1 ------------------------------------------------------------------------------
3 -- GNAT LIBRARY COMPONENTS --
5 -- ADA.CONTAINERS.INDEFINITE_ORDERED_SETS --
9 -- Copyright (C) 2004-2017, Free Software Foundation, Inc. --
11 -- GNAT is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. --
18 -- As a special exception under Section 7 of GPL version 3, you are granted --
19 -- additional permissions described in the GCC Runtime Library Exception, --
20 -- version 3.1, as published by the Free Software Foundation. --
22 -- You should have received a copy of the GNU General Public License and --
23 -- a copy of the GCC Runtime Library Exception along with this program; --
24 -- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see --
25 -- <http://www.gnu.org/licenses/>. --
27 -- This unit was originally developed by Matthew J Heaney. --
28 ------------------------------------------------------------------------------
30 with Ada
.Containers
.Helpers
; use Ada
.Containers
.Helpers
;
32 with Ada
.Containers
.Red_Black_Trees
.Generic_Operations
;
33 pragma Elaborate_All
(Ada
.Containers
.Red_Black_Trees
.Generic_Operations
);
35 with Ada
.Containers
.Red_Black_Trees
.Generic_Keys
;
36 pragma Elaborate_All
(Ada
.Containers
.Red_Black_Trees
.Generic_Keys
);
38 with Ada
.Containers
.Red_Black_Trees
.Generic_Set_Operations
;
39 pragma Elaborate_All
(Ada
.Containers
.Red_Black_Trees
.Generic_Set_Operations
);
41 with Ada
.Unchecked_Deallocation
;
43 with System
; use type System
.Address
;
45 package body Ada
.Containers
.Indefinite_Ordered_Sets
is
47 pragma Warnings
(Off
, "variable ""Busy*"" is not referenced");
48 pragma Warnings
(Off
, "variable ""Lock*"" is not referenced");
49 -- See comment in Ada.Containers.Helpers
51 -----------------------
52 -- Local Subprograms --
53 -----------------------
55 function Color
(Node
: Node_Access
) return Color_Type
;
56 pragma Inline
(Color
);
58 function Copy_Node
(Source
: Node_Access
) return Node_Access
;
59 pragma Inline
(Copy_Node
);
61 procedure Free
(X
: in out Node_Access
);
63 procedure Insert_Sans_Hint
64 (Tree
: in out Tree_Type
;
65 New_Item
: Element_Type
;
66 Node
: out Node_Access
;
67 Inserted
: out Boolean);
69 procedure Insert_With_Hint
70 (Dst_Tree
: in out Tree_Type
;
71 Dst_Hint
: Node_Access
;
72 Src_Node
: Node_Access
;
73 Dst_Node
: out Node_Access
);
75 function Is_Greater_Element_Node
77 Right
: Node_Access
) return Boolean;
78 pragma Inline
(Is_Greater_Element_Node
);
80 function Is_Less_Element_Node
82 Right
: Node_Access
) return Boolean;
83 pragma Inline
(Is_Less_Element_Node
);
85 function Is_Less_Node_Node
(L
, R
: Node_Access
) return Boolean;
86 pragma Inline
(Is_Less_Node_Node
);
88 function Left
(Node
: Node_Access
) return Node_Access
;
91 function Parent
(Node
: Node_Access
) return Node_Access
;
92 pragma Inline
(Parent
);
94 procedure Replace_Element
95 (Tree
: in out Tree_Type
;
99 function Right
(Node
: Node_Access
) return Node_Access
;
100 pragma Inline
(Right
);
102 procedure Set_Color
(Node
: Node_Access
; Color
: Color_Type
);
103 pragma Inline
(Set_Color
);
105 procedure Set_Left
(Node
: Node_Access
; Left
: Node_Access
);
106 pragma Inline
(Set_Left
);
108 procedure Set_Parent
(Node
: Node_Access
; Parent
: Node_Access
);
109 pragma Inline
(Set_Parent
);
111 procedure Set_Right
(Node
: Node_Access
; Right
: Node_Access
);
112 pragma Inline
(Set_Right
);
114 --------------------------
115 -- Local Instantiations --
116 --------------------------
118 procedure Free_Element
is
119 new Ada
.Unchecked_Deallocation
(Element_Type
, Element_Access
);
121 package Tree_Operations
is
122 new Red_Black_Trees
.Generic_Operations
(Tree_Types
);
124 procedure Delete_Tree
is
125 new Tree_Operations
.Generic_Delete_Tree
(Free
);
127 function Copy_Tree
is
128 new Tree_Operations
.Generic_Copy_Tree
(Copy_Node
, Delete_Tree
);
132 package Element_Keys
is
133 new Red_Black_Trees
.Generic_Keys
134 (Tree_Operations
=> Tree_Operations
,
135 Key_Type
=> Element_Type
,
136 Is_Less_Key_Node
=> Is_Less_Element_Node
,
137 Is_Greater_Key_Node
=> Is_Greater_Element_Node
);
140 new Generic_Set_Operations
141 (Tree_Operations
=> Tree_Operations
,
142 Insert_With_Hint
=> Insert_With_Hint
,
143 Copy_Tree
=> Copy_Tree
,
144 Delete_Tree
=> Delete_Tree
,
145 Is_Less
=> Is_Less_Node_Node
,
152 function "<" (Left
, Right
: Cursor
) return Boolean is
154 if Checks
and then Left
.Node
= null then
155 raise Constraint_Error
with "Left cursor equals No_Element";
158 if Checks
and then Right
.Node
= null then
159 raise Constraint_Error
with "Right cursor equals No_Element";
162 if Checks
and then Left
.Node
.Element
= null then
163 raise Program_Error
with "Left cursor is bad";
166 if Checks
and then Right
.Node
.Element
= null then
167 raise Program_Error
with "Right cursor is bad";
170 pragma Assert
(Vet
(Left
.Container
.Tree
, Left
.Node
),
171 "bad Left cursor in ""<""");
173 pragma Assert
(Vet
(Right
.Container
.Tree
, Right
.Node
),
174 "bad Right cursor in ""<""");
176 return Left
.Node
.Element
.all < Right
.Node
.Element
.all;
179 function "<" (Left
: Cursor
; Right
: Element_Type
) return Boolean is
181 if Checks
and then Left
.Node
= null then
182 raise Constraint_Error
with "Left cursor equals No_Element";
185 if Checks
and then Left
.Node
.Element
= null then
186 raise Program_Error
with "Left cursor is bad";
189 pragma Assert
(Vet
(Left
.Container
.Tree
, Left
.Node
),
190 "bad Left cursor in ""<""");
192 return Left
.Node
.Element
.all < Right
;
195 function "<" (Left
: Element_Type
; Right
: Cursor
) return Boolean is
197 if Checks
and then Right
.Node
= null then
198 raise Constraint_Error
with "Right cursor equals No_Element";
201 if Checks
and then Right
.Node
.Element
= null then
202 raise Program_Error
with "Right cursor is bad";
205 pragma Assert
(Vet
(Right
.Container
.Tree
, Right
.Node
),
206 "bad Right cursor in ""<""");
208 return Left
< Right
.Node
.Element
.all;
215 function "=" (Left
, Right
: Set
) return Boolean is
217 function Is_Equal_Node_Node
(L
, R
: Node_Access
) return Boolean;
218 pragma Inline
(Is_Equal_Node_Node
);
221 new Tree_Operations
.Generic_Equal
(Is_Equal_Node_Node
);
223 ------------------------
224 -- Is_Equal_Node_Node --
225 ------------------------
227 function Is_Equal_Node_Node
(L
, R
: Node_Access
) return Boolean is
229 return L
.Element
.all = R
.Element
.all;
230 end Is_Equal_Node_Node
;
232 -- Start of processing for "="
235 return Is_Equal
(Left
.Tree
, Right
.Tree
);
242 function ">" (Left
, Right
: Cursor
) return Boolean is
244 if Checks
and then Left
.Node
= null then
245 raise Constraint_Error
with "Left cursor equals No_Element";
248 if Checks
and then Right
.Node
= null then
249 raise Constraint_Error
with "Right cursor equals No_Element";
252 if Checks
and then Left
.Node
.Element
= null then
253 raise Program_Error
with "Left cursor is bad";
256 if Checks
and then Right
.Node
.Element
= null then
257 raise Program_Error
with "Right cursor is bad";
260 pragma Assert
(Vet
(Left
.Container
.Tree
, Left
.Node
),
261 "bad Left cursor in "">""");
263 pragma Assert
(Vet
(Right
.Container
.Tree
, Right
.Node
),
264 "bad Right cursor in "">""");
266 -- L > R same as R < L
268 return Right
.Node
.Element
.all < Left
.Node
.Element
.all;
271 function ">" (Left
: Cursor
; Right
: Element_Type
) return Boolean is
273 if Checks
and then Left
.Node
= null then
274 raise Constraint_Error
with "Left cursor equals No_Element";
277 if Checks
and then Left
.Node
.Element
= null then
278 raise Program_Error
with "Left cursor is bad";
281 pragma Assert
(Vet
(Left
.Container
.Tree
, Left
.Node
),
282 "bad Left cursor in "">""");
284 return Right
< Left
.Node
.Element
.all;
287 function ">" (Left
: Element_Type
; Right
: Cursor
) return Boolean is
289 if Checks
and then Right
.Node
= null then
290 raise Constraint_Error
with "Right cursor equals No_Element";
293 if Checks
and then Right
.Node
.Element
= null then
294 raise Program_Error
with "Right cursor is bad";
297 pragma Assert
(Vet
(Right
.Container
.Tree
, Right
.Node
),
298 "bad Right cursor in "">""");
300 return Right
.Node
.Element
.all < Left
;
307 procedure Adjust
is new Tree_Operations
.Generic_Adjust
(Copy_Tree
);
309 procedure Adjust
(Container
: in out Set
) is
311 Adjust
(Container
.Tree
);
318 procedure Assign
(Target
: in out Set
; Source
: Set
) is
320 if Target
'Address = Source
'Address then
325 Target
.Union
(Source
);
332 function Ceiling
(Container
: Set
; Item
: Element_Type
) return Cursor
is
333 Node
: constant Node_Access
:=
334 Element_Keys
.Ceiling
(Container
.Tree
, Item
);
336 return (if Node
= null then No_Element
337 else Cursor
'(Container'Unrestricted_Access, Node));
345 new Tree_Operations.Generic_Clear (Delete_Tree);
347 procedure Clear (Container : in out Set) is
349 Clear (Container.Tree);
356 function Color (Node : Node_Access) return Color_Type is
361 ------------------------
362 -- Constant_Reference --
363 ------------------------
365 function Constant_Reference
366 (Container : aliased Set;
367 Position : Cursor) return Constant_Reference_Type
370 if Checks and then Position.Container = null then
371 raise Constraint_Error with "Position cursor has no element";
374 if Checks and then Position.Container /= Container'Unrestricted_Access
376 raise Program_Error with
377 "Position cursor designates wrong container";
380 if Checks and then Position.Node.Element = null then
381 raise Program_Error with "Node has no element";
385 (Vet (Container.Tree, Position.Node),
386 "bad cursor in Constant_Reference");
389 Tree : Tree_Type renames Position.Container.all.Tree;
390 TC : constant Tamper_Counts_Access :=
391 Tree.TC'Unrestricted_Access;
393 return R : constant Constant_Reference_Type :=
394 (Element => Position.Node.Element.all'Access,
395 Control => (Controlled with TC))
400 end Constant_Reference;
406 function Contains (Container : Set; Item : Element_Type) return Boolean is
408 return Find (Container, Item) /= No_Element;
415 function Copy (Source : Set) return Set is
417 return Target : Set do
418 Target.Assign (Source);
426 function Copy_Node (Source : Node_Access) return Node_Access is
427 Element : Element_Access := new Element_Type'(Source
.Element
.all);
430 return new Node_Type
'(Parent => null,
433 Color => Source.Color,
438 Free_Element (Element);
446 procedure Delete (Container : in out Set; Position : in out Cursor) is
448 if Checks and then Position.Node = null then
449 raise Constraint_Error with "Position cursor equals No_Element";
452 if Checks and then Position.Node.Element = null then
453 raise Program_Error with "Position cursor is bad";
456 if Checks and then Position.Container /= Container'Unrestricted_Access
458 raise Program_Error with "Position cursor designates wrong set";
461 pragma Assert (Vet (Container.Tree, Position.Node),
462 "bad cursor in Delete");
464 Tree_Operations.Delete_Node_Sans_Free (Container.Tree, Position.Node);
465 Free (Position.Node);
466 Position.Container := null;
469 procedure Delete (Container : in out Set; Item : Element_Type) is
470 X : Node_Access := Element_Keys.Find (Container.Tree, Item);
472 if Checks and then X = null then
473 raise Constraint_Error with "attempt to delete element not in set";
476 Tree_Operations.Delete_Node_Sans_Free (Container.Tree, X);
484 procedure Delete_First (Container : in out Set) is
485 Tree : Tree_Type renames Container.Tree;
486 X : Node_Access := Tree.First;
489 Tree_Operations.Delete_Node_Sans_Free (Tree, X);
498 procedure Delete_Last (Container : in out Set) is
499 Tree : Tree_Type renames Container.Tree;
500 X : Node_Access := Tree.Last;
503 Tree_Operations.Delete_Node_Sans_Free (Tree, X);
512 procedure Difference (Target : in out Set; Source : Set) is
514 Set_Ops.Difference (Target.Tree, Source.Tree);
517 function Difference (Left, Right : Set) return Set is
518 Tree : constant Tree_Type := Set_Ops.Difference (Left.Tree, Right.Tree);
520 return Set'(Controlled
with Tree
);
527 function Element
(Position
: Cursor
) return Element_Type
is
529 if Checks
and then Position
.Node
= null then
530 raise Constraint_Error
with "Position cursor equals No_Element";
533 if Checks
and then Position
.Node
.Element
= null then
534 raise Program_Error
with "Position cursor is bad";
537 pragma Assert
(Vet
(Position
.Container
.Tree
, Position
.Node
),
538 "bad cursor in Element");
540 return Position
.Node
.Element
.all;
543 -------------------------
544 -- Equivalent_Elements --
545 -------------------------
547 function Equivalent_Elements
(Left
, Right
: Element_Type
) return Boolean is
549 if Left
< Right
or else Right
< Left
then
554 end Equivalent_Elements
;
556 ---------------------
557 -- Equivalent_Sets --
558 ---------------------
560 function Equivalent_Sets
(Left
, Right
: Set
) return Boolean is
562 function Is_Equivalent_Node_Node
(L
, R
: Node_Access
) return Boolean;
563 pragma Inline
(Is_Equivalent_Node_Node
);
565 function Is_Equivalent
is
566 new Tree_Operations
.Generic_Equal
(Is_Equivalent_Node_Node
);
568 -----------------------------
569 -- Is_Equivalent_Node_Node --
570 -----------------------------
572 function Is_Equivalent_Node_Node
(L
, R
: Node_Access
) return Boolean is
574 if L
.Element
.all < R
.Element
.all then
576 elsif R
.Element
.all < L
.Element
.all then
581 end Is_Equivalent_Node_Node
;
583 -- Start of processing for Equivalent_Sets
586 return Is_Equivalent
(Left
.Tree
, Right
.Tree
);
593 procedure Exclude
(Container
: in out Set
; Item
: Element_Type
) is
594 X
: Node_Access
:= Element_Keys
.Find
(Container
.Tree
, Item
);
597 Tree_Operations
.Delete_Node_Sans_Free
(Container
.Tree
, X
);
606 procedure Finalize
(Object
: in out Iterator
) is
608 if Object
.Container
/= null then
609 Unbusy
(Object
.Container
.Tree
.TC
);
617 function Find
(Container
: Set
; Item
: Element_Type
) return Cursor
is
618 Node
: constant Node_Access
:= Element_Keys
.Find
(Container
.Tree
, Item
);
623 return Cursor
'(Container'Unrestricted_Access, Node);
631 function First (Container : Set) return Cursor is
634 (if Container.Tree.First = null then No_Element
635 else Cursor'(Container
'Unrestricted_Access, Container
.Tree
.First
));
638 function First
(Object
: Iterator
) return Cursor
is
640 -- The value of the iterator object's Node component influences the
641 -- behavior of the First (and Last) selector function.
643 -- When the Node component is null, this means the iterator object was
644 -- constructed without a start expression, in which case the (forward)
645 -- iteration starts from the (logical) beginning of the entire sequence
646 -- of items (corresponding to Container.First, for a forward iterator).
648 -- Otherwise, this is iteration over a partial sequence of items. When
649 -- the Node component is non-null, the iterator object was constructed
650 -- with a start expression, that specifies the position from which the
651 -- (forward) partial iteration begins.
653 if Object
.Node
= null then
654 return Object
.Container
.First
;
656 return Cursor
'(Object.Container, Object.Node);
664 function First_Element (Container : Set) return Element_Type is
666 if Checks and then Container.Tree.First = null then
667 raise Constraint_Error with "set is empty";
670 return Container.Tree.First.Element.all;
677 function Floor (Container : Set; Item : Element_Type) return Cursor is
678 Node : constant Node_Access := Element_Keys.Floor (Container.Tree, Item);
680 return (if Node = null then No_Element
681 else Cursor'(Container
'Unrestricted_Access, Node
));
688 procedure Free
(X
: in out Node_Access
) is
689 procedure Deallocate
is
690 new Ada
.Unchecked_Deallocation
(Node_Type
, Node_Access
);
702 Free_Element
(X
.Element
);
717 package body Generic_Keys
is
719 -----------------------
720 -- Local Subprograms --
721 -----------------------
723 function Is_Greater_Key_Node
725 Right
: Node_Access
) return Boolean;
726 pragma Inline
(Is_Greater_Key_Node
);
728 function Is_Less_Key_Node
730 Right
: Node_Access
) return Boolean;
731 pragma Inline
(Is_Less_Key_Node
);
733 --------------------------
734 -- Local Instantiations --
735 --------------------------
738 new Red_Black_Trees
.Generic_Keys
739 (Tree_Operations
=> Tree_Operations
,
740 Key_Type
=> Key_Type
,
741 Is_Less_Key_Node
=> Is_Less_Key_Node
,
742 Is_Greater_Key_Node
=> Is_Greater_Key_Node
);
748 function Ceiling
(Container
: Set
; Key
: Key_Type
) return Cursor
is
749 Node
: constant Node_Access
:= Key_Keys
.Ceiling
(Container
.Tree
, Key
);
751 return (if Node
= null then No_Element
752 else Cursor
'(Container'Unrestricted_Access, Node));
755 ------------------------
756 -- Constant_Reference --
757 ------------------------
759 function Constant_Reference
760 (Container : aliased Set;
761 Key : Key_Type) return Constant_Reference_Type
763 Node : constant Node_Access := Key_Keys.Find (Container.Tree, Key);
766 if Checks and then Node = null then
767 raise Constraint_Error with "Key not in set";
770 if Checks and then Node.Element = null then
771 raise Program_Error with "Node has no element";
775 Tree : Tree_Type renames Container'Unrestricted_Access.all.Tree;
776 TC : constant Tamper_Counts_Access :=
777 Tree.TC'Unrestricted_Access;
779 return R : constant Constant_Reference_Type :=
780 (Element => Node.Element.all'Access,
781 Control => (Controlled with TC))
786 end Constant_Reference;
792 function Contains (Container : Set; Key : Key_Type) return Boolean is
794 return Find (Container, Key) /= No_Element;
801 procedure Delete (Container : in out Set; Key : Key_Type) is
802 X : Node_Access := Key_Keys.Find (Container.Tree, Key);
805 if Checks and then X = null then
806 raise Constraint_Error with "attempt to delete key not in set";
809 Tree_Operations.Delete_Node_Sans_Free (Container.Tree, X);
817 function Element (Container : Set; Key : Key_Type) return Element_Type is
818 Node : constant Node_Access := Key_Keys.Find (Container.Tree, Key);
820 if Checks and then Node = null then
821 raise Constraint_Error with "key not in set";
824 return Node.Element.all;
827 ---------------------
828 -- Equivalent_Keys --
829 ---------------------
831 function Equivalent_Keys (Left, Right : Key_Type) return Boolean is
833 if Left < Right or else Right < Left then
844 procedure Exclude (Container : in out Set; Key : Key_Type) is
845 X : Node_Access := Key_Keys.Find (Container.Tree, Key);
848 Tree_Operations.Delete_Node_Sans_Free (Container.Tree, X);
857 procedure Finalize (Control : in out Reference_Control_Type) is
859 if Control.Container /= null then
860 Impl.Reference_Control_Type (Control).Finalize;
862 if Checks and then not (Key (Control.Pos) = Control.Old_Key.all)
864 Delete (Control.Container.all, Key (Control.Pos));
868 Control.Container := null;
869 Control.Old_Key := null;
877 function Find (Container : Set; Key : Key_Type) return Cursor is
878 Node : constant Node_Access := Key_Keys.Find (Container.Tree, Key);
880 return (if Node = null then No_Element
881 else Cursor'(Container
'Unrestricted_Access, Node
));
888 function Floor
(Container
: Set
; Key
: Key_Type
) return Cursor
is
889 Node
: constant Node_Access
:= Key_Keys
.Floor
(Container
.Tree
, Key
);
891 return (if Node
= null then No_Element
892 else Cursor
'(Container'Unrestricted_Access, Node));
895 -------------------------
896 -- Is_Greater_Key_Node --
897 -------------------------
899 function Is_Greater_Key_Node
901 Right : Node_Access) return Boolean
904 return Key (Right.Element.all) < Left;
905 end Is_Greater_Key_Node;
907 ----------------------
908 -- Is_Less_Key_Node --
909 ----------------------
911 function Is_Less_Key_Node
913 Right : Node_Access) return Boolean
916 return Left < Key (Right.Element.all);
917 end Is_Less_Key_Node;
923 function Key (Position : Cursor) return Key_Type is
925 if Checks and then Position.Node = null then
926 raise Constraint_Error with
927 "Position cursor equals No_Element";
930 if Checks and then Position.Node.Element = null then
931 raise Program_Error with
932 "Position cursor is bad";
935 pragma Assert (Vet (Position.Container.Tree, Position.Node),
936 "bad cursor in Key");
938 return Key (Position.Node.Element.all);
946 (Container : in out Set;
948 New_Item : Element_Type)
950 Node : constant Node_Access := Key_Keys.Find (Container.Tree, Key);
953 if Checks and then Node = null then
954 raise Constraint_Error with
955 "attempt to replace key not in set";
958 Replace_Element (Container.Tree, Node, New_Item);
966 (Stream : not null access Root_Stream_Type'Class;
967 Item : out Reference_Type)
970 raise Program_Error with "attempt to stream reference";
973 ------------------------------
974 -- Reference_Preserving_Key --
975 ------------------------------
977 function Reference_Preserving_Key
978 (Container : aliased in out Set;
979 Position : Cursor) return Reference_Type
982 if Checks and then Position.Container = null then
983 raise Constraint_Error with "Position cursor has no element";
986 if Checks and then Position.Container /= Container'Unrestricted_Access
988 raise Program_Error with
989 "Position cursor designates wrong container";
992 if Checks and then Position.Node.Element = null then
993 raise Program_Error with "Node has no element";
997 (Vet (Container.Tree, Position.Node),
998 "bad cursor in function Reference_Preserving_Key");
1001 Tree : Tree_Type renames Container.Tree;
1003 return R : constant Reference_Type :=
1004 (Element => Position.Node.Element.all'Unchecked_Access,
1007 Tree.TC'Unrestricted_Access,
1008 Container => Container'Access,
1010 Old_Key => new Key_Type'(Key
(Position
))))
1015 end Reference_Preserving_Key
;
1017 function Reference_Preserving_Key
1018 (Container
: aliased in out Set
;
1019 Key
: Key_Type
) return Reference_Type
1021 Node
: constant Node_Access
:= Key_Keys
.Find
(Container
.Tree
, Key
);
1024 if Checks
and then Node
= null then
1025 raise Constraint_Error
with "Key not in set";
1028 if Checks
and then Node
.Element
= null then
1029 raise Program_Error
with "Node has no element";
1033 Tree
: Tree_Type
renames Container
.Tree
;
1035 return R
: constant Reference_Type
:=
1036 (Element
=> Node
.Element
.all'Unchecked_Access,
1039 Tree
.TC
'Unrestricted_Access,
1040 Container
=> Container
'Access,
1041 Pos
=> Find
(Container
, Key
),
1042 Old_Key
=> new Key_Type
'(Key)))
1047 end Reference_Preserving_Key;
1049 -----------------------------------
1050 -- Update_Element_Preserving_Key --
1051 -----------------------------------
1053 procedure Update_Element_Preserving_Key
1054 (Container : in out Set;
1056 Process : not null access
1057 procedure (Element : in out Element_Type))
1059 Tree : Tree_Type renames Container.Tree;
1062 if Checks and then Position.Node = null then
1063 raise Constraint_Error with "Position cursor equals No_Element";
1066 if Checks and then Position.Node.Element = null then
1067 raise Program_Error with "Position cursor is bad";
1070 if Checks and then Position.Container /= Container'Unrestricted_Access
1072 raise Program_Error with "Position cursor designates wrong set";
1075 pragma Assert (Vet (Container.Tree, Position.Node),
1076 "bad cursor in Update_Element_Preserving_Key");
1079 E : Element_Type renames Position.Node.Element.all;
1080 K : constant Key_Type := Key (E);
1081 Lock : With_Lock (Tree.TC'Unrestricted_Access);
1084 if Equivalent_Keys (K, Key (E)) then
1090 X : Node_Access := Position.Node;
1092 Tree_Operations.Delete_Node_Sans_Free (Tree, X);
1096 raise Program_Error with "key was modified";
1097 end Update_Element_Preserving_Key;
1104 (Stream : not null access Root_Stream_Type'Class;
1105 Item : Reference_Type)
1108 raise Program_Error with "attempt to stream reference";
1113 ------------------------
1114 -- Get_Element_Access --
1115 ------------------------
1117 function Get_Element_Access
1118 (Position : Cursor) return not null Element_Access is
1120 return Position.Node.Element;
1121 end Get_Element_Access;
1127 function Has_Element (Position : Cursor) return Boolean is
1129 return Position /= No_Element;
1136 procedure Include (Container : in out Set; New_Item : Element_Type) is
1143 Insert (Container, New_Item, Position, Inserted);
1145 if not Inserted then
1146 TE_Check (Container.Tree.TC);
1149 -- The element allocator may need an accessibility check in the
1150 -- case the actual type is class-wide or has access discriminants
1151 -- (see RM 4.8(10.1) and AI12-0035).
1153 pragma Unsuppress (Accessibility_Check);
1156 X := Position.Node.Element;
1157 Position.Node.Element := new Element_Type'(New_Item
);
1168 (Container
: in out Set
;
1169 New_Item
: Element_Type
;
1170 Position
: out Cursor
;
1171 Inserted
: out Boolean)
1180 Position
.Container
:= Container
'Unrestricted_Access;
1183 procedure Insert
(Container
: in out Set
; New_Item
: Element_Type
) is
1185 pragma Unreferenced
(Position
);
1190 Insert
(Container
, New_Item
, Position
, Inserted
);
1192 if Checks
and then not Inserted
then
1193 raise Constraint_Error
with
1194 "attempt to insert element already in set";
1198 ----------------------
1199 -- Insert_Sans_Hint --
1200 ----------------------
1202 procedure Insert_Sans_Hint
1203 (Tree
: in out Tree_Type
;
1204 New_Item
: Element_Type
;
1205 Node
: out Node_Access
;
1206 Inserted
: out Boolean)
1208 function New_Node
return Node_Access
;
1209 pragma Inline
(New_Node
);
1211 procedure Insert_Post
is
1212 new Element_Keys
.Generic_Insert_Post
(New_Node
);
1214 procedure Conditional_Insert_Sans_Hint
is
1215 new Element_Keys
.Generic_Conditional_Insert
(Insert_Post
);
1221 function New_Node
return Node_Access
is
1222 -- The element allocator may need an accessibility check in the case
1223 -- the actual type is class-wide or has access discriminants (see
1224 -- RM 4.8(10.1) and AI12-0035).
1226 pragma Unsuppress
(Accessibility_Check
);
1228 Element
: Element_Access
:= new Element_Type
'(New_Item);
1231 return new Node_Type'(Parent
=> null,
1234 Color
=> Red_Black_Trees
.Red
,
1235 Element
=> Element
);
1239 Free_Element
(Element
);
1243 -- Start of processing for Insert_Sans_Hint
1246 Conditional_Insert_Sans_Hint
1251 end Insert_Sans_Hint
;
1253 ----------------------
1254 -- Insert_With_Hint --
1255 ----------------------
1257 procedure Insert_With_Hint
1258 (Dst_Tree
: in out Tree_Type
;
1259 Dst_Hint
: Node_Access
;
1260 Src_Node
: Node_Access
;
1261 Dst_Node
: out Node_Access
)
1264 pragma Unreferenced
(Success
);
1266 function New_Node
return Node_Access
;
1268 procedure Insert_Post
is
1269 new Element_Keys
.Generic_Insert_Post
(New_Node
);
1271 procedure Insert_Sans_Hint
is
1272 new Element_Keys
.Generic_Conditional_Insert
(Insert_Post
);
1274 procedure Insert_With_Hint
is
1275 new Element_Keys
.Generic_Conditional_Insert_With_Hint
1283 function New_Node
return Node_Access
is
1284 Element
: Element_Access
:= new Element_Type
'(Src_Node.Element.all);
1289 Node := new Node_Type;
1292 Free_Element (Element);
1296 Node.Element := Element;
1300 -- Start of processing for Insert_With_Hint
1306 Src_Node.Element.all,
1309 end Insert_With_Hint;
1315 procedure Intersection (Target : in out Set; Source : Set) is
1317 Set_Ops.Intersection (Target.Tree, Source.Tree);
1320 function Intersection (Left, Right : Set) return Set is
1321 Tree : constant Tree_Type :=
1322 Set_Ops.Intersection (Left.Tree, Right.Tree);
1324 return Set'(Controlled
with Tree
);
1331 function Is_Empty
(Container
: Set
) return Boolean is
1333 return Container
.Tree
.Length
= 0;
1336 -----------------------------
1337 -- Is_Greater_Element_Node --
1338 -----------------------------
1340 function Is_Greater_Element_Node
1341 (Left
: Element_Type
;
1342 Right
: Node_Access
) return Boolean
1345 -- e > node same as node < e
1347 return Right
.Element
.all < Left
;
1348 end Is_Greater_Element_Node
;
1350 --------------------------
1351 -- Is_Less_Element_Node --
1352 --------------------------
1354 function Is_Less_Element_Node
1355 (Left
: Element_Type
;
1356 Right
: Node_Access
) return Boolean
1359 return Left
< Right
.Element
.all;
1360 end Is_Less_Element_Node
;
1362 -----------------------
1363 -- Is_Less_Node_Node --
1364 -----------------------
1366 function Is_Less_Node_Node
(L
, R
: Node_Access
) return Boolean is
1368 return L
.Element
.all < R
.Element
.all;
1369 end Is_Less_Node_Node
;
1375 function Is_Subset
(Subset
: Set
; Of_Set
: Set
) return Boolean is
1377 return Set_Ops
.Is_Subset
(Subset
=> Subset
.Tree
, Of_Set
=> Of_Set
.Tree
);
1386 Process
: not null access procedure (Position
: Cursor
))
1388 procedure Process_Node
(Node
: Node_Access
);
1389 pragma Inline
(Process_Node
);
1391 procedure Local_Iterate
is
1392 new Tree_Operations
.Generic_Iteration
(Process_Node
);
1398 procedure Process_Node
(Node
: Node_Access
) is
1400 Process
(Cursor
'(Container'Unrestricted_Access, Node));
1403 T : Tree_Type renames Container'Unrestricted_Access.all.Tree;
1404 Busy : With_Busy (T.TC'Unrestricted_Access);
1406 -- Start of processing for Iterate
1414 return Set_Iterator_Interfaces.Reversible_Iterator'class
1417 -- The value of the Node component influences the behavior of the First
1418 -- and Last selector functions of the iterator object. When the Node
1419 -- component is null (as is the case here), this means the iterator
1420 -- object was constructed without a start expression. This is a complete
1421 -- iterator, meaning that the iteration starts from the (logical)
1422 -- beginning of the sequence of items.
1424 -- Note: For a forward iterator, Container.First is the beginning, and
1425 -- for a reverse iterator, Container.Last is the beginning.
1427 return It : constant Iterator :=
1428 Iterator'(Limited_Controlled
with
1429 Container
=> Container
'Unrestricted_Access,
1432 Busy
(Container
.Tree
.TC
'Unrestricted_Access.all);
1439 return Set_Iterator_Interfaces
.Reversible_Iterator
'class
1442 -- It was formerly the case that when Start = No_Element, the partial
1443 -- iterator was defined to behave the same as for a complete iterator,
1444 -- and iterate over the entire sequence of items. However, those
1445 -- semantics were unintuitive and arguably error-prone (it is too easy
1446 -- to accidentally create an endless loop), and so they were changed,
1447 -- per the ARG meeting in Denver on 2011/11. However, there was no
1448 -- consensus about what positive meaning this corner case should have,
1449 -- and so it was decided to simply raise an exception. This does imply,
1450 -- however, that it is not possible to use a partial iterator to specify
1451 -- an empty sequence of items.
1453 if Checks
and then Start
= No_Element
then
1454 raise Constraint_Error
with
1455 "Start position for iterator equals No_Element";
1458 if Checks
and then Start
.Container
/= Container
'Unrestricted_Access then
1459 raise Program_Error
with
1460 "Start cursor of Iterate designates wrong set";
1463 pragma Assert
(Vet
(Container
.Tree
, Start
.Node
),
1464 "Start cursor of Iterate is bad");
1466 -- The value of the Node component influences the behavior of the First
1467 -- and Last selector functions of the iterator object. When the Node
1468 -- component is non-null (as is the case here), it means that this is a
1469 -- partial iteration, over a subset of the complete sequence of
1470 -- items. The iterator object was constructed with a start expression,
1471 -- indicating the position from which the iteration begins. Note that
1472 -- the start position has the same value irrespective of whether this is
1473 -- a forward or reverse iteration.
1475 return It
: constant Iterator
:=
1476 (Limited_Controlled
with
1477 Container
=> Container
'Unrestricted_Access,
1480 Busy
(Container
.Tree
.TC
'Unrestricted_Access.all);
1488 function Last
(Container
: Set
) return Cursor
is
1491 (if Container
.Tree
.Last
= null then No_Element
1492 else Cursor
'(Container'Unrestricted_Access, Container.Tree.Last));
1495 function Last (Object : Iterator) return Cursor is
1497 -- The value of the iterator object's Node component influences the
1498 -- behavior of the Last (and First) selector function.
1500 -- When the Node component is null, this means the iterator object was
1501 -- constructed without a start expression, in which case the (reverse)
1502 -- iteration starts from the (logical) beginning of the entire sequence
1503 -- (corresponding to Container.Last, for a reverse iterator).
1505 -- Otherwise, this is iteration over a partial sequence of items. When
1506 -- the Node component is non-null, the iterator object was constructed
1507 -- with a start expression, that specifies the position from which the
1508 -- (reverse) partial iteration begins.
1510 if Object.Node = null then
1511 return Object.Container.Last;
1513 return Cursor'(Object
.Container
, Object
.Node
);
1521 function Last_Element
(Container
: Set
) return Element_Type
is
1523 if Checks
and then Container
.Tree
.Last
= null then
1524 raise Constraint_Error
with "set is empty";
1527 return Container
.Tree
.Last
.Element
.all;
1534 function Left
(Node
: Node_Access
) return Node_Access
is
1543 function Length
(Container
: Set
) return Count_Type
is
1545 return Container
.Tree
.Length
;
1552 procedure Move
is new Tree_Operations
.Generic_Move
(Clear
);
1554 procedure Move
(Target
: in out Set
; Source
: in out Set
) is
1556 Move
(Target
=> Target
.Tree
, Source
=> Source
.Tree
);
1563 procedure Next
(Position
: in out Cursor
) is
1565 Position
:= Next
(Position
);
1568 function Next
(Position
: Cursor
) return Cursor
is
1570 if Position
= No_Element
then
1574 if Checks
and then Position
.Node
.Element
= null then
1575 raise Program_Error
with "Position cursor is bad";
1578 pragma Assert
(Vet
(Position
.Container
.Tree
, Position
.Node
),
1579 "bad cursor in Next");
1582 Node
: constant Node_Access
:= Tree_Operations
.Next
(Position
.Node
);
1584 return (if Node
= null then No_Element
1585 else Cursor
'(Position.Container, Node));
1591 Position : Cursor) return Cursor
1594 if Position.Container = null then
1598 if Checks and then Position.Container /= Object.Container then
1599 raise Program_Error with
1600 "Position cursor of Next designates wrong set";
1603 return Next (Position);
1610 function Overlap (Left, Right : Set) return Boolean is
1612 return Set_Ops.Overlap (Left.Tree, Right.Tree);
1619 function Parent (Node : Node_Access) return Node_Access is
1628 procedure Previous (Position : in out Cursor) is
1630 Position := Previous (Position);
1633 function Previous (Position : Cursor) return Cursor is
1635 if Position = No_Element then
1639 if Checks and then Position.Node.Element = null then
1640 raise Program_Error with "Position cursor is bad";
1643 pragma Assert (Vet (Position.Container.Tree, Position.Node),
1644 "bad cursor in Previous");
1647 Node : constant Node_Access :=
1648 Tree_Operations.Previous (Position.Node);
1650 return (if Node = null then No_Element
1651 else Cursor'(Position
.Container
, Node
));
1657 Position
: Cursor
) return Cursor
1660 if Position
.Container
= null then
1664 if Checks
and then Position
.Container
/= Object
.Container
then
1665 raise Program_Error
with
1666 "Position cursor of Previous designates wrong set";
1669 return Previous
(Position
);
1672 ----------------------
1673 -- Pseudo_Reference --
1674 ----------------------
1676 function Pseudo_Reference
1677 (Container
: aliased Set
'Class) return Reference_Control_Type
1679 TC
: constant Tamper_Counts_Access
:=
1680 Container
.Tree
.TC
'Unrestricted_Access;
1682 return R
: constant Reference_Control_Type
:= (Controlled
with TC
) do
1685 end Pseudo_Reference
;
1691 procedure Query_Element
1693 Process
: not null access procedure (Element
: Element_Type
))
1696 if Checks
and then Position
.Node
= null then
1697 raise Constraint_Error
with "Position cursor equals No_Element";
1700 if Checks
and then Position
.Node
.Element
= null then
1701 raise Program_Error
with "Position cursor is bad";
1704 pragma Assert
(Vet
(Position
.Container
.Tree
, Position
.Node
),
1705 "bad cursor in Query_Element");
1708 T
: Tree_Type
renames Position
.Container
.Tree
;
1709 Lock
: With_Lock
(T
.TC
'Unrestricted_Access);
1711 Process
(Position
.Node
.Element
.all);
1720 (Stream
: not null access Root_Stream_Type
'Class;
1721 Container
: out Set
)
1724 (Stream
: not null access Root_Stream_Type
'Class) return Node_Access
;
1725 pragma Inline
(Read_Node
);
1728 new Tree_Operations
.Generic_Read
(Clear
, Read_Node
);
1735 (Stream
: not null access Root_Stream_Type
'Class) return Node_Access
1737 Node
: Node_Access
:= new Node_Type
;
1740 Node
.Element
:= new Element_Type
'(Element_Type'Input (Stream));
1745 Free (Node); -- Note that Free deallocates elem too
1749 -- Start of processing for Read
1752 Read (Stream, Container.Tree);
1756 (Stream : not null access Root_Stream_Type'Class;
1760 raise Program_Error with "attempt to stream set cursor";
1764 (Stream : not null access Root_Stream_Type'Class;
1765 Item : out Constant_Reference_Type)
1768 raise Program_Error with "attempt to stream reference";
1775 procedure Replace (Container : in out Set; New_Item : Element_Type) is
1776 Node : constant Node_Access :=
1777 Element_Keys.Find (Container.Tree, New_Item);
1780 pragma Warnings (Off, X);
1783 if Checks and then Node = null then
1784 raise Constraint_Error with "attempt to replace element not in set";
1787 TE_Check (Container.Tree.TC);
1790 -- The element allocator may need an accessibility check in the case
1791 -- the actual type is class-wide or has access discriminants (see
1792 -- RM 4.8(10.1) and AI12-0035).
1794 pragma Unsuppress (Accessibility_Check);
1798 Node.Element := new Element_Type'(New_Item
);
1803 ---------------------
1804 -- Replace_Element --
1805 ---------------------
1807 procedure Replace_Element
1808 (Tree
: in out Tree_Type
;
1810 Item
: Element_Type
)
1812 pragma Assert
(Node
/= null);
1813 pragma Assert
(Node
.Element
/= null);
1815 function New_Node
return Node_Access
;
1816 pragma Inline
(New_Node
);
1818 procedure Local_Insert_Post
is
1819 new Element_Keys
.Generic_Insert_Post
(New_Node
);
1821 procedure Local_Insert_Sans_Hint
is
1822 new Element_Keys
.Generic_Conditional_Insert
(Local_Insert_Post
);
1824 procedure Local_Insert_With_Hint
is
1825 new Element_Keys
.Generic_Conditional_Insert_With_Hint
1827 Local_Insert_Sans_Hint
);
1833 function New_Node
return Node_Access
is
1835 -- The element allocator may need an accessibility check in the case
1836 -- the actual type is class-wide or has access discriminants (see
1837 -- RM 4.8(10.1) and AI12-0035).
1839 pragma Unsuppress
(Accessibility_Check
);
1842 Node
.Element
:= new Element_Type
'(Item); -- OK if fails
1844 Node.Parent := null;
1851 Result : Node_Access;
1855 X : Element_Access := Node.Element;
1857 -- Start of processing for Replace_Element
1860 -- Replace_Element assigns value Item to the element designated by Node,
1861 -- per certain semantic constraints, described as follows.
1863 -- If Item is equivalent to the element, then element is replaced and
1864 -- there's nothing else to do. This is the easy case.
1866 -- If Item is not equivalent, then the node will (possibly) have to move
1867 -- to some other place in the tree. This is slighly more complicated,
1868 -- because we must ensure that Item is not equivalent to some other
1869 -- element in the tree (in which case, the replacement is not allowed).
1871 -- Determine whether Item is equivalent to element on the specified
1875 Lock : With_Lock (Tree.TC'Unrestricted_Access);
1877 Compare := (if Item < Node.Element.all then False
1878 elsif Node.Element.all < Item then False
1883 -- Item is equivalent to the node's element, so we will not have to
1889 -- The element allocator may need an accessibility check in the
1890 -- case the actual type is class-wide or has access discriminants
1891 -- (see RM 4.8(10.1) and AI12-0035).
1893 pragma Unsuppress (Accessibility_Check);
1896 Node.Element := new Element_Type'(Item
);
1903 -- The replacement Item is not equivalent to the element on the
1904 -- specified node, which means that it will need to be re-inserted in a
1905 -- different position in the tree. We must now determine whether Item is
1906 -- equivalent to some other element in the tree (which would prohibit
1907 -- the assignment and hence the move).
1909 -- Ceiling returns the smallest element equivalent or greater than the
1910 -- specified Item; if there is no such element, then it returns null.
1912 Hint
:= Element_Keys
.Ceiling
(Tree
, Item
);
1914 if Hint
/= null then
1916 Lock
: With_Lock
(Tree
.TC
'Unrestricted_Access);
1918 Compare
:= Item
< Hint
.Element
.all;
1921 -- Item >= Hint.Element
1923 if Checks
and then not Compare
then
1925 -- Ceiling returns an element that is equivalent or greater
1926 -- than Item. If Item is "not less than" the element, then
1927 -- by elimination we know that Item is equivalent to the element.
1929 -- But this means that it is not possible to assign the value of
1930 -- Item to the specified element (on Node), because a different
1931 -- element (on Hint) equivalent to Item already exsits. (Were we
1932 -- to change Node's element value, we would have to move Node, but
1933 -- we would be unable to move the Node, because its new position
1934 -- in the tree is already occupied by an equivalent element.)
1936 raise Program_Error
with "attempt to replace existing element";
1939 -- Item is not equivalent to any other element in the tree, so it is
1940 -- safe to assign the value of Item to Node.Element. This means that
1941 -- the node will have to move to a different position in the tree
1942 -- (because its element will have a different value).
1944 -- The nearest (greater) neighbor of Item is Hint. This will be the
1945 -- insertion position of Node (because its element will have Item as
1948 -- If Node equals Hint, the relative position of Node does not
1949 -- change. This allows us to perform an optimization: we need not
1950 -- remove Node from the tree and then reinsert it with its new value,
1951 -- because it would only be placed in the exact same position.
1957 -- The element allocator may need an accessibility check in the
1958 -- case actual type is class-wide or has access discriminants
1959 -- (see RM 4.8(10.1) and AI12-0035).
1961 pragma Unsuppress
(Accessibility_Check
);
1964 Node
.Element
:= new Element_Type
'(Item);
1972 -- If we get here, it is because Item was greater than all elements in
1973 -- the tree (Hint = null), or because Item was less than some element at
1974 -- a different place in the tree (Item < Hint.Element.all). In either
1975 -- case, we remove Node from the tree (without actually deallocating
1976 -- it), and then insert Item into the tree, onto the same Node (so no
1977 -- new node is actually allocated).
1979 Tree_Operations.Delete_Node_Sans_Free (Tree, Node); -- Checks busy-bit
1981 Local_Insert_With_Hint
1986 Inserted => Inserted);
1988 pragma Assert (Inserted);
1989 pragma Assert (Result = Node);
1992 end Replace_Element;
1994 procedure Replace_Element
1995 (Container : in out Set;
1997 New_Item : Element_Type)
2000 if Checks and then Position.Node = null then
2001 raise Constraint_Error with "Position cursor equals No_Element";
2004 if Checks and then Position.Node.Element = null then
2005 raise Program_Error with "Position cursor is bad";
2008 if Checks and then Position.Container /= Container'Unrestricted_Access
2010 raise Program_Error with "Position cursor designates wrong set";
2013 pragma Assert (Vet (Container.Tree, Position.Node),
2014 "bad cursor in Replace_Element");
2016 Replace_Element (Container.Tree, Position.Node, New_Item);
2017 end Replace_Element;
2019 ---------------------
2020 -- Reverse_Iterate --
2021 ---------------------
2023 procedure Reverse_Iterate
2025 Process : not null access procedure (Position : Cursor))
2027 procedure Process_Node (Node : Node_Access);
2028 pragma Inline (Process_Node);
2030 procedure Local_Reverse_Iterate is
2031 new Tree_Operations.Generic_Reverse_Iteration (Process_Node);
2037 procedure Process_Node (Node : Node_Access) is
2039 Process (Cursor'(Container
'Unrestricted_Access, Node
));
2042 T
: Tree_Type
renames Container
.Tree
'Unrestricted_Access.all;
2043 Busy
: With_Busy
(T
.TC
'Unrestricted_Access);
2045 -- Start of processing for Reverse_Iterate
2048 Local_Reverse_Iterate
(T
);
2049 end Reverse_Iterate
;
2055 function Right
(Node
: Node_Access
) return Node_Access
is
2064 procedure Set_Color
(Node
: Node_Access
; Color
: Color_Type
) is
2066 Node
.Color
:= Color
;
2073 procedure Set_Left
(Node
: Node_Access
; Left
: Node_Access
) is
2082 procedure Set_Parent
(Node
: Node_Access
; Parent
: Node_Access
) is
2084 Node
.Parent
:= Parent
;
2091 procedure Set_Right
(Node
: Node_Access
; Right
: Node_Access
) is
2093 Node
.Right
:= Right
;
2096 --------------------------
2097 -- Symmetric_Difference --
2098 --------------------------
2100 procedure Symmetric_Difference
(Target
: in out Set
; Source
: Set
) is
2102 Set_Ops
.Symmetric_Difference
(Target
.Tree
, Source
.Tree
);
2103 end Symmetric_Difference
;
2105 function Symmetric_Difference
(Left
, Right
: Set
) return Set
is
2106 Tree
: constant Tree_Type
:=
2107 Set_Ops
.Symmetric_Difference
(Left
.Tree
, Right
.Tree
);
2109 return Set
'(Controlled with Tree);
2110 end Symmetric_Difference;
2116 function To_Set (New_Item : Element_Type) return Set is
2120 pragma Unreferenced (Node, Inserted);
2122 Insert_Sans_Hint (Tree, New_Item, Node, Inserted);
2123 return Set'(Controlled
with Tree
);
2130 procedure Union
(Target
: in out Set
; Source
: Set
) is
2132 Set_Ops
.Union
(Target
.Tree
, Source
.Tree
);
2135 function Union
(Left
, Right
: Set
) return Set
is
2136 Tree
: constant Tree_Type
:= Set_Ops
.Union
(Left
.Tree
, Right
.Tree
);
2138 return Set
'(Controlled with Tree);
2146 (Stream : not null access Root_Stream_Type'Class;
2149 procedure Write_Node
2150 (Stream : not null access Root_Stream_Type'Class;
2151 Node : Node_Access);
2152 pragma Inline (Write_Node);
2155 new Tree_Operations.Generic_Write (Write_Node);
2161 procedure Write_Node
2162 (Stream : not null access Root_Stream_Type'Class;
2166 Element_Type'Output (Stream, Node.Element.all);
2169 -- Start of processing for Write
2172 Write (Stream, Container.Tree);
2176 (Stream : not null access Root_Stream_Type'Class;
2180 raise Program_Error with "attempt to stream set cursor";
2184 (Stream : not null access Root_Stream_Type'Class;
2185 Item : Constant_Reference_Type)
2188 raise Program_Error with "attempt to stream reference";
2191 end Ada.Containers.Indefinite_Ordered_Sets;