------------------------------------------------------------------------------
-- --
-- GNAT COMPILER COMPONENTS --
-- --
-- S Y S T E M . S T O R A G E _ P O O L S . S U B P O O L S --
-- --
-- B o d y --
-- --
-- Copyright (C) 2011-2012, Free Software Foundation, Inc. --
-- --
-- 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 --
-- . --
-- --
-- GNAT was originally developed by the GNAT team at New York University. --
-- Extensive contributions were provided by Ada Core Technologies Inc. --
-- --
------------------------------------------------------------------------------
with Ada.Exceptions; use Ada.Exceptions;
with Ada.Unchecked_Conversion;
with System.Address_Image;
with System.Finalization_Masters; use System.Finalization_Masters;
with System.IO; use System.IO;
with System.Soft_Links; use System.Soft_Links;
with System.Storage_Elements; use System.Storage_Elements;
with System.Storage_Pools.Subpools.Finalization;
use System.Storage_Pools.Subpools.Finalization;
package body System.Storage_Pools.Subpools is
Finalize_Address_Table_In_Use : Boolean := False;
-- This flag should be set only when a successfull allocation on a subpool
-- has been performed and the associated Finalize_Address has been added to
-- the hash table in System.Finalization_Masters.
function Address_To_FM_Node_Ptr is
new Ada.Unchecked_Conversion (Address, FM_Node_Ptr);
procedure Attach (N : not null SP_Node_Ptr; L : not null SP_Node_Ptr);
-- Attach a subpool node to a pool
-----------------------------------
-- Adjust_Controlled_Dereference --
-----------------------------------
procedure Adjust_Controlled_Dereference
(Addr : in out System.Address;
Storage_Size : in out System.Storage_Elements.Storage_Count;
Alignment : System.Storage_Elements.Storage_Count)
is
Header_And_Padding : constant Storage_Offset :=
Header_Size_With_Padding (Alignment);
begin
-- Expose the two hidden pointers by shifting the address from the
-- start of the object to the FM_Node equivalent of the pointers.
Addr := Addr - Header_And_Padding;
-- Update the size of the object to include the two pointers
Storage_Size := Storage_Size + Header_And_Padding;
end Adjust_Controlled_Dereference;
--------------
-- Allocate --
--------------
overriding procedure Allocate
(Pool : in out Root_Storage_Pool_With_Subpools;
Storage_Address : out System.Address;
Size_In_Storage_Elements : System.Storage_Elements.Storage_Count;
Alignment : System.Storage_Elements.Storage_Count)
is
begin
-- Dispatch to the user-defined implementations of Allocate_From_Subpool
-- and Default_Subpool_For_Pool.
Allocate_From_Subpool
(Root_Storage_Pool_With_Subpools'Class (Pool),
Storage_Address,
Size_In_Storage_Elements,
Alignment,
Default_Subpool_For_Pool
(Root_Storage_Pool_With_Subpools'Class (Pool)));
end Allocate;
-----------------------------
-- Allocate_Any_Controlled --
-----------------------------
procedure Allocate_Any_Controlled
(Pool : in out Root_Storage_Pool'Class;
Context_Subpool : Subpool_Handle;
Context_Master : Finalization_Masters.Finalization_Master_Ptr;
Fin_Address : Finalization_Masters.Finalize_Address_Ptr;
Addr : out System.Address;
Storage_Size : System.Storage_Elements.Storage_Count;
Alignment : System.Storage_Elements.Storage_Count;
Is_Controlled : Boolean;
On_Subpool : Boolean)
is
Is_Subpool_Allocation : constant Boolean :=
Pool in Root_Storage_Pool_With_Subpools'Class;
Master : Finalization_Master_Ptr := null;
N_Addr : Address;
N_Ptr : FM_Node_Ptr;
N_Size : Storage_Count;
Subpool : Subpool_Handle := null;
Allocation_Locked : Boolean;
-- This flag stores the state of the associated collection
Header_And_Padding : Storage_Offset;
-- This offset includes the size of a FM_Node plus any additional
-- padding due to a larger alignment.
begin
-- Step 1: Pool-related runtime checks
-- Allocation on a pool_with_subpools. In this scenario there is a
-- master for each subpool. The master of the access type is ignored.
if Is_Subpool_Allocation then
-- Case of an allocation without a Subpool_Handle. Dispatch to the
-- implementation of Default_Subpool_For_Pool.
if Context_Subpool = null then
Subpool :=
Default_Subpool_For_Pool
(Root_Storage_Pool_With_Subpools'Class (Pool));
-- Allocation with a Subpool_Handle
else
Subpool := Context_Subpool;
end if;
-- Ensure proper ownership and chaining of the subpool
if Subpool.Owner /=
Root_Storage_Pool_With_Subpools'Class (Pool)'Unchecked_Access
or else Subpool.Node = null
or else Subpool.Node.Prev = null
or else Subpool.Node.Next = null
then
raise Program_Error with "incorrect owner of subpool";
end if;
Master := Subpool.Master'Unchecked_Access;
-- Allocation on a simple pool. In this scenario there is a master for
-- each access-to-controlled type. No context subpool should be present.
else
-- If the master is missing, then the expansion of the access type
-- failed to create one. This is a serious error.
if Context_Master = null then
raise Program_Error
with "missing master in pool allocation";
-- If a subpool is present, then this is the result of erroneous
-- allocator expansion. This is not a serious error, but it should
-- still be detected.
elsif Context_Subpool /= null then
raise Program_Error
with "subpool not required in pool allocation";
-- If the allocation is intended to be on a subpool, but the access
-- type's pool does not support subpools, then this is the result of
-- erroneous end-user code.
elsif On_Subpool then
raise Program_Error
with "pool of access type does not support subpools";
end if;
Master := Context_Master;
end if;
-- Step 2: Master, Finalize_Address-related runtime checks and size
-- calculations.
-- Allocation of a descendant from [Limited_]Controlled, a class-wide
-- object or a record with controlled components.
if Is_Controlled then
-- Synchronization:
-- Read - allocation, finalization
-- Write - finalization
Lock_Task.all;
Allocation_Locked := Finalization_Started (Master.all);
Unlock_Task.all;
-- Do not allow the allocation of controlled objects while the
-- associated master is being finalized.
if Allocation_Locked then
raise Program_Error with "allocation after finalization started";
end if;
-- Check whether primitive Finalize_Address is available. If it is
-- not, then either the expansion of the designated type failed or
-- the expansion of the allocator failed. This is a serious error.
if Fin_Address = null then
raise Program_Error
with "primitive Finalize_Address not available";
end if;
-- The size must acount for the hidden header preceding the object.
-- Account for possible padding space before the header due to a
-- larger alignment.
Header_And_Padding := Header_Size_With_Padding (Alignment);
N_Size := Storage_Size + Header_And_Padding;
-- Non-controlled allocation
else
N_Size := Storage_Size;
end if;
-- Step 3: Allocation of object
-- For descendants of Root_Storage_Pool_With_Subpools, dispatch to the
-- implementation of Allocate_From_Subpool.
if Is_Subpool_Allocation then
Allocate_From_Subpool
(Root_Storage_Pool_With_Subpools'Class (Pool),
N_Addr, N_Size, Alignment, Subpool);
-- For descendants of Root_Storage_Pool, dispatch to the implementation
-- of Allocate.
else
Allocate (Pool, N_Addr, N_Size, Alignment);
end if;
-- Step 4: Attachment
if Is_Controlled then
Lock_Task.all;
-- Map the allocated memory into a FM_Node record. This converts the
-- top of the allocated bits into a list header. If there is padding
-- due to larger alignment, the header is placed right next to the
-- object:
-- N_Addr N_Ptr
-- | |
-- V V
-- +-------+---------------+----------------------+
-- |Padding| Header | Object |
-- +-------+---------------+----------------------+
-- ^ ^ ^
-- | +- Header_Size -+
-- | |
-- +- Header_And_Padding --+
N_Ptr := Address_To_FM_Node_Ptr
(N_Addr + Header_And_Padding - Header_Offset);
-- Prepend the allocated object to the finalization master
-- Synchronization:
-- Write - allocation, deallocation, finalization
Attach_Unprotected (N_Ptr, Objects (Master.all));
-- Move the address from the hidden list header to the start of the
-- object. This operation effectively hides the list header.
Addr := N_Addr + Header_And_Padding;
-- Homogeneous masters service the following:
-- 1) Allocations on / Deallocations from regular pools
-- 2) Named access types
-- 3) Most cases of anonymous access types usage
-- Synchronization:
-- Read - allocation, finalization
-- Write - outside
if Master.Is_Homogeneous then
-- Synchronization:
-- Read - finalization
-- Write - allocation, outside
Set_Finalize_Address_Unprotected (Master.all, Fin_Address);
-- Heterogeneous masters service the following:
-- 1) Allocations on / Deallocations from subpools
-- 2) Certain cases of anonymous access types usage
else
-- Synchronization:
-- Read - finalization
-- Write - allocation, deallocation
Set_Heterogeneous_Finalize_Address_Unprotected (Addr, Fin_Address);
Finalize_Address_Table_In_Use := True;
end if;
Unlock_Task.all;
-- Non-controlled allocation
else
Addr := N_Addr;
end if;
end Allocate_Any_Controlled;
------------
-- Attach --
------------
procedure Attach (N : not null SP_Node_Ptr; L : not null SP_Node_Ptr) is
begin
-- Ensure that the node has not been attached already
pragma Assert (N.Prev = null and then N.Next = null);
Lock_Task.all;
L.Next.Prev := N;
N.Next := L.Next;
L.Next := N;
N.Prev := L;
Unlock_Task.all;
-- Note: No need to unlock in case of an exception because the above
-- code can never raise one.
end Attach;
-------------------------------
-- Deallocate_Any_Controlled --
-------------------------------
procedure Deallocate_Any_Controlled
(Pool : in out Root_Storage_Pool'Class;
Addr : System.Address;
Storage_Size : System.Storage_Elements.Storage_Count;
Alignment : System.Storage_Elements.Storage_Count;
Is_Controlled : Boolean)
is
N_Addr : Address;
N_Ptr : FM_Node_Ptr;
N_Size : Storage_Count;
Header_And_Padding : Storage_Offset;
-- This offset includes the size of a FM_Node plus any additional
-- padding due to a larger alignment.
begin
-- Step 1: Detachment
if Is_Controlled then
Lock_Task.all;
-- Destroy the relation pair object - Finalize_Address since it is no
-- longer needed.
if Finalize_Address_Table_In_Use then
-- Synchronization:
-- Read - finalization
-- Write - allocation, deallocation
Delete_Finalize_Address_Unprotected (Addr);
end if;
-- Account for possible padding space before the header due to a
-- larger alignment.
Header_And_Padding := Header_Size_With_Padding (Alignment);
-- N_Addr N_Ptr Addr (from input)
-- | | |
-- V V V
-- +-------+---------------+----------------------+
-- |Padding| Header | Object |
-- +-------+---------------+----------------------+
-- ^ ^ ^
-- | +- Header_Size -+
-- | |
-- +- Header_And_Padding --+
-- Convert the bits preceding the object into a list header
N_Ptr := Address_To_FM_Node_Ptr (Addr - Header_Offset);
-- Detach the object from the related finalization master. This
-- action does not need to know the prior context used during
-- allocation.
-- Synchronization:
-- Write - allocation, deallocation, finalization
Detach_Unprotected (N_Ptr);
-- Move the address from the object to the beginning of the list
-- header.
N_Addr := Addr - Header_And_Padding;
-- The size of the deallocated object must include the size of the
-- hidden list header.
N_Size := Storage_Size + Header_And_Padding;
Unlock_Task.all;
else
N_Addr := Addr;
N_Size := Storage_Size;
end if;
-- Step 2: Deallocation
-- Dispatch to the proper implementation of Deallocate. This action
-- covers both Root_Storage_Pool and Root_Storage_Pool_With_Subpools
-- implementations.
Deallocate (Pool, N_Addr, N_Size, Alignment);
end Deallocate_Any_Controlled;
------------------------------
-- Default_Subpool_For_Pool --
------------------------------
function Default_Subpool_For_Pool
(Pool : Root_Storage_Pool_With_Subpools) return not null Subpool_Handle
is
begin
raise Program_Error;
return Pool.Subpools.Subpool;
end Default_Subpool_For_Pool;
------------
-- Detach --
------------
procedure Detach (N : not null SP_Node_Ptr) is
begin
-- Ensure that the node is attached to some list
pragma Assert (N.Next /= null and then N.Prev /= null);
Lock_Task.all;
N.Prev.Next := N.Next;
N.Next.Prev := N.Prev;
N.Prev := null;
N.Next := null;
Unlock_Task.all;
-- Note: No need to unlock in case of an exception because the above
-- code can never raise one.
end Detach;
--------------
-- Finalize --
--------------
overriding procedure Finalize (Controller : in out Pool_Controller) is
begin
Finalize_Pool (Controller.Enclosing_Pool.all);
end Finalize;
-------------------
-- Finalize_Pool --
-------------------
procedure Finalize_Pool (Pool : in out Root_Storage_Pool_With_Subpools) is
Curr_Ptr : SP_Node_Ptr;
Ex_Occur : Exception_Occurrence;
Raised : Boolean := False;
function Is_Empty_List (L : not null SP_Node_Ptr) return Boolean;
-- Determine whether a list contains only one element, the dummy head
-------------------
-- Is_Empty_List --
-------------------
function Is_Empty_List (L : not null SP_Node_Ptr) return Boolean is
begin
return L.Next = L and then L.Prev = L;
end Is_Empty_List;
-- Start of processing for Finalize_Pool
begin
-- It is possible for multiple tasks to cause the finalization of a
-- common pool. Allow only one task to finalize the contents.
if Pool.Finalization_Started then
return;
end if;
-- Lock the pool to prevent the creation of additional subpools while
-- the available ones are finalized. The pool remains locked because
-- either it is about to be deallocated or the associated access type
-- is about to go out of scope.
Pool.Finalization_Started := True;
while not Is_Empty_List (Pool.Subpools'Unchecked_Access) loop
Curr_Ptr := Pool.Subpools.Next;
-- Perform the following actions:
-- 1) Finalize all objects chained on the subpool's master
-- 2) Remove the the subpool from the owner's list of subpools
-- 3) Deallocate the doubly linked list node associated with the
-- subpool.
-- 4) Call Deallocate_Subpool
begin
Finalize_And_Deallocate (Curr_Ptr.Subpool);
exception
when Fin_Occur : others =>
if not Raised then
Raised := True;
Save_Occurrence (Ex_Occur, Fin_Occur);
end if;
end;
end loop;
-- If the finalization of a particular master failed, reraise the
-- exception now.
if Raised then
Reraise_Occurrence (Ex_Occur);
end if;
end Finalize_Pool;
------------------------------
-- Header_Size_With_Padding --
------------------------------
function Header_Size_With_Padding
(Alignment : System.Storage_Elements.Storage_Count)
return System.Storage_Elements.Storage_Count
is
Size : constant Storage_Count := Header_Size;
begin
if Size mod Alignment = 0 then
return Size;
-- Add enough padding to reach the nearest multiple of the alignment
-- rounding up.
else
return ((Size + Alignment - 1) / Alignment) * Alignment;
end if;
end Header_Size_With_Padding;
----------------
-- Initialize --
----------------
overriding procedure Initialize (Controller : in out Pool_Controller) is
begin
Initialize_Pool (Controller.Enclosing_Pool.all);
end Initialize;
---------------------
-- Initialize_Pool --
---------------------
procedure Initialize_Pool (Pool : in out Root_Storage_Pool_With_Subpools) is
begin
-- The dummy head must point to itself in both directions
Pool.Subpools.Next := Pool.Subpools'Unchecked_Access;
Pool.Subpools.Prev := Pool.Subpools'Unchecked_Access;
end Initialize_Pool;
---------------------
-- Pool_Of_Subpool --
---------------------
function Pool_Of_Subpool
(Subpool : not null Subpool_Handle)
return access Root_Storage_Pool_With_Subpools'Class
is
begin
return Subpool.Owner;
end Pool_Of_Subpool;
----------------
-- Print_Pool --
----------------
procedure Print_Pool (Pool : Root_Storage_Pool_With_Subpools) is
Head : constant SP_Node_Ptr := Pool.Subpools'Unrestricted_Access;
Head_Seen : Boolean := False;
SP_Ptr : SP_Node_Ptr;
begin
-- Output the contents of the pool
-- Pool : 0x123456789
-- Subpools : 0x123456789
-- Fin_Start : TRUE FALSE
-- Controller: OK NOK
Put ("Pool : ");
Put_Line (Address_Image (Pool'Address));
Put ("Subpools : ");
Put_Line (Address_Image (Pool.Subpools'Address));
Put ("Fin_Start : ");
Put_Line (Pool.Finalization_Started'Img);
Put ("Controlled: ");
if Pool.Controller.Enclosing_Pool = Pool'Unrestricted_Access then
Put_Line ("OK");
else
Put_Line ("NOK (ERROR)");
end if;
SP_Ptr := Head;
while SP_Ptr /= null loop -- Should never be null
Put_Line ("V");
-- We see the head initially; we want to exit when we see the head a
-- second time.
if SP_Ptr = Head then
exit when Head_Seen;
Head_Seen := True;
end if;
-- The current element is null. This should never happend since the
-- list is circular.
if SP_Ptr.Prev = null then
Put_Line ("null (ERROR)");
-- The current element points back to the correct element
elsif SP_Ptr.Prev.Next = SP_Ptr then
Put_Line ("^");
-- The current element points to an erroneous element
else
Put_Line ("? (ERROR)");
end if;
-- Output the contents of the node
Put ("|Header: ");
Put (Address_Image (SP_Ptr.all'Address));
if SP_Ptr = Head then
Put_Line (" (dummy head)");
else
Put_Line ("");
end if;
Put ("| Prev: ");
if SP_Ptr.Prev = null then
Put_Line ("null");
else
Put_Line (Address_Image (SP_Ptr.Prev.all'Address));
end if;
Put ("| Next: ");
if SP_Ptr.Next = null then
Put_Line ("null");
else
Put_Line (Address_Image (SP_Ptr.Next.all'Address));
end if;
Put ("| Subp: ");
if SP_Ptr.Subpool = null then
Put_Line ("null");
else
Put_Line (Address_Image (SP_Ptr.Subpool.all'Address));
end if;
SP_Ptr := SP_Ptr.Next;
end loop;
end Print_Pool;
-------------------
-- Print_Subpool --
-------------------
procedure Print_Subpool (Subpool : Subpool_Handle) is
begin
if Subpool = null then
Put_Line ("null");
return;
end if;
-- Output the contents of a subpool
-- Owner : 0x123456789
-- Master: 0x123456789
-- Node : 0x123456789
Put ("Owner : ");
if Subpool.Owner = null then
Put_Line ("null");
else
Put_Line (Address_Image (Subpool.Owner'Address));
end if;
Put ("Master: ");
Put_Line (Address_Image (Subpool.Master'Address));
Put ("Node : ");
if Subpool.Node = null then
Put ("null");
if Subpool.Owner = null then
Put_Line (" OK");
else
Put_Line (" (ERROR)");
end if;
else
Put_Line (Address_Image (Subpool.Node'Address));
end if;
Print_Master (Subpool.Master);
end Print_Subpool;
-------------------------
-- Set_Pool_Of_Subpool --
-------------------------
procedure Set_Pool_Of_Subpool
(Subpool : not null Subpool_Handle;
To : in out Root_Storage_Pool_With_Subpools'Class)
is
N_Ptr : SP_Node_Ptr;
begin
-- If the subpool is already owned, raise Program_Error. This is a
-- direct violation of the RM rules.
if Subpool.Owner /= null then
raise Program_Error with "subpool already belongs to a pool";
end if;
-- Prevent the creation of a new subpool while the owner is being
-- finalized. This is a serious error.
if To.Finalization_Started then
raise Program_Error
with "subpool creation after finalization started";
end if;
Subpool.Owner := To'Unchecked_Access;
-- Create a subpool node and decorate it. Since this node is not
-- allocated on the owner's pool, it must be explicitly destroyed by
-- Finalize_And_Detach.
N_Ptr := new SP_Node;
N_Ptr.Subpool := Subpool;
Subpool.Node := N_Ptr;
Attach (N_Ptr, To.Subpools'Unchecked_Access);
-- Mark the subpool's master as being a heterogeneous collection of
-- controlled objects.
Set_Is_Heterogeneous (Subpool.Master);
end Set_Pool_Of_Subpool;
end System.Storage_Pools.Subpools;