1 ------------------------------------------------------------------------------
3 -- GNAT COMPILER COMPONENTS --
9 -- Copyright (C) 1992-2017, 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 -- GNAT was originally developed by the GNAT team at New York University. --
28 -- Extensive contributions were provided by Ada Core Technologies Inc. --
30 ------------------------------------------------------------------------------
32 -- WARNING: There is a C version of this package. Any changes to this source
33 -- file must be properly reflected in the corresponding C header a-nlists.h
36 with Atree
; use Atree
;
37 with Debug
; use Debug
;
38 with Output
; use Output
;
39 with Sinfo
; use Sinfo
;
42 package body Nlists
is
43 Locked
: Boolean := False;
44 -- Compiling with assertions enabled, list contents modifications are
45 -- permitted only when this switch is set to False; compiling without
46 -- assertions this lock has no effect.
48 use Atree_Private_Part
;
49 -- Get access to Nodes table
51 ----------------------------------
52 -- Implementation of Node Lists --
53 ----------------------------------
55 -- A node list is represented by a list header which contains
58 type List_Header
is record
59 First
: Node_Or_Entity_Id
;
60 -- Pointer to first node in list. Empty if list is empty
62 Last
: Node_Or_Entity_Id
;
63 -- Pointer to last node in list. Empty if list is empty
66 -- Pointer to parent of list. Empty if list has no parent
69 -- The node lists are stored in a table indexed by List_Id values
71 package Lists
is new Table
.Table
(
72 Table_Component_Type
=> List_Header
,
73 Table_Index_Type
=> List_Id
'Base,
74 Table_Low_Bound
=> First_List_Id
,
75 Table_Initial
=> Alloc
.Lists_Initial
,
76 Table_Increment
=> Alloc
.Lists_Increment
,
77 Table_Name
=> "Lists");
79 -- The nodes in the list all have the In_List flag set, and their Link
80 -- fields (which otherwise point to the parent) contain the List_Id of
81 -- the list header giving immediate access to the list containing the
82 -- node, and its parent and first and last elements.
84 -- Two auxiliary tables, indexed by Node_Id values and built in parallel
85 -- with the main nodes table and always having the same size contain the
86 -- list link values that allow locating the previous and next node in a
87 -- list. The entries in these tables are valid only if the In_List flag
88 -- is set in the corresponding node. Next_Node is Empty at the end of a
89 -- list and Prev_Node is Empty at the start of a list.
91 package Next_Node
is new Table
.Table
(
92 Table_Component_Type
=> Node_Or_Entity_Id
,
93 Table_Index_Type
=> Node_Or_Entity_Id
'Base,
94 Table_Low_Bound
=> First_Node_Id
,
95 Table_Initial
=> Alloc
.Nodes_Initial
,
96 Table_Increment
=> Alloc
.Nodes_Increment
,
97 Release_Threshold
=> Alloc
.Nodes_Release_Threshold
,
98 Table_Name
=> "Next_Node");
100 package Prev_Node
is new Table
.Table
(
101 Table_Component_Type
=> Node_Or_Entity_Id
,
102 Table_Index_Type
=> Node_Or_Entity_Id
'Base,
103 Table_Low_Bound
=> First_Node_Id
,
104 Table_Initial
=> Alloc
.Nodes_Initial
,
105 Table_Increment
=> Alloc
.Nodes_Increment
,
106 Table_Name
=> "Prev_Node");
108 -----------------------
109 -- Local Subprograms --
110 -----------------------
112 procedure Set_First
(List
: List_Id
; To
: Node_Or_Entity_Id
);
113 pragma Inline
(Set_First
);
114 -- Sets First field of list header List to reference To
116 procedure Set_Last
(List
: List_Id
; To
: Node_Or_Entity_Id
);
117 pragma Inline
(Set_Last
);
118 -- Sets Last field of list header List to reference To
120 procedure Set_List_Link
(Node
: Node_Or_Entity_Id
; To
: List_Id
);
121 pragma Inline
(Set_List_Link
);
122 -- Sets list link of Node to list header To
124 procedure Set_Next
(Node
: Node_Or_Entity_Id
; To
: Node_Or_Entity_Id
);
125 pragma Inline
(Set_Next
);
126 -- Sets the Next_Node pointer for Node to reference To
128 procedure Set_Prev
(Node
: Node_Or_Entity_Id
; To
: Node_Or_Entity_Id
);
129 pragma Inline
(Set_Prev
);
130 -- Sets the Prev_Node pointer for Node to reference To
132 --------------------------
133 -- Allocate_List_Tables --
134 --------------------------
136 procedure Allocate_List_Tables
(N
: Node_Or_Entity_Id
) is
137 Old_Last
: constant Node_Or_Entity_Id
'Base := Next_Node
.Last
;
140 pragma Assert
(N
>= Old_Last
);
141 Next_Node
.Set_Last
(N
);
142 Prev_Node
.Set_Last
(N
);
144 -- Make sure we have no uninitialized junk in any new entires added.
145 -- This ensures that Tree_Gen will not write out any uninitialized junk.
147 for J
in Old_Last
+ 1 .. N
loop
148 Next_Node
.Table
(J
) := Empty
;
149 Prev_Node
.Table
(J
) := Empty
;
151 end Allocate_List_Tables
;
157 procedure Append
(Node
: Node_Or_Entity_Id
; To
: List_Id
) is
158 L
: constant Node_Or_Entity_Id
:= Last
(To
);
160 procedure Append_Debug
;
161 pragma Inline
(Append_Debug
);
162 -- Output debug information if Debug_Flag_N set
168 procedure Append_Debug
is
171 Write_Str
("Append node ");
172 Write_Int
(Int
(Node
));
173 Write_Str
(" to list ");
174 Write_Int
(Int
(To
));
179 -- Start of processing for Append
182 pragma Assert
(not Is_List_Member
(Node
));
188 pragma Debug
(Append_Debug
);
191 Set_First
(To
, Node
);
198 Nodes
.Table
(Node
).In_List
:= True;
200 Set_Next
(Node
, Empty
);
202 Set_List_Link
(Node
, To
);
209 procedure Append_List
(List
: List_Id
; To
: List_Id
) is
210 procedure Append_List_Debug
;
211 pragma Inline
(Append_List_Debug
);
212 -- Output debug information if Debug_Flag_N set
214 -----------------------
215 -- Append_List_Debug --
216 -----------------------
218 procedure Append_List_Debug
is
221 Write_Str
("Append list ");
222 Write_Int
(Int
(List
));
223 Write_Str
(" to list ");
224 Write_Int
(Int
(To
));
227 end Append_List_Debug
;
229 -- Start of processing for Append_List
232 if Is_Empty_List
(List
) then
237 L
: constant Node_Or_Entity_Id
:= Last
(To
);
238 F
: constant Node_Or_Entity_Id
:= First
(List
);
239 N
: Node_Or_Entity_Id
;
242 pragma Debug
(Append_List_Debug
);
246 Set_List_Link
(N
, To
);
258 Set_Last
(To
, Last
(List
));
260 Set_First
(List
, Empty
);
261 Set_Last
(List
, Empty
);
270 procedure Append_List_To
(To
: List_Id
; List
: List_Id
) is
272 Append_List
(List
, To
);
279 procedure Append_New
(Node
: Node_Or_Entity_Id
; To
: in out List_Id
) is
292 procedure Append_New_To
(To
: in out List_Id
; Node
: Node_Or_Entity_Id
) is
294 Append_New
(Node
, To
);
301 procedure Append_To
(To
: List_Id
; Node
: Node_Or_Entity_Id
) is
310 function First
(List
: List_Id
) return Node_Or_Entity_Id
is
312 if List
= No_List
then
315 pragma Assert
(List
<= Lists
.Last
);
316 return Lists
.Table
(List
).First
;
320 ----------------------
321 -- First_Non_Pragma --
322 ----------------------
324 function First_Non_Pragma
(List
: List_Id
) return Node_Or_Entity_Id
is
325 N
: constant Node_Or_Entity_Id
:= First
(List
);
327 if Nkind
(N
) /= N_Pragma
329 Nkind
(N
) /= N_Null_Statement
333 return Next_Non_Pragma
(N
);
335 end First_Non_Pragma
;
341 procedure Initialize
is
342 E
: constant List_Id
:= Error_List
;
349 -- Allocate Error_List list header
351 Lists
.Increment_Last
;
352 Set_Parent
(E
, Empty
);
353 Set_First
(E
, Empty
);
361 function In_Same_List
(N1
, N2
: Node_Or_Entity_Id
) return Boolean is
363 return List_Containing
(N1
) = List_Containing
(N2
);
370 procedure Insert_After
371 (After
: Node_Or_Entity_Id
;
372 Node
: Node_Or_Entity_Id
)
374 procedure Insert_After_Debug
;
375 pragma Inline
(Insert_After_Debug
);
376 -- Output debug information if Debug_Flag_N set
378 ------------------------
379 -- Insert_After_Debug --
380 ------------------------
382 procedure Insert_After_Debug
is
385 Write_Str
("Insert node");
386 Write_Int
(Int
(Node
));
387 Write_Str
(" after node ");
388 Write_Int
(Int
(After
));
391 end Insert_After_Debug
;
393 -- Start of processing for Insert_After
397 (Is_List_Member
(After
) and then not Is_List_Member
(Node
));
403 pragma Debug
(Insert_After_Debug
);
406 Before
: constant Node_Or_Entity_Id
:= Next
(After
);
407 LC
: constant List_Id
:= List_Containing
(After
);
410 if Present
(Before
) then
411 Set_Prev
(Before
, Node
);
416 Set_Next
(After
, Node
);
418 Nodes
.Table
(Node
).In_List
:= True;
420 Set_Prev
(Node
, After
);
421 Set_Next
(Node
, Before
);
422 Set_List_Link
(Node
, LC
);
430 procedure Insert_Before
431 (Before
: Node_Or_Entity_Id
;
432 Node
: Node_Or_Entity_Id
)
434 procedure Insert_Before_Debug
;
435 pragma Inline
(Insert_Before_Debug
);
436 -- Output debug information if Debug_Flag_N set
438 -------------------------
439 -- Insert_Before_Debug --
440 -------------------------
442 procedure Insert_Before_Debug
is
445 Write_Str
("Insert node");
446 Write_Int
(Int
(Node
));
447 Write_Str
(" before node ");
448 Write_Int
(Int
(Before
));
451 end Insert_Before_Debug
;
453 -- Start of processing for Insert_Before
457 (Is_List_Member
(Before
) and then not Is_List_Member
(Node
));
463 pragma Debug
(Insert_Before_Debug
);
466 After
: constant Node_Or_Entity_Id
:= Prev
(Before
);
467 LC
: constant List_Id
:= List_Containing
(Before
);
470 if Present
(After
) then
471 Set_Next
(After
, Node
);
473 Set_First
(LC
, Node
);
476 Set_Prev
(Before
, Node
);
478 Nodes
.Table
(Node
).In_List
:= True;
480 Set_Prev
(Node
, After
);
481 Set_Next
(Node
, Before
);
482 Set_List_Link
(Node
, LC
);
486 -----------------------
487 -- Insert_List_After --
488 -----------------------
490 procedure Insert_List_After
(After
: Node_Or_Entity_Id
; List
: List_Id
) is
492 procedure Insert_List_After_Debug
;
493 pragma Inline
(Insert_List_After_Debug
);
494 -- Output debug information if Debug_Flag_N set
496 -----------------------------
497 -- Insert_List_After_Debug --
498 -----------------------------
500 procedure Insert_List_After_Debug
is
503 Write_Str
("Insert list ");
504 Write_Int
(Int
(List
));
505 Write_Str
(" after node ");
506 Write_Int
(Int
(After
));
509 end Insert_List_After_Debug
;
511 -- Start of processing for Insert_List_After
514 pragma Assert
(Is_List_Member
(After
));
516 if Is_Empty_List
(List
) then
521 Before
: constant Node_Or_Entity_Id
:= Next
(After
);
522 LC
: constant List_Id
:= List_Containing
(After
);
523 F
: constant Node_Or_Entity_Id
:= First
(List
);
524 L
: constant Node_Or_Entity_Id
:= Last
(List
);
525 N
: Node_Or_Entity_Id
;
528 pragma Debug
(Insert_List_After_Debug
);
532 Set_List_Link
(N
, LC
);
537 if Present
(Before
) then
538 Set_Prev
(Before
, L
);
545 Set_Next
(L
, Before
);
547 Set_First
(List
, Empty
);
548 Set_Last
(List
, Empty
);
551 end Insert_List_After
;
553 ------------------------
554 -- Insert_List_Before --
555 ------------------------
557 procedure Insert_List_Before
(Before
: Node_Or_Entity_Id
; List
: List_Id
) is
559 procedure Insert_List_Before_Debug
;
560 pragma Inline
(Insert_List_Before_Debug
);
561 -- Output debug information if Debug_Flag_N set
563 ------------------------------
564 -- Insert_List_Before_Debug --
565 ------------------------------
567 procedure Insert_List_Before_Debug
is
570 Write_Str
("Insert list ");
571 Write_Int
(Int
(List
));
572 Write_Str
(" before node ");
573 Write_Int
(Int
(Before
));
576 end Insert_List_Before_Debug
;
578 -- Start of processing for Insert_List_Before
581 pragma Assert
(Is_List_Member
(Before
));
583 if Is_Empty_List
(List
) then
588 After
: constant Node_Or_Entity_Id
:= Prev
(Before
);
589 LC
: constant List_Id
:= List_Containing
(Before
);
590 F
: constant Node_Or_Entity_Id
:= First
(List
);
591 L
: constant Node_Or_Entity_Id
:= Last
(List
);
592 N
: Node_Or_Entity_Id
;
595 pragma Debug
(Insert_List_Before_Debug
);
599 Set_List_Link
(N
, LC
);
604 if Present
(After
) then
610 Set_Prev
(Before
, L
);
612 Set_Next
(L
, Before
);
614 Set_First
(List
, Empty
);
615 Set_Last
(List
, Empty
);
618 end Insert_List_Before
;
624 function Is_Empty_List
(List
: List_Id
) return Boolean is
626 return First
(List
) = Empty
;
633 function Is_List_Member
(Node
: Node_Or_Entity_Id
) return Boolean is
635 return Nodes
.Table
(Node
).In_List
;
638 -----------------------
639 -- Is_Non_Empty_List --
640 -----------------------
642 function Is_Non_Empty_List
(List
: List_Id
) return Boolean is
644 return First
(List
) /= Empty
;
645 end Is_Non_Empty_List
;
651 function Last
(List
: List_Id
) return Node_Or_Entity_Id
is
653 pragma Assert
(List
<= Lists
.Last
);
654 return Lists
.Table
(List
).Last
;
661 function Last_List_Id
return List_Id
is
666 ---------------------
667 -- Last_Non_Pragma --
668 ---------------------
670 function Last_Non_Pragma
(List
: List_Id
) return Node_Or_Entity_Id
is
671 N
: constant Node_Or_Entity_Id
:= Last
(List
);
673 if Nkind
(N
) /= N_Pragma
then
676 return Prev_Non_Pragma
(N
);
680 ---------------------
681 -- List_Containing --
682 ---------------------
684 function List_Containing
(Node
: Node_Or_Entity_Id
) return List_Id
is
686 pragma Assert
(Is_List_Member
(Node
));
687 return List_Id
(Nodes
.Table
(Node
).Link
);
694 function List_Length
(List
: List_Id
) return Nat
is
696 Node
: Node_Or_Entity_Id
;
700 Node
:= First
(List
);
701 while Present
(Node
) loop
702 Result
:= Result
+ 1;
713 function Lists_Address
return System
.Address
is
715 return Lists
.Table
(First_List_Id
)'Address;
725 Lists
.Locked
:= True;
727 Prev_Node
.Locked
:= True;
729 Next_Node
.Locked
:= True;
736 procedure Lock_Lists
is
738 pragma Assert
(not Locked
);
746 function New_Copy_List
(List
: List_Id
) return List_Id
is
748 E
: Node_Or_Entity_Id
;
751 if List
= No_List
then
758 while Present
(E
) loop
759 Append
(New_Copy
(E
), NL
);
767 ----------------------------
768 -- New_Copy_List_Original --
769 ----------------------------
771 function New_Copy_List_Original
(List
: List_Id
) return List_Id
is
773 E
: Node_Or_Entity_Id
;
776 if List
= No_List
then
783 while Present
(E
) loop
784 if Comes_From_Source
(E
) then
785 Append
(New_Copy
(E
), NL
);
793 end New_Copy_List_Original
;
799 function New_List
return List_Id
is
801 procedure New_List_Debug
;
802 pragma Inline
(New_List_Debug
);
803 -- Output debugging information if Debug_Flag_N is set
809 procedure New_List_Debug
is
812 Write_Str
("Allocate new list, returned ID = ");
813 Write_Int
(Int
(Lists
.Last
));
818 -- Start of processing for New_List
821 Lists
.Increment_Last
;
824 List
: constant List_Id
:= Lists
.Last
;
827 Set_Parent
(List
, Empty
);
828 Set_First
(List
, Empty
);
829 Set_Last
(List
, Empty
);
831 pragma Debug
(New_List_Debug
);
836 -- Since the one argument case is common, we optimize to build the right
837 -- list directly, rather than first building an empty list and then doing
838 -- the insertion, which results in some unnecessary work.
840 function New_List
(Node
: Node_Or_Entity_Id
) return List_Id
is
842 procedure New_List_Debug
;
843 pragma Inline
(New_List_Debug
);
844 -- Output debugging information if Debug_Flag_N is set
850 procedure New_List_Debug
is
853 Write_Str
("Allocate new list, returned ID = ");
854 Write_Int
(Int
(Lists
.Last
));
859 -- Start of processing for New_List
866 pragma Assert
(not Is_List_Member
(Node
));
868 Lists
.Increment_Last
;
871 List
: constant List_Id
:= Lists
.Last
;
874 Set_Parent
(List
, Empty
);
875 Set_First
(List
, Node
);
876 Set_Last
(List
, Node
);
878 Nodes
.Table
(Node
).In_List
:= True;
879 Set_List_Link
(Node
, List
);
880 Set_Prev
(Node
, Empty
);
881 Set_Next
(Node
, Empty
);
882 pragma Debug
(New_List_Debug
);
889 (Node1
: Node_Or_Entity_Id
;
890 Node2
: Node_Or_Entity_Id
) return List_Id
892 L
: constant List_Id
:= New_List
(Node1
);
899 (Node1
: Node_Or_Entity_Id
;
900 Node2
: Node_Or_Entity_Id
;
901 Node3
: Node_Or_Entity_Id
) return List_Id
903 L
: constant List_Id
:= New_List
(Node1
);
911 (Node1
: Node_Or_Entity_Id
;
912 Node2
: Node_Or_Entity_Id
;
913 Node3
: Node_Or_Entity_Id
;
914 Node4
: Node_Or_Entity_Id
) return List_Id
916 L
: constant List_Id
:= New_List
(Node1
);
925 (Node1
: Node_Or_Entity_Id
;
926 Node2
: Node_Or_Entity_Id
;
927 Node3
: Node_Or_Entity_Id
;
928 Node4
: Node_Or_Entity_Id
;
929 Node5
: Node_Or_Entity_Id
) return List_Id
931 L
: constant List_Id
:= New_List
(Node1
);
941 (Node1
: Node_Or_Entity_Id
;
942 Node2
: Node_Or_Entity_Id
;
943 Node3
: Node_Or_Entity_Id
;
944 Node4
: Node_Or_Entity_Id
;
945 Node5
: Node_Or_Entity_Id
;
946 Node6
: Node_Or_Entity_Id
) return List_Id
948 L
: constant List_Id
:= New_List
(Node1
);
962 function Next
(Node
: Node_Or_Entity_Id
) return Node_Or_Entity_Id
is
964 pragma Assert
(Is_List_Member
(Node
));
965 return Next_Node
.Table
(Node
);
968 procedure Next
(Node
: in out Node_Or_Entity_Id
) is
973 -----------------------
974 -- Next_Node_Address --
975 -----------------------
977 function Next_Node_Address
return System
.Address
is
979 return Next_Node
.Table
(First_Node_Id
)'Address;
980 end Next_Node_Address
;
982 ---------------------
983 -- Next_Non_Pragma --
984 ---------------------
986 function Next_Non_Pragma
987 (Node
: Node_Or_Entity_Id
) return Node_Or_Entity_Id
989 N
: Node_Or_Entity_Id
;
995 exit when not Nkind_In
(N
, N_Pragma
, N_Null_Statement
);
1001 procedure Next_Non_Pragma
(Node
: in out Node_Or_Entity_Id
) is
1003 Node
:= Next_Non_Pragma
(Node
);
1004 end Next_Non_Pragma
;
1010 function No
(List
: List_Id
) return Boolean is
1012 return List
= No_List
;
1019 function Num_Lists
return Nat
is
1021 return Int
(Lists
.Last
) - Int
(Lists
.First
) + 1;
1028 function Parent
(List
: List_Id
) return Node_Or_Entity_Id
is
1030 pragma Assert
(List
<= Lists
.Last
);
1031 return Lists
.Table
(List
).Parent
;
1038 function Pick
(List
: List_Id
; Index
: Pos
) return Node_Or_Entity_Id
is
1039 Elmt
: Node_Or_Entity_Id
;
1042 Elmt
:= First
(List
);
1043 for J
in 1 .. Index
- 1 loop
1044 Elmt
:= Next
(Elmt
);
1054 procedure Prepend
(Node
: Node_Or_Entity_Id
; To
: List_Id
) is
1055 F
: constant Node_Or_Entity_Id
:= First
(To
);
1057 procedure Prepend_Debug
;
1058 pragma Inline
(Prepend_Debug
);
1059 -- Output debug information if Debug_Flag_N set
1065 procedure Prepend_Debug
is
1067 if Debug_Flag_N
then
1068 Write_Str
("Prepend node ");
1069 Write_Int
(Int
(Node
));
1070 Write_Str
(" to list ");
1071 Write_Int
(Int
(To
));
1076 -- Start of processing for Prepend_Debug
1079 pragma Assert
(not Is_List_Member
(Node
));
1081 if Node
= Error
then
1085 pragma Debug
(Prepend_Debug
);
1088 Set_Last
(To
, Node
);
1093 Set_First
(To
, Node
);
1095 Nodes
.Table
(Node
).In_List
:= True;
1098 Set_Prev
(Node
, Empty
);
1099 Set_List_Link
(Node
, To
);
1106 procedure Prepend_List
(List
: List_Id
; To
: List_Id
) is
1108 procedure Prepend_List_Debug
;
1109 pragma Inline
(Prepend_List_Debug
);
1110 -- Output debug information if Debug_Flag_N set
1112 ------------------------
1113 -- Prepend_List_Debug --
1114 ------------------------
1116 procedure Prepend_List_Debug
is
1118 if Debug_Flag_N
then
1119 Write_Str
("Prepend list ");
1120 Write_Int
(Int
(List
));
1121 Write_Str
(" to list ");
1122 Write_Int
(Int
(To
));
1125 end Prepend_List_Debug
;
1127 -- Start of processing for Prepend_List
1130 if Is_Empty_List
(List
) then
1135 F
: constant Node_Or_Entity_Id
:= First
(To
);
1136 L
: constant Node_Or_Entity_Id
:= Last
(List
);
1137 N
: Node_Or_Entity_Id
;
1140 pragma Debug
(Prepend_List_Debug
);
1144 Set_List_Link
(N
, To
);
1156 Set_First
(To
, First
(List
));
1158 Set_First
(List
, Empty
);
1159 Set_Last
(List
, Empty
);
1164 ---------------------
1165 -- Prepend_List_To --
1166 ---------------------
1168 procedure Prepend_List_To
(To
: List_Id
; List
: List_Id
) is
1170 Prepend_List
(List
, To
);
1171 end Prepend_List_To
;
1177 procedure Prepend_New
(Node
: Node_Or_Entity_Id
; To
: in out List_Id
) is
1186 --------------------
1187 -- Prepend_New_To --
1188 --------------------
1190 procedure Prepend_New_To
(To
: in out List_Id
; Node
: Node_Or_Entity_Id
) is
1192 Prepend_New
(Node
, To
);
1199 procedure Prepend_To
(To
: List_Id
; Node
: Node_Or_Entity_Id
) is
1208 function Present
(List
: List_Id
) return Boolean is
1210 return List
/= No_List
;
1217 function Prev
(Node
: Node_Or_Entity_Id
) return Node_Or_Entity_Id
is
1219 pragma Assert
(Is_List_Member
(Node
));
1220 return Prev_Node
.Table
(Node
);
1223 procedure Prev
(Node
: in out Node_Or_Entity_Id
) is
1225 Node
:= Prev
(Node
);
1228 -----------------------
1229 -- Prev_Node_Address --
1230 -----------------------
1232 function Prev_Node_Address
return System
.Address
is
1234 return Prev_Node
.Table
(First_Node_Id
)'Address;
1235 end Prev_Node_Address
;
1237 ---------------------
1238 -- Prev_Non_Pragma --
1239 ---------------------
1241 function Prev_Non_Pragma
1242 (Node
: Node_Or_Entity_Id
) return Node_Or_Entity_Id
1244 N
: Node_Or_Entity_Id
;
1250 exit when Nkind
(N
) /= N_Pragma
;
1254 end Prev_Non_Pragma
;
1256 procedure Prev_Non_Pragma
(Node
: in out Node_Or_Entity_Id
) is
1258 Node
:= Prev_Non_Pragma
(Node
);
1259 end Prev_Non_Pragma
;
1265 procedure Remove
(Node
: Node_Or_Entity_Id
) is
1266 Lst
: constant List_Id
:= List_Containing
(Node
);
1267 Prv
: constant Node_Or_Entity_Id
:= Prev
(Node
);
1268 Nxt
: constant Node_Or_Entity_Id
:= Next
(Node
);
1270 procedure Remove_Debug
;
1271 pragma Inline
(Remove_Debug
);
1272 -- Output debug information if Debug_Flag_N set
1278 procedure Remove_Debug
is
1280 if Debug_Flag_N
then
1281 Write_Str
("Remove node ");
1282 Write_Int
(Int
(Node
));
1287 -- Start of processing for Remove
1290 pragma Debug
(Remove_Debug
);
1293 Set_First
(Lst
, Nxt
);
1295 Set_Next
(Prv
, Nxt
);
1299 Set_Last
(Lst
, Prv
);
1301 Set_Prev
(Nxt
, Prv
);
1304 Nodes
.Table
(Node
).In_List
:= False;
1305 Set_Parent
(Node
, Empty
);
1312 function Remove_Head
(List
: List_Id
) return Node_Or_Entity_Id
is
1313 Frst
: constant Node_Or_Entity_Id
:= First
(List
);
1315 procedure Remove_Head_Debug
;
1316 pragma Inline
(Remove_Head_Debug
);
1317 -- Output debug information if Debug_Flag_N set
1319 -----------------------
1320 -- Remove_Head_Debug --
1321 -----------------------
1323 procedure Remove_Head_Debug
is
1325 if Debug_Flag_N
then
1326 Write_Str
("Remove head of list ");
1327 Write_Int
(Int
(List
));
1330 end Remove_Head_Debug
;
1332 -- Start of processing for Remove_Head
1335 pragma Debug
(Remove_Head_Debug
);
1337 if Frst
= Empty
then
1342 Nxt
: constant Node_Or_Entity_Id
:= Next
(Frst
);
1345 Set_First
(List
, Nxt
);
1348 Set_Last
(List
, Empty
);
1350 Set_Prev
(Nxt
, Empty
);
1353 Nodes
.Table
(Frst
).In_List
:= False;
1354 Set_Parent
(Frst
, Empty
);
1364 function Remove_Next
1365 (Node
: Node_Or_Entity_Id
) return Node_Or_Entity_Id
1367 Nxt
: constant Node_Or_Entity_Id
:= Next
(Node
);
1369 procedure Remove_Next_Debug
;
1370 pragma Inline
(Remove_Next_Debug
);
1371 -- Output debug information if Debug_Flag_N set
1373 -----------------------
1374 -- Remove_Next_Debug --
1375 -----------------------
1377 procedure Remove_Next_Debug
is
1379 if Debug_Flag_N
then
1380 Write_Str
("Remove next node after ");
1381 Write_Int
(Int
(Node
));
1384 end Remove_Next_Debug
;
1386 -- Start of processing for Remove_Next
1389 if Present
(Nxt
) then
1391 Nxt2
: constant Node_Or_Entity_Id
:= Next
(Nxt
);
1392 LC
: constant List_Id
:= List_Containing
(Node
);
1395 pragma Debug
(Remove_Next_Debug
);
1396 Set_Next
(Node
, Nxt2
);
1399 Set_Last
(LC
, Node
);
1401 Set_Prev
(Nxt2
, Node
);
1404 Nodes
.Table
(Nxt
).In_List
:= False;
1405 Set_Parent
(Nxt
, Empty
);
1416 procedure Set_First
(List
: List_Id
; To
: Node_Or_Entity_Id
) is
1418 pragma Assert
(not Locked
);
1419 Lists
.Table
(List
).First
:= To
;
1426 procedure Set_Last
(List
: List_Id
; To
: Node_Or_Entity_Id
) is
1428 pragma Assert
(not Locked
);
1429 Lists
.Table
(List
).Last
:= To
;
1436 procedure Set_List_Link
(Node
: Node_Or_Entity_Id
; To
: List_Id
) is
1438 pragma Assert
(not Locked
);
1439 Nodes
.Table
(Node
).Link
:= Union_Id
(To
);
1446 procedure Set_Next
(Node
: Node_Or_Entity_Id
; To
: Node_Or_Entity_Id
) is
1448 pragma Assert
(not Locked
);
1449 Next_Node
.Table
(Node
) := To
;
1456 procedure Set_Parent
(List
: List_Id
; Node
: Node_Or_Entity_Id
) is
1458 pragma Assert
(not Locked
);
1459 pragma Assert
(List
<= Lists
.Last
);
1460 Lists
.Table
(List
).Parent
:= Node
;
1467 procedure Set_Prev
(Node
: Node_Or_Entity_Id
; To
: Node_Or_Entity_Id
) is
1469 pragma Assert
(not Locked
);
1470 Prev_Node
.Table
(Node
) := To
;
1477 procedure Tree_Read
is
1479 pragma Assert
(not Locked
);
1481 Next_Node
.Tree_Read
;
1482 Prev_Node
.Tree_Read
;
1489 procedure Tree_Write
is
1492 Next_Node
.Tree_Write
;
1493 Prev_Node
.Tree_Write
;
1502 Lists
.Locked
:= False;
1503 Prev_Node
.Locked
:= False;
1504 Next_Node
.Locked
:= False;
1511 procedure Unlock_Lists
is
1513 pragma Assert
(Locked
);