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8sa1-gcc/gcc/ada/a-convec.adb
Arnaud Charlet ea10ca9c75 [multiple changes] 
2011-10-16  Tristan Gingold  <gingold@adacore.com>

	* link.c (_AIX): Add support for GNU ld.        

2011-10-16  Fedor Rybin  <frybin@adacore.com>

	* gnat_ugn.texi: Fixing gnattest example names in the doc.
	Adding explanation to additional tests usage.

2011-10-16  Robert Dewar  <dewar@adacore.com>

	* exp_ch6.adb, sem_ch6.adb: Minor reformatting.

2011-10-16  Eric Botcazou  <ebotcazou@adacore.com>

	* a-convec.adb: Fix minor inconsistencies.

2011-10-16  Matthew Heaney  <heaney@adacore.com>

	* a-cusyqu.ads, a-cbsyqu.ads, a-cuprqu.ads, a-cbprqu.ads (package
	Implementation): Specify pragma Implementation_Defined.

From-SVN: r180056
2011-10-16 14:12:11 +02:00

3304 lines
108 KiB
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------------------------------------------------------------------------------
-- --
-- GNAT LIBRARY COMPONENTS --
-- --
-- A D A . C O N T A I N E R S . V E C T O R S --
-- --
-- B o d y --
-- --
-- Copyright (C) 2004-2011, 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 --
-- <http://www.gnu.org/licenses/>. --
-- --
-- This unit was originally developed by Matthew J Heaney. --
------------------------------------------------------------------------------
with Ada.Containers.Generic_Array_Sort;
with Ada.Unchecked_Deallocation;
with System; use type System.Address;
package body Ada.Containers.Vectors is
procedure Free is
new Ada.Unchecked_Deallocation (Elements_Type, Elements_Access);
type Iterator is new Vector_Iterator_Interfaces.Reversible_Iterator with
record
Container : Vector_Access;
Index : Index_Type;
end record;
overriding function First (Object : Iterator) return Cursor;
overriding function Last (Object : Iterator) return Cursor;
overriding function Next
(Object : Iterator;
Position : Cursor) return Cursor;
overriding function Previous
(Object : Iterator;
Position : Cursor) return Cursor;
---------
-- "&" --
---------
function "&" (Left, Right : Vector) return Vector is
LN : constant Count_Type := Length (Left);
RN : constant Count_Type := Length (Right);
N : Count_Type'Base; -- length of result
J : Count_Type'Base; -- for computing intermediate index values
Last : Index_Type'Base; -- Last index of result
begin
-- We decide that the capacity of the result is the sum of the lengths
-- of the vector parameters. We could decide to make it larger, but we
-- have no basis for knowing how much larger, so we just allocate the
-- minimum amount of storage.
-- Here we handle the easy cases first, when one of the vector
-- parameters is empty. (We say "easy" because there's nothing to
-- compute, that can potentially overflow.)
if LN = 0 then
if RN = 0 then
return Empty_Vector;
end if;
declare
RE : Elements_Array renames
Right.Elements.EA (Index_Type'First .. Right.Last);
Elements : constant Elements_Access :=
new Elements_Type'(Right.Last, RE);
begin
return (Controlled with Elements, Right.Last, 0, 0);
end;
end if;
if RN = 0 then
declare
LE : Elements_Array renames
Left.Elements.EA (Index_Type'First .. Left.Last);
Elements : constant Elements_Access :=
new Elements_Type'(Left.Last, LE);
begin
return (Controlled with Elements, Left.Last, 0, 0);
end;
end if;
-- Neither of the vector parameters is empty, so must compute the length
-- of the result vector and its last index. (This is the harder case,
-- because our computations must avoid overflow.)
-- There are two constraints we need to satisfy. The first constraint is
-- that a container cannot have more than Count_Type'Last elements, so
-- we must check the sum of the combined lengths. Note that we cannot
-- simply add the lengths, because of the possibility of overflow.
if LN > Count_Type'Last - RN then
raise Constraint_Error with "new length is out of range";
end if;
-- It is now safe compute the length of the new vector, without fear of
-- overflow.
N := LN + RN;
-- The second constraint is that the new Last index value cannot
-- exceed Index_Type'Last. We use the wider of Index_Type'Base and
-- Count_Type'Base as the type for intermediate values.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
-- We perform a two-part test. First we determine whether the
-- computed Last value lies in the base range of the type, and then
-- determine whether it lies in the range of the index (sub)type.
-- Last must satisfy this relation:
-- First + Length - 1 <= Last
-- We regroup terms:
-- First - 1 <= Last - Length
-- Which can rewrite as:
-- No_Index <= Last - Length
if Index_Type'Base'Last - Index_Type'Base (N) < No_Index then
raise Constraint_Error with "new length is out of range";
end if;
-- We now know that the computed value of Last is within the base
-- range of the type, so it is safe to compute its value:
Last := No_Index + Index_Type'Base (N);
-- Finally we test whether the value is within the range of the
-- generic actual index subtype:
if Last > Index_Type'Last then
raise Constraint_Error with "new length is out of range";
end if;
elsif Index_Type'First <= 0 then
-- Here we can compute Last directly, in the normal way. We know that
-- No_Index is less than 0, so there is no danger of overflow when
-- adding the (positive) value of length.
J := Count_Type'Base (No_Index) + N; -- Last
if J > Count_Type'Base (Index_Type'Last) then
raise Constraint_Error with "new length is out of range";
end if;
-- We know that the computed value (having type Count_Type) of Last
-- is within the range of the generic actual index subtype, so it is
-- safe to convert to Index_Type:
Last := Index_Type'Base (J);
else
-- Here Index_Type'First (and Index_Type'Last) is positive, so we
-- must test the length indirectly (by working backwards from the
-- largest possible value of Last), in order to prevent overflow.
J := Count_Type'Base (Index_Type'Last) - N; -- No_Index
if J < Count_Type'Base (No_Index) then
raise Constraint_Error with "new length is out of range";
end if;
-- We have determined that the result length would not create a Last
-- index value outside of the range of Index_Type, so we can now
-- safely compute its value.
Last := Index_Type'Base (Count_Type'Base (No_Index) + N);
end if;
declare
LE : Elements_Array renames
Left.Elements.EA (Index_Type'First .. Left.Last);
RE : Elements_Array renames
Right.Elements.EA (Index_Type'First .. Right.Last);
Elements : constant Elements_Access :=
new Elements_Type'(Last, LE & RE);
begin
return (Controlled with Elements, Last, 0, 0);
end;
end "&";
function "&" (Left : Vector; Right : Element_Type) return Vector is
begin
-- We decide that the capacity of the result is the sum of the lengths
-- of the parameters. We could decide to make it larger, but we have no
-- basis for knowing how much larger, so we just allocate the minimum
-- amount of storage.
-- Handle easy case first, when the vector parameter (Left) is empty
if Left.Is_Empty then
declare
Elements : constant Elements_Access :=
new Elements_Type'
(Last => Index_Type'First,
EA => (others => Right));
begin
return (Controlled with Elements, Index_Type'First, 0, 0);
end;
end if;
-- The vector parameter is not empty, so we must compute the length of
-- the result vector and its last index, but in such a way that overflow
-- is avoided. We must satisfy two constraints: the new length cannot
-- exceed Count_Type'Last, and the new Last index cannot exceed
-- Index_Type'Last.
if Left.Length = Count_Type'Last then
raise Constraint_Error with "new length is out of range";
end if;
if Left.Last >= Index_Type'Last then
raise Constraint_Error with "new length is out of range";
end if;
declare
Last : constant Index_Type := Left.Last + 1;
LE : Elements_Array renames
Left.Elements.EA (Index_Type'First .. Left.Last);
Elements : constant Elements_Access :=
new Elements_Type'(Last => Last, EA => LE & Right);
begin
return (Controlled with Elements, Last, 0, 0);
end;
end "&";
function "&" (Left : Element_Type; Right : Vector) return Vector is
begin
-- We decide that the capacity of the result is the sum of the lengths
-- of the parameters. We could decide to make it larger, but we have no
-- basis for knowing how much larger, so we just allocate the minimum
-- amount of storage.
-- Handle easy case first, when the vector parameter (Right) is empty
if Right.Is_Empty then
declare
Elements : constant Elements_Access :=
new Elements_Type'
(Last => Index_Type'First,
EA => (others => Left));
begin
return (Controlled with Elements, Index_Type'First, 0, 0);
end;
end if;
-- The vector parameter is not empty, so we must compute the length of
-- the result vector and its last index, but in such a way that overflow
-- is avoided. We must satisfy two constraints: the new length cannot
-- exceed Count_Type'Last, and the new Last index cannot exceed
-- Index_Type'Last.
if Right.Length = Count_Type'Last then
raise Constraint_Error with "new length is out of range";
end if;
if Right.Last >= Index_Type'Last then
raise Constraint_Error with "new length is out of range";
end if;
declare
Last : constant Index_Type := Right.Last + 1;
RE : Elements_Array renames
Right.Elements.EA (Index_Type'First .. Right.Last);
Elements : constant Elements_Access :=
new Elements_Type'
(Last => Last,
EA => Left & RE);
begin
return (Controlled with Elements, Last, 0, 0);
end;
end "&";
function "&" (Left, Right : Element_Type) return Vector is
begin
-- We decide that the capacity of the result is the sum of the lengths
-- of the parameters. We could decide to make it larger, but we have no
-- basis for knowing how much larger, so we just allocate the minimum
-- amount of storage.
-- We must compute the length of the result vector and its last index,
-- but in such a way that overflow is avoided. We must satisfy two
-- constraints: the new length cannot exceed Count_Type'Last (here, we
-- know that that condition is satisfied), and the new Last index cannot
-- exceed Index_Type'Last.
if Index_Type'First >= Index_Type'Last then
raise Constraint_Error with "new length is out of range";
end if;
declare
Last : constant Index_Type := Index_Type'First + 1;
Elements : constant Elements_Access :=
new Elements_Type'
(Last => Last,
EA => (Left, Right));
begin
return (Controlled with Elements, Last, 0, 0);
end;
end "&";
---------
-- "=" --
---------
overriding function "=" (Left, Right : Vector) return Boolean is
begin
if Left'Address = Right'Address then
return True;
end if;
if Left.Last /= Right.Last then
return False;
end if;
for J in Index_Type range Index_Type'First .. Left.Last loop
if Left.Elements.EA (J) /= Right.Elements.EA (J) then
return False;
end if;
end loop;
return True;
end "=";
------------
-- Adjust --
------------
procedure Adjust (Container : in out Vector) is
begin
if Container.Last = No_Index then
Container.Elements := null;
return;
end if;
declare
L : constant Index_Type := Container.Last;
EA : Elements_Array renames
Container.Elements.EA (Index_Type'First .. L);
begin
Container.Elements := null;
Container.Busy := 0;
Container.Lock := 0;
-- Note: it may seem that the following assignment to Container.Last
-- is useless, since we assign it to L below. However this code is
-- used in case 'new Elements_Type' below raises an exception, to
-- keep Container in a consistent state.
Container.Last := No_Index;
Container.Elements := new Elements_Type'(L, EA);
Container.Last := L;
end;
end Adjust;
------------
-- Append --
------------
procedure Append (Container : in out Vector; New_Item : Vector) is
begin
if Is_Empty (New_Item) then
return;
end if;
if Container.Last = Index_Type'Last then
raise Constraint_Error with "vector is already at its maximum length";
end if;
Insert
(Container,
Container.Last + 1,
New_Item);
end Append;
procedure Append
(Container : in out Vector;
New_Item : Element_Type;
Count : Count_Type := 1)
is
begin
if Count = 0 then
return;
end if;
if Container.Last = Index_Type'Last then
raise Constraint_Error with "vector is already at its maximum length";
end if;
Insert
(Container,
Container.Last + 1,
New_Item,
Count);
end Append;
--------------
-- Capacity --
--------------
function Capacity (Container : Vector) return Count_Type is
begin
if Container.Elements = null then
return 0;
else
return Container.Elements.EA'Length;
end if;
end Capacity;
-----------
-- Clear --
-----------
procedure Clear (Container : in out Vector) is
begin
if Container.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (vector is busy)";
else
Container.Last := No_Index;
end if;
end Clear;
--------------
-- Contains --
--------------
function Contains
(Container : Vector;
Item : Element_Type) return Boolean
is
begin
return Find_Index (Container, Item) /= No_Index;
end Contains;
------------
-- Delete --
------------
procedure Delete
(Container : in out Vector;
Index : Extended_Index;
Count : Count_Type := 1)
is
Old_Last : constant Index_Type'Base := Container.Last;
New_Last : Index_Type'Base;
Count2 : Count_Type'Base; -- count of items from Index to Old_Last
J : Index_Type'Base; -- first index of items that slide down
begin
-- Delete removes items from the vector, the number of which is the
-- minimum of the specified Count and the items (if any) that exist from
-- Index to Container.Last. There are no constraints on the specified
-- value of Count (it can be larger than what's available at this
-- position in the vector, for example), but there are constraints on
-- the allowed values of the Index.
-- As a precondition on the generic actual Index_Type, the base type
-- must include Index_Type'Pred (Index_Type'First); this is the value
-- that Container.Last assumes when the vector is empty. However, we do
-- not allow that as the value for Index when specifying which items
-- should be deleted, so we must manually check. (That the user is
-- allowed to specify the value at all here is a consequence of the
-- declaration of the Extended_Index subtype, which includes the values
-- in the base range that immediately precede and immediately follow the
-- values in the Index_Type.)
if Index < Index_Type'First then
raise Constraint_Error with "Index is out of range (too small)";
end if;
-- We do allow a value greater than Container.Last to be specified as
-- the Index, but only if it's immediately greater. This allows the
-- corner case of deleting no items from the back end of the vector to
-- be treated as a no-op. (It is assumed that specifying an index value
-- greater than Last + 1 indicates some deeper flaw in the caller's
-- algorithm, so that case is treated as a proper error.)
if Index > Old_Last then
if Index > Old_Last + 1 then
raise Constraint_Error with "Index is out of range (too large)";
end if;
return;
end if;
-- Here and elsewhere we treat deleting 0 items from the container as a
-- no-op, even when the container is busy, so we simply return.
if Count = 0 then
return;
end if;
-- The tampering bits exist to prevent an item from being deleted (or
-- otherwise harmfully manipulated) while it is being visited. Query,
-- Update, and Iterate increment the busy count on entry, and decrement
-- the count on exit. Delete checks the count to determine whether it is
-- being called while the associated callback procedure is executing.
if Container.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (vector is busy)";
end if;
-- We first calculate what's available for deletion starting at
-- Index. Here and elsewhere we use the wider of Index_Type'Base and
-- Count_Type'Base as the type for intermediate values. (See function
-- Length for more information.)
if Count_Type'Base'Last >= Index_Type'Pos (Index_Type'Base'Last) then
Count2 := Count_Type'Base (Old_Last) - Count_Type'Base (Index) + 1;
else
Count2 := Count_Type'Base (Old_Last - Index + 1);
end if;
-- If more elements are requested (Count) for deletion than are
-- available (Count2) for deletion beginning at Index, then everything
-- from Index is deleted. There are no elements to slide down, and so
-- all we need to do is set the value of Container.Last.
if Count >= Count2 then
Container.Last := Index - 1;
return;
end if;
-- There are some elements aren't being deleted (the requested count was
-- less than the available count), so we must slide them down to
-- Index. We first calculate the index values of the respective array
-- slices, using the wider of Index_Type'Base and Count_Type'Base as the
-- type for intermediate calculations. For the elements that slide down,
-- index value New_Last is the last index value of their new home, and
-- index value J is the first index of their old home.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
New_Last := Old_Last - Index_Type'Base (Count);
J := Index + Index_Type'Base (Count);
else
New_Last := Index_Type'Base (Count_Type'Base (Old_Last) - Count);
J := Index_Type'Base (Count_Type'Base (Index) + Count);
end if;
-- The internal elements array isn't guaranteed to exist unless we have
-- elements, but we have that guarantee here because we know we have
-- elements to slide. The array index values for each slice have
-- already been determined, so we just slide down to Index the elements
-- that weren't deleted.
declare
EA : Elements_Array renames Container.Elements.EA;
begin
EA (Index .. New_Last) := EA (J .. Old_Last);
Container.Last := New_Last;
end;
end Delete;
procedure Delete
(Container : in out Vector;
Position : in out Cursor;
Count : Count_Type := 1)
is
pragma Warnings (Off, Position);
begin
if Position.Container = null then
raise Constraint_Error with "Position cursor has no element";
end if;
if Position.Container /= Container'Unrestricted_Access then
raise Program_Error with "Position cursor denotes wrong container";
end if;
if Position.Index > Container.Last then
raise Program_Error with "Position index is out of range";
end if;
Delete (Container, Position.Index, Count);
Position := No_Element;
end Delete;
------------------
-- Delete_First --
------------------
procedure Delete_First
(Container : in out Vector;
Count : Count_Type := 1)
is
begin
if Count = 0 then
return;
end if;
if Count >= Length (Container) then
Clear (Container);
return;
end if;
Delete (Container, Index_Type'First, Count);
end Delete_First;
-----------------
-- Delete_Last --
-----------------
procedure Delete_Last
(Container : in out Vector;
Count : Count_Type := 1)
is
begin
-- It is not permitted to delete items while the container is busy (for
-- example, we're in the middle of a passive iteration). However, we
-- always treat deleting 0 items as a no-op, even when we're busy, so we
-- simply return without checking.
if Count = 0 then
return;
end if;
-- The tampering bits exist to prevent an item from being deleted (or
-- otherwise harmfully manipulated) while it is being visited. Query,
-- Update, and Iterate increment the busy count on entry, and decrement
-- the count on exit. Delete_Last checks the count to determine whether
-- it is being called while the associated callback procedure is
-- executing.
if Container.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (vector is busy)";
end if;
-- There is no restriction on how large Count can be when deleting
-- items. If it is equal or greater than the current length, then this
-- is equivalent to clearing the vector. (In particular, there's no need
-- for us to actually calculate the new value for Last.)
-- If the requested count is less than the current length, then we must
-- calculate the new value for Last. For the type we use the widest of
-- Index_Type'Base and Count_Type'Base for the intermediate values of
-- our calculation. (See the comments in Length for more information.)
if Count >= Container.Length then
Container.Last := No_Index;
elsif Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
Container.Last := Container.Last - Index_Type'Base (Count);
else
Container.Last :=
Index_Type'Base (Count_Type'Base (Container.Last) - Count);
end if;
end Delete_Last;
-------------
-- Element --
-------------
function Element
(Container : Vector;
Index : Index_Type) return Element_Type
is
begin
if Index > Container.Last then
raise Constraint_Error with "Index is out of range";
end if;
return Container.Elements.EA (Index);
end Element;
function Element (Position : Cursor) return Element_Type is
begin
if Position.Container = null then
raise Constraint_Error with "Position cursor has no element";
elsif Position.Index > Position.Container.Last then
raise Constraint_Error with "Position cursor is out of range";
else
return Position.Container.Elements.EA (Position.Index);
end if;
end Element;
--------------
-- Finalize --
--------------
procedure Finalize (Container : in out Vector) is
X : Elements_Access := Container.Elements;
begin
if Container.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (vector is busy)";
end if;
Container.Elements := null;
Container.Last := No_Index;
Free (X);
end Finalize;
----------
-- Find --
----------
function Find
(Container : Vector;
Item : Element_Type;
Position : Cursor := No_Element) return Cursor
is
begin
if Position.Container /= null then
if Position.Container /= Container'Unrestricted_Access then
raise Program_Error with "Position cursor denotes wrong container";
end if;
if Position.Index > Container.Last then
raise Program_Error with "Position index is out of range";
end if;
end if;
for J in Position.Index .. Container.Last loop
if Container.Elements.EA (J) = Item then
return (Container'Unchecked_Access, J);
end if;
end loop;
return No_Element;
end Find;
----------------
-- Find_Index --
----------------
function Find_Index
(Container : Vector;
Item : Element_Type;
Index : Index_Type := Index_Type'First) return Extended_Index
is
begin
for Indx in Index .. Container.Last loop
if Container.Elements.EA (Indx) = Item then
return Indx;
end if;
end loop;
return No_Index;
end Find_Index;
-----------
-- First --
-----------
function First (Container : Vector) return Cursor is
begin
if Is_Empty (Container) then
return No_Element;
else
return (Container'Unchecked_Access, Index_Type'First);
end if;
end First;
function First (Object : Iterator) return Cursor is
begin
if Is_Empty (Object.Container.all) then
return No_Element;
else
return (Object.Container, Index_Type'First);
end if;
end First;
-------------------
-- First_Element --
-------------------
function First_Element (Container : Vector) return Element_Type is
begin
if Container.Last = No_Index then
raise Constraint_Error with "Container is empty";
else
return Container.Elements.EA (Index_Type'First);
end if;
end First_Element;
-----------------
-- First_Index --
-----------------
function First_Index (Container : Vector) return Index_Type is
pragma Unreferenced (Container);
begin
return Index_Type'First;
end First_Index;
---------------------
-- Generic_Sorting --
---------------------
package body Generic_Sorting is
---------------
-- Is_Sorted --
---------------
function Is_Sorted (Container : Vector) return Boolean is
begin
if Container.Last <= Index_Type'First then
return True;
end if;
declare
EA : Elements_Array renames Container.Elements.EA;
begin
for J in Index_Type'First .. Container.Last - 1 loop
if EA (J + 1) < EA (J) then
return False;
end if;
end loop;
end;
return True;
end Is_Sorted;
-----------
-- Merge --
-----------
procedure Merge (Target, Source : in out Vector) is
I : Index_Type'Base := Target.Last;
J : Index_Type'Base;
begin
if Target.Last < Index_Type'First then
Move (Target => Target, Source => Source);
return;
end if;
if Target'Address = Source'Address then
return;
end if;
if Source.Last < Index_Type'First then
return;
end if;
if Source.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (vector is busy)";
end if;
Target.Set_Length (Length (Target) + Length (Source));
declare
TA : Elements_Array renames Target.Elements.EA;
SA : Elements_Array renames Source.Elements.EA;
begin
J := Target.Last;
while Source.Last >= Index_Type'First loop
pragma Assert (Source.Last <= Index_Type'First
or else not (SA (Source.Last) <
SA (Source.Last - 1)));
if I < Index_Type'First then
TA (Index_Type'First .. J) :=
SA (Index_Type'First .. Source.Last);
Source.Last := No_Index;
return;
end if;
pragma Assert (I <= Index_Type'First
or else not (TA (I) < TA (I - 1)));
if SA (Source.Last) < TA (I) then
TA (J) := TA (I);
I := I - 1;
else
TA (J) := SA (Source.Last);
Source.Last := Source.Last - 1;
end if;
J := J - 1;
end loop;
end;
end Merge;
----------
-- Sort --
----------
procedure Sort (Container : in out Vector)
is
procedure Sort is
new Generic_Array_Sort
(Index_Type => Index_Type,
Element_Type => Element_Type,
Array_Type => Elements_Array,
"<" => "<");
begin
if Container.Last <= Index_Type'First then
return;
end if;
if Container.Lock > 0 then
raise Program_Error with
"attempt to tamper with elements (vector is locked)";
end if;
Sort (Container.Elements.EA (Index_Type'First .. Container.Last));
end Sort;
end Generic_Sorting;
-----------------
-- Has_Element --
-----------------
function Has_Element (Position : Cursor) return Boolean is
begin
return Position /= No_Element;
end Has_Element;
------------
-- Insert --
------------
procedure Insert
(Container : in out Vector;
Before : Extended_Index;
New_Item : Element_Type;
Count : Count_Type := 1)
is
Old_Length : constant Count_Type := Container.Length;
Max_Length : Count_Type'Base; -- determined from range of Index_Type
New_Length : Count_Type'Base; -- sum of current length and Count
New_Last : Index_Type'Base; -- last index of vector after insertion
Index : Index_Type'Base; -- scratch for intermediate values
J : Count_Type'Base; -- scratch
New_Capacity : Count_Type'Base; -- length of new, expanded array
Dst_Last : Index_Type'Base; -- last index of new, expanded array
Dst : Elements_Access; -- new, expanded internal array
begin
-- As a precondition on the generic actual Index_Type, the base type
-- must include Index_Type'Pred (Index_Type'First); this is the value
-- that Container.Last assumes when the vector is empty. However, we do
-- not allow that as the value for Index when specifying where the new
-- items should be inserted, so we must manually check. (That the user
-- is allowed to specify the value at all here is a consequence of the
-- declaration of the Extended_Index subtype, which includes the values
-- in the base range that immediately precede and immediately follow the
-- values in the Index_Type.)
if Before < Index_Type'First then
raise Constraint_Error with
"Before index is out of range (too small)";
end if;
-- We do allow a value greater than Container.Last to be specified as
-- the Index, but only if it's immediately greater. This allows for the
-- case of appending items to the back end of the vector. (It is assumed
-- that specifying an index value greater than Last + 1 indicates some
-- deeper flaw in the caller's algorithm, so that case is treated as a
-- proper error.)
if Before > Container.Last
and then Before > Container.Last + 1
then
raise Constraint_Error with
"Before index is out of range (too large)";
end if;
-- We treat inserting 0 items into the container as a no-op, even when
-- the container is busy, so we simply return.
if Count = 0 then
return;
end if;
-- There are two constraints we need to satisfy. The first constraint is
-- that a container cannot have more than Count_Type'Last elements, so
-- we must check the sum of the current length and the insertion count.
-- Note: we cannot simply add these values, because of the possibility
-- of overflow.
if Old_Length > Count_Type'Last - Count then
raise Constraint_Error with "Count is out of range";
end if;
-- It is now safe compute the length of the new vector, without fear of
-- overflow.
New_Length := Old_Length + Count;
-- The second constraint is that the new Last index value cannot exceed
-- Index_Type'Last. In each branch below, we calculate the maximum
-- length (computed from the range of values in Index_Type), and then
-- compare the new length to the maximum length. If the new length is
-- acceptable, then we compute the new last index from that.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
-- We have to handle the case when there might be more values in the
-- range of Index_Type than in the range of Count_Type.
if Index_Type'First <= 0 then
-- We know that No_Index (the same as Index_Type'First - 1) is
-- less than 0, so it is safe to compute the following sum without
-- fear of overflow.
Index := No_Index + Index_Type'Base (Count_Type'Last);
if Index <= Index_Type'Last then
-- We have determined that range of Index_Type has at least as
-- many values as in Count_Type, so Count_Type'Last is the
-- maximum number of items that are allowed.
Max_Length := Count_Type'Last;
else
-- The range of Index_Type has fewer values than in Count_Type,
-- so the maximum number of items is computed from the range of
-- the Index_Type.
Max_Length := Count_Type'Base (Index_Type'Last - No_Index);
end if;
else
-- No_Index is equal or greater than 0, so we can safely compute
-- the difference without fear of overflow (which we would have to
-- worry about if No_Index were less than 0, but that case is
-- handled above).
Max_Length := Count_Type'Base (Index_Type'Last - No_Index);
end if;
elsif Index_Type'First <= 0 then
-- We know that No_Index (the same as Index_Type'First - 1) is less
-- than 0, so it is safe to compute the following sum without fear of
-- overflow.
J := Count_Type'Base (No_Index) + Count_Type'Last;
if J <= Count_Type'Base (Index_Type'Last) then
-- We have determined that range of Index_Type has at least as
-- many values as in Count_Type, so Count_Type'Last is the maximum
-- number of items that are allowed.
Max_Length := Count_Type'Last;
else
-- The range of Index_Type has fewer values than Count_Type does,
-- so the maximum number of items is computed from the range of
-- the Index_Type.
Max_Length :=
Count_Type'Base (Index_Type'Last) - Count_Type'Base (No_Index);
end if;
else
-- No_Index is equal or greater than 0, so we can safely compute the
-- difference without fear of overflow (which we would have to worry
-- about if No_Index were less than 0, but that case is handled
-- above).
Max_Length :=
Count_Type'Base (Index_Type'Last) - Count_Type'Base (No_Index);
end if;
-- We have just computed the maximum length (number of items). We must
-- now compare the requested length to the maximum length, as we do not
-- allow a vector expand beyond the maximum (because that would create
-- an internal array with a last index value greater than
-- Index_Type'Last, with no way to index those elements).
if New_Length > Max_Length then
raise Constraint_Error with "Count is out of range";
end if;
-- New_Last is the last index value of the items in the container after
-- insertion. Use the wider of Index_Type'Base and Count_Type'Base to
-- compute its value from the New_Length.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
New_Last := No_Index + Index_Type'Base (New_Length);
else
New_Last := Index_Type'Base (Count_Type'Base (No_Index) + New_Length);
end if;
if Container.Elements = null then
pragma Assert (Container.Last = No_Index);
-- This is the simplest case, with which we must always begin: we're
-- inserting items into an empty vector that hasn't allocated an
-- internal array yet. Note that we don't need to check the busy bit
-- here, because an empty container cannot be busy.
-- In order to preserve container invariants, we allocate the new
-- internal array first, before setting the Last index value, in case
-- the allocation fails (which can happen either because there is no
-- storage available, or because element initialization fails).
Container.Elements := new Elements_Type'
(Last => New_Last,
EA => (others => New_Item));
-- The allocation of the new, internal array succeeded, so it is now
-- safe to update the Last index, restoring container invariants.
Container.Last := New_Last;
return;
end if;
-- The tampering bits exist to prevent an item from being harmfully
-- manipulated while it is being visited. Query, Update, and Iterate
-- increment the busy count on entry, and decrement the count on
-- exit. Insert checks the count to determine whether it is being called
-- while the associated callback procedure is executing.
if Container.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (vector is busy)";
end if;
-- An internal array has already been allocated, so we must determine
-- whether there is enough unused storage for the new items.
if New_Length <= Container.Elements.EA'Length then
-- In this case, we're inserting elements into a vector that has
-- already allocated an internal array, and the existing array has
-- enough unused storage for the new items.
declare
EA : Elements_Array renames Container.Elements.EA;
begin
if Before > Container.Last then
-- The new items are being appended to the vector, so no
-- sliding of existing elements is required.
EA (Before .. New_Last) := (others => New_Item);
else
-- The new items are being inserted before some existing
-- elements, so we must slide the existing elements up to their
-- new home. We use the wider of Index_Type'Base and
-- Count_Type'Base as the type for intermediate index values.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
Index := Before + Index_Type'Base (Count);
else
Index := Index_Type'Base (Count_Type'Base (Before) + Count);
end if;
EA (Index .. New_Last) := EA (Before .. Container.Last);
EA (Before .. Index - 1) := (others => New_Item);
end if;
end;
Container.Last := New_Last;
return;
end if;
-- In this case, we're inserting elements into a vector that has already
-- allocated an internal array, but the existing array does not have
-- enough storage, so we must allocate a new, longer array. In order to
-- guarantee that the amortized insertion cost is O(1), we always
-- allocate an array whose length is some power-of-two factor of the
-- current array length. (The new array cannot have a length less than
-- the New_Length of the container, but its last index value cannot be
-- greater than Index_Type'Last.)
New_Capacity := Count_Type'Max (1, Container.Elements.EA'Length);
while New_Capacity < New_Length loop
if New_Capacity > Count_Type'Last / 2 then
New_Capacity := Count_Type'Last;
exit;
end if;
New_Capacity := 2 * New_Capacity;
end loop;
if New_Capacity > Max_Length then
-- We have reached the limit of capacity, so no further expansion
-- will occur. (This is not a problem, as there is never a need to
-- have more capacity than the maximum container length.)
New_Capacity := Max_Length;
end if;
-- We have computed the length of the new internal array (and this is
-- what "vector capacity" means), so use that to compute its last index.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
Dst_Last := No_Index + Index_Type'Base (New_Capacity);
else
Dst_Last :=
Index_Type'Base (Count_Type'Base (No_Index) + New_Capacity);
end if;
-- Now we allocate the new, longer internal array. If the allocation
-- fails, we have not changed any container state, so no side-effect
-- will occur as a result of propagating the exception.
Dst := new Elements_Type (Dst_Last);
-- We have our new internal array. All that needs to be done now is to
-- copy the existing items (if any) from the old array (the "source"
-- array, object SA below) to the new array (the "destination" array,
-- object DA below), and then deallocate the old array.
declare
SA : Elements_Array renames Container.Elements.EA; -- source
DA : Elements_Array renames Dst.EA; -- destination
begin
DA (Index_Type'First .. Before - 1) :=
SA (Index_Type'First .. Before - 1);
if Before > Container.Last then
DA (Before .. New_Last) := (others => New_Item);
else
-- The new items are being inserted before some existing elements,
-- so we must slide the existing elements up to their new home.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
Index := Before + Index_Type'Base (Count);
else
Index := Index_Type'Base (Count_Type'Base (Before) + Count);
end if;
DA (Before .. Index - 1) := (others => New_Item);
DA (Index .. New_Last) := SA (Before .. Container.Last);
end if;
exception
when others =>
Free (Dst);
raise;
end;
-- We have successfully copied the items onto the new array, so the
-- final thing to do is deallocate the old array.
declare
X : Elements_Access := Container.Elements;
begin
-- We first isolate the old internal array, removing it from the
-- container and replacing it with the new internal array, before we
-- deallocate the old array (which can fail if finalization of
-- elements propagates an exception).
Container.Elements := Dst;
Container.Last := New_Last;
-- The container invariants have been restored, so it is now safe to
-- attempt to deallocate the old array.
Free (X);
end;
end Insert;
procedure Insert
(Container : in out Vector;
Before : Extended_Index;
New_Item : Vector)
is
N : constant Count_Type := Length (New_Item);
J : Index_Type'Base;
begin
-- Use Insert_Space to create the "hole" (the destination slice) into
-- which we copy the source items.
Insert_Space (Container, Before, Count => N);
if N = 0 then
-- There's nothing else to do here (vetting of parameters was
-- performed already in Insert_Space), so we simply return.
return;
end if;
-- We calculate the last index value of the destination slice using the
-- wider of Index_Type'Base and count_Type'Base.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
J := (Before - 1) + Index_Type'Base (N);
else
J := Index_Type'Base (Count_Type'Base (Before - 1) + N);
end if;
if Container'Address /= New_Item'Address then
-- This is the simple case. New_Item denotes an object different
-- from Container, so there's nothing special we need to do to copy
-- the source items to their destination, because all of the source
-- items are contiguous.
Container.Elements.EA (Before .. J) :=
New_Item.Elements.EA (Index_Type'First .. New_Item.Last);
return;
end if;
-- New_Item denotes the same object as Container, so an insertion has
-- potentially split the source items. The destination is always the
-- range [Before, J], but the source is [Index_Type'First, Before) and
-- (J, Container.Last]. We perform the copy in two steps, using each of
-- the two slices of the source items.
declare
L : constant Index_Type'Base := Before - 1;
subtype Src_Index_Subtype is Index_Type'Base range
Index_Type'First .. L;
Src : Elements_Array renames
Container.Elements.EA (Src_Index_Subtype);
K : Index_Type'Base;
begin
-- We first copy the source items that precede the space we
-- inserted. Index value K is the last index of that portion
-- destination that receives this slice of the source. (If Before
-- equals Index_Type'First, then this first source slice will be
-- empty, which is harmless.)
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
K := L + Index_Type'Base (Src'Length);
else
K := Index_Type'Base (Count_Type'Base (L) + Src'Length);
end if;
Container.Elements.EA (Before .. K) := Src;
if Src'Length = N then
-- The new items were effectively appended to the container, so we
-- have already copied all of the items that need to be copied.
-- We return early here, even though the source slice below is
-- empty (so the assignment would be harmless), because we want to
-- avoid computing J + 1, which will overflow if J equals
-- Index_Type'Base'Last.
return;
end if;
end;
declare
-- Note that we want to avoid computing J + 1 here, in case J equals
-- Index_Type'Base'Last. We prevent that by returning early above,
-- immediately after copying the first slice of the source, and
-- determining that this second slice of the source is empty.
F : constant Index_Type'Base := J + 1;
subtype Src_Index_Subtype is Index_Type'Base range
F .. Container.Last;
Src : Elements_Array renames
Container.Elements.EA (Src_Index_Subtype);
K : Index_Type'Base;
begin
-- We next copy the source items that follow the space we
-- inserted. Index value K is the first index of that portion of the
-- destination that receives this slice of the source. (For the
-- reasons given above, this slice is guaranteed to be non-empty.)
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
K := F - Index_Type'Base (Src'Length);
else
K := Index_Type'Base (Count_Type'Base (F) - Src'Length);
end if;
Container.Elements.EA (K .. J) := Src;
end;
end Insert;
procedure Insert
(Container : in out Vector;
Before : Cursor;
New_Item : Vector)
is
Index : Index_Type'Base;
begin
if Before.Container /= null
and then Before.Container /= Container'Unchecked_Access
then
raise Program_Error with "Before cursor denotes wrong container";
end if;
if Is_Empty (New_Item) then
return;
end if;
if Before.Container = null
or else Before.Index > Container.Last
then
if Container.Last = Index_Type'Last then
raise Constraint_Error with
"vector is already at its maximum length";
end if;
Index := Container.Last + 1;
else
Index := Before.Index;
end if;
Insert (Container, Index, New_Item);
end Insert;
procedure Insert
(Container : in out Vector;
Before : Cursor;
New_Item : Vector;
Position : out Cursor)
is
Index : Index_Type'Base;
begin
if Before.Container /= null
and then Before.Container /= Container'Unchecked_Access
then
raise Program_Error with "Before cursor denotes wrong container";
end if;
if Is_Empty (New_Item) then
if Before.Container = null
or else Before.Index > Container.Last
then
Position := No_Element;
else
Position := (Container'Unchecked_Access, Before.Index);
end if;
return;
end if;
if Before.Container = null
or else Before.Index > Container.Last
then
if Container.Last = Index_Type'Last then
raise Constraint_Error with
"vector is already at its maximum length";
end if;
Index := Container.Last + 1;
else
Index := Before.Index;
end if;
Insert (Container, Index, New_Item);
Position := (Container'Unchecked_Access, Index);
end Insert;
procedure Insert
(Container : in out Vector;
Before : Cursor;
New_Item : Element_Type;
Count : Count_Type := 1)
is
Index : Index_Type'Base;
begin
if Before.Container /= null
and then Before.Container /= Container'Unchecked_Access
then
raise Program_Error with "Before cursor denotes wrong container";
end if;
if Count = 0 then
return;
end if;
if Before.Container = null
or else Before.Index > Container.Last
then
if Container.Last = Index_Type'Last then
raise Constraint_Error with
"vector is already at its maximum length";
else
Index := Container.Last + 1;
end if;
else
Index := Before.Index;
end if;
Insert (Container, Index, New_Item, Count);
end Insert;
procedure Insert
(Container : in out Vector;
Before : Cursor;
New_Item : Element_Type;
Position : out Cursor;
Count : Count_Type := 1)
is
Index : Index_Type'Base;
begin
if Before.Container /= null
and then Before.Container /= Container'Unchecked_Access
then
raise Program_Error with "Before cursor denotes wrong container";
end if;
if Count = 0 then
if Before.Container = null
or else Before.Index > Container.Last
then
Position := No_Element;
else
Position := (Container'Unchecked_Access, Before.Index);
end if;
return;
end if;
if Before.Container = null
or else Before.Index > Container.Last
then
if Container.Last = Index_Type'Last then
raise Constraint_Error with
"vector is already at its maximum length";
end if;
Index := Container.Last + 1;
else
Index := Before.Index;
end if;
Insert (Container, Index, New_Item, Count);
Position := (Container'Unchecked_Access, Index);
end Insert;
procedure Insert
(Container : in out Vector;
Before : Extended_Index;
Count : Count_Type := 1)
is
New_Item : Element_Type; -- Default-initialized value
pragma Warnings (Off, New_Item);
begin
Insert (Container, Before, New_Item, Count);
end Insert;
procedure Insert
(Container : in out Vector;
Before : Cursor;
Position : out Cursor;
Count : Count_Type := 1)
is
New_Item : Element_Type; -- Default-initialized value
pragma Warnings (Off, New_Item);
begin
Insert (Container, Before, New_Item, Position, Count);
end Insert;
------------------
-- Insert_Space --
------------------
procedure Insert_Space
(Container : in out Vector;
Before : Extended_Index;
Count : Count_Type := 1)
is
Old_Length : constant Count_Type := Container.Length;
Max_Length : Count_Type'Base; -- determined from range of Index_Type
New_Length : Count_Type'Base; -- sum of current length and Count
New_Last : Index_Type'Base; -- last index of vector after insertion
Index : Index_Type'Base; -- scratch for intermediate values
J : Count_Type'Base; -- scratch
New_Capacity : Count_Type'Base; -- length of new, expanded array
Dst_Last : Index_Type'Base; -- last index of new, expanded array
Dst : Elements_Access; -- new, expanded internal array
begin
-- As a precondition on the generic actual Index_Type, the base type
-- must include Index_Type'Pred (Index_Type'First); this is the value
-- that Container.Last assumes when the vector is empty. However, we do
-- not allow that as the value for Index when specifying where the new
-- items should be inserted, so we must manually check. (That the user
-- is allowed to specify the value at all here is a consequence of the
-- declaration of the Extended_Index subtype, which includes the values
-- in the base range that immediately precede and immediately follow the
-- values in the Index_Type.)
if Before < Index_Type'First then
raise Constraint_Error with
"Before index is out of range (too small)";
end if;
-- We do allow a value greater than Container.Last to be specified as
-- the Index, but only if it's immediately greater. This allows for the
-- case of appending items to the back end of the vector. (It is assumed
-- that specifying an index value greater than Last + 1 indicates some
-- deeper flaw in the caller's algorithm, so that case is treated as a
-- proper error.)
if Before > Container.Last
and then Before > Container.Last + 1
then
raise Constraint_Error with
"Before index is out of range (too large)";
end if;
-- We treat inserting 0 items into the container as a no-op, even when
-- the container is busy, so we simply return.
if Count = 0 then
return;
end if;
-- There are two constraints we need to satisfy. The first constraint is
-- that a container cannot have more than Count_Type'Last elements, so
-- we must check the sum of the current length and the insertion count.
-- Note: we cannot simply add these values, because of the possibility
-- of overflow.
if Old_Length > Count_Type'Last - Count then
raise Constraint_Error with "Count is out of range";
end if;
-- It is now safe compute the length of the new vector, without fear of
-- overflow.
New_Length := Old_Length + Count;
-- The second constraint is that the new Last index value cannot exceed
-- Index_Type'Last. In each branch below, we calculate the maximum
-- length (computed from the range of values in Index_Type), and then
-- compare the new length to the maximum length. If the new length is
-- acceptable, then we compute the new last index from that.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
-- We have to handle the case when there might be more values in the
-- range of Index_Type than in the range of Count_Type.
if Index_Type'First <= 0 then
-- We know that No_Index (the same as Index_Type'First - 1) is
-- less than 0, so it is safe to compute the following sum without
-- fear of overflow.
Index := No_Index + Index_Type'Base (Count_Type'Last);
if Index <= Index_Type'Last then
-- We have determined that range of Index_Type has at least as
-- many values as in Count_Type, so Count_Type'Last is the
-- maximum number of items that are allowed.
Max_Length := Count_Type'Last;
else
-- The range of Index_Type has fewer values than in Count_Type,
-- so the maximum number of items is computed from the range of
-- the Index_Type.
Max_Length := Count_Type'Base (Index_Type'Last - No_Index);
end if;
else
-- No_Index is equal or greater than 0, so we can safely compute
-- the difference without fear of overflow (which we would have to
-- worry about if No_Index were less than 0, but that case is
-- handled above).
Max_Length := Count_Type'Base (Index_Type'Last - No_Index);
end if;
elsif Index_Type'First <= 0 then
-- We know that No_Index (the same as Index_Type'First - 1) is less
-- than 0, so it is safe to compute the following sum without fear of
-- overflow.
J := Count_Type'Base (No_Index) + Count_Type'Last;
if J <= Count_Type'Base (Index_Type'Last) then
-- We have determined that range of Index_Type has at least as
-- many values as in Count_Type, so Count_Type'Last is the maximum
-- number of items that are allowed.
Max_Length := Count_Type'Last;
else
-- The range of Index_Type has fewer values than Count_Type does,
-- so the maximum number of items is computed from the range of
-- the Index_Type.
Max_Length :=
Count_Type'Base (Index_Type'Last) - Count_Type'Base (No_Index);
end if;
else
-- No_Index is equal or greater than 0, so we can safely compute the
-- difference without fear of overflow (which we would have to worry
-- about if No_Index were less than 0, but that case is handled
-- above).
Max_Length :=
Count_Type'Base (Index_Type'Last) - Count_Type'Base (No_Index);
end if;
-- We have just computed the maximum length (number of items). We must
-- now compare the requested length to the maximum length, as we do not
-- allow a vector expand beyond the maximum (because that would create
-- an internal array with a last index value greater than
-- Index_Type'Last, with no way to index those elements).
if New_Length > Max_Length then
raise Constraint_Error with "Count is out of range";
end if;
-- New_Last is the last index value of the items in the container after
-- insertion. Use the wider of Index_Type'Base and Count_Type'Base to
-- compute its value from the New_Length.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
New_Last := No_Index + Index_Type'Base (New_Length);
else
New_Last := Index_Type'Base (Count_Type'Base (No_Index) + New_Length);
end if;
if Container.Elements = null then
pragma Assert (Container.Last = No_Index);
-- This is the simplest case, with which we must always begin: we're
-- inserting items into an empty vector that hasn't allocated an
-- internal array yet. Note that we don't need to check the busy bit
-- here, because an empty container cannot be busy.
-- In order to preserve container invariants, we allocate the new
-- internal array first, before setting the Last index value, in case
-- the allocation fails (which can happen either because there is no
-- storage available, or because default-valued element
-- initialization fails).
Container.Elements := new Elements_Type (New_Last);
-- The allocation of the new, internal array succeeded, so it is now
-- safe to update the Last index, restoring container invariants.
Container.Last := New_Last;
return;
end if;
-- The tampering bits exist to prevent an item from being harmfully
-- manipulated while it is being visited. Query, Update, and Iterate
-- increment the busy count on entry, and decrement the count on
-- exit. Insert checks the count to determine whether it is being called
-- while the associated callback procedure is executing.
if Container.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (vector is busy)";
end if;
-- An internal array has already been allocated, so we must determine
-- whether there is enough unused storage for the new items.
if New_Last <= Container.Elements.Last then
-- In this case, we're inserting space into a vector that has already
-- allocated an internal array, and the existing array has enough
-- unused storage for the new items.
declare
EA : Elements_Array renames Container.Elements.EA;
begin
if Before <= Container.Last then
-- The space is being inserted before some existing elements,
-- so we must slide the existing elements up to their new
-- home. We use the wider of Index_Type'Base and
-- Count_Type'Base as the type for intermediate index values.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
Index := Before + Index_Type'Base (Count);
else
Index := Index_Type'Base (Count_Type'Base (Before) + Count);
end if;
EA (Index .. New_Last) := EA (Before .. Container.Last);
end if;
end;
Container.Last := New_Last;
return;
end if;
-- In this case, we're inserting space into a vector that has already
-- allocated an internal array, but the existing array does not have
-- enough storage, so we must allocate a new, longer array. In order to
-- guarantee that the amortized insertion cost is O(1), we always
-- allocate an array whose length is some power-of-two factor of the
-- current array length. (The new array cannot have a length less than
-- the New_Length of the container, but its last index value cannot be
-- greater than Index_Type'Last.)
New_Capacity := Count_Type'Max (1, Container.Elements.EA'Length);
while New_Capacity < New_Length loop
if New_Capacity > Count_Type'Last / 2 then
New_Capacity := Count_Type'Last;
exit;
end if;
New_Capacity := 2 * New_Capacity;
end loop;
if New_Capacity > Max_Length then
-- We have reached the limit of capacity, so no further expansion
-- will occur. (This is not a problem, as there is never a need to
-- have more capacity than the maximum container length.)
New_Capacity := Max_Length;
end if;
-- We have computed the length of the new internal array (and this is
-- what "vector capacity" means), so use that to compute its last index.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
Dst_Last := No_Index + Index_Type'Base (New_Capacity);
else
Dst_Last :=
Index_Type'Base (Count_Type'Base (No_Index) + New_Capacity);
end if;
-- Now we allocate the new, longer internal array. If the allocation
-- fails, we have not changed any container state, so no side-effect
-- will occur as a result of propagating the exception.
Dst := new Elements_Type (Dst_Last);
-- We have our new internal array. All that needs to be done now is to
-- copy the existing items (if any) from the old array (the "source"
-- array, object SA below) to the new array (the "destination" array,
-- object DA below), and then deallocate the old array.
declare
SA : Elements_Array renames Container.Elements.EA; -- source
DA : Elements_Array renames Dst.EA; -- destination
begin
DA (Index_Type'First .. Before - 1) :=
SA (Index_Type'First .. Before - 1);
if Before <= Container.Last then
-- The space is being inserted before some existing elements, so
-- we must slide the existing elements up to their new home.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
Index := Before + Index_Type'Base (Count);
else
Index := Index_Type'Base (Count_Type'Base (Before) + Count);
end if;
DA (Index .. New_Last) := SA (Before .. Container.Last);
end if;
exception
when others =>
Free (Dst);
raise;
end;
-- We have successfully copied the items onto the new array, so the
-- final thing to do is restore invariants, and deallocate the old
-- array.
declare
X : Elements_Access := Container.Elements;
begin
-- We first isolate the old internal array, removing it from the
-- container and replacing it with the new internal array, before we
-- deallocate the old array (which can fail if finalization of
-- elements propagates an exception).
Container.Elements := Dst;
Container.Last := New_Last;
-- The container invariants have been restored, so it is now safe to
-- attempt to deallocate the old array.
Free (X);
end;
end Insert_Space;
procedure Insert_Space
(Container : in out Vector;
Before : Cursor;
Position : out Cursor;
Count : Count_Type := 1)
is
Index : Index_Type'Base;
begin
if Before.Container /= null
and then Before.Container /= Container'Unchecked_Access
then
raise Program_Error with "Before cursor denotes wrong container";
end if;
if Count = 0 then
if Before.Container = null
or else Before.Index > Container.Last
then
Position := No_Element;
else
Position := (Container'Unchecked_Access, Before.Index);
end if;
return;
end if;
if Before.Container = null
or else Before.Index > Container.Last
then
if Container.Last = Index_Type'Last then
raise Constraint_Error with
"vector is already at its maximum length";
else
Index := Container.Last + 1;
end if;
else
Index := Before.Index;
end if;
Insert_Space (Container, Index, Count => Count);
Position := (Container'Unchecked_Access, Index);
end Insert_Space;
--------------
-- Is_Empty --
--------------
function Is_Empty (Container : Vector) return Boolean is
begin
return Container.Last < Index_Type'First;
end Is_Empty;
-------------
-- Iterate --
-------------
procedure Iterate
(Container : Vector;
Process : not null access procedure (Position : Cursor))
is
V : Vector renames Container'Unrestricted_Access.all;
B : Natural renames V.Busy;
begin
B := B + 1;
begin
for Indx in Index_Type'First .. Container.Last loop
Process (Cursor'(Container'Unchecked_Access, Indx));
end loop;
exception
when others =>
B := B - 1;
raise;
end;
B := B - 1;
end Iterate;
function Iterate
(Container : Vector)
return Vector_Iterator_Interfaces.Reversible_Iterator'Class
is
It : constant Iterator := (Container'Unchecked_Access, Index_Type'First);
begin
return It;
end Iterate;
function Iterate
(Container : Vector;
Start : Cursor)
return Vector_Iterator_Interfaces.Reversible_Iterator'class
is
It : constant Iterator := (Container'Unchecked_Access, Start.Index);
begin
return It;
end Iterate;
----------
-- Last --
----------
function Last (Container : Vector) return Cursor is
begin
if Is_Empty (Container) then
return No_Element;
else
return (Container'Unchecked_Access, Container.Last);
end if;
end Last;
function Last (Object : Iterator) return Cursor is
begin
if Is_Empty (Object.Container.all) then
return No_Element;
else
return (Object.Container, Object.Container.Last);
end if;
end Last;
------------------
-- Last_Element --
------------------
function Last_Element (Container : Vector) return Element_Type is
begin
if Container.Last = No_Index then
raise Constraint_Error with "Container is empty";
else
return Container.Elements.EA (Container.Last);
end if;
end Last_Element;
----------------
-- Last_Index --
----------------
function Last_Index (Container : Vector) return Extended_Index is
begin
return Container.Last;
end Last_Index;
------------
-- Length --
------------
function Length (Container : Vector) return Count_Type is
L : constant Index_Type'Base := Container.Last;
F : constant Index_Type := Index_Type'First;
begin
-- The base range of the index type (Index_Type'Base) might not include
-- all values for length (Count_Type). Contrariwise, the index type
-- might include values outside the range of length. Hence we use
-- whatever type is wider for intermediate values when calculating
-- length. Note that no matter what the index type is, the maximum
-- length to which a vector is allowed to grow is always the minimum
-- of Count_Type'Last and (IT'Last - IT'First + 1).
-- For example, an Index_Type with range -127 .. 127 is only guaranteed
-- to have a base range of -128 .. 127, but the corresponding vector
-- would have lengths in the range 0 .. 255. In this case we would need
-- to use Count_Type'Base for intermediate values.
-- Another case would be the index range -2**63 + 1 .. -2**63 + 10. The
-- vector would have a maximum length of 10, but the index values lie
-- outside the range of Count_Type (which is only 32 bits). In this
-- case we would need to use Index_Type'Base for intermediate values.
if Count_Type'Base'Last >= Index_Type'Pos (Index_Type'Base'Last) then
return Count_Type'Base (L) - Count_Type'Base (F) + 1;
else
return Count_Type (L - F + 1);
end if;
end Length;
----------
-- Move --
----------
procedure Move
(Target : in out Vector;
Source : in out Vector)
is
begin
if Target'Address = Source'Address then
return;
end if;
if Target.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (Target is busy)";
end if;
if Source.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (Source is busy)";
end if;
declare
Target_Elements : constant Elements_Access := Target.Elements;
begin
Target.Elements := Source.Elements;
Source.Elements := Target_Elements;
end;
Target.Last := Source.Last;
Source.Last := No_Index;
end Move;
----------
-- Next --
----------
function Next (Position : Cursor) return Cursor is
begin
if Position.Container = null then
return No_Element;
elsif Position.Index < Position.Container.Last then
return (Position.Container, Position.Index + 1);
else
return No_Element;
end if;
end Next;
function Next (Object : Iterator; Position : Cursor) return Cursor is
begin
if Position.Index < Object.Container.Last then
return (Object.Container, Position.Index + 1);
else
return No_Element;
end if;
end Next;
procedure Next (Position : in out Cursor) is
begin
if Position.Container = null then
return;
elsif Position.Index < Position.Container.Last then
Position.Index := Position.Index + 1;
else
Position := No_Element;
end if;
end Next;
-------------
-- Prepend --
-------------
procedure Prepend (Container : in out Vector; New_Item : Vector) is
begin
Insert (Container, Index_Type'First, New_Item);
end Prepend;
procedure Prepend
(Container : in out Vector;
New_Item : Element_Type;
Count : Count_Type := 1)
is
begin
Insert (Container,
Index_Type'First,
New_Item,
Count);
end Prepend;
--------------
-- Previous --
--------------
function Previous (Position : Cursor) return Cursor is
begin
if Position.Container = null then
return No_Element;
elsif Position.Index > Index_Type'First then
return (Position.Container, Position.Index - 1);
else
return No_Element;
end if;
end Previous;
function Previous (Object : Iterator; Position : Cursor) return Cursor is
begin
if Position.Index > Index_Type'First then
return (Object.Container, Position.Index - 1);
else
return No_Element;
end if;
end Previous;
procedure Previous (Position : in out Cursor) is
begin
if Position.Container = null then
return;
elsif Position.Index > Index_Type'First then
Position.Index := Position.Index - 1;
else
Position := No_Element;
end if;
end Previous;
-------------------
-- Query_Element --
-------------------
procedure Query_Element
(Container : Vector;
Index : Index_Type;
Process : not null access procedure (Element : Element_Type))
is
V : Vector renames Container'Unrestricted_Access.all;
B : Natural renames V.Busy;
L : Natural renames V.Lock;
begin
if Index > Container.Last then
raise Constraint_Error with "Index is out of range";
end if;
B := B + 1;
L := L + 1;
begin
Process (V.Elements.EA (Index));
exception
when others =>
L := L - 1;
B := B - 1;
raise;
end;
L := L - 1;
B := B - 1;
end Query_Element;
procedure Query_Element
(Position : Cursor;
Process : not null access procedure (Element : Element_Type))
is
begin
if Position.Container = null then
raise Constraint_Error with "Position cursor has no element";
end if;
Query_Element (Position.Container.all, Position.Index, Process);
end Query_Element;
----------
-- Read --
----------
procedure Read
(Stream : not null access Root_Stream_Type'Class;
Container : out Vector)
is
Length : Count_Type'Base;
Last : Index_Type'Base := No_Index;
begin
Clear (Container);
Count_Type'Base'Read (Stream, Length);
if Length > Capacity (Container) then
Reserve_Capacity (Container, Capacity => Length);
end if;
for J in Count_Type range 1 .. Length loop
Last := Last + 1;
Element_Type'Read (Stream, Container.Elements.EA (Last));
Container.Last := Last;
end loop;
end Read;
procedure Read
(Stream : not null access Root_Stream_Type'Class;
Position : out Cursor)
is
begin
raise Program_Error with "attempt to stream vector cursor";
end Read;
procedure Read
(Stream : not null access Root_Stream_Type'Class;
Item : out Reference_Type)
is
begin
raise Program_Error with "attempt to stream reference";
end Read;
procedure Read
(Stream : not null access Root_Stream_Type'Class;
Item : out Constant_Reference_Type)
is
begin
raise Program_Error with "attempt to stream reference";
end Read;
---------------
-- Reference --
---------------
function Constant_Reference
(Container : Vector;
Position : Cursor) -- SHOULD BE ALIASED
return Constant_Reference_Type
is
begin
pragma Unreferenced (Container);
if Position.Container = null then
raise Constraint_Error with "Position cursor has no element";
end if;
if Position.Index > Position.Container.Last then
raise Constraint_Error with "Position cursor is out of range";
end if;
return
(Element =>
Position.Container.Elements.EA (Position.Index)'Access);
end Constant_Reference;
function Constant_Reference
(Container : Vector;
Position : Index_Type)
return Constant_Reference_Type
is
begin
if Position > Container.Last then
raise Constraint_Error with "Index is out of range";
else
return (Element => Container.Elements.EA (Position)'Access);
end if;
end Constant_Reference;
function Reference (Container : Vector; Position : Cursor)
return Reference_Type is
begin
pragma Unreferenced (Container);
if Position.Container = null then
raise Constraint_Error with "Position cursor has no element";
end if;
if Position.Index > Position.Container.Last then
raise Constraint_Error with "Position cursor is out of range";
end if;
return
(Element => Position.Container.Elements.EA (Position.Index)'Access);
end Reference;
function Reference (Container : Vector; Position : Index_Type)
return Reference_Type is
begin
if Position > Container.Last then
raise Constraint_Error with "Index is out of range";
else
return (Element => Container.Elements.EA (Position)'Access);
end if;
end Reference;
---------------------
-- Replace_Element --
---------------------
procedure Replace_Element
(Container : in out Vector;
Index : Index_Type;
New_Item : Element_Type)
is
begin
if Index > Container.Last then
raise Constraint_Error with "Index is out of range";
end if;
if Container.Lock > 0 then
raise Program_Error with
"attempt to tamper with elements (vector is locked)";
end if;
Container.Elements.EA (Index) := New_Item;
end Replace_Element;
procedure Replace_Element
(Container : in out Vector;
Position : Cursor;
New_Item : Element_Type)
is
begin
if Position.Container = null then
raise Constraint_Error with "Position cursor has no element";
end if;
if Position.Container /= Container'Unrestricted_Access then
raise Program_Error with "Position cursor denotes wrong container";
end if;
if Position.Index > Container.Last then
raise Constraint_Error with "Position cursor is out of range";
end if;
if Container.Lock > 0 then
raise Program_Error with
"attempt to tamper with elements (vector is locked)";
end if;
Container.Elements.EA (Position.Index) := New_Item;
end Replace_Element;
----------------------
-- Reserve_Capacity --
----------------------
procedure Reserve_Capacity
(Container : in out Vector;
Capacity : Count_Type)
is
N : constant Count_Type := Length (Container);
Index : Count_Type'Base;
Last : Index_Type'Base;
begin
-- Reserve_Capacity can be used to either expand the storage available
-- for elements (this would be its typical use, in anticipation of
-- future insertion), or to trim back storage. In the latter case,
-- storage can only be trimmed back to the limit of the container
-- length. Note that Reserve_Capacity neither deletes (active) elements
-- nor inserts elements; it only affects container capacity, never
-- container length.
if Capacity = 0 then
-- This is a request to trim back storage, to the minimum amount
-- possible given the current state of the container.
if N = 0 then
-- The container is empty, so in this unique case we can
-- deallocate the entire internal array. Note that an empty
-- container can never be busy, so there's no need to check the
-- tampering bits.
declare
X : Elements_Access := Container.Elements;
begin
-- First we remove the internal array from the container, to
-- handle the case when the deallocation raises an exception.
Container.Elements := null;
-- Container invariants have been restored, so it is now safe
-- to attempt to deallocate the internal array.
Free (X);
end;
elsif N < Container.Elements.EA'Length then
-- The container is not empty, and the current length is less than
-- the current capacity, so there's storage available to trim. In
-- this case, we allocate a new internal array having a length
-- that exactly matches the number of items in the
-- container. (Reserve_Capacity does not delete active elements,
-- so this is the best we can do with respect to minimizing
-- storage).
if Container.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (vector is busy)";
end if;
declare
subtype Src_Index_Subtype is Index_Type'Base range
Index_Type'First .. Container.Last;
Src : Elements_Array renames
Container.Elements.EA (Src_Index_Subtype);
X : Elements_Access := Container.Elements;
begin
-- Although we have isolated the old internal array that we're
-- going to deallocate, we don't deallocate it until we have
-- successfully allocated a new one. If there is an exception
-- during allocation (either because there is not enough
-- storage, or because initialization of the elements fails),
-- we let it propagate without causing any side-effect.
Container.Elements := new Elements_Type'(Container.Last, Src);
-- We have successfully allocated a new internal array (with a
-- smaller length than the old one, and containing a copy of
-- just the active elements in the container), so it is now
-- safe to attempt to deallocate the old array. The old array
-- has been isolated, and container invariants have been
-- restored, so if the deallocation fails (because finalization
-- of the elements fails), we simply let it propagate.
Free (X);
end;
end if;
return;
end if;
-- Reserve_Capacity can be used to expand the storage available for
-- elements, but we do not let the capacity grow beyond the number of
-- values in Index_Type'Range. (Were it otherwise, there would be no way
-- to refer to the elements with an index value greater than
-- Index_Type'Last, so that storage would be wasted.) Here we compute
-- the Last index value of the new internal array, in a way that avoids
-- any possibility of overflow.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
-- We perform a two-part test. First we determine whether the
-- computed Last value lies in the base range of the type, and then
-- determine whether it lies in the range of the index (sub)type.
-- Last must satisfy this relation:
-- First + Length - 1 <= Last
-- We regroup terms:
-- First - 1 <= Last - Length
-- Which can rewrite as:
-- No_Index <= Last - Length
if Index_Type'Base'Last - Index_Type'Base (Capacity) < No_Index then
raise Constraint_Error with "Capacity is out of range";
end if;
-- We now know that the computed value of Last is within the base
-- range of the type, so it is safe to compute its value:
Last := No_Index + Index_Type'Base (Capacity);
-- Finally we test whether the value is within the range of the
-- generic actual index subtype:
if Last > Index_Type'Last then
raise Constraint_Error with "Capacity is out of range";
end if;
elsif Index_Type'First <= 0 then
-- Here we can compute Last directly, in the normal way. We know that
-- No_Index is less than 0, so there is no danger of overflow when
-- adding the (positive) value of Capacity.
Index := Count_Type'Base (No_Index) + Capacity; -- Last
if Index > Count_Type'Base (Index_Type'Last) then
raise Constraint_Error with "Capacity is out of range";
end if;
-- We know that the computed value (having type Count_Type) of Last
-- is within the range of the generic actual index subtype, so it is
-- safe to convert to Index_Type:
Last := Index_Type'Base (Index);
else
-- Here Index_Type'First (and Index_Type'Last) is positive, so we
-- must test the length indirectly (by working backwards from the
-- largest possible value of Last), in order to prevent overflow.
Index := Count_Type'Base (Index_Type'Last) - Capacity; -- No_Index
if Index < Count_Type'Base (No_Index) then
raise Constraint_Error with "Capacity is out of range";
end if;
-- We have determined that the value of Capacity would not create a
-- Last index value outside of the range of Index_Type, so we can now
-- safely compute its value.
Last := Index_Type'Base (Count_Type'Base (No_Index) + Capacity);
end if;
-- The requested capacity is non-zero, but we don't know yet whether
-- this is a request for expansion or contraction of storage.
if Container.Elements = null then
-- The container is empty (it doesn't even have an internal array),
-- so this represents a request to allocate (expand) storage having
-- the given capacity.
Container.Elements := new Elements_Type (Last);
return;
end if;
if Capacity <= N then
-- This is a request to trim back storage, but only to the limit of
-- what's already in the container. (Reserve_Capacity never deletes
-- active elements, it only reclaims excess storage.)
if N < Container.Elements.EA'Length then
-- The container is not empty (because the requested capacity is
-- positive, and less than or equal to the container length), and
-- the current length is less than the current capacity, so
-- there's storage available to trim. In this case, we allocate a
-- new internal array having a length that exactly matches the
-- number of items in the container.
if Container.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (vector is busy)";
end if;
declare
subtype Src_Index_Subtype is Index_Type'Base range
Index_Type'First .. Container.Last;
Src : Elements_Array renames
Container.Elements.EA (Src_Index_Subtype);
X : Elements_Access := Container.Elements;
begin
-- Although we have isolated the old internal array that we're
-- going to deallocate, we don't deallocate it until we have
-- successfully allocated a new one. If there is an exception
-- during allocation (either because there is not enough
-- storage, or because initialization of the elements fails),
-- we let it propagate without causing any side-effect.
Container.Elements := new Elements_Type'(Container.Last, Src);
-- We have successfully allocated a new internal array (with a
-- smaller length than the old one, and containing a copy of
-- just the active elements in the container), so it is now
-- safe to attempt to deallocate the old array. The old array
-- has been isolated, and container invariants have been
-- restored, so if the deallocation fails (because finalization
-- of the elements fails), we simply let it propagate.
Free (X);
end;
end if;
return;
end if;
-- The requested capacity is larger than the container length (the
-- number of active elements). Whether this represents a request for
-- expansion or contraction of the current capacity depends on what the
-- current capacity is.
if Capacity = Container.Elements.EA'Length then
-- The requested capacity matches the existing capacity, so there's
-- nothing to do here. We treat this case as a no-op, and simply
-- return without checking the busy bit.
return;
end if;
-- There is a change in the capacity of a non-empty container, so a new
-- internal array will be allocated. (The length of the new internal
-- array could be less or greater than the old internal array. We know
-- only that the length of the new internal array is greater than the
-- number of active elements in the container.) We must check whether
-- the container is busy before doing anything else.
if Container.Busy > 0 then
raise Program_Error with
"attempt to tamper with cursors (vector is busy)";
end if;
-- We now allocate a new internal array, having a length different from
-- its current value.
declare
E : Elements_Access := new Elements_Type (Last);
begin
-- We have successfully allocated the new internal array. We first
-- attempt to copy the existing elements from the old internal array
-- ("src" elements) onto the new internal array ("tgt" elements).
declare
subtype Index_Subtype is Index_Type'Base range
Index_Type'First .. Container.Last;
Src : Elements_Array renames
Container.Elements.EA (Index_Subtype);
Tgt : Elements_Array renames E.EA (Index_Subtype);
begin
Tgt := Src;
exception
when others =>
Free (E);
raise;
end;
-- We have successfully copied the existing elements onto the new
-- internal array, so now we can attempt to deallocate the old one.
declare
X : Elements_Access := Container.Elements;
begin
-- First we isolate the old internal array, and replace it in the
-- container with the new internal array.
Container.Elements := E;
-- Container invariants have been restored, so it is now safe to
-- attempt to deallocate the old internal array.
Free (X);
end;
end;
end Reserve_Capacity;
----------------------
-- Reverse_Elements --
----------------------
procedure Reverse_Elements (Container : in out Vector) is
begin
if Container.Length <= 1 then
return;
end if;
if Container.Lock > 0 then
raise Program_Error with
"attempt to tamper with elements (vector is locked)";
end if;
declare
I, J : Index_Type;
E : Elements_Type renames Container.Elements.all;
begin
I := Index_Type'First;
J := Container.Last;
while I < J loop
declare
EI : constant Element_Type := E.EA (I);
begin
E.EA (I) := E.EA (J);
E.EA (J) := EI;
end;
I := I + 1;
J := J - 1;
end loop;
end;
end Reverse_Elements;
------------------
-- Reverse_Find --
------------------
function Reverse_Find
(Container : Vector;
Item : Element_Type;
Position : Cursor := No_Element) return Cursor
is
Last : Index_Type'Base;
begin
if Position.Container /= null
and then Position.Container /= Container'Unchecked_Access
then
raise Program_Error with "Position cursor denotes wrong container";
end if;
Last :=
(if Position.Container = null or else Position.Index > Container.Last
then Container.Last
else Position.Index);
for Indx in reverse Index_Type'First .. Last loop
if Container.Elements.EA (Indx) = Item then
return (Container'Unchecked_Access, Indx);
end if;
end loop;
return No_Element;
end Reverse_Find;
------------------------
-- Reverse_Find_Index --
------------------------
function Reverse_Find_Index
(Container : Vector;
Item : Element_Type;
Index : Index_Type := Index_Type'Last) return Extended_Index
is
Last : constant Index_Type'Base :=
Index_Type'Min (Container.Last, Index);
begin
for Indx in reverse Index_Type'First .. Last loop
if Container.Elements.EA (Indx) = Item then
return Indx;
end if;
end loop;
return No_Index;
end Reverse_Find_Index;
---------------------
-- Reverse_Iterate --
---------------------
procedure Reverse_Iterate
(Container : Vector;
Process : not null access procedure (Position : Cursor))
is
V : Vector renames Container'Unrestricted_Access.all;
B : Natural renames V.Busy;
begin
B := B + 1;
begin
for Indx in reverse Index_Type'First .. Container.Last loop
Process (Cursor'(Container'Unchecked_Access, Indx));
end loop;
exception
when others =>
B := B - 1;
raise;
end;
B := B - 1;
end Reverse_Iterate;
----------------
-- Set_Length --
----------------
procedure Set_Length (Container : in out Vector; Length : Count_Type) is
Count : constant Count_Type'Base := Container.Length - Length;
begin
-- Set_Length allows the user to set the length explicitly, instead of
-- implicitly as a side-effect of deletion or insertion. If the
-- requested length is less then the current length, this is equivalent
-- to deleting items from the back end of the vector. If the requested
-- length is greater than the current length, then this is equivalent to
-- inserting "space" (nonce items) at the end.
if Count >= 0 then
Container.Delete_Last (Count);
elsif Container.Last >= Index_Type'Last then
raise Constraint_Error with "vector is already at its maximum length";
else
Container.Insert_Space (Container.Last + 1, -Count);
end if;
end Set_Length;
----------
-- Swap --
----------
procedure Swap (Container : in out Vector; I, J : Index_Type) is
begin
if I > Container.Last then
raise Constraint_Error with "I index is out of range";
end if;
if J > Container.Last then
raise Constraint_Error with "J index is out of range";
end if;
if I = J then
return;
end if;
if Container.Lock > 0 then
raise Program_Error with
"attempt to tamper with elements (vector is locked)";
end if;
declare
EI_Copy : constant Element_Type := Container.Elements.EA (I);
begin
Container.Elements.EA (I) := Container.Elements.EA (J);
Container.Elements.EA (J) := EI_Copy;
end;
end Swap;
procedure Swap (Container : in out Vector; I, J : Cursor) is
begin
if I.Container = null then
raise Constraint_Error with "I cursor has no element";
end if;
if J.Container = null then
raise Constraint_Error with "J cursor has no element";
end if;
if I.Container /= Container'Unrestricted_Access then
raise Program_Error with "I cursor denotes wrong container";
end if;
if J.Container /= Container'Unrestricted_Access then
raise Program_Error with "J cursor denotes wrong container";
end if;
Swap (Container, I.Index, J.Index);
end Swap;
---------------
-- To_Cursor --
---------------
function To_Cursor
(Container : Vector;
Index : Extended_Index) return Cursor
is
begin
if Index not in Index_Type'First .. Container.Last then
return No_Element;
else
return (Container'Unchecked_Access, Index);
end if;
end To_Cursor;
--------------
-- To_Index --
--------------
function To_Index (Position : Cursor) return Extended_Index is
begin
if Position.Container = null then
return No_Index;
end if;
if Position.Index <= Position.Container.Last then
return Position.Index;
end if;
return No_Index;
end To_Index;
---------------
-- To_Vector --
---------------
function To_Vector (Length : Count_Type) return Vector is
Index : Count_Type'Base;
Last : Index_Type'Base;
Elements : Elements_Access;
begin
if Length = 0 then
return Empty_Vector;
end if;
-- We create a vector object with a capacity that matches the specified
-- Length, but we do not allow the vector capacity (the length of the
-- internal array) to exceed the number of values in Index_Type'Range
-- (otherwise, there would be no way to refer to those components via an
-- index). We must therefore check whether the specified Length would
-- create a Last index value greater than Index_Type'Last.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
-- We perform a two-part test. First we determine whether the
-- computed Last value lies in the base range of the type, and then
-- determine whether it lies in the range of the index (sub)type.
-- Last must satisfy this relation:
-- First + Length - 1 <= Last
-- We regroup terms:
-- First - 1 <= Last - Length
-- Which can rewrite as:
-- No_Index <= Last - Length
if Index_Type'Base'Last - Index_Type'Base (Length) < No_Index then
raise Constraint_Error with "Length is out of range";
end if;
-- We now know that the computed value of Last is within the base
-- range of the type, so it is safe to compute its value:
Last := No_Index + Index_Type'Base (Length);
-- Finally we test whether the value is within the range of the
-- generic actual index subtype:
if Last > Index_Type'Last then
raise Constraint_Error with "Length is out of range";
end if;
elsif Index_Type'First <= 0 then
-- Here we can compute Last directly, in the normal way. We know that
-- No_Index is less than 0, so there is no danger of overflow when
-- adding the (positive) value of Length.
Index := Count_Type'Base (No_Index) + Length; -- Last
if Index > Count_Type'Base (Index_Type'Last) then
raise Constraint_Error with "Length is out of range";
end if;
-- We know that the computed value (having type Count_Type) of Last
-- is within the range of the generic actual index subtype, so it is
-- safe to convert to Index_Type:
Last := Index_Type'Base (Index);
else
-- Here Index_Type'First (and Index_Type'Last) is positive, so we
-- must test the length indirectly (by working backwards from the
-- largest possible value of Last), in order to prevent overflow.
Index := Count_Type'Base (Index_Type'Last) - Length; -- No_Index
if Index < Count_Type'Base (No_Index) then
raise Constraint_Error with "Length is out of range";
end if;
-- We have determined that the value of Length would not create a
-- Last index value outside of the range of Index_Type, so we can now
-- safely compute its value.
Last := Index_Type'Base (Count_Type'Base (No_Index) + Length);
end if;
Elements := new Elements_Type (Last);
return Vector'(Controlled with Elements, Last, 0, 0);
end To_Vector;
function To_Vector
(New_Item : Element_Type;
Length : Count_Type) return Vector
is
Index : Count_Type'Base;
Last : Index_Type'Base;
Elements : Elements_Access;
begin
if Length = 0 then
return Empty_Vector;
end if;
-- We create a vector object with a capacity that matches the specified
-- Length, but we do not allow the vector capacity (the length of the
-- internal array) to exceed the number of values in Index_Type'Range
-- (otherwise, there would be no way to refer to those components via an
-- index). We must therefore check whether the specified Length would
-- create a Last index value greater than Index_Type'Last.
if Index_Type'Base'Last >= Count_Type'Pos (Count_Type'Last) then
-- We perform a two-part test. First we determine whether the
-- computed Last value lies in the base range of the type, and then
-- determine whether it lies in the range of the index (sub)type.
-- Last must satisfy this relation:
-- First + Length - 1 <= Last
-- We regroup terms:
-- First - 1 <= Last - Length
-- Which can rewrite as:
-- No_Index <= Last - Length
if Index_Type'Base'Last - Index_Type'Base (Length) < No_Index then
raise Constraint_Error with "Length is out of range";
end if;
-- We now know that the computed value of Last is within the base
-- range of the type, so it is safe to compute its value:
Last := No_Index + Index_Type'Base (Length);
-- Finally we test whether the value is within the range of the
-- generic actual index subtype:
if Last > Index_Type'Last then
raise Constraint_Error with "Length is out of range";
end if;
elsif Index_Type'First <= 0 then
-- Here we can compute Last directly, in the normal way. We know that
-- No_Index is less than 0, so there is no danger of overflow when
-- adding the (positive) value of Length.
Index := Count_Type'Base (No_Index) + Length; -- same value as V.Last
if Index > Count_Type'Base (Index_Type'Last) then
raise Constraint_Error with "Length is out of range";
end if;
-- We know that the computed value (having type Count_Type) of Last
-- is within the range of the generic actual index subtype, so it is
-- safe to convert to Index_Type:
Last := Index_Type'Base (Index);
else
-- Here Index_Type'First (and Index_Type'Last) is positive, so we
-- must test the length indirectly (by working backwards from the
-- largest possible value of Last), in order to prevent overflow.
Index := Count_Type'Base (Index_Type'Last) - Length; -- No_Index
if Index < Count_Type'Base (No_Index) then
raise Constraint_Error with "Length is out of range";
end if;
-- We have determined that the value of Length would not create a
-- Last index value outside of the range of Index_Type, so we can now
-- safely compute its value.
Last := Index_Type'Base (Count_Type'Base (No_Index) + Length);
end if;
Elements := new Elements_Type'(Last, EA => (others => New_Item));
return Vector'(Controlled with Elements, Last, 0, 0);
end To_Vector;
--------------------
-- Update_Element --
--------------------
procedure Update_Element
(Container : in out Vector;
Index : Index_Type;
Process : not null access procedure (Element : in out Element_Type))
is
B : Natural renames Container.Busy;
L : Natural renames Container.Lock;
begin
if Index > Container.Last then
raise Constraint_Error with "Index is out of range";
end if;
B := B + 1;
L := L + 1;
begin
Process (Container.Elements.EA (Index));
exception
when others =>
L := L - 1;
B := B - 1;
raise;
end;
L := L - 1;
B := B - 1;
end Update_Element;
procedure Update_Element
(Container : in out Vector;
Position : Cursor;
Process : not null access procedure (Element : in out Element_Type))
is
begin
if Position.Container = null then
raise Constraint_Error with "Position cursor has no element";
end if;
if Position.Container /= Container'Unrestricted_Access then
raise Program_Error with "Position cursor denotes wrong container";
end if;
Update_Element (Container, Position.Index, Process);
end Update_Element;
-----------
-- Write --
-----------
procedure Write
(Stream : not null access Root_Stream_Type'Class;
Container : Vector)
is
begin
Count_Type'Base'Write (Stream, Length (Container));
for J in Index_Type'First .. Container.Last loop
Element_Type'Write (Stream, Container.Elements.EA (J));
end loop;
end Write;
procedure Write
(Stream : not null access Root_Stream_Type'Class;
Position : Cursor)
is
begin
raise Program_Error with "attempt to stream vector cursor";
end Write;
procedure Write
(Stream : not null access Root_Stream_Type'Class;
Item : Reference_Type)
is
begin
raise Program_Error with "attempt to stream reference";
end Write;
procedure Write
(Stream : not null access Root_Stream_Type'Class;
Item : Constant_Reference_Type)
is
begin
raise Program_Error with "attempt to stream reference";
end Write;
end Ada.Containers.Vectors;
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