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8sa1-gcc/gcc/ada/a-tasatt.adb
Arnaud Charlet 607d0635d8 [multiple changes] 
2011-08-01  Arnaud Charlet  <charlet@adacore.com>

	* g-socket-dummy.adb, s-osinte-linux.ads, g-socket-dummy.ads,
	g-debuti.adb, g-tasloc.adb, g-debuti.ads, g-tasloc.ads,
	s-osinte-hpux.ads, g-sercom.adb, g-soliop-solaris.ads, g-sercom.ads,
	g-sptain.ads, g-curexc.ads, s-tasloc.adb, s-tasloc.ads, s-tataat.adb,
	g-ctrl_c.adb, a-reatim.adb, s-tataat.ads, g-dirope.adb, g-ctrl_c.ads,
	g-dirope.ads, g-boubuf.adb, g-calend.adb, g-boubuf.ads, g-souinf.ads,
	g-table.adb, g-bytswa-x86.adb, g-wispch.adb, g-io.adb, g-table.ads,
	g-wispch.ads, g-io.ads, g-memdum.adb, g-memdum.ads, g-busorg.adb,
	g-busorg.ads, g-regpat.adb, g-sothco-dummy.adb, g-encstr.adb,
	g-regpat.ads, g-sothco-dummy.ads, s-osinte-aix.ads, g-encstr.ads,
	g-sercom-mingw.adb, s-mastop-vms.adb, g-diopit.adb, g-diopit.ads,
	s-vxwext.adb, g-dyntab.adb, g-dyntab.ads, g-crc32.adb,
	g-sercom-linux.adb, g-crc32.ads, s-regpat.adb, g-flocon.ads,
	s-regpat.ads, g-stheme.adb, g-sestin.ads, s-taspri-posix-noaltstack.ads,
	g-soliop.ads, s-inmaop-posix.adb, g-locfil.ads, g-enblsp-vms-alpha.adb,
	g-socthi-dummy.adb, g-socthi-dummy.ads, gnat.ads, g-moreex.adb,
	g-moreex.ads, g-dynhta.adb, g-dynhta.ads, g-deutst.ads, g-htable.adb,
	g-cgicoo.adb, g-htable.ads, g-cgicoo.ads, a-interr.adb,
	g-socthi-vms.adb, g-socthi-vms.ads, g-hesora.adb, g-bubsor.adb,
	g-hesora.ads, g-bubsor.ads, g-md5.adb, g-md5.ads, s-intman-irix.adb,
	s-htable.adb, s-osinte-vms.adb, s-htable.ads, s-osinte-vms.ads,
	s-taprob.adb, g-bytswa.adb, g-bytswa.ads, s-osinte-solaris-posix.ads,
	a-suenco.adb, g-comver.adb, g-comver.ads, g-exctra.adb,
	s-osinte-solaris.adb, g-exctra.ads, s-osinte-irix.ads,
	s-osinte-solaris.ads, a-caldel-vms.adb, g-socthi-vxworks.adb,
	g-expect.adb, g-socthi-vxworks.ads, g-expect.ads, g-comlin.ads,
	g-heasor.adb, g-heasor.ads, g-traceb.adb, g-traceb.ads, g-decstr.adb,
	g-spipat.adb, g-decstr.ads, g-spipat.ads, s-mastop-tru64.adb,
	g-except.ads, g-thread.adb, g-hesorg.adb, g-thread.ads, g-hesorg.ads,
	g-expect-vms.adb, a-stuten.ads, g-spchge.adb, g-spchge.ads,
	g-u3spch.adb, g-u3spch.ads, g-spitbo.adb, g-spitbo.ads,
	s-osinte-dummy.ads, s-osinte-posix.adb, g-pehage.adb, g-pehage.ads,
	s-gloloc-mingw.adb, g-sha1.ads, s-traceb-hpux.adb,
	g-trasym-unimplemented.adb, g-trasym-unimplemented.ads, g-io_aux.adb,
	g-regexp.adb, g-io_aux.ads, g-socthi-mingw.adb, g-regexp.ads,
	s-osinte-hpux-dce.adb, g-socthi-mingw.ads, g-cgi.adb,
	s-osinte-hpux-dce.ads, g-cgi.ads, g-byorma.adb, g-boumai.ads,
	g-byorma.ads, a-caldel.adb, s-regexp.adb, s-regexp.ads,
	g-soliop-mingw.ads, g-sptavs.ads, s-osinte-tru64.ads, g-speche.adb,
	g-speche.ads, g-socthi.adb, g-stsifd-sockets.adb, g-socthi.ads,
	s-osinte-darwin.ads, i-vxwork-x86.ads, g-awk.adb, i-vxwork.ads,
	g-awk.ads, g-zspche.adb, g-zspche.ads, g-socket.adb, g-sptabo.ads,
	g-socket.ads, g-semaph.adb, g-semaph.ads, s-taspri-posix.ads,
	g-enblsp-vms-ia64.adb, g-cgideb.adb, g-cgideb.ads, g-sothco.adb,
	s-osinte-freebsd.ads, g-sothco.ads, g-catiio.adb, g-casuti.adb,
	g-catiio.ads, g-casuti.ads, g-trasym.adb, g-trasym.ads, s-casuti.adb,
	g-os_lib.adb, s-traceb-mastop.adb, g-busora.adb, s-interr-dummy.adb,
	g-busora.ads, g-enutst.ads, s-os_lib.adb, a-tasatt.adb,
	s-osinte-mingw.ads: Update to GPLv3 run-time license.
	Use GNAT instead of GNARL.

2011-08-01  Bob Duff  <duff@adacore.com>

	* a-cdlili.ads, a-cihama.ads, a-coinve.ads, a-ciorse.ads, a-coorma.ads,
	a-cidlli.ads, a-ciormu.ads, a-cihase.ads, a-cohama.ads, a-coorse.ads,
	a-ciorma.ads, a-coormu.ads, a-convec.ads, a-cohase.ads: Minor
	reformatting.

2011-08-01  Yannick Moy  <moy@adacore.com>

	* debug.adb (d.D) reverve flag for the SPARK mode
	(d.E) reverve flag for SPARK generation mode
	(d.F) reverve flag for Why generation mode
	* opt.ads, opt.adb (ALFA_Mode, ALFA_Through_SPARK_Mode, 
	ALFA_Through_Why_Mode, Formal_Verification_Mode, SPARK_Mode):  New
	functions which return True when the corresponding modes are set
	(Formal_Language): return "spark" or "alfa" when in formal verification
	mode.
	* sem_util.ads, sem_util.adb (Formal_Error_Msg): new wrapper on
	Error_Msg to prefix the error message with a tag giving the formal
	language
	(Formal_Error_Msg_N): new wrapper on Error_Msg_N to prefix the error
	message with a tag giving the formal language
	* sem_ch5.adb (Analyze_Block_Statement): issue error in formal mode on
	block statement
	(Analyze_Case_Statement): issue error in formal mode on case statement
	with a single "others" case alternative
	(Analyze_Exit_Statement): issue errors in formal mode on exit
	statements which do not respect SPARK restrictions
	(Analyze_Goto_Statement): issue error in formal mode on goto statement
	(Check_Unreachable_Code): always issue an error (not a warning) in
	formal mode on unreachable code (concerns both code after an infinite
	loop and after an unconditional jump, both not allowed in SPARK)
	* sem_ch6.adb (Analyze_Return_Statement): add call to
	Set_Return_Present for a procedure containing a return statement
	(already done for functions in Analyze_Function_Return)
	(Analyze_Function_Return): issue error in formal mode on extended
	return or if return is not last statement in function
	(Check_Missing_Return): issue error in formal mode if function does
	not end with return or if procedure contains a return
	* sem_ch8.ads, sem_ch8.adb (Has_Loop_In_Inner_Open_Scopes): new
	function to detect if there is an inner scope of its parameter S which
	is a loop.

2011-08-01  Thomas Quinot  <quinot@adacore.com>

	* sem_ch6.ads: Minor reformatting.

From-SVN: r177040
2011-08-01 17:05:02 +02:00

763 lines
29 KiB
Ada
Raw Blame History

------------------------------------------------------------------------------
-- --
-- GNAT RUN-TIME COMPONENTS --
-- --
-- A D A . T A S K _ A T T R I B U T E S --
-- --
-- B o d y --
-- --
-- Copyright (C) 1991-1994, Florida State University --
-- Copyright (C) 1995-2010, AdaCore --
-- --
-- GNAT 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. --
-- --
------------------------------------------------------------------------------
-- The following notes are provided in case someone decides the implementation
-- of this package is too complicated, or too slow. Please read this before
-- making any "simplifications".
-- Correct implementation of this package is more difficult than one might
-- expect. After considering (and coding) several alternatives, we settled on
-- the present compromise. Things we do not like about this implementation
-- include:
-- - It is vulnerable to bad Task_Id values, to the extent of possibly
-- trashing memory and crashing the runtime system.
-- - It requires dynamic storage allocation for each new attribute value,
-- except for types that happen to be the same size as System.Address, or
-- shorter.
-- - Instantiations at other than the library level rely on being able to
-- do down-level calls to a procedure declared in the generic package body.
-- This makes it potentially vulnerable to compiler changes.
-- The main implementation issue here is that the connection from task to
-- attribute is a potential source of dangling references.
-- When a task goes away, we want to be able to recover all the storage
-- associated with its attributes. The Ada mechanism for this is finalization,
-- via controlled attribute types. For this reason, the ARM requires
-- finalization of attribute values when the associated task terminates.
-- This finalization must be triggered by the tasking runtime system, during
-- termination of the task. Given the active set of instantiations of
-- Ada.Task_Attributes is dynamic, the number and types of attributes
-- belonging to a task will not be known until the task actually terminates.
-- Some of these types may be controlled and some may not. The RTS must find
-- some way to determine which of these attributes need finalization, and
-- invoke the appropriate finalization on them.
-- One way this might be done is to create a special finalization chain for
-- each task, similar to the finalization chain that is used for controlled
-- objects within the task. This would differ from the usual finalization
-- chain in that it would not have a LIFO structure, since attributes may be
-- added to a task at any time during its lifetime. This might be the right
-- way to go for the longer term, but at present this approach is not open,
-- since GNAT does not provide such special finalization support.
-- Lacking special compiler support, the RTS is limited to the normal ways an
-- application invokes finalization, i.e.
-- a) Explicit call to the procedure Finalize, if we know the type has this
-- operation defined on it. This is not sufficient, since we have no way
-- of determining whether a given generic formal Attribute type is
-- controlled, and no visibility of the associated Finalize procedure, in
-- the generic body.
-- b) Leaving the scope of a local object of a controlled type. This does not
-- help, since the lifetime of an instantiation of Ada.Task_Attributes
-- does not correspond to the lifetimes of the various tasks which may
-- have that attribute.
-- c) Assignment of another value to the object. This would not help, since
-- we then have to finalize the new value of the object.
-- d) Unchecked deallocation of an object of a controlled type. This seems to
-- be the only mechanism available to the runtime system for finalization
-- of task attributes.
-- We considered two ways of using unchecked deallocation, both based on a
-- linked list of that would hang from the task control block.
-- In the first approach the objects on the attribute list are all derived
-- from one controlled type, say T, and are linked using an access type to
-- T'Class. The runtime system has an Ada.Unchecked_Deallocation for T'Class
-- with access type T'Class, and uses this to deallocate and finalize all the
-- items in the list. The limitation of this approach is that each
-- instantiation of the package Ada.Task_Attributes derives a new record
-- extension of T, and since T is controlled (RM 3.9.1 (3)), instantiation is
-- only allowed at the library level.
-- In the second approach the objects on the attribute list are of unrelated
-- but structurally similar types. Unchecked conversion is used to circument
-- Ada type checking. Each attribute-storage node contains not only the
-- attribute value and a link for chaining, but also a pointer to descriptor
-- for the corresponding instantiation of Task_Attributes. The instantiation
-- descriptor contains pointer to a procedure that can do the correct
-- deallocation and finalization for that type of attribute. On task
-- termination, the runtime system uses the pointer to call the appropriate
-- deallocator.
-- While this gets around the limitation that instantations be at the library
-- level, it relies on an implementation feature that may not always be safe,
-- i.e. that it is safe to call the Deallocate procedure for an instantiation
-- of Ada.Task_Attributes that no longer exists. In general, it seems this
-- might result in dangling references.
-- Another problem with instantiations deeper than the library level is that
-- there is risk of storage leakage, or dangling references to reused storage.
-- That is, if an instantiation of Ada.Task_Attributes is made within a
-- procedure, what happens to the storage allocated for attributes, when the
-- procedure call returns? Apparently (RM 7.6.1 (4)) any such objects must be
-- finalized, since they will no longer be accessible, and in general one
-- would expect that the storage they occupy would be recovered for later
-- reuse. (If not, we would have a case of storage leakage.) Assuming the
-- storage is recovered and later reused, we have potentially dangerous
-- dangling references. When the procedure containing the instantiation of
-- Ada.Task_Attributes returns, there may still be unterminated tasks with
-- associated attribute values for that instantiation. When such tasks
-- eventually terminate, the RTS will attempt to call the Deallocate procedure
-- on them. If the corresponding storage has already been deallocated, when
-- the master of the access type was left, we have a potential disaster. This
-- disaster is compounded since the pointer to Deallocate is probably through
-- a "trampoline" which will also have been destroyed.
-- For this reason, we arrange to remove all dangling references before
-- leaving the scope of an instantiation. This is ugly, since it requires
-- traversing the list of all tasks, but it is no more ugly than a similar
-- traversal that we must do at the point of instantiation in order to
-- initialize the attributes of all tasks. At least we only need to do these
-- traversals if the type is controlled.
-- We chose to defer allocation of storage for attributes until the Reference
-- function is called or the attribute is first set to a value different from
-- the default initial one. This allows a potential savings in allocation,
-- for attributes that are not used by all tasks.
-- For efficiency, we reserve space in the TCB for a fixed number of direct-
-- access attributes. These are required to be of a size that fits in the
-- space of an object of type System.Address. Because we must use unchecked
-- bitwise copy operations on these values, they cannot be of a controlled
-- type, but that is covered automatically since controlled objects are too
-- large to fit in the spaces.
-- We originally deferred initialization of these direct-access attributes,
-- just as we do for the indirect-access attributes, and used a per-task bit
-- vector to keep track of which attributes were currently defined for that
-- task. We found that the overhead of maintaining this bit-vector seriously
-- slowed down access to the attributes, and made the fetch operation non-
-- atomic, so that even to read an attribute value required locking the TCB.
-- Therefore, we now initialize such attributes for all existing tasks at the
-- time of the attribute instantiation, and initialize existing attributes for
-- each new task at the time it is created.
-- The latter initialization requires a list of all the instantiation
-- descriptors. Updates to this list, as well as the bit-vector that is used
-- to reserve slots for attributes in the TCB, require mutual exclusion. That
-- is provided by the Lock/Unlock_RTS.
-- One special problem that added complexity to the design is that the per-
-- task list of indirect attributes contains objects of different types. We
-- use unchecked pointer conversion to link these nodes together and access
-- them, but the records may not have identical internal structure. Initially,
-- we thought it would be enough to allocate all the common components of
-- the records at the front of each record, so that their positions would
-- correspond. Unfortunately, GNAT adds "dope" information at the front
-- of a record, if the record contains any controlled-type components.
--
-- This means that the offset of the fields we use to link the nodes is at
-- different positions on nodes of different types. To get around this, each
-- attribute storage record consists of a core node and wrapper. The core
-- nodes are all of the same type, and it is these that are linked together
-- and generally "seen" by the RTS. Each core node contains a pointer to its
-- own wrapper, which is a record that contains the core node along with an
-- attribute value, approximately as follows:
-- type Node;
-- type Node_Access is access all Node;
-- type Wrapper;
-- type Access_Wrapper is access all Wrapper;
-- type Node is record
-- Next : Node_Access;
-- ...
-- Wrapper : Access_Wrapper;
-- end record;
-- type Wrapper is record
-- Dummy_Node : aliased Node;
-- Value : aliased Attribute; -- the generic formal type
-- end record;
-- Another interesting problem is with the initialization of the instantiation
-- descriptors. Originally, we did this all via the Initialize procedure of
-- the descriptor type and code in the package body. It turned out that the
-- Initialize procedure needed quite a bit of information, including the size
-- of the attribute type, the initial value of the attribute (if it fits in
-- the TCB), and a pointer to the deallocator procedure. These needed to be
-- "passed" in via access discriminants. GNAT was having trouble with access
-- discriminants, so all this work was moved to the package body.
-- Note that references to objects declared in this package body must in
-- general use 'Unchecked_Access instead of 'Access as the package can be
-- instantiated from within a local context.
with System.Storage_Elements;
with System.Task_Primitives.Operations;
with System.Tasking;
with System.Tasking.Initialization;
with System.Tasking.Task_Attributes;
with Ada.Exceptions;
with Ada.Unchecked_Conversion;
with Ada.Unchecked_Deallocation;
pragma Elaborate_All (System.Tasking.Task_Attributes);
-- To ensure the initialization of object Local (below) will work
package body Ada.Task_Attributes is
use System.Tasking.Initialization,
System.Tasking,
System.Tasking.Task_Attributes,
Ada.Exceptions;
package POP renames System.Task_Primitives.Operations;
---------------------------
-- Unchecked Conversions --
---------------------------
-- The following type corresponds to Dummy_Wrapper, declared in
-- System.Tasking.Task_Attributes.
type Wrapper;
type Access_Wrapper is access all Wrapper;
pragma Warnings (Off);
-- We turn warnings off for the following To_Attribute_Handle conversions,
-- since these are used only for small attributes where we know that there
-- are no problems with alignment, but the compiler will generate warnings
-- for the occurrences in the large attribute case, even though they will
-- not actually be used.
function To_Attribute_Handle is new Ada.Unchecked_Conversion
(System.Address, Attribute_Handle);
function To_Direct_Attribute_Element is new Ada.Unchecked_Conversion
(System.Address, Direct_Attribute_Element);
-- For reference to directly addressed task attributes
type Access_Integer_Address is access all
System.Storage_Elements.Integer_Address;
function To_Attribute_Handle is new Ada.Unchecked_Conversion
(Access_Integer_Address, Attribute_Handle);
-- For reference to directly addressed task attributes
pragma Warnings (On);
-- End warnings off region for directly addressed attribute conversions
function To_Access_Address is new Ada.Unchecked_Conversion
(Access_Node, Access_Address);
-- To store pointer to list of indirect attributes
pragma Warnings (Off);
function To_Access_Wrapper is new Ada.Unchecked_Conversion
(Access_Dummy_Wrapper, Access_Wrapper);
pragma Warnings (On);
-- To fetch pointer to actual wrapper of attribute node. We turn off
-- warnings since this may generate an alignment warning. The warning can
-- be ignored since Dummy_Wrapper is only a non-generic standin for the
-- real wrapper type (we never actually allocate objects of type
-- Dummy_Wrapper).
function To_Access_Dummy_Wrapper is new Ada.Unchecked_Conversion
(Access_Wrapper, Access_Dummy_Wrapper);
-- To store pointer to actual wrapper of attribute node
function To_Task_Id is new Ada.Unchecked_Conversion
(Task_Identification.Task_Id, Task_Id);
-- To access TCB of identified task
type Local_Deallocator is access procedure (P : in out Access_Node);
function To_Lib_Level_Deallocator is new Ada.Unchecked_Conversion
(Local_Deallocator, Deallocator);
-- To defeat accessibility check
------------------------
-- Storage Management --
------------------------
procedure Deallocate (P : in out Access_Node);
-- Passed to the RTS via unchecked conversion of a pointer to permit
-- finalization and deallocation of attribute storage nodes.
--------------------------
-- Instantiation Record --
--------------------------
Local : aliased Instance;
-- Initialized in package body
type Wrapper is record
Dummy_Node : aliased Node;
Value : aliased Attribute := Initial_Value;
-- The generic formal type, may be controlled
end record;
-- A number of unchecked conversions involving Wrapper_Access sources are
-- performed in this unit. We have to ensure that the designated object is
-- always strictly enough aligned.
for Wrapper'Alignment use Standard'Maximum_Alignment;
procedure Free is
new Ada.Unchecked_Deallocation (Wrapper, Access_Wrapper);
procedure Deallocate (P : in out Access_Node) is
T : Access_Wrapper := To_Access_Wrapper (P.Wrapper);
begin
Free (T);
end Deallocate;
---------------
-- Reference --
---------------
function Reference
(T : Task_Identification.Task_Id := Task_Identification.Current_Task)
return Attribute_Handle
is
TT : constant Task_Id := To_Task_Id (T);
Error_Message : constant String := "Trying to get the reference of a ";
begin
if TT = null then
Raise_Exception (Program_Error'Identity, Error_Message & "null task");
end if;
if TT.Common.State = Terminated then
Raise_Exception (Tasking_Error'Identity,
Error_Message & "terminated task");
end if;
-- Directly addressed case
if Local.Index /= 0 then
-- Return the attribute handle. Warnings off because this return
-- statement generates alignment warnings for large attributes
-- (but will never be executed in this case anyway).
pragma Warnings (Off);
return
To_Attribute_Handle (TT.Direct_Attributes (Local.Index)'Address);
pragma Warnings (On);
-- Not directly addressed
else
declare
P : Access_Node := To_Access_Node (TT.Indirect_Attributes);
W : Access_Wrapper;
Self_Id : constant Task_Id := POP.Self;
begin
Defer_Abort (Self_Id);
POP.Lock_RTS;
while P /= null loop
if P.Instance = Access_Instance'(Local'Unchecked_Access) then
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
return To_Access_Wrapper (P.Wrapper).Value'Access;
end if;
P := P.Next;
end loop;
-- Unlock the RTS here to follow the lock ordering rule that
-- prevent us from using new (i.e the Global_Lock) while holding
-- any other lock.
POP.Unlock_RTS;
W := new Wrapper'
((null, Local'Unchecked_Access, null), Initial_Value);
POP.Lock_RTS;
P := W.Dummy_Node'Unchecked_Access;
P.Wrapper := To_Access_Dummy_Wrapper (W);
P.Next := To_Access_Node (TT.Indirect_Attributes);
TT.Indirect_Attributes := To_Access_Address (P);
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
return W.Value'Access;
exception
when others =>
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
raise;
end;
end if;
exception
when Tasking_Error | Program_Error =>
raise;
when others =>
raise Program_Error;
end Reference;
------------------
-- Reinitialize --
------------------
procedure Reinitialize
(T : Task_Identification.Task_Id := Task_Identification.Current_Task)
is
TT : constant Task_Id := To_Task_Id (T);
Error_Message : constant String := "Trying to Reinitialize a ";
begin
if TT = null then
Raise_Exception (Program_Error'Identity, Error_Message & "null task");
end if;
if TT.Common.State = Terminated then
Raise_Exception (Tasking_Error'Identity,
Error_Message & "terminated task");
end if;
if Local.Index /= 0 then
Set_Value (Initial_Value, T);
else
declare
P, Q : Access_Node;
W : Access_Wrapper;
Self_Id : constant Task_Id := POP.Self;
begin
Defer_Abort (Self_Id);
POP.Lock_RTS;
Q := To_Access_Node (TT.Indirect_Attributes);
while Q /= null loop
if Q.Instance = Access_Instance'(Local'Unchecked_Access) then
if P = null then
TT.Indirect_Attributes := To_Access_Address (Q.Next);
else
P.Next := Q.Next;
end if;
W := To_Access_Wrapper (Q.Wrapper);
Free (W);
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
return;
end if;
P := Q;
Q := Q.Next;
end loop;
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
exception
when others =>
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
raise;
end;
end if;
exception
when Tasking_Error | Program_Error =>
raise;
when others =>
raise Program_Error;
end Reinitialize;
---------------
-- Set_Value --
---------------
procedure Set_Value
(Val : Attribute;
T : Task_Identification.Task_Id := Task_Identification.Current_Task)
is
TT : constant Task_Id := To_Task_Id (T);
Error_Message : constant String := "Trying to Set the Value of a ";
begin
if TT = null then
Raise_Exception (Program_Error'Identity, Error_Message & "null task");
end if;
if TT.Common.State = Terminated then
Raise_Exception (Tasking_Error'Identity,
Error_Message & "terminated task");
end if;
-- Directly addressed case
if Local.Index /= 0 then
-- Set attribute handle, warnings off, because this code can generate
-- alignment warnings with large attributes (but of course will not
-- be executed in this case, since we never have direct addressing in
-- such cases).
pragma Warnings (Off);
To_Attribute_Handle
(TT.Direct_Attributes (Local.Index)'Address).all := Val;
pragma Warnings (On);
return;
end if;
-- Not directly addressed
declare
P : Access_Node := To_Access_Node (TT.Indirect_Attributes);
W : Access_Wrapper;
Self_Id : constant Task_Id := POP.Self;
begin
Defer_Abort (Self_Id);
POP.Lock_RTS;
while P /= null loop
if P.Instance = Access_Instance'(Local'Unchecked_Access) then
To_Access_Wrapper (P.Wrapper).Value := Val;
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
return;
end if;
P := P.Next;
end loop;
-- Unlock RTS here to follow the lock ordering rule that prevent us
-- from using new (i.e the Global_Lock) while holding any other lock.
POP.Unlock_RTS;
W := new Wrapper'((null, Local'Unchecked_Access, null), Val);
POP.Lock_RTS;
P := W.Dummy_Node'Unchecked_Access;
P.Wrapper := To_Access_Dummy_Wrapper (W);
P.Next := To_Access_Node (TT.Indirect_Attributes);
TT.Indirect_Attributes := To_Access_Address (P);
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
exception
when others =>
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
raise;
end;
exception
when Tasking_Error | Program_Error =>
raise;
when others =>
raise Program_Error;
end Set_Value;
-----------
-- Value --
-----------
function Value
(T : Task_Identification.Task_Id := Task_Identification.Current_Task)
return Attribute
is
TT : constant Task_Id := To_Task_Id (T);
Error_Message : constant String := "Trying to get the Value of a ";
begin
if TT = null then
Raise_Exception (Program_Error'Identity, Error_Message & "null task");
end if;
if TT.Common.State = Terminated then
Raise_Exception
(Program_Error'Identity, Error_Message & "terminated task");
end if;
-- Directly addressed case
if Local.Index /= 0 then
-- Get value of attribute. We turn Warnings off, because for large
-- attributes, this code can generate alignment warnings. But of
-- course large attributes are never directly addressed so in fact
-- we will never execute the code in this case.
pragma Warnings (Off);
return To_Attribute_Handle
(TT.Direct_Attributes (Local.Index)'Address).all;
pragma Warnings (On);
end if;
-- Not directly addressed
declare
P : Access_Node;
Result : Attribute;
Self_Id : constant Task_Id := POP.Self;
begin
Defer_Abort (Self_Id);
POP.Lock_RTS;
P := To_Access_Node (TT.Indirect_Attributes);
while P /= null loop
if P.Instance = Access_Instance'(Local'Unchecked_Access) then
Result := To_Access_Wrapper (P.Wrapper).Value;
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
return Result;
end if;
P := P.Next;
end loop;
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
return Initial_Value;
exception
when others =>
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
raise;
end;
exception
when Tasking_Error | Program_Error =>
raise;
when others =>
raise Program_Error;
end Value;
-- Start of elaboration code for package Ada.Task_Attributes
begin
-- This unchecked conversion can give warnings when alignments are
-- incorrect, but they will not be used in such cases anyway, so the
-- warnings can be safely ignored.
pragma Warnings (Off);
Local.Deallocate := To_Lib_Level_Deallocator (Deallocate'Access);
pragma Warnings (On);
declare
Two_To_J : Direct_Index_Vector;
Self_Id : constant Task_Id := POP.Self;
begin
Defer_Abort (Self_Id);
-- Need protection for updating links to per-task initialization and
-- finalization routines, in case some task is being created or
-- terminated concurrently.
POP.Lock_RTS;
-- Add this instantiation to the list of all instantiations
Local.Next := System.Tasking.Task_Attributes.All_Attributes;
System.Tasking.Task_Attributes.All_Attributes :=
Local'Unchecked_Access;
-- Try to find space for the attribute in the TCB
Local.Index := 0;
Two_To_J := 1;
if Attribute'Size <= System.Address'Size then
for J in Direct_Index_Range loop
if (Two_To_J and In_Use) = 0 then
-- Reserve location J for this attribute
In_Use := In_Use or Two_To_J;
Local.Index := J;
-- This unchecked conversion can give a warning when the
-- alignment is incorrect, but it will not be used in such
-- a case anyway, so the warning can be safely ignored.
pragma Warnings (Off);
To_Attribute_Handle (Local.Initial_Value'Access).all :=
Initial_Value;
pragma Warnings (On);
exit;
end if;
Two_To_J := Two_To_J * 2;
end loop;
end if;
-- Attribute goes directly in the TCB
if Local.Index /= 0 then
-- Replace stub for initialization routine that is called at task
-- creation.
Initialization.Initialize_Attributes_Link :=
System.Tasking.Task_Attributes.Initialize_Attributes'Access;
-- Initialize the attribute, for all tasks
declare
C : System.Tasking.Task_Id := System.Tasking.All_Tasks_List;
begin
while C /= null loop
C.Direct_Attributes (Local.Index) :=
To_Direct_Attribute_Element
(System.Storage_Elements.To_Address (Local.Initial_Value));
C := C.Common.All_Tasks_Link;
end loop;
end;
-- Attribute goes into a node onto a linked list
else
-- Replace stub for finalization routine called at task termination
Initialization.Finalize_Attributes_Link :=
System.Tasking.Task_Attributes.Finalize_Attributes'Access;
end if;
POP.Unlock_RTS;
Undefer_Abort (Self_Id);
end;
end Ada.Task_Attributes;
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