2015-06-23 Paolo Carlini <paolo.carlini@oracle.com>
[official-gcc.git] / gcc / ada / a-ciormu.adb
blob38dd5ae6a40bca5f98efb03920d3b3f595dd4087
1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT LIBRARY COMPONENTS --
4 -- --
5 -- ADA.CONTAINERS.INDEFINITE_ORDERED_MULTISETS --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 2004-2015, Free Software Foundation, Inc. --
10 -- --
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. --
17 -- --
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. --
21 -- --
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/>. --
26 -- --
27 -- This unit was originally developed by Matthew J Heaney. --
28 ------------------------------------------------------------------------------
30 with Ada.Unchecked_Deallocation;
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 System; use type System.Address;
43 package body Ada.Containers.Indefinite_Ordered_Multisets is
45 pragma Annotate (CodePeer, Skip_Analysis);
47 -----------------------------
48 -- Node Access Subprograms --
49 -----------------------------
51 -- These subprograms provide a functional interface to access fields
52 -- of a node, and a procedural interface for modifying these values.
54 function Color (Node : Node_Access) return Color_Type;
55 pragma Inline (Color);
57 function Left (Node : Node_Access) return Node_Access;
58 pragma Inline (Left);
60 function Parent (Node : Node_Access) return Node_Access;
61 pragma Inline (Parent);
63 function Right (Node : Node_Access) return Node_Access;
64 pragma Inline (Right);
66 procedure Set_Parent (Node : Node_Access; Parent : Node_Access);
67 pragma Inline (Set_Parent);
69 procedure Set_Left (Node : Node_Access; Left : Node_Access);
70 pragma Inline (Set_Left);
72 procedure Set_Right (Node : Node_Access; Right : Node_Access);
73 pragma Inline (Set_Right);
75 procedure Set_Color (Node : Node_Access; Color : Color_Type);
76 pragma Inline (Set_Color);
78 -----------------------
79 -- Local Subprograms --
80 -----------------------
82 function Copy_Node (Source : Node_Access) return Node_Access;
83 pragma Inline (Copy_Node);
85 procedure Free (X : in out Node_Access);
87 procedure Insert_Sans_Hint
88 (Tree : in out Tree_Type;
89 New_Item : Element_Type;
90 Node : out Node_Access);
92 procedure Insert_With_Hint
93 (Dst_Tree : in out Tree_Type;
94 Dst_Hint : Node_Access;
95 Src_Node : Node_Access;
96 Dst_Node : out Node_Access);
98 function Is_Equal_Node_Node (L, R : Node_Access) return Boolean;
99 pragma Inline (Is_Equal_Node_Node);
101 function Is_Greater_Element_Node
102 (Left : Element_Type;
103 Right : Node_Access) return Boolean;
104 pragma Inline (Is_Greater_Element_Node);
106 function Is_Less_Element_Node
107 (Left : Element_Type;
108 Right : Node_Access) return Boolean;
109 pragma Inline (Is_Less_Element_Node);
111 function Is_Less_Node_Node (L, R : Node_Access) return Boolean;
112 pragma Inline (Is_Less_Node_Node);
114 procedure Replace_Element
115 (Tree : in out Tree_Type;
116 Node : Node_Access;
117 Item : Element_Type);
119 --------------------------
120 -- Local Instantiations --
121 --------------------------
123 package Tree_Operations is
124 new Red_Black_Trees.Generic_Operations (Tree_Types);
126 procedure Delete_Tree is
127 new Tree_Operations.Generic_Delete_Tree (Free);
129 function Copy_Tree is
130 new Tree_Operations.Generic_Copy_Tree (Copy_Node, Delete_Tree);
132 use Tree_Operations;
134 procedure Free_Element is
135 new Ada.Unchecked_Deallocation (Element_Type, Element_Access);
137 function Is_Equal is
138 new Tree_Operations.Generic_Equal (Is_Equal_Node_Node);
140 package Set_Ops is
141 new Generic_Set_Operations
142 (Tree_Operations => Tree_Operations,
143 Insert_With_Hint => Insert_With_Hint,
144 Copy_Tree => Copy_Tree,
145 Delete_Tree => Delete_Tree,
146 Is_Less => Is_Less_Node_Node,
147 Free => Free);
149 package Element_Keys is
150 new Red_Black_Trees.Generic_Keys
151 (Tree_Operations => Tree_Operations,
152 Key_Type => Element_Type,
153 Is_Less_Key_Node => Is_Less_Element_Node,
154 Is_Greater_Key_Node => Is_Greater_Element_Node);
156 ---------
157 -- "<" --
158 ---------
160 function "<" (Left, Right : Cursor) return Boolean is
161 begin
162 if Left.Node = null then
163 raise Constraint_Error with "Left cursor equals No_Element";
164 end if;
166 if Right.Node = null then
167 raise Constraint_Error with "Right cursor equals No_Element";
168 end if;
170 if Left.Node.Element = null then
171 raise Program_Error with "Left cursor is bad";
172 end if;
174 if Right.Node.Element = null then
175 raise Program_Error with "Right cursor is bad";
176 end if;
178 pragma Assert (Vet (Left.Container.Tree, Left.Node),
179 "bad Left cursor in ""<""");
181 pragma Assert (Vet (Right.Container.Tree, Right.Node),
182 "bad Right cursor in ""<""");
184 return Left.Node.Element.all < Right.Node.Element.all;
185 end "<";
187 function "<" (Left : Cursor; Right : Element_Type) return Boolean is
188 begin
189 if Left.Node = null then
190 raise Constraint_Error with "Left cursor equals No_Element";
191 end if;
193 if Left.Node.Element = null then
194 raise Program_Error with "Left cursor is bad";
195 end if;
197 pragma Assert (Vet (Left.Container.Tree, Left.Node),
198 "bad Left cursor in ""<""");
200 return Left.Node.Element.all < Right;
201 end "<";
203 function "<" (Left : Element_Type; Right : Cursor) return Boolean is
204 begin
205 if Right.Node = null then
206 raise Constraint_Error with "Right cursor equals No_Element";
207 end if;
209 if Right.Node.Element = null then
210 raise Program_Error with "Right cursor is bad";
211 end if;
213 pragma Assert (Vet (Right.Container.Tree, Right.Node),
214 "bad Right cursor in ""<""");
216 return Left < Right.Node.Element.all;
217 end "<";
219 ---------
220 -- "=" --
221 ---------
223 function "=" (Left, Right : Set) return Boolean is
224 begin
225 return Is_Equal (Left.Tree, Right.Tree);
226 end "=";
228 ---------
229 -- ">" --
230 ---------
232 function ">" (Left, Right : Cursor) return Boolean is
233 begin
234 if Left.Node = null then
235 raise Constraint_Error with "Left cursor equals No_Element";
236 end if;
238 if Right.Node = null then
239 raise Constraint_Error with "Right cursor equals No_Element";
240 end if;
242 if Left.Node.Element = null then
243 raise Program_Error with "Left cursor is bad";
244 end if;
246 if Right.Node.Element = null then
247 raise Program_Error with "Right cursor is bad";
248 end if;
250 pragma Assert (Vet (Left.Container.Tree, Left.Node),
251 "bad Left cursor in "">""");
253 pragma Assert (Vet (Right.Container.Tree, Right.Node),
254 "bad Right cursor in "">""");
256 -- L > R same as R < L
258 return Right.Node.Element.all < Left.Node.Element.all;
259 end ">";
261 function ">" (Left : Cursor; Right : Element_Type) return Boolean is
262 begin
263 if Left.Node = null then
264 raise Constraint_Error with "Left cursor equals No_Element";
265 end if;
267 if Left.Node.Element = null then
268 raise Program_Error with "Left cursor is bad";
269 end if;
271 pragma Assert (Vet (Left.Container.Tree, Left.Node),
272 "bad Left cursor in "">""");
274 return Right < Left.Node.Element.all;
275 end ">";
277 function ">" (Left : Element_Type; Right : Cursor) return Boolean is
278 begin
279 if Right.Node = null then
280 raise Constraint_Error with "Right cursor equals No_Element";
281 end if;
283 if Right.Node.Element = null then
284 raise Program_Error with "Right cursor is bad";
285 end if;
287 pragma Assert (Vet (Right.Container.Tree, Right.Node),
288 "bad Right cursor in "">""");
290 return Right.Node.Element.all < Left;
291 end ">";
293 ------------
294 -- Adjust --
295 ------------
297 procedure Adjust is
298 new Tree_Operations.Generic_Adjust (Copy_Tree);
300 procedure Adjust (Container : in out Set) is
301 begin
302 Adjust (Container.Tree);
303 end Adjust;
305 ------------
306 -- Assign --
307 ------------
309 procedure Assign (Target : in out Set; Source : Set) is
310 begin
311 if Target'Address = Source'Address then
312 return;
313 end if;
315 Target.Clear;
316 Target.Union (Source);
317 end Assign;
319 -------------
320 -- Ceiling --
321 -------------
323 function Ceiling (Container : Set; Item : Element_Type) return Cursor is
324 Node : constant Node_Access :=
325 Element_Keys.Ceiling (Container.Tree, Item);
327 begin
328 if Node = null then
329 return No_Element;
330 end if;
332 return Cursor'(Container'Unrestricted_Access, Node);
333 end Ceiling;
335 -----------
336 -- Clear --
337 -----------
339 procedure Clear is
340 new Tree_Operations.Generic_Clear (Delete_Tree);
342 procedure Clear (Container : in out Set) is
343 begin
344 Clear (Container.Tree);
345 end Clear;
347 -----------
348 -- Color --
349 -----------
351 function Color (Node : Node_Access) return Color_Type is
352 begin
353 return Node.Color;
354 end Color;
356 ------------------------
357 -- Constant_Reference --
358 ------------------------
360 function Constant_Reference
361 (Container : aliased Set;
362 Position : Cursor) return Constant_Reference_Type
364 begin
365 if Position.Container = null then
366 raise Constraint_Error with "Position cursor has no element";
367 end if;
369 if Position.Container /= Container'Unrestricted_Access then
370 raise Program_Error with
371 "Position cursor designates wrong container";
372 end if;
374 pragma Assert (Vet (Position.Container.Tree, Position.Node),
375 "bad cursor in Constant_Reference");
377 -- Note: in predefined container units, the creation of a reference
378 -- increments the busy bit of the container, and its finalization
379 -- decrements it. In the absence of control machinery, this tampering
380 -- protection is missing.
382 declare
383 T : Tree_Type renames Container.Tree'Unrestricted_Access.all;
384 pragma Unreferenced (T);
385 begin
386 return R : constant Constant_Reference_Type :=
387 (Element => Position.Node.Element,
388 Control => (Container => Container'Unrestricted_Access))
390 null;
391 end return;
392 end;
393 end Constant_Reference;
395 --------------
396 -- Contains --
397 --------------
399 function Contains (Container : Set; Item : Element_Type) return Boolean is
400 begin
401 return Find (Container, Item) /= No_Element;
402 end Contains;
404 ----------
405 -- Copy --
406 ----------
408 function Copy (Source : Set) return Set is
409 begin
410 return Target : Set do
411 Target.Assign (Source);
412 end return;
413 end Copy;
415 ---------------
416 -- Copy_Node --
417 ---------------
419 function Copy_Node (Source : Node_Access) return Node_Access is
420 X : Element_Access := new Element_Type'(Source.Element.all);
422 begin
423 return new Node_Type'(Parent => null,
424 Left => null,
425 Right => null,
426 Color => Source.Color,
427 Element => X);
429 exception
430 when others =>
431 Free_Element (X);
432 raise;
433 end Copy_Node;
435 ------------
436 -- Delete --
437 ------------
439 procedure Delete (Container : in out Set; Item : Element_Type) is
440 Tree : Tree_Type renames Container.Tree;
441 Node : Node_Access := Element_Keys.Ceiling (Tree, Item);
442 Done : constant Node_Access := Element_Keys.Upper_Bound (Tree, Item);
443 X : Node_Access;
445 begin
446 if Node = Done then
447 raise Constraint_Error with "attempt to delete element not in set";
448 end if;
450 loop
451 X := Node;
452 Node := Tree_Operations.Next (Node);
453 Tree_Operations.Delete_Node_Sans_Free (Tree, X);
454 Free (X);
456 exit when Node = Done;
457 end loop;
458 end Delete;
460 procedure Delete (Container : in out Set; Position : in out Cursor) is
461 begin
462 if Position.Node = null then
463 raise Constraint_Error with "Position cursor equals No_Element";
464 end if;
466 if Position.Node.Element = null then
467 raise Program_Error with "Position cursor is bad";
468 end if;
470 if Position.Container /= Container'Unrestricted_Access then
471 raise Program_Error with "Position cursor designates wrong set";
472 end if;
474 pragma Assert (Vet (Container.Tree, Position.Node),
475 "bad cursor in Delete");
477 Tree_Operations.Delete_Node_Sans_Free (Container.Tree, Position.Node);
478 Free (Position.Node);
480 Position.Container := null;
481 end Delete;
483 ------------------
484 -- Delete_First --
485 ------------------
487 procedure Delete_First (Container : in out Set) is
488 Tree : Tree_Type renames Container.Tree;
489 X : Node_Access := Tree.First;
491 begin
492 if X = null then
493 return;
494 end if;
496 Tree_Operations.Delete_Node_Sans_Free (Tree, X);
497 Free (X);
498 end Delete_First;
500 -----------------
501 -- Delete_Last --
502 -----------------
504 procedure Delete_Last (Container : in out Set) is
505 Tree : Tree_Type renames Container.Tree;
506 X : Node_Access := Tree.Last;
508 begin
509 if X = null then
510 return;
511 end if;
513 Tree_Operations.Delete_Node_Sans_Free (Tree, X);
514 Free (X);
515 end Delete_Last;
517 ----------------
518 -- Difference --
519 ----------------
521 procedure Difference (Target : in out Set; Source : Set) is
522 begin
523 Set_Ops.Difference (Target.Tree, Source.Tree);
524 end Difference;
526 function Difference (Left, Right : Set) return Set is
527 Tree : constant Tree_Type := Set_Ops.Difference (Left.Tree, Right.Tree);
528 begin
529 return Set'(Controlled with Tree);
530 end Difference;
532 -------------
533 -- Element --
534 -------------
536 function Element (Position : Cursor) return Element_Type is
537 begin
538 if Position.Node = null then
539 raise Constraint_Error with "Position cursor equals No_Element";
540 end if;
542 if Position.Node.Element = null then
543 raise Program_Error with "Position cursor is bad";
544 end if;
546 pragma Assert (Vet (Position.Container.Tree, Position.Node),
547 "bad cursor in Element");
549 return Position.Node.Element.all;
550 end Element;
552 -------------------------
553 -- Equivalent_Elements --
554 -------------------------
556 function Equivalent_Elements (Left, Right : Element_Type) return Boolean is
557 begin
558 if Left < Right
559 or else Right < Left
560 then
561 return False;
562 else
563 return True;
564 end if;
565 end Equivalent_Elements;
567 ---------------------
568 -- Equivalent_Sets --
569 ---------------------
571 function Equivalent_Sets (Left, Right : Set) return Boolean is
573 function Is_Equivalent_Node_Node (L, R : Node_Access) return Boolean;
574 pragma Inline (Is_Equivalent_Node_Node);
576 function Is_Equivalent is
577 new Tree_Operations.Generic_Equal (Is_Equivalent_Node_Node);
579 -----------------------------
580 -- Is_Equivalent_Node_Node --
581 -----------------------------
583 function Is_Equivalent_Node_Node (L, R : Node_Access) return Boolean is
584 begin
585 if L.Element.all < R.Element.all then
586 return False;
587 elsif R.Element.all < L.Element.all then
588 return False;
589 else
590 return True;
591 end if;
592 end Is_Equivalent_Node_Node;
594 -- Start of processing for Equivalent_Sets
596 begin
597 return Is_Equivalent (Left.Tree, Right.Tree);
598 end Equivalent_Sets;
600 -------------
601 -- Exclude --
602 -------------
604 procedure Exclude (Container : in out Set; Item : Element_Type) is
605 Tree : Tree_Type renames Container.Tree;
606 Node : Node_Access := Element_Keys.Ceiling (Tree, Item);
607 Done : constant Node_Access := Element_Keys.Upper_Bound (Tree, Item);
608 X : Node_Access;
610 begin
611 while Node /= Done loop
612 X := Node;
613 Node := Tree_Operations.Next (Node);
614 Tree_Operations.Delete_Node_Sans_Free (Tree, X);
615 Free (X);
616 end loop;
617 end Exclude;
619 ----------
620 -- Find --
621 ----------
623 function Find (Container : Set; Item : Element_Type) return Cursor is
624 Node : constant Node_Access := Element_Keys.Find (Container.Tree, Item);
626 begin
627 if Node = null then
628 return No_Element;
629 end if;
631 return Cursor'(Container'Unrestricted_Access, Node);
632 end Find;
634 --------------
635 -- Finalize --
636 --------------
638 procedure Finalize (Object : in out Iterator) is
639 B : Natural renames Object.Container.Tree.Busy;
640 pragma Assert (B > 0);
641 begin
642 B := B - 1;
643 end Finalize;
645 -----------
646 -- First --
647 -----------
649 function First (Container : Set) return Cursor is
650 begin
651 if Container.Tree.First = null then
652 return No_Element;
653 end if;
655 return Cursor'(Container'Unrestricted_Access, Container.Tree.First);
656 end First;
658 function First (Object : Iterator) return Cursor is
659 begin
660 -- The value of the iterator object's Node component influences the
661 -- behavior of the First (and Last) selector function.
663 -- When the Node component is null, this means the iterator object was
664 -- constructed without a start expression, in which case the (forward)
665 -- iteration starts from the (logical) beginning of the entire sequence
666 -- of items (corresponding to Container.First, for a forward iterator).
668 -- Otherwise, this is iteration over a partial sequence of items. When
669 -- the Node component is non-null, the iterator object was constructed
670 -- with a start expression, that specifies the position from which the
671 -- (forward) partial iteration begins.
673 if Object.Node = null then
674 return Object.Container.First;
675 else
676 return Cursor'(Object.Container, Object.Node);
677 end if;
678 end First;
680 -------------------
681 -- First_Element --
682 -------------------
684 function First_Element (Container : Set) return Element_Type is
685 begin
686 if Container.Tree.First = null then
687 raise Constraint_Error with "set is empty";
688 end if;
690 pragma Assert (Container.Tree.First.Element /= null);
691 return Container.Tree.First.Element.all;
692 end First_Element;
694 -----------
695 -- Floor --
696 -----------
698 function Floor (Container : Set; Item : Element_Type) return Cursor is
699 Node : constant Node_Access := Element_Keys.Floor (Container.Tree, Item);
701 begin
702 if Node = null then
703 return No_Element;
704 end if;
706 return Cursor'(Container'Unrestricted_Access, Node);
707 end Floor;
709 ----------
710 -- Free --
711 ----------
713 procedure Free (X : in out Node_Access) is
714 procedure Deallocate is
715 new Ada.Unchecked_Deallocation (Node_Type, Node_Access);
717 begin
718 if X = null then
719 return;
720 end if;
722 X.Parent := X;
723 X.Left := X;
724 X.Right := X;
726 begin
727 Free_Element (X.Element);
728 exception
729 when others =>
730 X.Element := null;
731 Deallocate (X);
732 raise;
733 end;
735 Deallocate (X);
736 end Free;
738 ------------------
739 -- Generic_Keys --
740 ------------------
742 package body Generic_Keys is
744 -----------------------
745 -- Local Subprograms --
746 -----------------------
748 function Is_Less_Key_Node
749 (Left : Key_Type;
750 Right : Node_Access) return Boolean;
751 pragma Inline (Is_Less_Key_Node);
753 function Is_Greater_Key_Node
754 (Left : Key_Type;
755 Right : Node_Access) return Boolean;
756 pragma Inline (Is_Greater_Key_Node);
758 --------------------------
759 -- Local Instantiations --
760 --------------------------
762 package Key_Keys is
763 new Red_Black_Trees.Generic_Keys
764 (Tree_Operations => Tree_Operations,
765 Key_Type => Key_Type,
766 Is_Less_Key_Node => Is_Less_Key_Node,
767 Is_Greater_Key_Node => Is_Greater_Key_Node);
769 -------------
770 -- Ceiling --
771 -------------
773 function Ceiling (Container : Set; Key : Key_Type) return Cursor is
774 Node : constant Node_Access := Key_Keys.Ceiling (Container.Tree, Key);
776 begin
777 if Node = null then
778 return No_Element;
779 end if;
781 return Cursor'(Container'Unrestricted_Access, Node);
782 end Ceiling;
784 --------------
785 -- Contains --
786 --------------
788 function Contains (Container : Set; Key : Key_Type) return Boolean is
789 begin
790 return Find (Container, Key) /= No_Element;
791 end Contains;
793 ------------
794 -- Delete --
795 ------------
797 procedure Delete (Container : in out Set; Key : Key_Type) is
798 Tree : Tree_Type renames Container.Tree;
799 Node : Node_Access := Key_Keys.Ceiling (Tree, Key);
800 Done : constant Node_Access := Key_Keys.Upper_Bound (Tree, Key);
801 X : Node_Access;
803 begin
804 if Node = Done then
805 raise Constraint_Error with "attempt to delete key not in set";
806 end if;
808 loop
809 X := Node;
810 Node := Tree_Operations.Next (Node);
811 Tree_Operations.Delete_Node_Sans_Free (Tree, X);
812 Free (X);
814 exit when Node = Done;
815 end loop;
816 end Delete;
818 -------------
819 -- Element --
820 -------------
822 function Element (Container : Set; Key : Key_Type) return Element_Type is
823 Node : constant Node_Access := Key_Keys.Find (Container.Tree, Key);
825 begin
826 if Node = null then
827 raise Constraint_Error with "key not in set";
828 end if;
830 return Node.Element.all;
831 end Element;
833 ---------------------
834 -- Equivalent_Keys --
835 ---------------------
837 function Equivalent_Keys (Left, Right : Key_Type) return Boolean is
838 begin
839 if Left < Right
840 or else Right < Left
841 then
842 return False;
843 else
844 return True;
845 end if;
846 end Equivalent_Keys;
848 -------------
849 -- Exclude --
850 -------------
852 procedure Exclude (Container : in out Set; Key : Key_Type) is
853 Tree : Tree_Type renames Container.Tree;
854 Node : Node_Access := Key_Keys.Ceiling (Tree, Key);
855 Done : constant Node_Access := Key_Keys.Upper_Bound (Tree, Key);
856 X : Node_Access;
858 begin
859 while Node /= Done loop
860 X := Node;
861 Node := Tree_Operations.Next (Node);
862 Tree_Operations.Delete_Node_Sans_Free (Tree, X);
863 Free (X);
864 end loop;
865 end Exclude;
867 ----------
868 -- Find --
869 ----------
871 function Find (Container : Set; Key : Key_Type) return Cursor is
872 Node : constant Node_Access := Key_Keys.Find (Container.Tree, Key);
874 begin
875 if Node = null then
876 return No_Element;
877 end if;
879 return Cursor'(Container'Unrestricted_Access, Node);
880 end Find;
882 -----------
883 -- Floor --
884 -----------
886 function Floor (Container : Set; Key : Key_Type) return Cursor is
887 Node : constant Node_Access := Key_Keys.Floor (Container.Tree, Key);
889 begin
890 if Node = null then
891 return No_Element;
892 end if;
894 return Cursor'(Container'Unrestricted_Access, Node);
895 end Floor;
897 -------------------------
898 -- Is_Greater_Key_Node --
899 -------------------------
901 function Is_Greater_Key_Node
902 (Left : Key_Type;
903 Right : Node_Access) return Boolean
905 begin
906 return Key (Right.Element.all) < Left;
907 end Is_Greater_Key_Node;
909 ----------------------
910 -- Is_Less_Key_Node --
911 ----------------------
913 function Is_Less_Key_Node
914 (Left : Key_Type;
915 Right : Node_Access) return Boolean
917 begin
918 return Left < Key (Right.Element.all);
919 end Is_Less_Key_Node;
921 -------------
922 -- Iterate --
923 -------------
925 procedure Iterate
926 (Container : Set;
927 Key : Key_Type;
928 Process : not null access procedure (Position : Cursor))
930 procedure Process_Node (Node : Node_Access);
931 pragma Inline (Process_Node);
933 procedure Local_Iterate is
934 new Key_Keys.Generic_Iteration (Process_Node);
936 ------------------
937 -- Process_Node --
938 ------------------
940 procedure Process_Node (Node : Node_Access) is
941 begin
942 Process (Cursor'(Container'Unrestricted_Access, Node));
943 end Process_Node;
945 T : Tree_Type renames Container.Tree'Unrestricted_Access.all;
946 B : Natural renames T.Busy;
948 -- Start of processing for Iterate
950 begin
951 B := B + 1;
953 begin
954 Local_Iterate (T, Key);
955 exception
956 when others =>
957 B := B - 1;
958 raise;
959 end;
961 B := B - 1;
962 end Iterate;
964 ---------
965 -- Key --
966 ---------
968 function Key (Position : Cursor) return Key_Type is
969 begin
970 if Position.Node = null then
971 raise Constraint_Error with
972 "Position cursor equals No_Element";
973 end if;
975 if Position.Node.Element = null then
976 raise Program_Error with
977 "Position cursor is bad";
978 end if;
980 pragma Assert (Vet (Position.Container.Tree, Position.Node),
981 "bad cursor in Key");
983 return Key (Position.Node.Element.all);
984 end Key;
986 ---------------------
987 -- Reverse_Iterate --
988 ---------------------
990 procedure Reverse_Iterate
991 (Container : Set;
992 Key : Key_Type;
993 Process : not null access procedure (Position : Cursor))
995 procedure Process_Node (Node : Node_Access);
996 pragma Inline (Process_Node);
998 -------------
999 -- Iterate --
1000 -------------
1002 procedure Local_Reverse_Iterate is
1003 new Key_Keys.Generic_Reverse_Iteration (Process_Node);
1005 ------------------
1006 -- Process_Node --
1007 ------------------
1009 procedure Process_Node (Node : Node_Access) is
1010 begin
1011 Process (Cursor'(Container'Unrestricted_Access, Node));
1012 end Process_Node;
1014 T : Tree_Type renames Container.Tree'Unrestricted_Access.all;
1015 B : Natural renames T.Busy;
1017 -- Start of processing for Reverse_Iterate
1019 begin
1020 B := B + 1;
1022 begin
1023 Local_Reverse_Iterate (T, Key);
1024 exception
1025 when others =>
1026 B := B - 1;
1027 raise;
1028 end;
1030 B := B - 1;
1031 end Reverse_Iterate;
1033 --------------------
1034 -- Update_Element --
1035 --------------------
1037 procedure Update_Element
1038 (Container : in out Set;
1039 Position : Cursor;
1040 Process : not null access procedure (Element : in out Element_Type))
1042 Tree : Tree_Type renames Container.Tree;
1043 Node : constant Node_Access := Position.Node;
1045 begin
1046 if Node = null then
1047 raise Constraint_Error with "Position cursor equals No_Element";
1048 end if;
1050 if Node.Element = null then
1051 raise Program_Error with "Position cursor is bad";
1052 end if;
1054 if Position.Container /= Container'Unrestricted_Access then
1055 raise Program_Error with "Position cursor designates wrong set";
1056 end if;
1058 pragma Assert (Vet (Tree, Node),
1059 "bad cursor in Update_Element");
1061 declare
1062 E : Element_Type renames Node.Element.all;
1063 K : constant Key_Type := Key (E);
1065 B : Natural renames Tree.Busy;
1066 L : Natural renames Tree.Lock;
1068 begin
1069 B := B + 1;
1070 L := L + 1;
1072 begin
1073 Process (E);
1074 exception
1075 when others =>
1076 L := L - 1;
1077 B := B - 1;
1078 raise;
1079 end;
1081 L := L - 1;
1082 B := B - 1;
1084 if Equivalent_Keys (Left => K, Right => Key (E)) then
1085 return;
1086 end if;
1087 end;
1089 -- Delete_Node checks busy-bit
1091 Tree_Operations.Delete_Node_Sans_Free (Tree, Node);
1093 Insert_New_Item : declare
1094 function New_Node return Node_Access;
1095 pragma Inline (New_Node);
1097 procedure Insert_Post is
1098 new Element_Keys.Generic_Insert_Post (New_Node);
1100 procedure Unconditional_Insert is
1101 new Element_Keys.Generic_Unconditional_Insert (Insert_Post);
1103 --------------
1104 -- New_Node --
1105 --------------
1107 function New_Node return Node_Access is
1108 begin
1109 Node.Color := Red_Black_Trees.Red;
1110 Node.Parent := null;
1111 Node.Left := null;
1112 Node.Right := null;
1114 return Node;
1115 end New_Node;
1117 Result : Node_Access;
1119 -- Start of processing for Insert_New_Item
1121 begin
1122 Unconditional_Insert
1123 (Tree => Tree,
1124 Key => Node.Element.all,
1125 Node => Result);
1127 pragma Assert (Result = Node);
1128 end Insert_New_Item;
1129 end Update_Element;
1131 end Generic_Keys;
1133 -----------------
1134 -- Has_Element --
1135 -----------------
1137 function Has_Element (Position : Cursor) return Boolean is
1138 begin
1139 return Position /= No_Element;
1140 end Has_Element;
1142 ------------
1143 -- Insert --
1144 ------------
1146 procedure Insert (Container : in out Set; New_Item : Element_Type) is
1147 Position : Cursor;
1148 pragma Unreferenced (Position);
1149 begin
1150 Insert (Container, New_Item, Position);
1151 end Insert;
1153 procedure Insert
1154 (Container : in out Set;
1155 New_Item : Element_Type;
1156 Position : out Cursor)
1158 begin
1159 Insert_Sans_Hint (Container.Tree, New_Item, Position.Node);
1160 Position.Container := Container'Unrestricted_Access;
1161 end Insert;
1163 ----------------------
1164 -- Insert_Sans_Hint --
1165 ----------------------
1167 procedure Insert_Sans_Hint
1168 (Tree : in out Tree_Type;
1169 New_Item : Element_Type;
1170 Node : out Node_Access)
1172 function New_Node return Node_Access;
1173 pragma Inline (New_Node);
1175 procedure Insert_Post is
1176 new Element_Keys.Generic_Insert_Post (New_Node);
1178 procedure Unconditional_Insert is
1179 new Element_Keys.Generic_Unconditional_Insert (Insert_Post);
1181 --------------
1182 -- New_Node --
1183 --------------
1185 function New_Node return Node_Access is
1186 -- The element allocator may need an accessibility check in the case
1187 -- the actual type is class-wide or has access discriminants (see
1188 -- RM 4.8(10.1) and AI12-0035).
1190 pragma Unsuppress (Accessibility_Check);
1192 Element : Element_Access := new Element_Type'(New_Item);
1194 begin
1195 return new Node_Type'(Parent => null,
1196 Left => null,
1197 Right => null,
1198 Color => Red_Black_Trees.Red,
1199 Element => Element);
1201 exception
1202 when others =>
1203 Free_Element (Element);
1204 raise;
1205 end New_Node;
1207 -- Start of processing for Insert_Sans_Hint
1209 begin
1210 Unconditional_Insert (Tree, New_Item, Node);
1211 end Insert_Sans_Hint;
1213 ----------------------
1214 -- Insert_With_Hint --
1215 ----------------------
1217 procedure Insert_With_Hint
1218 (Dst_Tree : in out Tree_Type;
1219 Dst_Hint : Node_Access;
1220 Src_Node : Node_Access;
1221 Dst_Node : out Node_Access)
1223 function New_Node return Node_Access;
1224 pragma Inline (New_Node);
1226 procedure Insert_Post is
1227 new Element_Keys.Generic_Insert_Post (New_Node);
1229 procedure Insert_Sans_Hint is
1230 new Element_Keys.Generic_Unconditional_Insert (Insert_Post);
1232 procedure Local_Insert_With_Hint is
1233 new Element_Keys.Generic_Unconditional_Insert_With_Hint
1234 (Insert_Post,
1235 Insert_Sans_Hint);
1237 --------------
1238 -- New_Node --
1239 --------------
1241 function New_Node return Node_Access is
1242 X : Element_Access := new Element_Type'(Src_Node.Element.all);
1244 begin
1245 return new Node_Type'(Parent => null,
1246 Left => null,
1247 Right => null,
1248 Color => Red,
1249 Element => X);
1251 exception
1252 when others =>
1253 Free_Element (X);
1254 raise;
1255 end New_Node;
1257 -- Start of processing for Insert_With_Hint
1259 begin
1260 Local_Insert_With_Hint
1261 (Dst_Tree,
1262 Dst_Hint,
1263 Src_Node.Element.all,
1264 Dst_Node);
1265 end Insert_With_Hint;
1267 ------------------
1268 -- Intersection --
1269 ------------------
1271 procedure Intersection (Target : in out Set; Source : Set) is
1272 begin
1273 Set_Ops.Intersection (Target.Tree, Source.Tree);
1274 end Intersection;
1276 function Intersection (Left, Right : Set) return Set is
1277 Tree : constant Tree_Type :=
1278 Set_Ops.Intersection (Left.Tree, Right.Tree);
1279 begin
1280 return Set'(Controlled with Tree);
1281 end Intersection;
1283 --------------
1284 -- Is_Empty --
1285 --------------
1287 function Is_Empty (Container : Set) return Boolean is
1288 begin
1289 return Container.Tree.Length = 0;
1290 end Is_Empty;
1292 ------------------------
1293 -- Is_Equal_Node_Node --
1294 ------------------------
1296 function Is_Equal_Node_Node (L, R : Node_Access) return Boolean is
1297 begin
1298 return L.Element.all = R.Element.all;
1299 end Is_Equal_Node_Node;
1301 -----------------------------
1302 -- Is_Greater_Element_Node --
1303 -----------------------------
1305 function Is_Greater_Element_Node
1306 (Left : Element_Type;
1307 Right : Node_Access) return Boolean
1309 begin
1310 -- e > node same as node < e
1312 return Right.Element.all < Left;
1313 end Is_Greater_Element_Node;
1315 --------------------------
1316 -- Is_Less_Element_Node --
1317 --------------------------
1319 function Is_Less_Element_Node
1320 (Left : Element_Type;
1321 Right : Node_Access) return Boolean
1323 begin
1324 return Left < Right.Element.all;
1325 end Is_Less_Element_Node;
1327 -----------------------
1328 -- Is_Less_Node_Node --
1329 -----------------------
1331 function Is_Less_Node_Node (L, R : Node_Access) return Boolean is
1332 begin
1333 return L.Element.all < R.Element.all;
1334 end Is_Less_Node_Node;
1336 ---------------
1337 -- Is_Subset --
1338 ---------------
1340 function Is_Subset (Subset : Set; Of_Set : Set) return Boolean is
1341 begin
1342 return Set_Ops.Is_Subset (Subset => Subset.Tree, Of_Set => Of_Set.Tree);
1343 end Is_Subset;
1345 -------------
1346 -- Iterate --
1347 -------------
1349 procedure Iterate
1350 (Container : Set;
1351 Item : Element_Type;
1352 Process : not null access procedure (Position : Cursor))
1354 procedure Process_Node (Node : Node_Access);
1355 pragma Inline (Process_Node);
1357 procedure Local_Iterate is
1358 new Element_Keys.Generic_Iteration (Process_Node);
1360 ------------------
1361 -- Process_Node --
1362 ------------------
1364 procedure Process_Node (Node : Node_Access) is
1365 begin
1366 Process (Cursor'(Container'Unrestricted_Access, Node));
1367 end Process_Node;
1369 T : Tree_Type renames Container.Tree'Unrestricted_Access.all;
1370 B : Natural renames T.Busy;
1372 -- Start of processing for Iterate
1374 begin
1375 B := B + 1;
1377 begin
1378 Local_Iterate (T, Item);
1379 exception
1380 when others =>
1381 B := B - 1;
1382 raise;
1383 end;
1385 B := B - 1;
1386 end Iterate;
1388 procedure Iterate
1389 (Container : Set;
1390 Process : not null access procedure (Position : Cursor))
1392 procedure Process_Node (Node : Node_Access);
1393 pragma Inline (Process_Node);
1395 procedure Local_Iterate is
1396 new Tree_Operations.Generic_Iteration (Process_Node);
1398 ------------------
1399 -- Process_Node --
1400 ------------------
1402 procedure Process_Node (Node : Node_Access) is
1403 begin
1404 Process (Cursor'(Container'Unrestricted_Access, Node));
1405 end Process_Node;
1407 T : Tree_Type renames Container.Tree'Unrestricted_Access.all;
1408 B : Natural renames T.Busy;
1410 -- Start of processing for Iterate
1412 begin
1413 B := B + 1;
1415 begin
1416 Local_Iterate (T);
1417 exception
1418 when others =>
1419 B := B - 1;
1420 raise;
1421 end;
1423 B := B - 1;
1424 end Iterate;
1426 function Iterate (Container : Set)
1427 return Set_Iterator_Interfaces.Reversible_Iterator'Class
1429 S : constant Set_Access := Container'Unrestricted_Access;
1430 B : Natural renames S.Tree.Busy;
1432 begin
1433 -- The value of the Node component influences the behavior of the First
1434 -- and Last selector functions of the iterator object. When the Node
1435 -- component is null (as is the case here), this means the iterator
1436 -- object was constructed without a start expression. This is a complete
1437 -- iterator, meaning that the iteration starts from the (logical)
1438 -- beginning of the sequence of items.
1440 -- Note: For a forward iterator, Container.First is the beginning, and
1441 -- for a reverse iterator, Container.Last is the beginning.
1443 return It : constant Iterator := (Limited_Controlled with S, null) do
1444 B := B + 1;
1445 end return;
1446 end Iterate;
1448 function Iterate (Container : Set; Start : Cursor)
1449 return Set_Iterator_Interfaces.Reversible_Iterator'Class
1451 S : constant Set_Access := Container'Unrestricted_Access;
1452 B : Natural renames S.Tree.Busy;
1454 begin
1455 -- It was formerly the case that when Start = No_Element, the partial
1456 -- iterator was defined to behave the same as for a complete iterator,
1457 -- and iterate over the entire sequence of items. However, those
1458 -- semantics were unintuitive and arguably error-prone (it is too easy
1459 -- to accidentally create an endless loop), and so they were changed,
1460 -- per the ARG meeting in Denver on 2011/11. However, there was no
1461 -- consensus about what positive meaning this corner case should have,
1462 -- and so it was decided to simply raise an exception. This does imply,
1463 -- however, that it is not possible to use a partial iterator to specify
1464 -- an empty sequence of items.
1466 if Start = No_Element then
1467 raise Constraint_Error with
1468 "Start position for iterator equals No_Element";
1469 end if;
1471 if Start.Container /= Container'Unrestricted_Access then
1472 raise Program_Error with
1473 "Start cursor of Iterate designates wrong set";
1474 end if;
1476 pragma Assert (Vet (Container.Tree, Start.Node),
1477 "Start cursor of Iterate is bad");
1479 -- The value of the Node component influences the behavior of the First
1480 -- and Last selector functions of the iterator object. When the Node
1481 -- component is non-null (as is the case here), it means that this is a
1482 -- partial iteration, over a subset of the complete sequence of
1483 -- items. The iterator object was constructed with a start expression,
1484 -- indicating the position from which the iteration begins. Note that
1485 -- the start position has the same value irrespective of whether this is
1486 -- a forward or reverse iteration.
1488 return It : constant Iterator :=
1489 (Limited_Controlled with S, Start.Node)
1491 B := B + 1;
1492 end return;
1493 end Iterate;
1495 ----------
1496 -- Last --
1497 ----------
1499 function Last (Container : Set) return Cursor is
1500 begin
1501 if Container.Tree.Last = null then
1502 return No_Element;
1503 end if;
1505 return Cursor'(Container'Unrestricted_Access, Container.Tree.Last);
1506 end Last;
1508 function Last (Object : Iterator) return Cursor is
1509 begin
1510 -- The value of the iterator object's Node component influences the
1511 -- behavior of the Last (and First) selector function.
1513 -- When the Node component is null, this means the iterator object was
1514 -- constructed without a start expression, in which case the (reverse)
1515 -- iteration starts from the (logical) beginning of the entire sequence
1516 -- (corresponding to Container.Last, for a reverse iterator).
1518 -- Otherwise, this is iteration over a partial sequence of items. When
1519 -- the Node component is non-null, the iterator object was constructed
1520 -- with a start expression, that specifies the position from which the
1521 -- (reverse) partial iteration begins.
1523 if Object.Node = null then
1524 return Object.Container.Last;
1525 else
1526 return Cursor'(Object.Container, Object.Node);
1527 end if;
1528 end Last;
1530 ------------------
1531 -- Last_Element --
1532 ------------------
1534 function Last_Element (Container : Set) return Element_Type is
1535 begin
1536 if Container.Tree.Last = null then
1537 raise Constraint_Error with "set is empty";
1538 end if;
1540 pragma Assert (Container.Tree.Last.Element /= null);
1541 return Container.Tree.Last.Element.all;
1542 end Last_Element;
1544 ----------
1545 -- Left --
1546 ----------
1548 function Left (Node : Node_Access) return Node_Access is
1549 begin
1550 return Node.Left;
1551 end Left;
1553 ------------
1554 -- Length --
1555 ------------
1557 function Length (Container : Set) return Count_Type is
1558 begin
1559 return Container.Tree.Length;
1560 end Length;
1562 ----------
1563 -- Move --
1564 ----------
1566 procedure Move is
1567 new Tree_Operations.Generic_Move (Clear);
1569 procedure Move (Target : in out Set; Source : in out Set) is
1570 begin
1571 Move (Target => Target.Tree, Source => Source.Tree);
1572 end Move;
1574 ----------
1575 -- Next --
1576 ----------
1578 function Next (Position : Cursor) return Cursor is
1579 begin
1580 if Position = No_Element then
1581 return No_Element;
1582 end if;
1584 pragma Assert (Vet (Position.Container.Tree, Position.Node),
1585 "bad cursor in Next");
1587 declare
1588 Node : constant Node_Access :=
1589 Tree_Operations.Next (Position.Node);
1591 begin
1592 if Node = null then
1593 return No_Element;
1594 end if;
1596 return Cursor'(Position.Container, Node);
1597 end;
1598 end Next;
1600 procedure Next (Position : in out Cursor) is
1601 begin
1602 Position := Next (Position);
1603 end Next;
1605 function Next (Object : Iterator; Position : Cursor) return Cursor is
1606 begin
1607 if Position.Container = null then
1608 return No_Element;
1609 end if;
1611 if Position.Container /= Object.Container then
1612 raise Program_Error with
1613 "Position cursor of Next designates wrong set";
1614 end if;
1616 return Next (Position);
1617 end Next;
1619 -------------
1620 -- Overlap --
1621 -------------
1623 function Overlap (Left, Right : Set) return Boolean is
1624 begin
1625 return Set_Ops.Overlap (Left.Tree, Right.Tree);
1626 end Overlap;
1628 ------------
1629 -- Parent --
1630 ------------
1632 function Parent (Node : Node_Access) return Node_Access is
1633 begin
1634 return Node.Parent;
1635 end Parent;
1637 --------------
1638 -- Previous --
1639 --------------
1641 function Previous (Position : Cursor) return Cursor is
1642 begin
1643 if Position = No_Element then
1644 return No_Element;
1645 end if;
1647 pragma Assert (Vet (Position.Container.Tree, Position.Node),
1648 "bad cursor in Previous");
1650 declare
1651 Node : constant Node_Access :=
1652 Tree_Operations.Previous (Position.Node);
1654 begin
1655 if Node = null then
1656 return No_Element;
1657 end if;
1659 return Cursor'(Position.Container, Node);
1660 end;
1661 end Previous;
1663 procedure Previous (Position : in out Cursor) is
1664 begin
1665 Position := Previous (Position);
1666 end Previous;
1668 function Previous (Object : Iterator; Position : Cursor) return Cursor is
1669 begin
1670 if Position.Container = null then
1671 return No_Element;
1672 end if;
1674 if Position.Container /= Object.Container then
1675 raise Program_Error with
1676 "Position cursor of Previous designates wrong set";
1677 end if;
1679 return Previous (Position);
1680 end Previous;
1682 -------------------
1683 -- Query_Element --
1684 -------------------
1686 procedure Query_Element
1687 (Position : Cursor;
1688 Process : not null access procedure (Element : Element_Type))
1690 begin
1691 if Position.Node = null then
1692 raise Constraint_Error with "Position cursor equals No_Element";
1693 end if;
1695 if Position.Node.Element = null then
1696 raise Program_Error with "Position cursor is bad";
1697 end if;
1699 pragma Assert (Vet (Position.Container.Tree, Position.Node),
1700 "bad cursor in Query_Element");
1702 declare
1703 T : Tree_Type renames Position.Container.Tree;
1705 B : Natural renames T.Busy;
1706 L : Natural renames T.Lock;
1708 begin
1709 B := B + 1;
1710 L := L + 1;
1712 begin
1713 Process (Position.Node.Element.all);
1714 exception
1715 when others =>
1716 L := L - 1;
1717 B := B - 1;
1718 raise;
1719 end;
1721 L := L - 1;
1722 B := B - 1;
1723 end;
1724 end Query_Element;
1726 ----------
1727 -- Read --
1728 ----------
1730 procedure Read
1731 (Stream : not null access Root_Stream_Type'Class;
1732 Container : out Set)
1734 function Read_Node
1735 (Stream : not null access Root_Stream_Type'Class) return Node_Access;
1736 pragma Inline (Read_Node);
1738 procedure Read is
1739 new Tree_Operations.Generic_Read (Clear, Read_Node);
1741 ---------------
1742 -- Read_Node --
1743 ---------------
1745 function Read_Node
1746 (Stream : not null access Root_Stream_Type'Class) return Node_Access
1748 Node : Node_Access := new Node_Type;
1749 begin
1750 Node.Element := new Element_Type'(Element_Type'Input (Stream));
1751 return Node;
1752 exception
1753 when others =>
1754 Free (Node); -- Note that Free deallocates elem too
1755 raise;
1756 end Read_Node;
1758 -- Start of processing for Read
1760 begin
1761 Read (Stream, Container.Tree);
1762 end Read;
1764 procedure Read
1765 (Stream : not null access Root_Stream_Type'Class;
1766 Item : out Cursor)
1768 begin
1769 raise Program_Error with "attempt to stream set cursor";
1770 end Read;
1772 procedure Read
1773 (Stream : not null access Root_Stream_Type'Class;
1774 Item : out Constant_Reference_Type)
1776 begin
1777 raise Program_Error with "attempt to stream reference";
1778 end Read;
1780 ---------------------
1781 -- Replace_Element --
1782 ---------------------
1784 procedure Replace_Element
1785 (Tree : in out Tree_Type;
1786 Node : Node_Access;
1787 Item : Element_Type)
1789 begin
1790 if Item < Node.Element.all
1791 or else Node.Element.all < Item
1792 then
1793 null;
1794 else
1795 if Tree.Lock > 0 then
1796 raise Program_Error with
1797 "attempt to tamper with elements (set is locked)";
1798 end if;
1800 declare
1801 X : Element_Access := Node.Element;
1803 -- The element allocator may need an accessibility check in the
1804 -- case the actual type is class-wide or has access discriminants
1805 -- (see RM 4.8(10.1) and AI12-0035).
1807 pragma Unsuppress (Accessibility_Check);
1809 begin
1810 Node.Element := new Element_Type'(Item);
1811 Free_Element (X);
1812 end;
1814 return;
1815 end if;
1817 Tree_Operations.Delete_Node_Sans_Free (Tree, Node); -- Checks busy-bit
1819 Insert_New_Item : declare
1820 function New_Node return Node_Access;
1821 pragma Inline (New_Node);
1823 procedure Insert_Post is
1824 new Element_Keys.Generic_Insert_Post (New_Node);
1826 procedure Unconditional_Insert is
1827 new Element_Keys.Generic_Unconditional_Insert (Insert_Post);
1829 --------------
1830 -- New_Node --
1831 --------------
1833 function New_Node return Node_Access is
1835 -- The element allocator may need an accessibility check in the
1836 -- case the actual type is class-wide or has access discriminants
1837 -- (see RM 4.8(10.1) and AI12-0035).
1839 pragma Unsuppress (Accessibility_Check);
1841 begin
1842 Node.Element := new Element_Type'(Item); -- OK if fails
1843 Node.Color := Red_Black_Trees.Red;
1844 Node.Parent := null;
1845 Node.Left := null;
1846 Node.Right := null;
1848 return Node;
1849 end New_Node;
1851 Result : Node_Access;
1853 X : Element_Access := Node.Element;
1855 -- Start of processing for Insert_New_Item
1857 begin
1858 Unconditional_Insert
1859 (Tree => Tree,
1860 Key => Item,
1861 Node => Result);
1862 pragma Assert (Result = Node);
1864 Free_Element (X); -- OK if fails
1865 end Insert_New_Item;
1866 end Replace_Element;
1868 procedure Replace_Element
1869 (Container : in out Set;
1870 Position : Cursor;
1871 New_Item : Element_Type)
1873 begin
1874 if Position.Node = null then
1875 raise Constraint_Error with "Position cursor equals No_Element";
1876 end if;
1878 if Position.Node.Element = null then
1879 raise Program_Error with "Position cursor is bad";
1880 end if;
1882 if Position.Container /= Container'Unrestricted_Access then
1883 raise Program_Error with "Position cursor designates wrong set";
1884 end if;
1886 pragma Assert (Vet (Container.Tree, Position.Node),
1887 "bad cursor in Replace_Element");
1889 Replace_Element (Container.Tree, Position.Node, New_Item);
1890 end Replace_Element;
1892 ---------------------
1893 -- Reverse_Iterate --
1894 ---------------------
1896 procedure Reverse_Iterate
1897 (Container : Set;
1898 Item : Element_Type;
1899 Process : not null access procedure (Position : Cursor))
1901 procedure Process_Node (Node : Node_Access);
1902 pragma Inline (Process_Node);
1904 procedure Local_Reverse_Iterate is
1905 new Element_Keys.Generic_Reverse_Iteration (Process_Node);
1907 ------------------
1908 -- Process_Node --
1909 ------------------
1911 procedure Process_Node (Node : Node_Access) is
1912 begin
1913 Process (Cursor'(Container'Unrestricted_Access, Node));
1914 end Process_Node;
1916 T : Tree_Type renames Container.Tree'Unrestricted_Access.all;
1917 B : Natural renames T.Busy;
1919 -- Start of processing for Reverse_Iterate
1921 begin
1922 B := B + 1;
1924 begin
1925 Local_Reverse_Iterate (T, Item);
1926 exception
1927 when others =>
1928 B := B - 1;
1929 raise;
1930 end;
1932 B := B - 1;
1933 end Reverse_Iterate;
1935 procedure Reverse_Iterate
1936 (Container : Set;
1937 Process : not null access procedure (Position : Cursor))
1939 procedure Process_Node (Node : Node_Access);
1940 pragma Inline (Process_Node);
1942 procedure Local_Reverse_Iterate is
1943 new Tree_Operations.Generic_Reverse_Iteration (Process_Node);
1945 ------------------
1946 -- Process_Node --
1947 ------------------
1949 procedure Process_Node (Node : Node_Access) is
1950 begin
1951 Process (Cursor'(Container'Unrestricted_Access, Node));
1952 end Process_Node;
1954 T : Tree_Type renames Container.Tree'Unrestricted_Access.all;
1955 B : Natural renames T.Busy;
1957 -- Start of processing for Reverse_Iterate
1959 begin
1960 B := B + 1;
1962 begin
1963 Local_Reverse_Iterate (T);
1964 exception
1965 when others =>
1966 B := B - 1;
1967 raise;
1968 end;
1970 B := B - 1;
1971 end Reverse_Iterate;
1973 -----------
1974 -- Right --
1975 -----------
1977 function Right (Node : Node_Access) return Node_Access is
1978 begin
1979 return Node.Right;
1980 end Right;
1982 ---------------
1983 -- Set_Color --
1984 ---------------
1986 procedure Set_Color (Node : Node_Access; Color : Color_Type) is
1987 begin
1988 Node.Color := Color;
1989 end Set_Color;
1991 --------------
1992 -- Set_Left --
1993 --------------
1995 procedure Set_Left (Node : Node_Access; Left : Node_Access) is
1996 begin
1997 Node.Left := Left;
1998 end Set_Left;
2000 ----------------
2001 -- Set_Parent --
2002 ----------------
2004 procedure Set_Parent (Node : Node_Access; Parent : Node_Access) is
2005 begin
2006 Node.Parent := Parent;
2007 end Set_Parent;
2009 ---------------
2010 -- Set_Right --
2011 ---------------
2013 procedure Set_Right (Node : Node_Access; Right : Node_Access) is
2014 begin
2015 Node.Right := Right;
2016 end Set_Right;
2018 --------------------------
2019 -- Symmetric_Difference --
2020 --------------------------
2022 procedure Symmetric_Difference (Target : in out Set; Source : Set) is
2023 begin
2024 Set_Ops.Symmetric_Difference (Target.Tree, Source.Tree);
2025 end Symmetric_Difference;
2027 function Symmetric_Difference (Left, Right : Set) return Set is
2028 Tree : constant Tree_Type :=
2029 Set_Ops.Symmetric_Difference (Left.Tree, Right.Tree);
2030 begin
2031 return Set'(Controlled with Tree);
2032 end Symmetric_Difference;
2034 ------------
2035 -- To_Set --
2036 ------------
2038 function To_Set (New_Item : Element_Type) return Set is
2039 Tree : Tree_Type;
2040 Node : Node_Access;
2041 pragma Unreferenced (Node);
2042 begin
2043 Insert_Sans_Hint (Tree, New_Item, Node);
2044 return Set'(Controlled with Tree);
2045 end To_Set;
2047 -----------
2048 -- Union --
2049 -----------
2051 procedure Union (Target : in out Set; Source : Set) is
2052 begin
2053 Set_Ops.Union (Target.Tree, Source.Tree);
2054 end Union;
2056 function Union (Left, Right : Set) return Set is
2057 Tree : constant Tree_Type :=
2058 Set_Ops.Union (Left.Tree, Right.Tree);
2059 begin
2060 return Set'(Controlled with Tree);
2061 end Union;
2063 -----------
2064 -- Write --
2065 -----------
2067 procedure Write
2068 (Stream : not null access Root_Stream_Type'Class;
2069 Container : Set)
2071 procedure Write_Node
2072 (Stream : not null access Root_Stream_Type'Class;
2073 Node : Node_Access);
2074 pragma Inline (Write_Node);
2076 procedure Write is
2077 new Tree_Operations.Generic_Write (Write_Node);
2079 ----------------
2080 -- Write_Node --
2081 ----------------
2083 procedure Write_Node
2084 (Stream : not null access Root_Stream_Type'Class;
2085 Node : Node_Access)
2087 begin
2088 Element_Type'Output (Stream, Node.Element.all);
2089 end Write_Node;
2091 -- Start of processing for Write
2093 begin
2094 Write (Stream, Container.Tree);
2095 end Write;
2097 procedure Write
2098 (Stream : not null access Root_Stream_Type'Class;
2099 Item : Cursor)
2101 begin
2102 raise Program_Error with "attempt to stream set cursor";
2103 end Write;
2105 procedure Write
2106 (Stream : not null access Root_Stream_Type'Class;
2107 Item : Constant_Reference_Type)
2109 begin
2110 raise Program_Error with "attempt to stream reference";
2111 end Write;
2112 end Ada.Containers.Indefinite_Ordered_Multisets;