In gcc/testsuite/: 2010-09-30 Nicola Pero <nicola.pero@meta-innovation.com>
[official-gcc.git] / gcc / ada / a-crdlli.adb
blob137290b11e0885c9d978587031d6357efc113e7f
1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT LIBRARY COMPONENTS --
4 -- --
5 -- ADA.CONTAINERS.RESTRICTED_DOUBLY_LINKED_LISTS --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 2004-2009, 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 System; use type System.Address;
32 package body Ada.Containers.Restricted_Doubly_Linked_Lists is
34 -----------------------
35 -- Local Subprograms --
36 -----------------------
38 procedure Allocate
39 (Container : in out List'Class;
40 New_Item : Element_Type;
41 New_Node : out Count_Type);
43 procedure Free
44 (Container : in out List'Class;
45 X : Count_Type);
47 procedure Insert_Internal
48 (Container : in out List'Class;
49 Before : Count_Type;
50 New_Node : Count_Type);
52 function Vet (Position : Cursor) return Boolean;
54 ---------
55 -- "=" --
56 ---------
58 function "=" (Left, Right : List) return Boolean is
59 LN : Node_Array renames Left.Nodes;
60 RN : Node_Array renames Right.Nodes;
62 LI : Count_Type := Left.First;
63 RI : Count_Type := Right.First;
65 begin
66 if Left'Address = Right'Address then
67 return True;
68 end if;
70 if Left.Length /= Right.Length then
71 return False;
72 end if;
74 for J in 1 .. Left.Length loop
75 if LN (LI).Element /= RN (RI).Element then
76 return False;
77 end if;
79 LI := LN (LI).Next;
80 RI := RN (RI).Next;
81 end loop;
83 return True;
84 end "=";
86 --------------
87 -- Allocate --
88 --------------
90 procedure Allocate
91 (Container : in out List'Class;
92 New_Item : Element_Type;
93 New_Node : out Count_Type)
95 N : Node_Array renames Container.Nodes;
97 begin
98 if Container.Free >= 0 then
99 New_Node := Container.Free;
100 N (New_Node).Element := New_Item;
101 Container.Free := N (New_Node).Next;
103 else
104 New_Node := abs Container.Free;
105 N (New_Node).Element := New_Item;
106 Container.Free := Container.Free - 1;
107 end if;
108 end Allocate;
110 ------------
111 -- Append --
112 ------------
114 procedure Append
115 (Container : in out List;
116 New_Item : Element_Type;
117 Count : Count_Type := 1)
119 begin
120 Insert (Container, No_Element, New_Item, Count);
121 end Append;
123 ------------
124 -- Assign --
125 ------------
127 procedure Assign (Target : in out List; Source : List) is
128 begin
129 if Target'Address = Source'Address then
130 return;
131 end if;
133 if Target.Capacity < Source.Length then
134 raise Constraint_Error; -- ???
135 end if;
137 Clear (Target);
139 declare
140 N : Node_Array renames Source.Nodes;
141 J : Count_Type := Source.First;
143 begin
144 while J /= 0 loop
145 Append (Target, N (J).Element);
146 J := N (J).Next;
147 end loop;
148 end;
149 end Assign;
151 -----------
152 -- Clear --
153 -----------
155 procedure Clear (Container : in out List) is
156 N : Node_Array renames Container.Nodes;
157 X : Count_Type;
159 begin
160 if Container.Length = 0 then
161 pragma Assert (Container.First = 0);
162 pragma Assert (Container.Last = 0);
163 -- pragma Assert (Container.Busy = 0);
164 -- pragma Assert (Container.Lock = 0);
165 return;
166 end if;
168 pragma Assert (Container.First >= 1);
169 pragma Assert (Container.Last >= 1);
170 pragma Assert (N (Container.First).Prev = 0);
171 pragma Assert (N (Container.Last).Next = 0);
173 -- if Container.Busy > 0 then
174 -- raise Program_Error;
175 -- end if;
177 while Container.Length > 1 loop
178 X := Container.First;
180 Container.First := N (X).Next;
181 N (Container.First).Prev := 0;
183 Container.Length := Container.Length - 1;
185 Free (Container, X);
186 end loop;
188 X := Container.First;
190 Container.First := 0;
191 Container.Last := 0;
192 Container.Length := 0;
194 Free (Container, X);
195 end Clear;
197 --------------
198 -- Contains --
199 --------------
201 function Contains
202 (Container : List;
203 Item : Element_Type) return Boolean
205 begin
206 return Find (Container, Item) /= No_Element;
207 end Contains;
209 ------------
210 -- Delete --
211 ------------
213 procedure Delete
214 (Container : in out List;
215 Position : in out Cursor;
216 Count : Count_Type := 1)
218 N : Node_Array renames Container.Nodes;
219 X : Count_Type;
221 begin
222 if Position.Node = 0 then
223 raise Constraint_Error;
224 end if;
226 if Position.Container /= Container'Unrestricted_Access then
227 raise Program_Error;
228 end if;
230 pragma Assert (Vet (Position), "bad cursor in Delete");
232 if Position.Node = Container.First then
233 Delete_First (Container, Count);
234 Position := No_Element;
235 return;
236 end if;
238 if Count = 0 then
239 Position := No_Element;
240 return;
241 end if;
243 -- if Container.Busy > 0 then
244 -- raise Program_Error;
245 -- end if;
247 pragma Assert (Container.First >= 1);
248 pragma Assert (Container.Last >= 1);
249 pragma Assert (N (Container.First).Prev = 0);
250 pragma Assert (N (Container.Last).Next = 0);
252 for Index in 1 .. Count loop
253 pragma Assert (Container.Length >= 2);
255 X := Position.Node;
256 Container.Length := Container.Length - 1;
258 if X = Container.Last then
259 Position := No_Element;
261 Container.Last := N (X).Prev;
262 N (Container.Last).Next := 0;
264 Free (Container, X);
265 return;
266 end if;
268 Position.Node := N (X).Next;
270 N (N (X).Next).Prev := N (X).Prev;
271 N (N (X).Prev).Next := N (X).Next;
273 Free (Container, X);
274 end loop;
276 Position := No_Element;
277 end Delete;
279 ------------------
280 -- Delete_First --
281 ------------------
283 procedure Delete_First
284 (Container : in out List;
285 Count : Count_Type := 1)
287 N : Node_Array renames Container.Nodes;
288 X : Count_Type;
290 begin
291 if Count >= Container.Length then
292 Clear (Container);
293 return;
294 end if;
296 if Count = 0 then
297 return;
298 end if;
300 -- if Container.Busy > 0 then
301 -- raise Program_Error;
302 -- end if;
304 for I in 1 .. Count loop
305 X := Container.First;
306 pragma Assert (N (N (X).Next).Prev = Container.First);
308 Container.First := N (X).Next;
309 N (Container.First).Prev := 0;
311 Container.Length := Container.Length - 1;
313 Free (Container, X);
314 end loop;
315 end Delete_First;
317 -----------------
318 -- Delete_Last --
319 -----------------
321 procedure Delete_Last
322 (Container : in out List;
323 Count : Count_Type := 1)
325 N : Node_Array renames Container.Nodes;
326 X : Count_Type;
328 begin
329 if Count >= Container.Length then
330 Clear (Container);
331 return;
332 end if;
334 if Count = 0 then
335 return;
336 end if;
338 -- if Container.Busy > 0 then
339 -- raise Program_Error;
340 -- end if;
342 for I in 1 .. Count loop
343 X := Container.Last;
344 pragma Assert (N (N (X).Prev).Next = Container.Last);
346 Container.Last := N (X).Prev;
347 N (Container.Last).Next := 0;
349 Container.Length := Container.Length - 1;
351 Free (Container, X);
352 end loop;
353 end Delete_Last;
355 -------------
356 -- Element --
357 -------------
359 function Element (Position : Cursor) return Element_Type is
360 begin
361 if Position.Node = 0 then
362 raise Constraint_Error;
363 end if;
365 pragma Assert (Vet (Position), "bad cursor in Element");
367 declare
368 N : Node_Array renames Position.Container.Nodes;
369 begin
370 return N (Position.Node).Element;
371 end;
372 end Element;
374 ----------
375 -- Find --
376 ----------
378 function Find
379 (Container : List;
380 Item : Element_Type;
381 Position : Cursor := No_Element) return Cursor
383 Nodes : Node_Array renames Container.Nodes;
384 Node : Count_Type := Position.Node;
386 begin
387 if Node = 0 then
388 Node := Container.First;
390 else
391 if Position.Container /= Container'Unrestricted_Access then
392 raise Program_Error;
393 end if;
395 pragma Assert (Vet (Position), "bad cursor in Find");
396 end if;
398 while Node /= 0 loop
399 if Nodes (Node).Element = Item then
400 return Cursor'(Container'Unrestricted_Access, Node);
401 end if;
403 Node := Nodes (Node).Next;
404 end loop;
406 return No_Element;
407 end Find;
409 -----------
410 -- First --
411 -----------
413 function First (Container : List) return Cursor is
414 begin
415 if Container.First = 0 then
416 return No_Element;
417 end if;
419 return Cursor'(Container'Unrestricted_Access, Container.First);
420 end First;
422 -------------------
423 -- First_Element --
424 -------------------
426 function First_Element (Container : List) return Element_Type is
427 N : Node_Array renames Container.Nodes;
429 begin
430 if Container.First = 0 then
431 raise Constraint_Error;
432 end if;
434 return N (Container.First).Element;
435 end First_Element;
437 ----------
438 -- Free --
439 ----------
441 procedure Free
442 (Container : in out List'Class;
443 X : Count_Type)
445 pragma Assert (X > 0);
446 pragma Assert (X <= Container.Capacity);
448 N : Node_Array renames Container.Nodes;
450 begin
451 N (X).Prev := -1; -- Node is deallocated (not on active list)
453 if Container.Free >= 0 then
454 N (X).Next := Container.Free;
455 Container.Free := X;
457 elsif X + 1 = abs Container.Free then
458 N (X).Next := 0; -- Not strictly necessary, but marginally safer
459 Container.Free := Container.Free + 1;
461 else
462 Container.Free := abs Container.Free;
464 if Container.Free > Container.Capacity then
465 Container.Free := 0;
467 else
468 for I in Container.Free .. Container.Capacity - 1 loop
469 N (I).Next := I + 1;
470 end loop;
472 N (Container.Capacity).Next := 0;
473 end if;
475 N (X).Next := Container.Free;
476 Container.Free := X;
477 end if;
478 end Free;
480 ---------------------
481 -- Generic_Sorting --
482 ---------------------
484 package body Generic_Sorting is
486 ---------------
487 -- Is_Sorted --
488 ---------------
490 function Is_Sorted (Container : List) return Boolean is
491 Nodes : Node_Array renames Container.Nodes;
492 Node : Count_Type := Container.First;
494 begin
495 for I in 2 .. Container.Length loop
496 if Nodes (Nodes (Node).Next).Element < Nodes (Node).Element then
497 return False;
498 end if;
500 Node := Nodes (Node).Next;
501 end loop;
503 return True;
504 end Is_Sorted;
506 ----------
507 -- Sort --
508 ----------
510 procedure Sort (Container : in out List) is
511 N : Node_Array renames Container.Nodes;
513 procedure Partition (Pivot, Back : Count_Type);
514 procedure Sort (Front, Back : Count_Type);
516 ---------------
517 -- Partition --
518 ---------------
520 procedure Partition (Pivot, Back : Count_Type) is
521 Node : Count_Type := N (Pivot).Next;
523 begin
524 while Node /= Back loop
525 if N (Node).Element < N (Pivot).Element then
526 declare
527 Prev : constant Count_Type := N (Node).Prev;
528 Next : constant Count_Type := N (Node).Next;
530 begin
531 N (Prev).Next := Next;
533 if Next = 0 then
534 Container.Last := Prev;
535 else
536 N (Next).Prev := Prev;
537 end if;
539 N (Node).Next := Pivot;
540 N (Node).Prev := N (Pivot).Prev;
542 N (Pivot).Prev := Node;
544 if N (Node).Prev = 0 then
545 Container.First := Node;
546 else
547 N (N (Node).Prev).Next := Node;
548 end if;
550 Node := Next;
551 end;
553 else
554 Node := N (Node).Next;
555 end if;
556 end loop;
557 end Partition;
559 ----------
560 -- Sort --
561 ----------
563 procedure Sort (Front, Back : Count_Type) is
564 Pivot : constant Count_Type :=
565 (if Front = 0 then Container.First else N (Front).Next);
566 begin
567 if Pivot /= Back then
568 Partition (Pivot, Back);
569 Sort (Front, Pivot);
570 Sort (Pivot, Back);
571 end if;
572 end Sort;
574 -- Start of processing for Sort
576 begin
577 if Container.Length <= 1 then
578 return;
579 end if;
581 pragma Assert (N (Container.First).Prev = 0);
582 pragma Assert (N (Container.Last).Next = 0);
584 -- if Container.Busy > 0 then
585 -- raise Program_Error;
586 -- end if;
588 Sort (Front => 0, Back => 0);
590 pragma Assert (N (Container.First).Prev = 0);
591 pragma Assert (N (Container.Last).Next = 0);
592 end Sort;
594 end Generic_Sorting;
596 -----------------
597 -- Has_Element --
598 -----------------
600 function Has_Element (Position : Cursor) return Boolean is
601 begin
602 pragma Assert (Vet (Position), "bad cursor in Has_Element");
603 return Position.Node /= 0;
604 end Has_Element;
606 ------------
607 -- Insert --
608 ------------
610 procedure Insert
611 (Container : in out List;
612 Before : Cursor;
613 New_Item : Element_Type;
614 Position : out Cursor;
615 Count : Count_Type := 1)
617 J : Count_Type;
619 begin
620 if Before.Container /= null then
621 if Before.Container /= Container'Unrestricted_Access then
622 raise Program_Error;
623 end if;
625 pragma Assert (Vet (Before), "bad cursor in Insert");
626 end if;
628 if Count = 0 then
629 Position := Before;
630 return;
631 end if;
633 if Container.Length > Container.Capacity - Count then
634 raise Constraint_Error;
635 end if;
637 -- if Container.Busy > 0 then
638 -- raise Program_Error;
639 -- end if;
641 Allocate (Container, New_Item, New_Node => J);
642 Insert_Internal (Container, Before.Node, New_Node => J);
643 Position := Cursor'(Container'Unrestricted_Access, Node => J);
645 for Index in 2 .. Count loop
646 Allocate (Container, New_Item, New_Node => J);
647 Insert_Internal (Container, Before.Node, New_Node => J);
648 end loop;
649 end Insert;
651 procedure Insert
652 (Container : in out List;
653 Before : Cursor;
654 New_Item : Element_Type;
655 Count : Count_Type := 1)
657 Position : Cursor;
658 pragma Unreferenced (Position);
659 begin
660 Insert (Container, Before, New_Item, Position, Count);
661 end Insert;
663 procedure Insert
664 (Container : in out List;
665 Before : Cursor;
666 Position : out Cursor;
667 Count : Count_Type := 1)
669 New_Item : Element_Type; -- Do we need to reinit node ???
670 pragma Warnings (Off, New_Item);
672 begin
673 Insert (Container, Before, New_Item, Position, Count);
674 end Insert;
676 ---------------------
677 -- Insert_Internal --
678 ---------------------
680 procedure Insert_Internal
681 (Container : in out List'Class;
682 Before : Count_Type;
683 New_Node : Count_Type)
685 N : Node_Array renames Container.Nodes;
687 begin
688 if Container.Length = 0 then
689 pragma Assert (Before = 0);
690 pragma Assert (Container.First = 0);
691 pragma Assert (Container.Last = 0);
693 Container.First := New_Node;
694 Container.Last := New_Node;
696 N (Container.First).Prev := 0;
697 N (Container.Last).Next := 0;
699 elsif Before = 0 then
700 pragma Assert (N (Container.Last).Next = 0);
702 N (Container.Last).Next := New_Node;
703 N (New_Node).Prev := Container.Last;
705 Container.Last := New_Node;
706 N (Container.Last).Next := 0;
708 elsif Before = Container.First then
709 pragma Assert (N (Container.First).Prev = 0);
711 N (Container.First).Prev := New_Node;
712 N (New_Node).Next := Container.First;
714 Container.First := New_Node;
715 N (Container.First).Prev := 0;
717 else
718 pragma Assert (N (Container.First).Prev = 0);
719 pragma Assert (N (Container.Last).Next = 0);
721 N (New_Node).Next := Before;
722 N (New_Node).Prev := N (Before).Prev;
724 N (N (Before).Prev).Next := New_Node;
725 N (Before).Prev := New_Node;
726 end if;
728 Container.Length := Container.Length + 1;
729 end Insert_Internal;
731 --------------
732 -- Is_Empty --
733 --------------
735 function Is_Empty (Container : List) return Boolean is
736 begin
737 return Container.Length = 0;
738 end Is_Empty;
740 -------------
741 -- Iterate --
742 -------------
744 procedure Iterate
745 (Container : List;
746 Process : not null access procedure (Position : Cursor))
748 C : List renames Container'Unrestricted_Access.all;
749 N : Node_Array renames C.Nodes;
750 -- B : Natural renames C.Busy;
752 Node : Count_Type := Container.First;
754 Index : Count_Type := 0;
755 Index_Max : constant Count_Type := Container.Length;
757 begin
758 if Index_Max = 0 then
759 pragma Assert (Node = 0);
760 return;
761 end if;
763 loop
764 pragma Assert (Node /= 0);
766 Process (Cursor'(C'Unchecked_Access, Node));
767 pragma Assert (Container.Length = Index_Max);
768 pragma Assert (N (Node).Prev /= -1);
770 Node := N (Node).Next;
771 Index := Index + 1;
773 if Index = Index_Max then
774 pragma Assert (Node = 0);
775 return;
776 end if;
777 end loop;
778 end Iterate;
780 ----------
781 -- Last --
782 ----------
784 function Last (Container : List) return Cursor is
785 begin
786 if Container.Last = 0 then
787 return No_Element;
788 end if;
790 return Cursor'(Container'Unrestricted_Access, Container.Last);
791 end Last;
793 ------------------
794 -- Last_Element --
795 ------------------
797 function Last_Element (Container : List) return Element_Type is
798 N : Node_Array renames Container.Nodes;
800 begin
801 if Container.Last = 0 then
802 raise Constraint_Error;
803 end if;
805 return N (Container.Last).Element;
806 end Last_Element;
808 ------------
809 -- Length --
810 ------------
812 function Length (Container : List) return Count_Type is
813 begin
814 return Container.Length;
815 end Length;
817 ----------
818 -- Next --
819 ----------
821 procedure Next (Position : in out Cursor) is
822 begin
823 Position := Next (Position);
824 end Next;
826 function Next (Position : Cursor) return Cursor is
827 begin
828 if Position.Node = 0 then
829 return No_Element;
830 end if;
832 pragma Assert (Vet (Position), "bad cursor in Next");
834 declare
835 Nodes : Node_Array renames Position.Container.Nodes;
836 Node : constant Count_Type := Nodes (Position.Node).Next;
838 begin
839 if Node = 0 then
840 return No_Element;
841 end if;
843 return Cursor'(Position.Container, Node);
844 end;
845 end Next;
847 -------------
848 -- Prepend --
849 -------------
851 procedure Prepend
852 (Container : in out List;
853 New_Item : Element_Type;
854 Count : Count_Type := 1)
856 begin
857 Insert (Container, First (Container), New_Item, Count);
858 end Prepend;
860 --------------
861 -- Previous --
862 --------------
864 procedure Previous (Position : in out Cursor) is
865 begin
866 Position := Previous (Position);
867 end Previous;
869 function Previous (Position : Cursor) return Cursor is
870 begin
871 if Position.Node = 0 then
872 return No_Element;
873 end if;
875 pragma Assert (Vet (Position), "bad cursor in Previous");
877 declare
878 Nodes : Node_Array renames Position.Container.Nodes;
879 Node : constant Count_Type := Nodes (Position.Node).Prev;
880 begin
881 if Node = 0 then
882 return No_Element;
883 end if;
885 return Cursor'(Position.Container, Node);
886 end;
887 end Previous;
889 -------------------
890 -- Query_Element --
891 -------------------
893 procedure Query_Element
894 (Position : Cursor;
895 Process : not null access procedure (Element : Element_Type))
897 begin
898 if Position.Node = 0 then
899 raise Constraint_Error;
900 end if;
902 pragma Assert (Vet (Position), "bad cursor in Query_Element");
904 declare
905 C : List renames Position.Container.all'Unrestricted_Access.all;
906 N : Node_Type renames C.Nodes (Position.Node);
908 begin
909 Process (N.Element);
910 pragma Assert (N.Prev >= 0);
911 end;
912 end Query_Element;
914 ---------------------
915 -- Replace_Element --
916 ---------------------
918 procedure Replace_Element
919 (Container : in out List;
920 Position : Cursor;
921 New_Item : Element_Type)
923 begin
924 if Position.Container = null then
925 raise Constraint_Error;
926 end if;
928 if Position.Container /= Container'Unrestricted_Access then
929 raise Program_Error;
930 end if;
932 -- if Container.Lock > 0 then
933 -- raise Program_Error;
934 -- end if;
936 pragma Assert (Vet (Position), "bad cursor in Replace_Element");
938 declare
939 N : Node_Array renames Container.Nodes;
940 begin
941 N (Position.Node).Element := New_Item;
942 end;
943 end Replace_Element;
945 ----------------------
946 -- Reverse_Elements --
947 ----------------------
949 procedure Reverse_Elements (Container : in out List) is
950 N : Node_Array renames Container.Nodes;
951 I : Count_Type := Container.First;
952 J : Count_Type := Container.Last;
954 procedure Swap (L, R : Count_Type);
956 ----------
957 -- Swap --
958 ----------
960 procedure Swap (L, R : Count_Type) is
961 LN : constant Count_Type := N (L).Next;
962 LP : constant Count_Type := N (L).Prev;
964 RN : constant Count_Type := N (R).Next;
965 RP : constant Count_Type := N (R).Prev;
967 begin
968 if LP /= 0 then
969 N (LP).Next := R;
970 end if;
972 if RN /= 0 then
973 N (RN).Prev := L;
974 end if;
976 N (L).Next := RN;
977 N (R).Prev := LP;
979 if LN = R then
980 pragma Assert (RP = L);
982 N (L).Prev := R;
983 N (R).Next := L;
985 else
986 N (L).Prev := RP;
987 N (RP).Next := L;
989 N (R).Next := LN;
990 N (LN).Prev := R;
991 end if;
992 end Swap;
994 -- Start of processing for Reverse_Elements
996 begin
997 if Container.Length <= 1 then
998 return;
999 end if;
1001 pragma Assert (N (Container.First).Prev = 0);
1002 pragma Assert (N (Container.Last).Next = 0);
1004 -- if Container.Busy > 0 then
1005 -- raise Program_Error;
1006 -- end if;
1008 Container.First := J;
1009 Container.Last := I;
1010 loop
1011 Swap (L => I, R => J);
1013 J := N (J).Next;
1014 exit when I = J;
1016 I := N (I).Prev;
1017 exit when I = J;
1019 Swap (L => J, R => I);
1021 I := N (I).Next;
1022 exit when I = J;
1024 J := N (J).Prev;
1025 exit when I = J;
1026 end loop;
1028 pragma Assert (N (Container.First).Prev = 0);
1029 pragma Assert (N (Container.Last).Next = 0);
1030 end Reverse_Elements;
1032 ------------------
1033 -- Reverse_Find --
1034 ------------------
1036 function Reverse_Find
1037 (Container : List;
1038 Item : Element_Type;
1039 Position : Cursor := No_Element) return Cursor
1041 N : Node_Array renames Container.Nodes;
1042 Node : Count_Type := Position.Node;
1044 begin
1045 if Node = 0 then
1046 Node := Container.Last;
1048 else
1049 if Position.Container /= Container'Unrestricted_Access then
1050 raise Program_Error;
1051 end if;
1053 pragma Assert (Vet (Position), "bad cursor in Reverse_Find");
1054 end if;
1056 while Node /= 0 loop
1057 if N (Node).Element = Item then
1058 return Cursor'(Container'Unrestricted_Access, Node);
1059 end if;
1061 Node := N (Node).Prev;
1062 end loop;
1064 return No_Element;
1065 end Reverse_Find;
1067 ---------------------
1068 -- Reverse_Iterate --
1069 ---------------------
1071 procedure Reverse_Iterate
1072 (Container : List;
1073 Process : not null access procedure (Position : Cursor))
1075 C : List renames Container'Unrestricted_Access.all;
1076 N : Node_Array renames C.Nodes;
1077 -- B : Natural renames C.Busy;
1079 Node : Count_Type := Container.Last;
1081 Index : Count_Type := 0;
1082 Index_Max : constant Count_Type := Container.Length;
1084 begin
1085 if Index_Max = 0 then
1086 pragma Assert (Node = 0);
1087 return;
1088 end if;
1090 loop
1091 pragma Assert (Node > 0);
1093 Process (Cursor'(C'Unchecked_Access, Node));
1094 pragma Assert (Container.Length = Index_Max);
1095 pragma Assert (N (Node).Prev /= -1);
1097 Node := N (Node).Prev;
1098 Index := Index + 1;
1100 if Index = Index_Max then
1101 pragma Assert (Node = 0);
1102 return;
1103 end if;
1104 end loop;
1105 end Reverse_Iterate;
1107 ------------
1108 -- Splice --
1109 ------------
1111 procedure Splice
1112 (Container : in out List;
1113 Before : Cursor;
1114 Position : in out Cursor)
1116 N : Node_Array renames Container.Nodes;
1118 begin
1119 if Before.Container /= null then
1120 if Before.Container /= Container'Unrestricted_Access then
1121 raise Program_Error;
1122 end if;
1124 pragma Assert (Vet (Before), "bad Before cursor in Splice");
1125 end if;
1127 if Position.Node = 0 then
1128 raise Constraint_Error;
1129 end if;
1131 if Position.Container /= Container'Unrestricted_Access then
1132 raise Program_Error;
1133 end if;
1135 pragma Assert (Vet (Position), "bad Position cursor in Splice");
1137 if Position.Node = Before.Node
1138 or else N (Position.Node).Next = Before.Node
1139 then
1140 return;
1141 end if;
1143 pragma Assert (Container.Length >= 2);
1145 -- if Container.Busy > 0 then
1146 -- raise Program_Error;
1147 -- end if;
1149 if Before.Node = 0 then
1150 pragma Assert (Position.Node /= Container.Last);
1152 if Position.Node = Container.First then
1153 Container.First := N (Position.Node).Next;
1154 N (Container.First).Prev := 0;
1156 else
1157 N (N (Position.Node).Prev).Next := N (Position.Node).Next;
1158 N (N (Position.Node).Next).Prev := N (Position.Node).Prev;
1159 end if;
1161 N (Container.Last).Next := Position.Node;
1162 N (Position.Node).Prev := Container.Last;
1164 Container.Last := Position.Node;
1165 N (Container.Last).Next := 0;
1167 return;
1168 end if;
1170 if Before.Node = Container.First then
1171 pragma Assert (Position.Node /= Container.First);
1173 if Position.Node = Container.Last then
1174 Container.Last := N (Position.Node).Prev;
1175 N (Container.Last).Next := 0;
1177 else
1178 N (N (Position.Node).Prev).Next := N (Position.Node).Next;
1179 N (N (Position.Node).Next).Prev := N (Position.Node).Prev;
1180 end if;
1182 N (Container.First).Prev := Position.Node;
1183 N (Position.Node).Next := Container.First;
1185 Container.First := Position.Node;
1186 N (Container.First).Prev := 0;
1188 return;
1189 end if;
1191 if Position.Node = Container.First then
1192 Container.First := N (Position.Node).Next;
1193 N (Container.First).Prev := 0;
1195 elsif Position.Node = Container.Last then
1196 Container.Last := N (Position.Node).Prev;
1197 N (Container.Last).Next := 0;
1199 else
1200 N (N (Position.Node).Prev).Next := N (Position.Node).Next;
1201 N (N (Position.Node).Next).Prev := N (Position.Node).Prev;
1202 end if;
1204 N (N (Before.Node).Prev).Next := Position.Node;
1205 N (Position.Node).Prev := N (Before.Node).Prev;
1207 N (Before.Node).Prev := Position.Node;
1208 N (Position.Node).Next := Before.Node;
1210 pragma Assert (N (Container.First).Prev = 0);
1211 pragma Assert (N (Container.Last).Next = 0);
1212 end Splice;
1214 ----------
1215 -- Swap --
1216 ----------
1218 procedure Swap
1219 (Container : in out List;
1220 I, J : Cursor)
1222 begin
1223 if I.Node = 0
1224 or else J.Node = 0
1225 then
1226 raise Constraint_Error;
1227 end if;
1229 if I.Container /= Container'Unrestricted_Access
1230 or else J.Container /= Container'Unrestricted_Access
1231 then
1232 raise Program_Error;
1233 end if;
1235 if I.Node = J.Node then
1236 return;
1237 end if;
1239 -- if Container.Lock > 0 then
1240 -- raise Program_Error;
1241 -- end if;
1243 pragma Assert (Vet (I), "bad I cursor in Swap");
1244 pragma Assert (Vet (J), "bad J cursor in Swap");
1246 declare
1247 N : Node_Array renames Container.Nodes;
1249 EI : Element_Type renames N (I.Node).Element;
1250 EJ : Element_Type renames N (J.Node).Element;
1252 EI_Copy : constant Element_Type := EI;
1254 begin
1255 EI := EJ;
1256 EJ := EI_Copy;
1257 end;
1258 end Swap;
1260 ----------------
1261 -- Swap_Links --
1262 ----------------
1264 procedure Swap_Links
1265 (Container : in out List;
1266 I, J : Cursor)
1268 begin
1269 if I.Node = 0
1270 or else J.Node = 0
1271 then
1272 raise Constraint_Error;
1273 end if;
1275 if I.Container /= Container'Unrestricted_Access
1276 or else I.Container /= J.Container
1277 then
1278 raise Program_Error;
1279 end if;
1281 if I.Node = J.Node then
1282 return;
1283 end if;
1285 -- if Container.Busy > 0 then
1286 -- raise Program_Error;
1287 -- end if;
1289 pragma Assert (Vet (I), "bad I cursor in Swap_Links");
1290 pragma Assert (Vet (J), "bad J cursor in Swap_Links");
1292 declare
1293 I_Next : constant Cursor := Next (I);
1295 J_Copy : Cursor := J;
1296 pragma Warnings (Off, J_Copy);
1298 begin
1299 if I_Next = J then
1300 Splice (Container, Before => I, Position => J_Copy);
1302 else
1303 declare
1304 J_Next : constant Cursor := Next (J);
1306 I_Copy : Cursor := I;
1307 pragma Warnings (Off, I_Copy);
1309 begin
1310 if J_Next = I then
1311 Splice (Container, Before => J, Position => I_Copy);
1313 else
1314 pragma Assert (Container.Length >= 3);
1316 Splice (Container, Before => I_Next, Position => J_Copy);
1317 Splice (Container, Before => J_Next, Position => I_Copy);
1318 end if;
1319 end;
1320 end if;
1321 end;
1322 end Swap_Links;
1324 --------------------
1325 -- Update_Element --
1326 --------------------
1328 procedure Update_Element
1329 (Container : in out List;
1330 Position : Cursor;
1331 Process : not null access procedure (Element : in out Element_Type))
1333 begin
1334 if Position.Node = 0 then
1335 raise Constraint_Error;
1336 end if;
1338 if Position.Container /= Container'Unrestricted_Access then
1339 raise Program_Error;
1340 end if;
1342 pragma Assert (Vet (Position), "bad cursor in Update_Element");
1344 declare
1345 N : Node_Type renames Container.Nodes (Position.Node);
1347 begin
1348 Process (N.Element);
1349 pragma Assert (N.Prev >= 0);
1350 end;
1351 end Update_Element;
1353 ---------
1354 -- Vet --
1355 ---------
1357 function Vet (Position : Cursor) return Boolean is
1358 begin
1359 if Position.Node = 0 then
1360 return Position.Container = null;
1361 end if;
1363 if Position.Container = null then
1364 return False;
1365 end if;
1367 declare
1368 L : List renames Position.Container.all;
1369 N : Node_Array renames L.Nodes;
1371 begin
1372 if L.Length = 0 then
1373 return False;
1374 end if;
1376 if L.First = 0 then
1377 return False;
1378 end if;
1380 if L.Last = 0 then
1381 return False;
1382 end if;
1384 if Position.Node > L.Capacity then
1385 return False;
1386 end if;
1388 if N (Position.Node).Prev < 0
1389 or else N (Position.Node).Prev > L.Capacity
1390 then
1391 return False;
1392 end if;
1394 if N (Position.Node).Next > L.Capacity then
1395 return False;
1396 end if;
1398 if N (L.First).Prev /= 0 then
1399 return False;
1400 end if;
1402 if N (L.Last).Next /= 0 then
1403 return False;
1404 end if;
1406 if N (Position.Node).Prev = 0
1407 and then Position.Node /= L.First
1408 then
1409 return False;
1410 end if;
1412 if N (Position.Node).Next = 0
1413 and then Position.Node /= L.Last
1414 then
1415 return False;
1416 end if;
1418 if L.Length = 1 then
1419 return L.First = L.Last;
1420 end if;
1422 if L.First = L.Last then
1423 return False;
1424 end if;
1426 if N (L.First).Next = 0 then
1427 return False;
1428 end if;
1430 if N (L.Last).Prev = 0 then
1431 return False;
1432 end if;
1434 if N (N (L.First).Next).Prev /= L.First then
1435 return False;
1436 end if;
1438 if N (N (L.Last).Prev).Next /= L.Last then
1439 return False;
1440 end if;
1442 if L.Length = 2 then
1443 if N (L.First).Next /= L.Last then
1444 return False;
1445 end if;
1447 if N (L.Last).Prev /= L.First then
1448 return False;
1449 end if;
1451 return True;
1452 end if;
1454 if N (L.First).Next = L.Last then
1455 return False;
1456 end if;
1458 if N (L.Last).Prev = L.First then
1459 return False;
1460 end if;
1462 if Position.Node = L.First then
1463 return True;
1464 end if;
1466 if Position.Node = L.Last then
1467 return True;
1468 end if;
1470 if N (Position.Node).Next = 0 then
1471 return False;
1472 end if;
1474 if N (Position.Node).Prev = 0 then
1475 return False;
1476 end if;
1478 if N (N (Position.Node).Next).Prev /= Position.Node then
1479 return False;
1480 end if;
1482 if N (N (Position.Node).Prev).Next /= Position.Node then
1483 return False;
1484 end if;
1486 if L.Length = 3 then
1487 if N (L.First).Next /= Position.Node then
1488 return False;
1489 end if;
1491 if N (L.Last).Prev /= Position.Node then
1492 return False;
1493 end if;
1494 end if;
1496 return True;
1497 end;
1498 end Vet;
1500 end Ada.Containers.Restricted_Doubly_Linked_Lists;