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diff --git a/gcc/ada/a-cihase.adb b/gcc/ada/a-cihase.adb new file mode 100644 index 00000000000..cc5589f0c1c --- /dev/null +++ b/gcc/ada/a-cihase.adb @@ -0,0 +1,1531 @@ +------------------------------------------------------------------------------ +-- -- +-- GNAT LIBRARY COMPONENTS -- +-- -- +-- ADA.CONTAINERS.INDEFINITE_HASHED_SETS -- +-- -- +-- B o d y -- +-- -- +-- Copyright (C) 2004 Free Software Foundation, Inc. -- +-- -- +-- This specification is derived from the Ada Reference Manual for use with -- +-- GNAT. The copyright notice above, and the license provisions that follow -- +-- apply solely to the contents of the part following the private keyword. -- +-- -- +-- 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 2, 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. See the GNU General Public License -- +-- for more details. You should have received a copy of the GNU General -- +-- Public License distributed with GNAT; see file COPYING. If not, write -- +-- to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, -- +-- MA 02111-1307, USA. -- +-- -- +-- As a special exception, if other files instantiate generics from this -- +-- unit, or you link this unit with other files to produce an executable, -- +-- this unit does not by itself cause the resulting executable to be -- +-- covered by the GNU General Public License. This exception does not -- +-- however invalidate any other reasons why the executable file might be -- +-- covered by the GNU Public License. -- +-- -- +-- This unit has originally being developed by Matthew J Heaney. -- +------------------------------------------------------------------------------ + +with Ada.Unchecked_Deallocation; + +with Ada.Containers.Hash_Tables.Generic_Operations; +pragma Elaborate_All (Ada.Containers.Hash_Tables.Generic_Operations); + +with Ada.Containers.Hash_Tables.Generic_Keys; +pragma Elaborate_All (Ada.Containers.Hash_Tables.Generic_Keys); + +with System; use type System.Address; + +with Ada.Containers.Prime_Numbers; + +with Ada.Finalization; use Ada.Finalization; + +package body Ada.Containers.Indefinite_Hashed_Sets is + + type Element_Access is access Element_Type; + + type Node_Type is + limited record + Element : Element_Access; + Next : Node_Access; + end record; + + function Hash_Node + (Node : Node_Access) return Hash_Type; + pragma Inline (Hash_Node); + + function Hash_Node + (Node : Node_Access) return Hash_Type is + begin + return Hash (Node.Element.all); + end Hash_Node; + + function Next + (Node : Node_Access) return Node_Access; + pragma Inline (Next); + + function Next + (Node : Node_Access) return Node_Access is + begin + return Node.Next; + end Next; + + procedure Set_Next + (Node : Node_Access; + Next : Node_Access); + pragma Inline (Set_Next); + + procedure Set_Next + (Node : Node_Access; + Next : Node_Access) is + begin + Node.Next := Next; + end Set_Next; + + function Equivalent_Keys + (Key : Element_Type; + Node : Node_Access) return Boolean; + pragma Inline (Equivalent_Keys); + + function Equivalent_Keys + (Key : Element_Type; + Node : Node_Access) return Boolean is + begin + return Equivalent_Keys (Key, Node.Element.all); + end Equivalent_Keys; + + function Copy_Node + (Source : Node_Access) return Node_Access; + pragma Inline (Copy_Node); + + function Copy_Node + (Source : Node_Access) return Node_Access is + + Target : constant Node_Access := + new Node_Type'(Element => Source.Element, + Next => null); + begin + return Target; + end Copy_Node; + + + procedure Free_Element is + new Ada.Unchecked_Deallocation (Element_Type, Element_Access); + + procedure Free (X : in out Node_Access); + + procedure Free (X : in out Node_Access) is + procedure Deallocate is + new Ada.Unchecked_Deallocation (Node_Type, Node_Access); + begin + if X /= null then + Free_Element (X.Element); + Deallocate (X); + end if; + end Free; + + package HT_Ops is + new Hash_Tables.Generic_Operations + (HT_Types => HT_Types, + Hash_Table_Type => Set, + Null_Node => null, + Hash_Node => Hash_Node, + Next => Next, + Set_Next => Set_Next, + Copy_Node => Copy_Node, + Free => Free); + + package Element_Keys is + new Hash_Tables.Generic_Keys + (HT_Types => HT_Types, + HT_Type => Set, + Null_Node => null, + Next => Next, + Set_Next => Set_Next, + Key_Type => Element_Type, + Hash => Hash, + Equivalent_Keys => Equivalent_Keys); + + + procedure Adjust (Container : in out Set) renames HT_Ops.Adjust; + + procedure Finalize (Container : in out Set) renames HT_Ops.Finalize; + + + function Find_Equal_Key + (R_Set : Set; + L_Node : Node_Access) return Boolean; + + function Find_Equal_Key + (R_Set : Set; + L_Node : Node_Access) return Boolean is + + R_Index : constant Hash_Type := + Element_Keys.Index (R_Set, L_Node.Element.all); + + R_Node : Node_Access := R_Set.Buckets (R_Index); + + begin + + loop + + if R_Node = null then + return False; + end if; + + if L_Node.Element.all = R_Node.Element.all then + return True; + end if; + + R_Node := Next (R_Node); + + end loop; + + end Find_Equal_Key; + + function Is_Equal is + new HT_Ops.Generic_Equal (Find_Equal_Key); + + function "=" (Left, Right : Set) return Boolean renames Is_Equal; + + + function Length (Container : Set) return Count_Type is + begin + return Container.Length; + end Length; + + + function Is_Empty (Container : Set) return Boolean is + begin + return Container.Length = 0; + end Is_Empty; + + + procedure Clear (Container : in out Set) renames HT_Ops.Clear; + + + function Element (Position : Cursor) return Element_Type is + begin + return Position.Node.Element.all; + end Element; + + + procedure Query_Element + (Position : in Cursor; + Process : not null access procedure (Element : in Element_Type)) is + begin + Process (Position.Node.Element.all); + end Query_Element; + + +-- TODO: +-- procedure Replace_Element (Container : in out Set; +-- Position : in Node_Access; +-- By : in Element_Type); + +-- procedure Replace_Element (Container : in out Set; +-- Position : in Node_Access; +-- By : in Element_Type) is + +-- Node : Node_Access := Position; + +-- begin + +-- if Equivalent_Keys (Node.Element.all, By) then + +-- declare +-- X : Element_Access := Node.Element; +-- begin +-- Node.Element := new Element_Type'(By); +-- -- +-- -- NOTE: If there's an exception here, then just +-- -- let it propagate. We haven't modified the +-- -- state of the container, so there's nothing else +-- -- we need to do. + +-- Free_Element (X); +-- end; + +-- return; + +-- end if; + +-- HT_Ops.Delete_Node_Sans_Free (Container, Node); + +-- begin +-- Free_Element (Node.Element); +-- exception +-- when others => +-- Node.Element := null; -- don't attempt to dealloc X.E again +-- Free (Node); +-- raise; +-- end; + +-- begin +-- Node.Element := new Element_Type'(By); +-- exception +-- when others => +-- Free (Node); +-- raise; +-- end; + +-- declare +-- function New_Node (Next : Node_Access) return Node_Access; +-- pragma Inline (New_Node); + +-- function New_Node (Next : Node_Access) return Node_Access is +-- begin +-- Node.Next := Next; +-- return Node; +-- end New_Node; + +-- procedure Insert is +-- new Element_Keys.Generic_Conditional_Insert (New_Node); + +-- Result : Node_Access; +-- Success : Boolean; +-- begin +-- Insert +-- (HT => Container, +-- Key => Node.Element.all, +-- Node => Result, +-- Success => Success); + +-- if not Success then +-- Free (Node); +-- raise Program_Error; +-- end if; + +-- pragma Assert (Result = Node); +-- end; + +-- end Replace_Element; + + +-- procedure Replace_Element (Container : in out Set; +-- Position : in Cursor; +-- By : in Element_Type) is +-- begin + +-- if Position.Container = null then +-- raise Constraint_Error; +-- end if; + +-- if Position.Container /= Set_Access'(Container'Unchecked_Access) then +-- raise Program_Error; +-- end if; + +-- Replace_Element (Container, Position.Node, By); + +-- end Replace_Element; + + + procedure Move (Target : in out Set; + Source : in out Set) renames HT_Ops.Move; + + + procedure Insert (Container : in out Set; + New_Item : in Element_Type; + Position : out Cursor; + Inserted : out Boolean) is + + function New_Node (Next : Node_Access) return Node_Access; + pragma Inline (New_Node); + + function New_Node (Next : Node_Access) return Node_Access is + Element : Element_Access := new Element_Type'(New_Item); + begin + return new Node_Type'(Element, Next); + exception + when others => + Free_Element (Element); + raise; + end New_Node; + + procedure Insert is + new Element_Keys.Generic_Conditional_Insert (New_Node); + + begin + + HT_Ops.Ensure_Capacity (Container, Container.Length + 1); + Insert (Container, New_Item, Position.Node, Inserted); + Position.Container := Container'Unchecked_Access; + + end Insert; + + + procedure Insert (Container : in out Set; + New_Item : in Element_Type) is + + Position : Cursor; + Inserted : Boolean; + + begin + + Insert (Container, New_Item, Position, Inserted); + + if not Inserted then + raise Constraint_Error; + end if; + + end Insert; + + + procedure Replace (Container : in out Set; + New_Item : in Element_Type) is + + Node : constant Node_Access := + Element_Keys.Find (Container, New_Item); + + X : Element_Access; + + begin + + if Node = null then + raise Constraint_Error; + end if; + + X := Node.Element; + + Node.Element := new Element_Type'(New_Item); + + Free_Element (X); + + end Replace; + + + procedure Include (Container : in out Set; + New_Item : in Element_Type) is + + Position : Cursor; + Inserted : Boolean; + + X : Element_Access; + + begin + + Insert (Container, New_Item, Position, Inserted); + + if not Inserted then + + X := Position.Node.Element; + + Position.Node.Element := new Element_Type'(New_Item); + + Free_Element (X); + + end if; + + end Include; + + + procedure Delete (Container : in out Set; + Item : in Element_Type) is + + X : Node_Access; + + begin + + Element_Keys.Delete_Key_Sans_Free (Container, Item, X); + + if X = null then + raise Constraint_Error; + end if; + + Free (X); + + end Delete; + + + procedure Exclude (Container : in out Set; + Item : in Element_Type) is + + X : Node_Access; + + begin + + Element_Keys.Delete_Key_Sans_Free (Container, Item, X); + Free (X); + + end Exclude; + + + procedure Delete (Container : in out Set; + Position : in out Cursor) is + begin + + if Position = No_Element then + return; + end if; + + if Position.Container /= Set_Access'(Container'Unchecked_Access) then + raise Program_Error; + end if; + + HT_Ops.Delete_Node_Sans_Free (Container, Position.Node); + Free (Position.Node); + + Position.Container := null; + + end Delete; + + + + procedure Union (Target : in out Set; + Source : in Set) is + + procedure Process (Src_Node : in Node_Access); + + procedure Process (Src_Node : in Node_Access) is + + Src : Element_Type renames Src_Node.Element.all; + + function New_Node (Next : Node_Access) return Node_Access; + pragma Inline (New_Node); + + function New_Node (Next : Node_Access) return Node_Access is + Tgt : Element_Access := new Element_Type'(Src); + begin + return new Node_Type'(Tgt, Next); + exception + when others => + Free_Element (Tgt); + raise; + end New_Node; + + procedure Insert is + new Element_Keys.Generic_Conditional_Insert (New_Node); + + Tgt_Node : Node_Access; + Success : Boolean; + + begin + + Insert (Target, Src, Tgt_Node, Success); + + end Process; + + procedure Iterate is + new HT_Ops.Generic_Iteration (Process); + + begin + + if Target'Address = Source'Address then + return; + end if; + + HT_Ops.Ensure_Capacity (Target, Target.Length + Source.Length); + + Iterate (Source); + + end Union; + + + + function Union (Left, Right : Set) return Set is + + Buckets : HT_Types.Buckets_Access; + Length : Count_Type; + + begin + + if Left'Address = Right'Address then + return Left; + end if; + + if Right.Length = 0 then + return Left; + end if; + + if Left.Length = 0 then + return Right; + end if; + + declare + Size : constant Hash_Type := + Prime_Numbers.To_Prime (Left.Length + Right.Length); + begin + Buckets := new Buckets_Type (0 .. Size - 1); + end; + + declare + procedure Process (L_Node : Node_Access); + + procedure Process (L_Node : Node_Access) is + I : constant Hash_Type := + Hash (L_Node.Element.all) mod Buckets'Length; + begin + Buckets (I) := new Node_Type'(L_Node.Element, Buckets (I)); + end Process; + + procedure Iterate is + new HT_Ops.Generic_Iteration (Process); + begin + Iterate (Left); + exception + when others => + HT_Ops.Free_Hash_Table (Buckets); + raise; + end; + + Length := Left.Length; + + declare + procedure Process (Src_Node : Node_Access); + + procedure Process (Src_Node : Node_Access) is + + Src : Element_Type renames Src_Node.Element.all; + + I : constant Hash_Type := + Hash (Src) mod Buckets'Length; + + Tgt_Node : Node_Access := Buckets (I); + + begin + + while Tgt_Node /= null loop + + if Equivalent_Keys (Src, Tgt_Node.Element.all) then + return; + end if; + + Tgt_Node := Next (Tgt_Node); + + end loop; + + declare + Tgt : Element_Access := new Element_Type'(Src); + begin + Buckets (I) := new Node_Type'(Tgt, Buckets (I)); + exception + when others => + Free_Element (Tgt); + raise; + end; + + Length := Length + 1; + + end Process; + + procedure Iterate is + new HT_Ops.Generic_Iteration (Process); + begin + Iterate (Right); + exception + when others => + HT_Ops.Free_Hash_Table (Buckets); + raise; + end; + + return (Controlled with Buckets, Length); + + end Union; + + + function Is_In + (HT : Set; + Key : Node_Access) return Boolean; + pragma Inline (Is_In); + + function Is_In + (HT : Set; + Key : Node_Access) return Boolean is + begin + return Element_Keys.Find (HT, Key.Element.all) /= null; + end Is_In; + + + procedure Intersection (Target : in out Set; + Source : in Set) is + + Tgt_Node : Node_Access; + + begin + + if Target'Address = Source'Address then + return; + end if; + + if Source.Length = 0 then + Clear (Target); + return; + end if; + + -- TODO: optimize this to use an explicit + -- loop instead of an active iterator + -- (similar to how a passive iterator is + -- implemented). + -- + -- Another possibility is to test which + -- set is smaller, and iterate over the + -- smaller set. + + Tgt_Node := HT_Ops.First (Target); + + while Tgt_Node /= null loop + + if Is_In (Source, Tgt_Node) then + + Tgt_Node := HT_Ops.Next (Target, Tgt_Node); + + else + + declare + X : Node_Access := Tgt_Node; + begin + Tgt_Node := HT_Ops.Next (Target, Tgt_Node); + HT_Ops.Delete_Node_Sans_Free (Target, X); + Free (X); + end; + + end if; + + end loop; + + end Intersection; + + + function Intersection (Left, Right : Set) return Set is + + Buckets : HT_Types.Buckets_Access; + Length : Count_Type; + + begin + + if Left'Address = Right'Address then + return Left; + end if; + + Length := Count_Type'Min (Left.Length, Right.Length); + + if Length = 0 then + return Empty_Set; + end if; + + declare + Size : constant Hash_Type := Prime_Numbers.To_Prime (Length); + begin + Buckets := new Buckets_Type (0 .. Size - 1); + end; + + Length := 0; + + declare + procedure Process (L_Node : Node_Access); + + procedure Process (L_Node : Node_Access) is + begin + if Is_In (Right, L_Node) then + + declare + I : constant Hash_Type := + Hash (L_Node.Element.all) mod Buckets'Length; + begin + Buckets (I) := new Node_Type'(L_Node.Element, Buckets (I)); + end; + + Length := Length + 1; + + end if; + end Process; + + procedure Iterate is + new HT_Ops.Generic_Iteration (Process); + begin + Iterate (Left); + exception + when others => + HT_Ops.Free_Hash_Table (Buckets); + raise; + end; + + return (Controlled with Buckets, Length); + + end Intersection; + + + procedure Difference (Target : in out Set; + Source : in Set) is + + + Tgt_Node : Node_Access; + + begin + + if Target'Address = Source'Address then + Clear (Target); + return; + end if; + + if Source.Length = 0 then + return; + end if; + + -- TODO: As I noted above, this can be + -- written in terms of a loop instead as + -- active-iterator style, sort of like a + -- passive iterator. + + Tgt_Node := HT_Ops.First (Target); + + while Tgt_Node /= null loop + + if Is_In (Source, Tgt_Node) then + + declare + X : Node_Access := Tgt_Node; + begin + Tgt_Node := HT_Ops.Next (Target, Tgt_Node); + HT_Ops.Delete_Node_Sans_Free (Target, X); + Free (X); + end; + + else + + Tgt_Node := HT_Ops.Next (Target, Tgt_Node); + + end if; + + end loop; + + end Difference; + + + + function Difference (Left, Right : Set) return Set is + + Buckets : HT_Types.Buckets_Access; + Length : Count_Type; + + begin + + if Left'Address = Right'Address then + return Empty_Set; + end if; + + if Left.Length = 0 then + return Empty_Set; + end if; + + if Right.Length = 0 then + return Left; + end if; + + declare + Size : constant Hash_Type := Prime_Numbers.To_Prime (Left.Length); + begin + Buckets := new Buckets_Type (0 .. Size - 1); + end; + + Length := 0; + + declare + procedure Process (L_Node : Node_Access); + + procedure Process (L_Node : Node_Access) is + begin + if not Is_In (Right, L_Node) then + + declare + I : constant Hash_Type := + Hash (L_Node.Element.all) mod Buckets'Length; + begin + Buckets (I) := new Node_Type'(L_Node.Element, Buckets (I)); + end; + + Length := Length + 1; + + end if; + end Process; + + procedure Iterate is + new HT_Ops.Generic_Iteration (Process); + begin + Iterate (Left); + exception + when others => + HT_Ops.Free_Hash_Table (Buckets); + raise; + end; + + return (Controlled with Buckets, Length); + + end Difference; + + + + procedure Symmetric_Difference (Target : in out Set; + Source : in Set) is + begin + + if Target'Address = Source'Address then + Clear (Target); + return; + end if; + + HT_Ops.Ensure_Capacity (Target, Target.Length + Source.Length); + + if Target.Length = 0 then + + declare + procedure Process (Src_Node : Node_Access); + + procedure Process (Src_Node : Node_Access) is + E : Element_Type renames Src_Node.Element.all; + B : Buckets_Type renames Target.Buckets.all; + I : constant Hash_Type := Hash (E) mod B'Length; + N : Count_Type renames Target.Length; + begin + declare + X : Element_Access := new Element_Type'(E); + begin + B (I) := new Node_Type'(X, B (I)); + exception + when others => + Free_Element (X); + raise; + end; + + N := N + 1; + end Process; + + procedure Iterate is + new HT_Ops.Generic_Iteration (Process); + begin + Iterate (Source); + end; + + else + + declare + procedure Process (Src_Node : Node_Access); + + procedure Process (Src_Node : Node_Access) is + E : Element_Type renames Src_Node.Element.all; + B : Buckets_Type renames Target.Buckets.all; + I : constant Hash_Type := Hash (E) mod B'Length; + N : Count_Type renames Target.Length; + begin + if B (I) = null then + + declare + X : Element_Access := new Element_Type'(E); + begin + B (I) := new Node_Type'(X, null); + exception + when others => + Free_Element (X); + raise; + end; + + N := N + 1; + + elsif Equivalent_Keys (E, B (I).Element.all) then + + declare + X : Node_Access := B (I); + begin + B (I) := B (I).Next; + N := N - 1; + Free (X); + end; + + else + + declare + Prev : Node_Access := B (I); + Curr : Node_Access := Prev.Next; + begin + while Curr /= null loop + if Equivalent_Keys (E, Curr.Element.all) then + Prev.Next := Curr.Next; + N := N - 1; + Free (Curr); + return; + end if; + + Prev := Curr; + Curr := Prev.Next; + end loop; + + declare + X : Element_Access := new Element_Type'(E); + begin + B (I) := new Node_Type'(X, B (I)); + exception + when others => + Free_Element (X); + raise; + end; + + N := N + 1; + end; + + end if; + end Process; + + procedure Iterate is + new HT_Ops.Generic_Iteration (Process); + begin + Iterate (Source); + end; + + end if; + + end Symmetric_Difference; + + + function Symmetric_Difference (Left, Right : Set) return Set is + + Buckets : HT_Types.Buckets_Access; + Length : Count_Type; + + begin + + if Left'Address = Right'Address then + return Empty_Set; + end if; + + if Right.Length = 0 then + return Left; + end if; + + if Left.Length = 0 then + return Right; + end if; + + declare + Size : constant Hash_Type := + Prime_Numbers.To_Prime (Left.Length + Right.Length); + begin + Buckets := new Buckets_Type (0 .. Size - 1); + end; + + Length := 0; + + declare + procedure Process (L_Node : Node_Access); + + procedure Process (L_Node : Node_Access) is + begin + if not Is_In (Right, L_Node) then + declare + E : Element_Type renames L_Node.Element.all; + I : constant Hash_Type := Hash (E) mod Buckets'Length; + begin + + declare + X : Element_Access := new Element_Type'(E); + begin + Buckets (I) := new Node_Type'(X, Buckets (I)); + exception + when others => + Free_Element (X); + raise; + end; + + Length := Length + 1; + end; + end if; + end Process; + + procedure Iterate is + new HT_Ops.Generic_Iteration (Process); + begin + Iterate (Left); + exception + when others => + HT_Ops.Free_Hash_Table (Buckets); + raise; + end; + + declare + procedure Process (R_Node : Node_Access); + + procedure Process (R_Node : Node_Access) is + begin + if not Is_In (Left, R_Node) then + declare + E : Element_Type renames R_Node.Element.all; + I : constant Hash_Type := Hash (E) mod Buckets'Length; + begin + + declare + X : Element_Access := new Element_Type'(E); + begin + Buckets (I) := new Node_Type'(X, Buckets (I)); + exception + when others => + Free_Element (X); + raise; + end; + + Length := Length + 1; + + end; + end if; + end Process; + + procedure Iterate is + new HT_Ops.Generic_Iteration (Process); + begin + Iterate (Right); + exception + when others => + HT_Ops.Free_Hash_Table (Buckets); + raise; + end; + + return (Controlled with Buckets, Length); + + end Symmetric_Difference; + + + function Is_Subset (Subset : Set; + Of_Set : Set) return Boolean is + + Subset_Node : Node_Access; + + begin + + if Subset'Address = Of_Set'Address then + return True; + end if; + + if Subset.Length > Of_Set.Length then + return False; + end if; + + -- TODO: rewrite this to loop in the + -- style of a passive iterator. + + Subset_Node := HT_Ops.First (Subset); + + while Subset_Node /= null loop + if not Is_In (Of_Set, Subset_Node) then + return False; + end if; + + Subset_Node := HT_Ops.Next (Subset, Subset_Node); + end loop; + + return True; + + end Is_Subset; + + + function Overlap (Left, Right : Set) return Boolean is + + Left_Node : Node_Access; + + begin + + if Right.Length = 0 then + return False; + end if; + + if Left'Address = Right'Address then + return True; + end if; + + Left_Node := HT_Ops.First (Left); + + while Left_Node /= null loop + if Is_In (Right, Left_Node) then + return True; + end if; + + Left_Node := HT_Ops.Next (Left, Left_Node); + end loop; + + return False; + + end Overlap; + + + function Find (Container : Set; + Item : Element_Type) return Cursor is + + Node : constant Node_Access := Element_Keys.Find (Container, Item); + + begin + + if Node = null then + return No_Element; + end if; + + return Cursor'(Container'Unchecked_Access, Node); + + end Find; + + + function Contains (Container : Set; + Item : Element_Type) return Boolean is + begin + return Find (Container, Item) /= No_Element; + end Contains; + + + + function First (Container : Set) return Cursor is + Node : constant Node_Access := HT_Ops.First (Container); + begin + if Node = null then + return No_Element; + end if; + + return Cursor'(Container'Unchecked_Access, Node); + end First; + + +-- function First_Element (Container : Set) return Element_Type is +-- Node : constant Node_Access := HT_Ops.First (Container); +-- begin +-- return Node.Element; +-- end First_Element; + + + function Next (Position : Cursor) return Cursor is + begin + if Position.Container = null + or else Position.Node = null + then + return No_Element; + end if; + + declare + S : Set renames Position.Container.all; + Node : constant Node_Access := HT_Ops.Next (S, Position.Node); + begin + if Node = null then + return No_Element; + end if; + + return Cursor'(Position.Container, Node); + end; + end Next; + + + procedure Next (Position : in out Cursor) is + begin + Position := Next (Position); + end Next; + + + function Has_Element (Position : Cursor) return Boolean is + begin + if Position.Container = null then + return False; + end if; + + if Position.Node = null then + return False; + end if; + + return True; + end Has_Element; + + + function Equivalent_Keys (Left, Right : Cursor) + return Boolean is + begin + return Equivalent_Keys (Left.Node.Element.all, Right.Node.Element.all); + end Equivalent_Keys; + + + function Equivalent_Keys (Left : Cursor; + Right : Element_Type) + return Boolean is + begin + return Equivalent_Keys (Left.Node.Element.all, Right); + end Equivalent_Keys; + + + function Equivalent_Keys (Left : Element_Type; + Right : Cursor) + return Boolean is + begin + return Equivalent_Keys (Left, Right.Node.Element.all); + end Equivalent_Keys; + + + procedure Iterate + (Container : in Set; + Process : not null access procedure (Position : in Cursor)) is + + procedure Process_Node (Node : in Node_Access); + pragma Inline (Process_Node); + + procedure Process_Node (Node : in Node_Access) is + begin + Process (Cursor'(Container'Unchecked_Access, Node)); + end Process_Node; + + procedure Iterate is + new HT_Ops.Generic_Iteration (Process_Node); + begin + Iterate (Container); + end Iterate; + + + function Capacity (Container : Set) return Count_Type + renames HT_Ops.Capacity; + + procedure Reserve_Capacity + (Container : in out Set; + Capacity : in Count_Type) + renames HT_Ops.Ensure_Capacity; + + + procedure Write_Node + (Stream : access Root_Stream_Type'Class; + Node : in Node_Access); + pragma Inline (Write_Node); + + procedure Write_Node + (Stream : access Root_Stream_Type'Class; + Node : in Node_Access) is + begin + Element_Type'Output (Stream, Node.Element.all); + end Write_Node; + + procedure Write_Nodes is + new HT_Ops.Generic_Write (Write_Node); + + procedure Write + (Stream : access Root_Stream_Type'Class; + Container : in Set) renames Write_Nodes; + + + function Read_Node (Stream : access Root_Stream_Type'Class) + return Node_Access; + pragma Inline (Read_Node); + + function Read_Node (Stream : access Root_Stream_Type'Class) + return Node_Access is + + X : Element_Access := new Element_Type'(Element_Type'Input (Stream)); + begin + return new Node_Type'(X, null); + exception + when others => + Free_Element (X); + raise; + end Read_Node; + + procedure Read_Nodes is + new HT_Ops.Generic_Read (Read_Node); + + procedure Read + (Stream : access Root_Stream_Type'Class; + Container : out Set) renames Read_Nodes; + + + package body Generic_Keys is + + function Equivalent_Keys (Left : Cursor; + Right : Key_Type) + return Boolean is + begin + return Equivalent_Keys (Right, Left.Node.Element.all); + end Equivalent_Keys; + + function Equivalent_Keys (Left : Key_Type; + Right : Cursor) + return Boolean is + begin + return Equivalent_Keys (Left, Right.Node.Element.all); + end Equivalent_Keys; + + function Equivalent_Keys + (Key : Key_Type; + Node : Node_Access) return Boolean; + pragma Inline (Equivalent_Keys); + + function Equivalent_Keys + (Key : Key_Type; + Node : Node_Access) return Boolean is + begin + return Equivalent_Keys (Key, Node.Element.all); + end Equivalent_Keys; + + package Key_Keys is + new Hash_Tables.Generic_Keys + (HT_Types => HT_Types, + HT_Type => Set, + Null_Node => null, + Next => Next, + Set_Next => Set_Next, + Key_Type => Key_Type, + Hash => Hash, + Equivalent_Keys => Equivalent_Keys); + + + function Find (Container : Set; + Key : Key_Type) + return Cursor is + + Node : constant Node_Access := + Key_Keys.Find (Container, Key); + + begin + + if Node = null then + return No_Element; + end if; + + return Cursor'(Container'Unchecked_Access, Node); + + end Find; + + + function Contains (Container : Set; + Key : Key_Type) return Boolean is + begin + return Find (Container, Key) /= No_Element; + end Contains; + + + function Element (Container : Set; + Key : Key_Type) + return Element_Type is + + Node : constant Node_Access := Key_Keys.Find (Container, Key); + begin + return Node.Element.all; + end Element; + + + function Key (Position : Cursor) return Key_Type is + begin + return Key (Position.Node.Element.all); + end Key; + + +-- TODO: +-- procedure Replace (Container : in out Set; +-- Key : in Key_Type; +-- New_Item : in Element_Type) is + +-- Node : constant Node_Access := +-- Key_Keys.Find (Container, Key); + +-- begin + +-- if Node = null then +-- raise Constraint_Error; +-- end if; + +-- Replace_Element (Container, Node, New_Item); + +-- end Replace; + + + procedure Delete (Container : in out Set; + Key : in Key_Type) is + + X : Node_Access; + + begin + + Key_Keys.Delete_Key_Sans_Free (Container, Key, X); + + if X = null then + raise Constraint_Error; + end if; + + Free (X); + + end Delete; + + + procedure Exclude (Container : in out Set; + Key : in Key_Type) is + + X : Node_Access; + + begin + + Key_Keys.Delete_Key_Sans_Free (Container, Key, X); + Free (X); + + end Exclude; + + + procedure Checked_Update_Element + (Container : in out Set; + Position : in Cursor; + Process : not null access + procedure (Element : in out Element_Type)) is + + begin + + if Position.Container = null then + raise Constraint_Error; + end if; + + if Position.Container /= Set_Access'(Container'Unchecked_Access) then + raise Program_Error; + end if; + + declare + Old_Key : Key_Type renames Key (Position.Node.Element.all); + begin + Process (Position.Node.Element.all); + + if Equivalent_Keys (Old_Key, Position.Node.Element.all) then + return; + end if; + end; + + declare + function New_Node (Next : Node_Access) return Node_Access; + pragma Inline (New_Node); + + function New_Node (Next : Node_Access) return Node_Access is + begin + Position.Node.Next := Next; + return Position.Node; + end New_Node; + + procedure Insert is + new Key_Keys.Generic_Conditional_Insert (New_Node); + + Result : Node_Access; + Success : Boolean; + begin + HT_Ops.Delete_Node_Sans_Free (Container, Position.Node); + + Insert + (HT => Container, + Key => Key (Position.Node.Element.all), + Node => Result, + Success => Success); + + if not Success then + declare + X : Node_Access := Position.Node; + begin + Free (X); + end; + + raise Program_Error; + end if; + + pragma Assert (Result = Position.Node); + end; + + end Checked_Update_Element; + + end Generic_Keys; + +end Ada.Containers.Indefinite_Hashed_Sets; + |