get here, we -- have timed out but we need to keep waiting until the call -- has actually completed or been cancelled successfully. loop Check_Pending_Actions_For_Entry_Call (Self_Id, Entry_Call); exit when Entry_Call.State >= Done; STPO.Sleep (Self_Id, Entry_Caller_Sleep); end loop; Self_Id.Common.State := Runnable; Utilities.Exit_One_ATC_Level (Self_Id); return; end if; end loop; -- This last part is the same as ordinary Wait_For_Completion, -- and is only executed if the call completed without timing out. if Parameters.Runtime_Traces then Send_Trace_Info (M_Call_Complete); end if; Self_Id.Common.State := Runnable; Utilities.Exit_One_ATC_Level (Self_Id); end Wait_For_Completion_With_Timeout; -------------------------- -- Wait_Until_Abortable -- -------------------------- procedure Wait_Until_Abortable (Self_ID : Task_Id; Call : Entry_Call_Link) is begin pragma Assert (Self_ID.ATC_Nesting_Level > 0); pragma Assert (Call.Mode = Asynchronous_Call); if Parameters.Runtime_Traces then Send_Trace_Info (W_Completion); end if; STPO.Write_Lock (Self_ID); Self_ID.Common.State := Entry_Caller_Sleep; loop Check_Pending_Actions_For_Entry_Call (Self_ID, Call); exit when Call.State >= Was_Abortable; STPO.Sleep (Self_ID, Async_Select_Sleep); end loop; Self_ID.Common.State := Runnable; STPO.Unlock (Self_ID); if Parameters.Runtime_Traces then Send_Trace_Info (M_Call_Complete); end if; end Wait_Until_Abortable; end System.Tasking.Entry_Calls;