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------------------------------------------------------------------------------ -- -- -- GNAT RUN-TIME LIBRARY (GNARL) COMPONENTS -- -- -- -- SYSTEM.TASKING.PROTECTED_OBJECTS.OPERATIONS -- -- -- -- B o d y -- -- -- -- Copyright (C) 1998-2011, 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. -- -- -- ------------------------------------------------------------------------------ -- This package contains all extended primitives related to Protected_Objects -- with entries. -- The handling of protected objects with no entries is done in -- System.Tasking.Protected_Objects, the simple routines for protected -- objects with entries in System.Tasking.Protected_Objects.Entries. -- The split between Entries and Operations is needed to break circular -- dependencies inside the run time. -- This package contains all primitives related to Protected_Objects. -- Note: the compiler generates direct calls to this interface, via Rtsfind. with System.Task_Primitives.Operations; with System.Tasking.Entry_Calls; with System.Tasking.Queuing; with System.Tasking.Rendezvous; with System.Tasking.Utilities; with System.Tasking.Debug; with System.Parameters; with System.Traces.Tasking; with System.Restrictions; with System.Tasking.Initialization; pragma Elaborate_All (System.Tasking.Initialization); -- Insures that tasking is initialized if any protected objects are created package body System.Tasking.Protected_Objects.Operations is package STPO renames System.Task_Primitives.Operations; use Parameters; use Task_Primitives; use Ada.Exceptions; use Entries; use System.Restrictions; use System.Restrictions.Rident; use System.Traces; use System.Traces.Tasking; ----------------------- -- Local Subprograms -- ----------------------- procedure Update_For_Queue_To_PO (Entry_Call : Entry_Call_Link; With_Abort : Boolean); pragma Inline (Update_For_Queue_To_PO); -- Update the state of an existing entry call to reflect the fact that it -- is being enqueued, based on whether the current queuing action is with -- or without abort. Call this only while holding the PO's lock. It returns -- with the PO's lock still held. procedure Requeue_Call (Self_Id : Task_Id; Object : Protection_Entries_Access; Entry_Call : Entry_Call_Link); -- Handle requeue of Entry_Call. -- In particular, queue the call if needed, or service it immediately -- if possible. --------------------------------- -- Cancel_Protected_Entry_Call -- --------------------------------- -- Compiler interface only (do not call from within the RTS) -- This should have analogous effect to Cancel_Task_Entry_Call, setting -- the value of Block.Cancelled instead of returning the parameter value -- Cancelled. -- The effect should be idempotent, since the call may already have been -- dequeued. -- Source code: -- select r.e; -- ...A... -- then abort -- ...B... -- end select; -- Expanded code: -- declare -- X : protected_entry_index := 1; -- B80b : communication_block; -- communication_blockIP (B80b); -- begin -- begin -- A79b : label -- A79b : declare -- procedure _clean is -- begin -- if enqueued (B80b) then -- cancel_protected_entry_call (B80b); -- end if; -- return; -- end _clean; -- begin -- protected_entry_call (rTV!(r)._object'unchecked_access, X, -- null_address, asynchronous_call, B80b, objectF => 0); -- if enqueued (B80b) then -- ...B... -- end if; -- at end -- _clean; -- end A79b; -- exception -- when _abort_signal => -- abort_undefer.all; -- null; -- end; -- if not cancelled (B80b) then -- x := ...A... -- end if; -- end; -- If the entry call completes after we get into the abortable part, -- Abort_Signal should be raised and ATC will take us to the at-end -- handler, which will call _clean. -- If the entry call returns with the call already completed, we can skip -- this, and use the "if enqueued()" to go past the at-end handler, but we -- will still call _clean. -- If the abortable part completes before the entry call is Done, it will -- call _clean. -- If the entry call or the abortable part raises an exception, -- we will still call _clean, but the value of Cancelled should not matter. -- Whoever calls _clean first gets to decide whether the call -- has been "cancelled". -- Enqueued should be true if there is any chance that the call is still on -- a queue. It seems to be safe to make it True if the call was Onqueue at -- some point before return from Protected_Entry_Call. -- Cancelled should be true iff the abortable part completed -- and succeeded in cancelling the entry call before it completed. -- ????? -- The need for Enqueued is less obvious. The "if enqueued ()" tests are -- not necessary, since Cancel_Protected_Entry_Call/Protected_Entry_Call -- must do the same test internally, with locking. The one that makes -- cancellation conditional may be a useful heuristic since at least 1/2 -- the time the call should be off-queue by that point. The other one seems -- totally useless, since Protected_Entry_Call must do the same check and -- then possibly wait for the call to be abortable, internally. -- We can check Call.State here without locking the caller's mutex, -- since the call must be over after returning from Wait_For_Completion. -- No other task can access the call record at this point. procedure Cancel_Protected_Entry_Call (Block : in out Communication_Block) is begin Entry_Calls.Try_To_Cancel_Entry_Call (Block.Cancelled); end Cancel_Protected_Entry_Call; --------------- -- Cancelled -- --------------- function Cancelled (Block : Communication_Block) return Boolean is begin return Block.Cancelled; end Cancelled; ------------------------- -- Complete_Entry_Body -- ------------------------- procedure Complete_Entry_Body (Object : Protection_Entries_Access) is begin Exceptional_Complete_Entry_Body (Object, Ada.Exceptions.Null_Id); end Complete_Entry_Body; -------------- -- Enqueued -- -------------- function Enqueued (Block : Communication_Block) return Boolean is begin return Block.Enqueued; end Enqueued; ------------------------------------- -- Exceptional_Complete_Entry_Body -- ------------------------------------- procedure Exceptional_Complete_Entry_Body (Object : Protection_Entries_Access; Ex : Ada.Exceptions.Exception_Id) is procedure Transfer_Occurrence (Target : Ada.Exceptions.Exception_Occurrence_Access; Source : Ada.Exceptions.Exception_Occurrence); pragma Import (C, Transfer_Occurrence, "__gnat_transfer_occurrence"); Entry_Call : constant Entry_Call_Link := Object.Call_In_Progress; Self_Id : Task_Id; begin pragma Debug (Debug.Trace (STPO.Self, "Exceptional_Complete_Entry_Body", 'P')); -- We must have abort deferred, since we are inside a protected -- operation. if Entry_Call /= null then -- The call was not requeued Entry_Call.Exception_To_Raise := Ex; if Ex /= Ada.Exceptions.Null_Id then -- An exception was raised and abort was deferred, so adjust -- before propagating, otherwise the task will stay with deferral -- enabled for its remaining life. Self_Id := STPO.Self; if not ZCX_By_Default then Initialization.Undefer_Abort_Nestable (Self_Id); end if; Transfer_Occurrence (Entry_Call.Self.Common.Compiler_Data.Current_Excep'Access, Self_Id.Common.Compiler_Data.Current_Excep); end if; -- Wakeup_Entry_Caller will be called from PO_Do_Or_Queue or -- PO_Service_Entries on return. end if; if Runtime_Traces then -- ??? Entry_Call can be null Send_Trace_Info (PO_Done, Entry_Call.Self); end if; end Exceptional_Complete_Entry_Body; -------------------- -- PO_Do_Or_Queue -- -------------------- procedure PO_Do_Or_Queue (Self_ID : Task_Id; Object : Protection_Entries_Access; Entry_Call : Entry_Call_Link) is E : constant Protected_Entry_Index := Protected_Entry_Index (Entry_Call.E); Barrier_Value : Boolean; begin -- When the Action procedure for an entry body returns, it is either -- completed (having called [Exceptional_]Complete_Entry_Body) or it -- is queued, having executed a requeue statement. Barrier_Value := Object.Entry_Bodies ( Object.Find_Body_Index (Object.Compiler_Info, E)). Barrier (Object.Compiler_Info, E); if Barrier_Value then -- Not abortable while service is in progress if Entry_Call.State = Now_Abortable then Entry_Call.State := Was_Abortable; end if; Object.Call_In_Progress := Entry_Call; pragma Debug (Debug.Trace (Self_ID, "PODOQ: start entry body", 'P')); Object.Entry_Bodies ( Object.Find_Body_Index (Object.Compiler_Info, E)).Action ( Object.Compiler_Info, Entry_Call.Uninterpreted_Data, E); if Object.Call_In_Progress /= null then -- Body of current entry served call to completion Object.Call_In_Progress := null; if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Entry_Call.Self); Initialization.Wakeup_Entry_Caller (Self_ID, Entry_Call, Done); STPO.Unlock (Entry_Call.Self); if Single_Lock then STPO.Unlock_RTS; end if; else Requeue_Call (Self_ID, Object, Entry_Call); end if; elsif Entry_Call.Mode /= Conditional_Call or else not Entry_Call.With_Abort then if Run_Time_Restrictions.Set (Max_Entry_Queue_Length) and then Run_Time_Restrictions.Value (Max_Entry_Queue_Length) <= Queuing.Count_Waiting (Object.Entry_Queues (E)) then -- This violates the Max_Entry_Queue_Length restriction, -- raise Program_Error. Entry_Call.Exception_To_Raise := Program_Error'Identity; if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Entry_Call.Self); Initialization.Wakeup_Entry_Caller (Self_ID, Entry_Call, Done); STPO.Unlock (Entry_Call.Self); if Single_Lock then STPO.Unlock_RTS; end if; else Queuing.Enqueue (Object.Entry_Queues (E), Entry_Call); Update_For_Queue_To_PO (Entry_Call, Entry_Call.With_Abort); end if; else -- Conditional_Call and With_Abort if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Entry_Call.Self); pragma Assert (Entry_Call.State >= Was_Abortable); Initialization.Wakeup_Entry_Caller (Self_ID, Entry_Call, Cancelled); STPO.Unlock (Entry_Call.Self); if Single_Lock then STPO.Unlock_RTS; end if; end if; exception when others => Queuing.Broadcast_Program_Error (Self_ID, Object, Entry_Call); end PO_Do_Or_Queue; ------------------------ -- PO_Service_Entries -- ------------------------ procedure PO_Service_Entries (Self_ID : Task_Id; Object : Entries.Protection_Entries_Access; Unlock_Object : Boolean := True) is E : Protected_Entry_Index; Caller : Task_Id; Entry_Call : Entry_Call_Link; begin loop Queuing.Select_Protected_Entry_Call (Self_ID, Object, Entry_Call); exit when Entry_Call = null; E := Protected_Entry_Index (Entry_Call.E); -- Not abortable while service is in progress if Entry_Call.State = Now_Abortable then Entry_Call.State := Was_Abortable; end if; Object.Call_In_Progress := Entry_Call; begin if Runtime_Traces then Send_Trace_Info (PO_Run, Self_ID, Entry_Call.Self, Entry_Index (E)); end if; pragma Debug (Debug.Trace (Self_ID, "POSE: start entry body", 'P')); Object.Entry_Bodies (Object.Find_Body_Index (Object.Compiler_Info, E)).Action (Object.Compiler_Info, Entry_Call.Uninterpreted_Data, E); exception when others => Queuing.Broadcast_Program_Error (Self_ID, Object, Entry_Call); end; if Object.Call_In_Progress = null then Requeue_Call (Self_ID, Object, Entry_Call); exit when Entry_Call.State = Cancelled; else Object.Call_In_Progress := null; Caller := Entry_Call.Self; if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Caller); Initialization.Wakeup_Entry_Caller (Self_ID, Entry_Call, Done); STPO.Unlock (Caller); if Single_Lock then STPO.Unlock_RTS; end if; end if; end loop; if Unlock_Object then Unlock_Entries (Object); end if; end PO_Service_Entries; --------------------- -- Protected_Count -- --------------------- function Protected_Count (Object : Protection_Entries'Class; E : Protected_Entry_Index) return Natural is begin return Queuing.Count_Waiting (Object.Entry_Queues (E)); end Protected_Count; -------------------------- -- Protected_Entry_Call -- -------------------------- -- Compiler interface only (do not call from within the RTS) -- select r.e; -- ...A... -- else -- ...B... -- end select; -- declare -- X : protected_entry_index := 1; -- B85b : communication_block; -- communication_blockIP (B85b); -- begin -- protected_entry_call (rTV!(r)._object'unchecked_access, X, -- null_address, conditional_call, B85b, objectF => 0); -- if cancelled (B85b) then -- ...B... -- else -- ...A... -- end if; -- end; -- See also Cancel_Protected_Entry_Call for code expansion of asynchronous -- entry call. -- The initial part of this procedure does not need to lock the calling -- task's ATCB, up to the point where the call record first may be queued -- (PO_Do_Or_Queue), since before that no other task will have access to -- the record. -- If this is a call made inside of an abort deferred region, the call -- should be never abortable. -- If the call was not queued abortably, we need to wait until it is before -- proceeding with the abortable part. -- There are some heuristics here, just to save time for frequently -- occurring cases. For example, we check Initially_Abortable to try to -- avoid calling the procedure Wait_Until_Abortable, since the normal case -- for async. entry calls is to be queued abortably. -- Another heuristic uses the Block.Enqueued to try to avoid calling -- Cancel_Protected_Entry_Call if the call can be served immediately. procedure Protected_Entry_Call (Object : Protection_Entries_Access; E : Protected_Entry_Index; Uninterpreted_Data : System.Address; Mode : Call_Modes; Block : out Communication_Block) is Self_ID : constant Task_Id := STPO.Self; Entry_Call : Entry_Call_Link; Initially_Abortable : Boolean; Ceiling_Violation : Boolean; begin pragma Debug (Debug.Trace (Self_ID, "Protected_Entry_Call", 'P')); if Runtime_Traces then Send_Trace_Info (PO_Call, Entry_Index (E)); end if; if Self_ID.ATC_Nesting_Level = ATC_Level'Last then raise Storage_Error with "not enough ATC nesting levels"; end if; -- If pragma Detect_Blocking is active then Program_Error must be -- raised if this potentially blocking operation is called from a -- protected action. if Detect_Blocking and then Self_ID.Common.Protected_Action_Nesting > 0 then raise Program_Error with "potentially blocking operation"; end if; -- Self_ID.Deferral_Level should be 0, except when called from Finalize, -- where abort is already deferred. Initialization.Defer_Abort_Nestable (Self_ID); Lock_Entries_With_Status (Object, Ceiling_Violation); if Ceiling_Violation then -- Failed ceiling check Initialization.Undefer_Abort_Nestable (Self_ID); raise Program_Error; end if; Block.Self := Self_ID; Self_ID.ATC_Nesting_Level := Self_ID.ATC_Nesting_Level + 1; pragma Debug (Debug.Trace (Self_ID, "PEC: entered ATC level: " & ATC_Level'Image (Self_ID.ATC_Nesting_Level), 'A')); Entry_Call := Self_ID.Entry_Calls (Self_ID.ATC_Nesting_Level)'Access; Entry_Call.Next := null; Entry_Call.Mode := Mode; Entry_Call.Cancellation_Attempted := False; Entry_Call.State := (if Self_ID.Deferral_Level > 1 then Never_Abortable else Now_Abortable); Entry_Call.E := Entry_Index (E); Entry_Call.Prio := STPO.Get_Priority (Self_ID); Entry_Call.Uninterpreted_Data := Uninterpreted_Data; Entry_Call.Called_PO := To_Address (Object); Entry_Call.Called_Task := null; Entry_Call.Exception_To_Raise := Ada.Exceptions.Null_Id; Entry_Call.With_Abort := True; PO_Do_Or_Queue (Self_ID, Object, Entry_Call); Initially_Abortable := Entry_Call.State = Now_Abortable; PO_Service_Entries (Self_ID, Object); -- Try to prevent waiting later (in Try_To_Cancel_Protected_Entry_Call) -- for completed or cancelled calls. (This is a heuristic, only.) if Entry_Call.State >= Done then -- Once State >= Done it will not change any more if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Self_ID); Utilities.Exit_One_ATC_Level (Self_ID); STPO.Unlock (Self_ID); if Single_Lock then STPO.Unlock_RTS; end if; Block.Enqueued := False; Block.Cancelled := Entry_Call.State = Cancelled; Initialization.Undefer_Abort_Nestable (Self_ID); Entry_Calls.Check_Exception (Self_ID, Entry_Call); return; else -- In this case we cannot conclude anything, since State can change -- concurrently. null; end if; -- Now for the general case if Mode = Asynchronous_Call then -- Try to avoid an expensive call if not Initially_Abortable then if Single_Lock then STPO.Lock_RTS; Entry_Calls.Wait_Until_Abortable (Self_ID, Entry_Call); STPO.Unlock_RTS; else Entry_Calls.Wait_Until_Abortable (Self_ID, Entry_Call); end if; end if; else case Mode is when Simple_Call | Conditional_Call => if Single_Lock then STPO.Lock_RTS; Entry_Calls.Wait_For_Completion (Entry_Call); STPO.Unlock_RTS; else STPO.Write_Lock (Self_ID); Entry_Calls.Wait_For_Completion (Entry_Call); STPO.Unlock (Self_ID); end if; Block.Cancelled := Entry_Call.State = Cancelled; when Asynchronous_Call | Timed_Call => pragma Assert (False); null; end case; end if; Initialization.Undefer_Abort_Nestable (Self_ID); Entry_Calls.Check_Exception (Self_ID, Entry_Call); end Protected_Entry_Call; ------------------ -- Requeue_Call -- ------------------ procedure Requeue_Call (Self_Id : Task_Id; Object : Protection_Entries_Access; Entry_Call : Entry_Call_Link) is New_Object : Protection_Entries_Access; Ceiling_Violation : Boolean; Result : Boolean; E : Protected_Entry_Index; begin New_Object := To_Protection (Entry_Call.Called_PO); if New_Object = null then -- Call is to be requeued to a task entry if Single_Lock then STPO.Lock_RTS; end if; Result := Rendezvous.Task_Do_Or_Queue (Self_Id, Entry_Call); if not Result then Queuing.Broadcast_Program_Error (Self_Id, Object, Entry_Call, RTS_Locked => True); end if; if Single_Lock then STPO.Unlock_RTS; end if; else -- Call should be requeued to a PO if Object /= New_Object then -- Requeue is to different PO Lock_Entries_With_Status (New_Object, Ceiling_Violation); if Ceiling_Violation then Object.Call_In_Progress := null; Queuing.Broadcast_Program_Error (Self_Id, Object, Entry_Call); else PO_Do_Or_Queue (Self_Id, New_Object, Entry_Call); PO_Service_Entries (Self_Id, New_Object); end if; else -- Requeue is to same protected object -- ??? Try to compensate apparent failure of the scheduler on some -- OS (e.g VxWorks) to give higher priority tasks a chance to run -- (see CXD6002). STPO.Yield (Do_Yield => False); if Entry_Call.With_Abort and then Entry_Call.Cancellation_Attempted then -- If this is a requeue with abort and someone tried to cancel -- this call, cancel it at this point. Entry_Call.State := Cancelled; return; end if; if not Entry_Call.With_Abort or else Entry_Call.Mode /= Conditional_Call then E := Protected_Entry_Index (Entry_Call.E); if Run_Time_Restrictions.Set (Max_Entry_Queue_Length) and then Run_Time_Restrictions.Value (Max_Entry_Queue_Length) <= Queuing.Count_Waiting (Object.Entry_Queues (E)) then -- This violates the Max_Entry_Queue_Length restriction, -- raise Program_Error. Entry_Call.Exception_To_Raise := Program_Error'Identity; if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Entry_Call.Self); Initialization.Wakeup_Entry_Caller (Self_Id, Entry_Call, Done); STPO.Unlock (Entry_Call.Self); if Single_Lock then STPO.Unlock_RTS; end if; else Queuing.Enqueue (New_Object.Entry_Queues (E), Entry_Call); Update_For_Queue_To_PO (Entry_Call, Entry_Call.With_Abort); end if; else PO_Do_Or_Queue (Self_Id, New_Object, Entry_Call); end if; end if; end if; end Requeue_Call; ---------------------------- -- Protected_Entry_Caller -- ---------------------------- function Protected_Entry_Caller (Object : Protection_Entries'Class) return Task_Id is begin return Object.Call_In_Progress.Self; end Protected_Entry_Caller; ----------------------------- -- Requeue_Protected_Entry -- ----------------------------- -- Compiler interface only (do not call from within the RTS) -- entry e when b is -- begin -- b := false; -- ...A... -- requeue e2; -- end e; -- procedure rPT__E10b (O : address; P : address; E : -- protected_entry_index) is -- type rTVP is access rTV; -- freeze rTVP [] -- _object : rTVP := rTVP!(O); -- begin -- declare -- rR : protection renames _object._object; -- vP : integer renames _object.v; -- bP : boolean renames _object.b; -- begin -- b := false; -- ...A... -- requeue_protected_entry (rR'unchecked_access, rR' -- unchecked_access, 2, false, objectF => 0, new_objectF => -- 0); -- return; -- end; -- complete_entry_body (_object._object'unchecked_access, objectF => -- 0); -- return; -- exception -- when others => -- abort_undefer.all; -- exceptional_complete_entry_body (_object._object' -- unchecked_access, current_exception, objectF => 0); -- return; -- end rPT__E10b; procedure Requeue_Protected_Entry (Object : Protection_Entries_Access; New_Object : Protection_Entries_Access; E : Protected_Entry_Index; With_Abort : Boolean) is Entry_Call : constant Entry_Call_Link := Object.Call_In_Progress; begin pragma Debug (Debug.Trace (STPO.Self, "Requeue_Protected_Entry", 'P')); pragma Assert (STPO.Self.Deferral_Level > 0); Entry_Call.E := Entry_Index (E); Entry_Call.Called_PO := To_Address (New_Object); Entry_Call.Called_Task := null; Entry_Call.With_Abort := With_Abort; Object.Call_In_Progress := null; end Requeue_Protected_Entry; ------------------------------------- -- Requeue_Task_To_Protected_Entry -- ------------------------------------- -- Compiler interface only (do not call from within the RTS) -- accept e1 do -- ...A... -- requeue r.e2; -- end e1; -- A79b : address; -- L78b : label -- begin -- accept_call (1, A79b); -- ...A... -- requeue_task_to_protected_entry (rTV!(r)._object' -- unchecked_access, 2, false, new_objectF => 0); -- goto L78b; -- <<L78b>> -- complete_rendezvous; -- exception -- when all others => -- exceptional_complete_rendezvous (get_gnat_exception); -- end; procedure Requeue_Task_To_Protected_Entry (New_Object : Protection_Entries_Access; E : Protected_Entry_Index; With_Abort : Boolean) is Self_ID : constant Task_Id := STPO.Self; Entry_Call : constant Entry_Call_Link := Self_ID.Common.Call; begin Initialization.Defer_Abort (Self_ID); -- We do not need to lock Self_ID here since the call is not abortable -- at this point, and therefore, the caller cannot cancel the call. Entry_Call.Needs_Requeue := True; Entry_Call.With_Abort := With_Abort; Entry_Call.Called_PO := To_Address (New_Object); Entry_Call.Called_Task := null; Entry_Call.E := Entry_Index (E); Initialization.Undefer_Abort (Self_ID); end Requeue_Task_To_Protected_Entry; --------------------- -- Service_Entries -- --------------------- procedure Service_Entries (Object : Protection_Entries_Access) is Self_ID : constant Task_Id := STPO.Self; begin PO_Service_Entries (Self_ID, Object); end Service_Entries; -------------------------------- -- Timed_Protected_Entry_Call -- -------------------------------- -- Compiler interface only (do not call from within the RTS) procedure Timed_Protected_Entry_Call (Object : Protection_Entries_Access; E : Protected_Entry_Index; Uninterpreted_Data : System.Address; Timeout : Duration; Mode : Delay_Modes; Entry_Call_Successful : out Boolean) is Self_Id : constant Task_Id := STPO.Self; Entry_Call : Entry_Call_Link; Ceiling_Violation : Boolean; Yielded : Boolean; pragma Unreferenced (Yielded); begin if Self_Id.ATC_Nesting_Level = ATC_Level'Last then raise Storage_Error with "not enough ATC nesting levels"; end if; -- If pragma Detect_Blocking is active then Program_Error must be -- raised if this potentially blocking operation is called from a -- protected action. if Detect_Blocking and then Self_Id.Common.Protected_Action_Nesting > 0 then raise Program_Error with "potentially blocking operation"; end if; if Runtime_Traces then Send_Trace_Info (POT_Call, Entry_Index (E), Timeout); end if; Initialization.Defer_Abort_Nestable (Self_Id); Lock_Entries_With_Status (Object, Ceiling_Violation); if Ceiling_Violation then Initialization.Undefer_Abort (Self_Id); raise Program_Error; end if; Self_Id.ATC_Nesting_Level := Self_Id.ATC_Nesting_Level + 1; pragma Debug (Debug.Trace (Self_Id, "TPEC: exited to ATC level: " & ATC_Level'Image (Self_Id.ATC_Nesting_Level), 'A')); Entry_Call := Self_Id.Entry_Calls (Self_Id.ATC_Nesting_Level)'Access; Entry_Call.Next := null; Entry_Call.Mode := Timed_Call; Entry_Call.Cancellation_Attempted := False; Entry_Call.State := (if Self_Id.Deferral_Level > 1 then Never_Abortable else Now_Abortable); Entry_Call.E := Entry_Index (E); Entry_Call.Prio := STPO.Get_Priority (Self_Id); Entry_Call.Uninterpreted_Data := Uninterpreted_Data; Entry_Call.Called_PO := To_Address (Object); Entry_Call.Called_Task := null; Entry_Call.Exception_To_Raise := Ada.Exceptions.Null_Id; Entry_Call.With_Abort := True; PO_Do_Or_Queue (Self_Id, Object, Entry_Call); PO_Service_Entries (Self_Id, Object); if Single_Lock then STPO.Lock_RTS; else STPO.Write_Lock (Self_Id); end if; -- Try to avoid waiting for completed or cancelled calls if Entry_Call.State >= Done then Utilities.Exit_One_ATC_Level (Self_Id); if Single_Lock then STPO.Unlock_RTS; else STPO.Unlock (Self_Id); end if; Entry_Call_Successful := Entry_Call.State = Done; Initialization.Undefer_Abort_Nestable (Self_Id); Entry_Calls.Check_Exception (Self_Id, Entry_Call); return; end if; Entry_Calls.Wait_For_Completion_With_Timeout (Entry_Call, Timeout, Mode, Yielded); if Single_Lock then STPO.Unlock_RTS; else STPO.Unlock (Self_Id); end if; -- ??? Do we need to yield in case Yielded is False Initialization.Undefer_Abort_Nestable (Self_Id); Entry_Call_Successful := Entry_Call.State = Done; Entry_Calls.Check_Exception (Self_Id, Entry_Call); end Timed_Protected_Entry_Call; ---------------------------- -- Update_For_Queue_To_PO -- ---------------------------- -- Update the state of an existing entry call, based on -- whether the current queuing action is with or without abort. -- Call this only while holding the server's lock. -- It returns with the server's lock released. New_State : constant array (Boolean, Entry_Call_State) of Entry_Call_State := (True => (Never_Abortable => Never_Abortable, Not_Yet_Abortable => Now_Abortable, Was_Abortable => Now_Abortable, Now_Abortable => Now_Abortable, Done => Done, Cancelled => Cancelled), False => (Never_Abortable => Never_Abortable, Not_Yet_Abortable => Not_Yet_Abortable, Was_Abortable => Was_Abortable, Now_Abortable => Now_Abortable, Done => Done, Cancelled => Cancelled) ); procedure Update_For_Queue_To_PO (Entry_Call : Entry_Call_Link; With_Abort : Boolean) is Old : constant Entry_Call_State := Entry_Call.State; begin pragma Assert (Old < Done); Entry_Call.State := New_State (With_Abort, Entry_Call.State); if Entry_Call.Mode = Asynchronous_Call then if Old < Was_Abortable and then Entry_Call.State = Now_Abortable then if Single_Lock then STPO.Lock_RTS; end if; STPO.Write_Lock (Entry_Call.Self); if Entry_Call.Self.Common.State = Async_Select_Sleep then STPO.Wakeup (Entry_Call.Self, Async_Select_Sleep); end if; STPO.Unlock (Entry_Call.Self); if Single_Lock then STPO.Unlock_RTS; end if; end if; elsif Entry_Call.Mode = Conditional_Call then pragma Assert (Entry_Call.State < Was_Abortable); null; end if; end Update_For_Queue_To_PO; end System.Tasking.Protected_Objects.Operations;
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