builtins.def: (_Float<N> and _Float<N>X BUILT_IN_CEIL): Add _Float<N> and _Float...
[official-gcc.git] / gcc / ada / treepr.adb
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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- T R E E P R --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 1992-2017, 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. See the GNU General Public License --
17 -- for more details. You should have received a copy of the GNU General --
18 -- Public License distributed with GNAT; see file COPYING3. If not, go to --
19 -- http://www.gnu.org/licenses for a complete copy of the license. --
20 -- --
21 -- GNAT was originally developed by the GNAT team at New York University. --
22 -- Extensive contributions were provided by Ada Core Technologies Inc. --
23 -- --
24 ------------------------------------------------------------------------------
26 with Aspects; use Aspects;
27 with Atree; use Atree;
28 with Csets; use Csets;
29 with Debug; use Debug;
30 with Einfo; use Einfo;
31 with Elists; use Elists;
32 with Lib; use Lib;
33 with Namet; use Namet;
34 with Nlists; use Nlists;
35 with Output; use Output;
36 with Sem_Mech; use Sem_Mech;
37 with Sinfo; use Sinfo;
38 with Snames; use Snames;
39 with Sinput; use Sinput;
40 with Stand; use Stand;
41 with Stringt; use Stringt;
42 with SCIL_LL; use SCIL_LL;
43 with Treeprs; use Treeprs;
44 with Uintp; use Uintp;
45 with Urealp; use Urealp;
46 with Uname; use Uname;
47 with Unchecked_Deallocation;
49 package body Treepr is
51 use Atree.Unchecked_Access;
52 -- This module uses the unchecked access functions in package Atree
53 -- since it does an untyped traversal of the tree (we do not want to
54 -- count on the structure of the tree being correct in this routine).
56 ----------------------------------
57 -- Approach Used for Tree Print --
58 ----------------------------------
60 -- When a complete subtree is being printed, a trace phase first marks
61 -- the nodes and lists to be printed. This trace phase allocates logical
62 -- numbers corresponding to the order in which the nodes and lists will
63 -- be printed. The Node_Id, List_Id and Elist_Id values are mapped to
64 -- logical node numbers using a hash table. Output is done using a set
65 -- of Print_xxx routines, which are similar to the Write_xxx routines
66 -- with the same name, except that they do not generate any output in
67 -- the marking phase. This allows identical logic to be used in the
68 -- two phases.
70 -- Note that the hash table not only holds the serial numbers, but also
71 -- acts as a record of which nodes have already been visited. In the
72 -- marking phase, a node has been visited if it is already in the hash
73 -- table, and in the printing phase, we can tell whether a node has
74 -- already been printed by looking at the value of the serial number.
76 ----------------------
77 -- Global Variables --
78 ----------------------
80 type Hash_Record is record
81 Serial : Nat;
82 -- Serial number for hash table entry. A value of zero means that
83 -- the entry is currently unused.
85 Id : Int;
86 -- If serial number field is non-zero, contains corresponding Id value
87 end record;
89 type Hash_Table_Type is array (Nat range <>) of Hash_Record;
90 type Access_Hash_Table_Type is access Hash_Table_Type;
91 Hash_Table : Access_Hash_Table_Type;
92 -- The hash table itself, see Serial_Number function for details of use
94 Hash_Table_Len : Nat;
95 -- Range of Hash_Table is from 0 .. Hash_Table_Len - 1 so that dividing
96 -- by Hash_Table_Len gives a remainder that is in Hash_Table'Range.
98 Next_Serial_Number : Nat;
99 -- Number of last visited node or list. Used during the marking phase to
100 -- set proper node numbers in the hash table, and during the printing
101 -- phase to make sure that a given node is not printed more than once.
102 -- (nodes are printed in order during the printing phase, that's the
103 -- point of numbering them in the first place).
105 Printing_Descendants : Boolean;
106 -- True if descendants are being printed, False if not. In the false case,
107 -- only node Id's are printed. In the true case, node numbers as well as
108 -- node Id's are printed, as described above.
110 type Phase_Type is (Marking, Printing);
111 -- Type for Phase variable
113 Phase : Phase_Type;
114 -- When an entire tree is being printed, the traversal operates in two
115 -- phases. The first phase marks the nodes in use by installing node
116 -- numbers in the node number table. The second phase prints the nodes.
117 -- This variable indicates the current phase.
119 ----------------------
120 -- Local Procedures --
121 ----------------------
123 procedure Print_End_Span (N : Node_Id);
124 -- Special routine to print contents of End_Span field of node N.
125 -- The format includes the implicit source location as well as the
126 -- value of the field.
128 procedure Print_Init;
129 -- Initialize for printing of tree with descendants
131 procedure Print_Term;
132 -- Clean up after printing of tree with descendants
134 procedure Print_Char (C : Character);
135 -- Print character C if currently in print phase, noop if in marking phase
137 procedure Print_Name (N : Name_Id);
138 -- Print name from names table if currently in print phase, noop if in
139 -- marking phase. Note that the name is output in mixed case mode.
141 procedure Print_Node_Header (N : Node_Id);
142 -- Print header line used by Print_Node and Print_Node_Briefly
144 procedure Print_Node_Kind (N : Node_Id);
145 -- Print node kind name in mixed case if in print phase, noop if in
146 -- marking phase.
148 procedure Print_Str (S : String);
149 -- Print string S if currently in print phase, noop if in marking phase
151 procedure Print_Str_Mixed_Case (S : String);
152 -- Like Print_Str, except that the string is printed in mixed case mode
154 procedure Print_Int (I : Int);
155 -- Print integer I if currently in print phase, noop if in marking phase
157 procedure Print_Eol;
158 -- Print end of line if currently in print phase, noop if in marking phase
160 procedure Print_Node_Ref (N : Node_Id);
161 -- Print "<empty>", "<error>" or "Node #nnn" with additional information
162 -- in the latter case, including the Id and the Nkind of the node.
164 procedure Print_List_Ref (L : List_Id);
165 -- Print "<no list>", or "<empty node list>" or "Node list #nnn"
167 procedure Print_Elist_Ref (E : Elist_Id);
168 -- Print "<no elist>", or "<empty element list>" or "Element list #nnn"
170 procedure Print_Entity_Info (Ent : Entity_Id; Prefix : String);
171 -- Called if the node being printed is an entity. Prints fields from the
172 -- extension, using routines in Einfo to get the field names and flags.
174 procedure Print_Field (Val : Union_Id; Format : UI_Format := Auto);
175 -- Print representation of Field value (name, tree, string, uint, charcode)
176 -- The format parameter controls the format of printing in the case of an
177 -- integer value (see UI_Write for details).
179 procedure Print_Flag (F : Boolean);
180 -- Print True or False
182 procedure Print_Node
183 (N : Node_Id;
184 Prefix_Str : String;
185 Prefix_Char : Character);
186 -- This is the internal routine used to print a single node. Each line of
187 -- output is preceded by Prefix_Str (which is used to set the indentation
188 -- level and the bars used to link list elements). In addition, for lines
189 -- other than the first, an additional character Prefix_Char is output.
191 function Serial_Number (Id : Int) return Nat;
192 -- Given a Node_Id, List_Id or Elist_Id, returns the previously assigned
193 -- serial number, or zero if no serial number has yet been assigned.
195 procedure Set_Serial_Number;
196 -- Can be called only immediately following a call to Serial_Number that
197 -- returned a value of zero. Causes the value of Next_Serial_Number to be
198 -- placed in the hash table (corresponding to the Id argument used in the
199 -- Serial_Number call), and increments Next_Serial_Number.
201 procedure Visit_Node
202 (N : Node_Id;
203 Prefix_Str : String;
204 Prefix_Char : Character);
205 -- Called to process a single node in the case where descendants are to
206 -- be printed before every line, and Prefix_Char added to all lines
207 -- except the header line for the node.
209 procedure Visit_List (L : List_Id; Prefix_Str : String);
210 -- Visit_List is called to process a list in the case where descendants
211 -- are to be printed. Prefix_Str is to be added to all printed lines.
213 procedure Visit_Elist (E : Elist_Id; Prefix_Str : String);
214 -- Visit_Elist is called to process an element list in the case where
215 -- descendants are to be printed. Prefix_Str is to be added to all
216 -- printed lines.
218 -------
219 -- p --
220 -------
222 function p (N : Union_Id) return Node_Or_Entity_Id is
223 begin
224 case N is
225 when List_Low_Bound .. List_High_Bound - 1 =>
226 return Nlists.Parent (List_Id (N));
228 when Node_Range =>
229 return Atree.Parent (Node_Or_Entity_Id (N));
231 when others =>
232 Write_Int (Int (N));
233 Write_Str (" is not a Node_Id or List_Id value");
234 Write_Eol;
235 return Empty;
236 end case;
237 end p;
239 ---------
240 -- par --
241 ---------
243 function par (N : Union_Id) return Node_Or_Entity_Id renames p;
245 --------
246 -- pe --
247 --------
249 procedure pe (N : Union_Id) renames pn;
251 --------
252 -- pl --
253 --------
255 procedure pl (L : Int) is
256 Lid : Int;
258 begin
259 if L < 0 then
260 Lid := L;
262 -- This is the case where we transform e.g. +36 to -99999936
264 else
265 if L <= 9 then
266 Lid := -(99999990 + L);
267 elsif L <= 99 then
268 Lid := -(99999900 + L);
269 elsif L <= 999 then
270 Lid := -(99999000 + L);
271 elsif L <= 9999 then
272 Lid := -(99990000 + L);
273 elsif L <= 99999 then
274 Lid := -(99900000 + L);
275 elsif L <= 999999 then
276 Lid := -(99000000 + L);
277 elsif L <= 9999999 then
278 Lid := -(90000000 + L);
279 else
280 Lid := -L;
281 end if;
282 end if;
284 -- Now output the list
286 Print_Tree_List (List_Id (Lid));
287 end pl;
289 --------
290 -- pn --
291 --------
293 procedure pn (N : Union_Id) is
294 begin
295 case N is
296 when List_Low_Bound .. List_High_Bound - 1 =>
297 pl (Int (N));
298 when Node_Range =>
299 Print_Tree_Node (Node_Id (N));
300 when Elist_Range =>
301 Print_Tree_Elist (Elist_Id (N));
302 when Elmt_Range =>
303 declare
304 Id : constant Elmt_Id := Elmt_Id (N);
305 begin
306 if No (Id) then
307 Write_Str ("No_Elmt");
308 Write_Eol;
309 else
310 Write_Str ("Elmt_Id --> ");
311 Print_Tree_Node (Node (Id));
312 end if;
313 end;
314 when Names_Range =>
315 Namet.wn (Name_Id (N));
316 when Strings_Range =>
317 Write_String_Table_Entry (String_Id (N));
318 when Uint_Range =>
319 Uintp.pid (From_Union (N));
320 when Ureal_Range =>
321 Urealp.pr (From_Union (N));
322 when others =>
323 Write_Str ("Invalid Union_Id: ");
324 Write_Int (Int (N));
325 Write_Eol;
326 end case;
327 end pn;
329 --------
330 -- pp --
331 --------
333 procedure pp (N : Union_Id) renames pn;
335 ---------
336 -- ppp --
337 ---------
339 procedure ppp (N : Union_Id) renames pt;
341 ----------------
342 -- Print_Char --
343 ----------------
345 procedure Print_Char (C : Character) is
346 begin
347 if Phase = Printing then
348 Write_Char (C);
349 end if;
350 end Print_Char;
352 ---------------------
353 -- Print_Elist_Ref --
354 ---------------------
356 procedure Print_Elist_Ref (E : Elist_Id) is
357 begin
358 if Phase /= Printing then
359 return;
360 end if;
362 if E = No_Elist then
363 Write_Str ("<no elist>");
365 elsif Is_Empty_Elmt_List (E) then
366 Write_Str ("Empty elist, (Elist_Id=");
367 Write_Int (Int (E));
368 Write_Char (')');
370 else
371 Write_Str ("(Elist_Id=");
372 Write_Int (Int (E));
373 Write_Char (')');
375 if Printing_Descendants then
376 Write_Str (" #");
377 Write_Int (Serial_Number (Int (E)));
378 end if;
379 end if;
380 end Print_Elist_Ref;
382 -------------------------
383 -- Print_Elist_Subtree --
384 -------------------------
386 procedure Print_Elist_Subtree (E : Elist_Id) is
387 begin
388 Print_Init;
390 Next_Serial_Number := 1;
391 Phase := Marking;
392 Visit_Elist (E, "");
394 Next_Serial_Number := 1;
395 Phase := Printing;
396 Visit_Elist (E, "");
398 Print_Term;
399 end Print_Elist_Subtree;
401 --------------------
402 -- Print_End_Span --
403 --------------------
405 procedure Print_End_Span (N : Node_Id) is
406 Val : constant Uint := End_Span (N);
408 begin
409 UI_Write (Val);
410 Write_Str (" (Uint = ");
411 Write_Int (Int (Field5 (N)));
412 Write_Str (") ");
414 if Val /= No_Uint then
415 Write_Location (End_Location (N));
416 end if;
417 end Print_End_Span;
419 -----------------------
420 -- Print_Entity_Info --
421 -----------------------
423 procedure Print_Entity_Info (Ent : Entity_Id; Prefix : String) is
424 function Field_Present (U : Union_Id) return Boolean;
425 -- Returns False unless the value U represents a missing value
426 -- (Empty, No_Elist, No_Uint, No_Ureal or No_String)
428 function Field_Present (U : Union_Id) return Boolean is
429 begin
430 return
431 U /= Union_Id (Empty) and then
432 U /= Union_Id (No_Elist) and then
433 U /= To_Union (No_Uint) and then
434 U /= To_Union (No_Ureal) and then
435 U /= Union_Id (No_String);
436 end Field_Present;
438 -- Start of processing for Print_Entity_Info
440 begin
441 Print_Str (Prefix);
442 Print_Str ("Ekind = ");
443 Print_Str_Mixed_Case (Entity_Kind'Image (Ekind (Ent)));
444 Print_Eol;
446 Print_Str (Prefix);
447 Print_Str ("Etype = ");
448 Print_Node_Ref (Etype (Ent));
449 Print_Eol;
451 if Convention (Ent) /= Convention_Ada then
452 Print_Str (Prefix);
453 Print_Str ("Convention = ");
455 -- Print convention name skipping the Convention_ at the start
457 declare
458 S : constant String := Convention_Id'Image (Convention (Ent));
460 begin
461 Print_Str_Mixed_Case (S (12 .. S'Last));
462 Print_Eol;
463 end;
464 end if;
466 if Field_Present (Field6 (Ent)) then
467 Print_Str (Prefix);
468 Write_Field6_Name (Ent);
469 Write_Str (" = ");
470 Print_Field (Field6 (Ent));
471 Print_Eol;
472 end if;
474 if Field_Present (Field7 (Ent)) then
475 Print_Str (Prefix);
476 Write_Field7_Name (Ent);
477 Write_Str (" = ");
478 Print_Field (Field7 (Ent));
479 Print_Eol;
480 end if;
482 if Field_Present (Field8 (Ent)) then
483 Print_Str (Prefix);
484 Write_Field8_Name (Ent);
485 Write_Str (" = ");
486 Print_Field (Field8 (Ent));
487 Print_Eol;
488 end if;
490 if Field_Present (Field9 (Ent)) then
491 Print_Str (Prefix);
492 Write_Field9_Name (Ent);
493 Write_Str (" = ");
494 Print_Field (Field9 (Ent));
495 Print_Eol;
496 end if;
498 if Field_Present (Field10 (Ent)) then
499 Print_Str (Prefix);
500 Write_Field10_Name (Ent);
501 Write_Str (" = ");
502 Print_Field (Field10 (Ent));
503 Print_Eol;
504 end if;
506 if Field_Present (Field11 (Ent)) then
507 Print_Str (Prefix);
508 Write_Field11_Name (Ent);
509 Write_Str (" = ");
510 Print_Field (Field11 (Ent));
511 Print_Eol;
512 end if;
514 if Field_Present (Field12 (Ent)) then
515 Print_Str (Prefix);
516 Write_Field12_Name (Ent);
517 Write_Str (" = ");
518 Print_Field (Field12 (Ent));
519 Print_Eol;
520 end if;
522 if Field_Present (Field13 (Ent)) then
523 Print_Str (Prefix);
524 Write_Field13_Name (Ent);
525 Write_Str (" = ");
526 Print_Field (Field13 (Ent));
527 Print_Eol;
528 end if;
530 if Field_Present (Field14 (Ent)) then
531 Print_Str (Prefix);
532 Write_Field14_Name (Ent);
533 Write_Str (" = ");
534 Print_Field (Field14 (Ent));
535 Print_Eol;
536 end if;
538 if Field_Present (Field15 (Ent)) then
539 Print_Str (Prefix);
540 Write_Field15_Name (Ent);
541 Write_Str (" = ");
542 Print_Field (Field15 (Ent));
543 Print_Eol;
544 end if;
546 if Field_Present (Field16 (Ent)) then
547 Print_Str (Prefix);
548 Write_Field16_Name (Ent);
549 Write_Str (" = ");
550 Print_Field (Field16 (Ent));
551 Print_Eol;
552 end if;
554 if Field_Present (Field17 (Ent)) then
555 Print_Str (Prefix);
556 Write_Field17_Name (Ent);
557 Write_Str (" = ");
558 Print_Field (Field17 (Ent));
559 Print_Eol;
560 end if;
562 if Field_Present (Field18 (Ent)) then
563 Print_Str (Prefix);
564 Write_Field18_Name (Ent);
565 Write_Str (" = ");
566 Print_Field (Field18 (Ent));
567 Print_Eol;
568 end if;
570 if Field_Present (Field19 (Ent)) then
571 Print_Str (Prefix);
572 Write_Field19_Name (Ent);
573 Write_Str (" = ");
574 Print_Field (Field19 (Ent));
575 Print_Eol;
576 end if;
578 if Field_Present (Field20 (Ent)) then
579 Print_Str (Prefix);
580 Write_Field20_Name (Ent);
581 Write_Str (" = ");
582 Print_Field (Field20 (Ent));
583 Print_Eol;
584 end if;
586 if Field_Present (Field21 (Ent)) then
587 Print_Str (Prefix);
588 Write_Field21_Name (Ent);
589 Write_Str (" = ");
590 Print_Field (Field21 (Ent));
591 Print_Eol;
592 end if;
594 if Field_Present (Field22 (Ent)) then
595 Print_Str (Prefix);
596 Write_Field22_Name (Ent);
597 Write_Str (" = ");
599 -- Mechanism case has to be handled specially
601 if Ekind (Ent) = E_Function or else Is_Formal (Ent) then
602 declare
603 M : constant Mechanism_Type := Mechanism (Ent);
605 begin
606 case M is
607 when Default_Mechanism =>
608 Write_Str ("Default");
610 when By_Copy =>
611 Write_Str ("By_Copy");
613 when By_Reference =>
614 Write_Str ("By_Reference");
616 when 1 .. Mechanism_Type'Last =>
617 Write_Str ("By_Copy if size <= ");
618 Write_Int (Int (M));
619 end case;
620 end;
622 -- Normal case (not Mechanism)
624 else
625 Print_Field (Field22 (Ent));
626 end if;
628 Print_Eol;
629 end if;
631 if Field_Present (Field23 (Ent)) then
632 Print_Str (Prefix);
633 Write_Field23_Name (Ent);
634 Write_Str (" = ");
635 Print_Field (Field23 (Ent));
636 Print_Eol;
637 end if;
639 if Field_Present (Field24 (Ent)) then
640 Print_Str (Prefix);
641 Write_Field24_Name (Ent);
642 Write_Str (" = ");
643 Print_Field (Field24 (Ent));
644 Print_Eol;
645 end if;
647 if Field_Present (Field25 (Ent)) then
648 Print_Str (Prefix);
649 Write_Field25_Name (Ent);
650 Write_Str (" = ");
651 Print_Field (Field25 (Ent));
652 Print_Eol;
653 end if;
655 if Field_Present (Field26 (Ent)) then
656 Print_Str (Prefix);
657 Write_Field26_Name (Ent);
658 Write_Str (" = ");
659 Print_Field (Field26 (Ent));
660 Print_Eol;
661 end if;
663 if Field_Present (Field27 (Ent)) then
664 Print_Str (Prefix);
665 Write_Field27_Name (Ent);
666 Write_Str (" = ");
667 Print_Field (Field27 (Ent));
668 Print_Eol;
669 end if;
671 if Field_Present (Field28 (Ent)) then
672 Print_Str (Prefix);
673 Write_Field28_Name (Ent);
674 Write_Str (" = ");
675 Print_Field (Field28 (Ent));
676 Print_Eol;
677 end if;
679 if Field_Present (Field29 (Ent)) then
680 Print_Str (Prefix);
681 Write_Field29_Name (Ent);
682 Write_Str (" = ");
683 Print_Field (Field29 (Ent));
684 Print_Eol;
685 end if;
687 if Field_Present (Field30 (Ent)) then
688 Print_Str (Prefix);
689 Write_Field30_Name (Ent);
690 Write_Str (" = ");
691 Print_Field (Field30 (Ent));
692 Print_Eol;
693 end if;
695 if Field_Present (Field31 (Ent)) then
696 Print_Str (Prefix);
697 Write_Field31_Name (Ent);
698 Write_Str (" = ");
699 Print_Field (Field31 (Ent));
700 Print_Eol;
701 end if;
703 if Field_Present (Field32 (Ent)) then
704 Print_Str (Prefix);
705 Write_Field32_Name (Ent);
706 Write_Str (" = ");
707 Print_Field (Field32 (Ent));
708 Print_Eol;
709 end if;
711 if Field_Present (Field33 (Ent)) then
712 Print_Str (Prefix);
713 Write_Field33_Name (Ent);
714 Write_Str (" = ");
715 Print_Field (Field33 (Ent));
716 Print_Eol;
717 end if;
719 if Field_Present (Field34 (Ent)) then
720 Print_Str (Prefix);
721 Write_Field34_Name (Ent);
722 Write_Str (" = ");
723 Print_Field (Field34 (Ent));
724 Print_Eol;
725 end if;
727 if Field_Present (Field35 (Ent)) then
728 Print_Str (Prefix);
729 Write_Field35_Name (Ent);
730 Write_Str (" = ");
731 Print_Field (Field35 (Ent));
732 Print_Eol;
733 end if;
735 if Field_Present (Field36 (Ent)) then
736 Print_Str (Prefix);
737 Write_Field36_Name (Ent);
738 Write_Str (" = ");
739 Print_Field (Field36 (Ent));
740 Print_Eol;
741 end if;
743 if Field_Present (Field37 (Ent)) then
744 Print_Str (Prefix);
745 Write_Field37_Name (Ent);
746 Write_Str (" = ");
747 Print_Field (Field37 (Ent));
748 Print_Eol;
749 end if;
751 if Field_Present (Field38 (Ent)) then
752 Print_Str (Prefix);
753 Write_Field38_Name (Ent);
754 Write_Str (" = ");
755 Print_Field (Field38 (Ent));
756 Print_Eol;
757 end if;
759 if Field_Present (Field39 (Ent)) then
760 Print_Str (Prefix);
761 Write_Field39_Name (Ent);
762 Write_Str (" = ");
763 Print_Field (Field39 (Ent));
764 Print_Eol;
765 end if;
767 if Field_Present (Field40 (Ent)) then
768 Print_Str (Prefix);
769 Write_Field40_Name (Ent);
770 Write_Str (" = ");
771 Print_Field (Field40 (Ent));
772 Print_Eol;
773 end if;
775 if Field_Present (Field41 (Ent)) then
776 Print_Str (Prefix);
777 Write_Field41_Name (Ent);
778 Write_Str (" = ");
779 Print_Field (Field41 (Ent));
780 Print_Eol;
781 end if;
783 Write_Entity_Flags (Ent, Prefix);
784 end Print_Entity_Info;
786 ---------------
787 -- Print_Eol --
788 ---------------
790 procedure Print_Eol is
791 begin
792 if Phase = Printing then
793 Write_Eol;
794 end if;
795 end Print_Eol;
797 -----------------
798 -- Print_Field --
799 -----------------
801 procedure Print_Field (Val : Union_Id; Format : UI_Format := Auto) is
802 begin
803 if Phase /= Printing then
804 return;
805 end if;
807 if Val in Node_Range then
808 Print_Node_Ref (Node_Id (Val));
810 elsif Val in List_Range then
811 Print_List_Ref (List_Id (Val));
813 elsif Val in Elist_Range then
814 Print_Elist_Ref (Elist_Id (Val));
816 elsif Val in Names_Range then
817 Print_Name (Name_Id (Val));
818 Write_Str (" (Name_Id=");
819 Write_Int (Int (Val));
820 Write_Char (')');
822 elsif Val in Strings_Range then
823 Write_String_Table_Entry (String_Id (Val));
824 Write_Str (" (String_Id=");
825 Write_Int (Int (Val));
826 Write_Char (')');
828 elsif Val in Uint_Range then
829 UI_Write (From_Union (Val), Format);
830 Write_Str (" (Uint = ");
831 Write_Int (Int (Val));
832 Write_Char (')');
834 elsif Val in Ureal_Range then
835 UR_Write (From_Union (Val));
836 Write_Str (" (Ureal = ");
837 Write_Int (Int (Val));
838 Write_Char (')');
840 else
841 Print_Str ("****** Incorrect value = ");
842 Print_Int (Int (Val));
843 end if;
844 end Print_Field;
846 ----------------
847 -- Print_Flag --
848 ----------------
850 procedure Print_Flag (F : Boolean) is
851 begin
852 if F then
853 Print_Str ("True");
854 else
855 Print_Str ("False");
856 end if;
857 end Print_Flag;
859 ----------------
860 -- Print_Init --
861 ----------------
863 procedure Print_Init is
864 begin
865 Printing_Descendants := True;
866 Write_Eol;
868 -- Allocate and clear serial number hash table. The size is 150% of
869 -- the maximum possible number of entries, so that the hash table
870 -- cannot get significantly overloaded.
872 Hash_Table_Len := (150 * (Num_Nodes + Num_Lists + Num_Elists)) / 100;
873 Hash_Table := new Hash_Table_Type (0 .. Hash_Table_Len - 1);
875 for J in Hash_Table'Range loop
876 Hash_Table (J).Serial := 0;
877 end loop;
879 end Print_Init;
881 ---------------
882 -- Print_Int --
883 ---------------
885 procedure Print_Int (I : Int) is
886 begin
887 if Phase = Printing then
888 Write_Int (I);
889 end if;
890 end Print_Int;
892 --------------------
893 -- Print_List_Ref --
894 --------------------
896 procedure Print_List_Ref (L : List_Id) is
897 begin
898 if Phase /= Printing then
899 return;
900 end if;
902 if No (L) then
903 Write_Str ("<no list>");
905 elsif Is_Empty_List (L) then
906 Write_Str ("<empty list> (List_Id=");
907 Write_Int (Int (L));
908 Write_Char (')');
910 else
911 Write_Str ("List");
913 if Printing_Descendants then
914 Write_Str (" #");
915 Write_Int (Serial_Number (Int (L)));
916 end if;
918 Write_Str (" (List_Id=");
919 Write_Int (Int (L));
920 Write_Char (')');
921 end if;
922 end Print_List_Ref;
924 ------------------------
925 -- Print_List_Subtree --
926 ------------------------
928 procedure Print_List_Subtree (L : List_Id) is
929 begin
930 Print_Init;
932 Next_Serial_Number := 1;
933 Phase := Marking;
934 Visit_List (L, "");
936 Next_Serial_Number := 1;
937 Phase := Printing;
938 Visit_List (L, "");
940 Print_Term;
941 end Print_List_Subtree;
943 ----------------
944 -- Print_Name --
945 ----------------
947 procedure Print_Name (N : Name_Id) is
948 begin
949 if Phase = Printing then
950 if N = No_Name then
951 Print_Str ("<No_Name>");
953 elsif N = Error_Name then
954 Print_Str ("<Error_Name>");
956 elsif Is_Valid_Name (N) then
957 Get_Name_String (N);
958 Print_Char ('"');
959 Write_Name (N);
960 Print_Char ('"');
962 else
963 Print_Str ("<invalid name ???>");
964 end if;
965 end if;
966 end Print_Name;
968 ----------------
969 -- Print_Node --
970 ----------------
972 procedure Print_Node
973 (N : Node_Id;
974 Prefix_Str : String;
975 Prefix_Char : Character)
977 F : Fchar;
978 P : Natural;
980 Field_To_Be_Printed : Boolean;
981 Prefix_Str_Char : String (Prefix_Str'First .. Prefix_Str'Last + 1);
983 Sfile : Source_File_Index;
984 Fmt : UI_Format;
986 begin
987 if Phase /= Printing then
988 return;
989 end if;
991 -- If there is no such node, indicate that. Skip the rest, so we don't
992 -- crash getting fields of the nonexistent node.
994 if N > Atree_Private_Part.Nodes.Last then
995 Print_Str ("No such node: ");
996 Print_Int (Int (N));
997 Print_Eol;
998 return;
999 end if;
1001 Prefix_Str_Char (Prefix_Str'Range) := Prefix_Str;
1002 Prefix_Str_Char (Prefix_Str'Last + 1) := Prefix_Char;
1004 -- Print header line
1006 Print_Str (Prefix_Str);
1007 Print_Node_Header (N);
1009 if Is_Rewrite_Substitution (N) then
1010 Print_Str (Prefix_Str);
1011 Print_Str (" Rewritten: original node = ");
1012 Print_Node_Ref (Original_Node (N));
1013 Print_Eol;
1014 end if;
1016 if N = Empty then
1017 return;
1018 end if;
1020 if not Is_List_Member (N) then
1021 Print_Str (Prefix_Str);
1022 Print_Str (" Parent = ");
1023 Print_Node_Ref (Parent (N));
1024 Print_Eol;
1025 end if;
1027 -- Print Sloc field if it is set
1029 if Sloc (N) /= No_Location then
1030 Print_Str (Prefix_Str_Char);
1031 Print_Str ("Sloc = ");
1033 if Sloc (N) = Standard_Location then
1034 Print_Str ("Standard_Location");
1036 elsif Sloc (N) = Standard_ASCII_Location then
1037 Print_Str ("Standard_ASCII_Location");
1039 else
1040 Sfile := Get_Source_File_Index (Sloc (N));
1041 Print_Int (Int (Sloc (N)) - Int (Source_Text (Sfile)'First));
1042 Write_Str (" ");
1043 Write_Location (Sloc (N));
1044 end if;
1046 Print_Eol;
1047 end if;
1049 -- Print Chars field if present
1051 if Nkind (N) in N_Has_Chars and then Chars (N) /= No_Name then
1052 Print_Str (Prefix_Str_Char);
1053 Print_Str ("Chars = ");
1054 Print_Name (Chars (N));
1055 Write_Str (" (Name_Id=");
1056 Write_Int (Int (Chars (N)));
1057 Write_Char (')');
1058 Print_Eol;
1059 end if;
1061 -- Special field print operations for non-entity nodes
1063 if Nkind (N) not in N_Entity then
1065 -- Deal with Left_Opnd and Right_Opnd fields
1067 if Nkind (N) in N_Op
1068 or else Nkind (N) in N_Short_Circuit
1069 or else Nkind (N) in N_Membership_Test
1070 then
1071 -- Print Left_Opnd if present
1073 if Nkind (N) not in N_Unary_Op then
1074 Print_Str (Prefix_Str_Char);
1075 Print_Str ("Left_Opnd = ");
1076 Print_Node_Ref (Left_Opnd (N));
1077 Print_Eol;
1078 end if;
1080 -- Print Right_Opnd
1082 Print_Str (Prefix_Str_Char);
1083 Print_Str ("Right_Opnd = ");
1084 Print_Node_Ref (Right_Opnd (N));
1085 Print_Eol;
1086 end if;
1088 -- Print Entity field if operator (other cases of Entity
1089 -- are in the table, so are handled in the normal circuit)
1091 if Nkind (N) in N_Op and then Present (Entity (N)) then
1092 Print_Str (Prefix_Str_Char);
1093 Print_Str ("Entity = ");
1094 Print_Node_Ref (Entity (N));
1095 Print_Eol;
1096 end if;
1098 -- Print special fields if we have a subexpression
1100 if Nkind (N) in N_Subexpr then
1102 if Assignment_OK (N) then
1103 Print_Str (Prefix_Str_Char);
1104 Print_Str ("Assignment_OK = True");
1105 Print_Eol;
1106 end if;
1108 if Do_Range_Check (N) then
1109 Print_Str (Prefix_Str_Char);
1110 Print_Str ("Do_Range_Check = True");
1111 Print_Eol;
1112 end if;
1114 if Has_Dynamic_Length_Check (N) then
1115 Print_Str (Prefix_Str_Char);
1116 Print_Str ("Has_Dynamic_Length_Check = True");
1117 Print_Eol;
1118 end if;
1120 if Has_Aspects (N) then
1121 Print_Str (Prefix_Str_Char);
1122 Print_Str ("Has_Aspects = True");
1123 Print_Eol;
1124 end if;
1126 if Has_Dynamic_Range_Check (N) then
1127 Print_Str (Prefix_Str_Char);
1128 Print_Str ("Has_Dynamic_Range_Check = True");
1129 Print_Eol;
1130 end if;
1132 if Is_Controlling_Actual (N) then
1133 Print_Str (Prefix_Str_Char);
1134 Print_Str ("Is_Controlling_Actual = True");
1135 Print_Eol;
1136 end if;
1138 if Is_Overloaded (N) then
1139 Print_Str (Prefix_Str_Char);
1140 Print_Str ("Is_Overloaded = True");
1141 Print_Eol;
1142 end if;
1144 if Is_Static_Expression (N) then
1145 Print_Str (Prefix_Str_Char);
1146 Print_Str ("Is_Static_Expression = True");
1147 Print_Eol;
1148 end if;
1150 if Must_Not_Freeze (N) then
1151 Print_Str (Prefix_Str_Char);
1152 Print_Str ("Must_Not_Freeze = True");
1153 Print_Eol;
1154 end if;
1156 if Paren_Count (N) /= 0 then
1157 Print_Str (Prefix_Str_Char);
1158 Print_Str ("Paren_Count = ");
1159 Print_Int (Int (Paren_Count (N)));
1160 Print_Eol;
1161 end if;
1163 if Raises_Constraint_Error (N) then
1164 Print_Str (Prefix_Str_Char);
1165 Print_Str ("Raise_Constraint_Error = True");
1166 Print_Eol;
1167 end if;
1169 end if;
1171 -- Print Do_Overflow_Check field if present
1173 if Nkind (N) in N_Op and then Do_Overflow_Check (N) then
1174 Print_Str (Prefix_Str_Char);
1175 Print_Str ("Do_Overflow_Check = True");
1176 Print_Eol;
1177 end if;
1179 -- Print Etype field if present (printing of this field for entities
1180 -- is handled by the Print_Entity_Info procedure).
1182 if Nkind (N) in N_Has_Etype and then Present (Etype (N)) then
1183 Print_Str (Prefix_Str_Char);
1184 Print_Str ("Etype = ");
1185 Print_Node_Ref (Etype (N));
1186 Print_Eol;
1187 end if;
1188 end if;
1190 -- Loop to print fields included in Pchars array
1192 P := Pchar_Pos (Nkind (N));
1194 if Nkind (N) = N_Integer_Literal and then Print_In_Hex (N) then
1195 Fmt := Hex;
1196 else
1197 Fmt := Auto;
1198 end if;
1200 while P < Pchar_Pos (Node_Kind'Succ (Nkind (N))) loop
1201 F := Pchars (P);
1202 P := P + 1;
1204 -- Check for case of False flag, which we never print, or an Empty
1205 -- field, which is also never printed.
1207 case F is
1208 when F_Field1 =>
1209 Field_To_Be_Printed := Field1 (N) /= Union_Id (Empty);
1211 when F_Field2 =>
1212 Field_To_Be_Printed := Field2 (N) /= Union_Id (Empty);
1214 when F_Field3 =>
1215 Field_To_Be_Printed := Field3 (N) /= Union_Id (Empty);
1217 when F_Field4 =>
1218 Field_To_Be_Printed := Field4 (N) /= Union_Id (Empty);
1220 when F_Field5 =>
1221 Field_To_Be_Printed := Field5 (N) /= Union_Id (Empty);
1223 when F_Flag1 => Field_To_Be_Printed := Flag1 (N);
1224 when F_Flag2 => Field_To_Be_Printed := Flag2 (N);
1225 when F_Flag3 => Field_To_Be_Printed := Flag3 (N);
1226 when F_Flag4 => Field_To_Be_Printed := Flag4 (N);
1227 when F_Flag5 => Field_To_Be_Printed := Flag5 (N);
1228 when F_Flag6 => Field_To_Be_Printed := Flag6 (N);
1229 when F_Flag7 => Field_To_Be_Printed := Flag7 (N);
1230 when F_Flag8 => Field_To_Be_Printed := Flag8 (N);
1231 when F_Flag9 => Field_To_Be_Printed := Flag9 (N);
1232 when F_Flag10 => Field_To_Be_Printed := Flag10 (N);
1233 when F_Flag11 => Field_To_Be_Printed := Flag11 (N);
1234 when F_Flag12 => Field_To_Be_Printed := Flag12 (N);
1235 when F_Flag13 => Field_To_Be_Printed := Flag13 (N);
1236 when F_Flag14 => Field_To_Be_Printed := Flag14 (N);
1237 when F_Flag15 => Field_To_Be_Printed := Flag15 (N);
1238 when F_Flag16 => Field_To_Be_Printed := Flag16 (N);
1239 when F_Flag17 => Field_To_Be_Printed := Flag17 (N);
1240 when F_Flag18 => Field_To_Be_Printed := Flag18 (N);
1241 end case;
1243 -- Print field if it is to be printed
1245 if Field_To_Be_Printed then
1246 Print_Str (Prefix_Str_Char);
1248 while P < Pchar_Pos (Node_Kind'Succ (Nkind (N)))
1249 and then Pchars (P) not in Fchar
1250 loop
1251 Print_Char (Pchars (P));
1252 P := P + 1;
1253 end loop;
1255 Print_Str (" = ");
1257 case F is
1258 when F_Field1 => Print_Field (Field1 (N), Fmt);
1259 when F_Field2 => Print_Field (Field2 (N), Fmt);
1260 when F_Field3 => Print_Field (Field3 (N), Fmt);
1261 when F_Field4 => Print_Field (Field4 (N), Fmt);
1263 -- Special case End_Span = Uint5
1265 when F_Field5 =>
1266 if Nkind_In (N, N_Case_Statement, N_If_Statement) then
1267 Print_End_Span (N);
1268 else
1269 Print_Field (Field5 (N), Fmt);
1270 end if;
1272 when F_Flag1 => Print_Flag (Flag1 (N));
1273 when F_Flag2 => Print_Flag (Flag2 (N));
1274 when F_Flag3 => Print_Flag (Flag3 (N));
1275 when F_Flag4 => Print_Flag (Flag4 (N));
1276 when F_Flag5 => Print_Flag (Flag5 (N));
1277 when F_Flag6 => Print_Flag (Flag6 (N));
1278 when F_Flag7 => Print_Flag (Flag7 (N));
1279 when F_Flag8 => Print_Flag (Flag8 (N));
1280 when F_Flag9 => Print_Flag (Flag9 (N));
1281 when F_Flag10 => Print_Flag (Flag10 (N));
1282 when F_Flag11 => Print_Flag (Flag11 (N));
1283 when F_Flag12 => Print_Flag (Flag12 (N));
1284 when F_Flag13 => Print_Flag (Flag13 (N));
1285 when F_Flag14 => Print_Flag (Flag14 (N));
1286 when F_Flag15 => Print_Flag (Flag15 (N));
1287 when F_Flag16 => Print_Flag (Flag16 (N));
1288 when F_Flag17 => Print_Flag (Flag17 (N));
1289 when F_Flag18 => Print_Flag (Flag18 (N));
1290 end case;
1292 Print_Eol;
1294 -- Field is not to be printed (False flag field)
1296 else
1297 while P < Pchar_Pos (Node_Kind'Succ (Nkind (N)))
1298 and then Pchars (P) not in Fchar
1299 loop
1300 P := P + 1;
1301 end loop;
1302 end if;
1303 end loop;
1305 -- Print aspects if present
1307 if Has_Aspects (N) then
1308 Print_Str (Prefix_Str_Char);
1309 Print_Str ("Aspect_Specifications = ");
1310 Print_Field (Union_Id (Aspect_Specifications (N)));
1311 Print_Eol;
1312 end if;
1314 -- Print entity information for entities
1316 if Nkind (N) in N_Entity then
1317 Print_Entity_Info (N, Prefix_Str_Char);
1318 end if;
1320 -- Print the SCIL node (if available)
1322 if Present (Get_SCIL_Node (N)) then
1323 Print_Str (Prefix_Str_Char);
1324 Print_Str ("SCIL_Node = ");
1325 Print_Node_Ref (Get_SCIL_Node (N));
1326 Print_Eol;
1327 end if;
1328 end Print_Node;
1330 ------------------------
1331 -- Print_Node_Briefly --
1332 ------------------------
1334 procedure Print_Node_Briefly (N : Node_Id) is
1335 begin
1336 Printing_Descendants := False;
1337 Phase := Printing;
1338 Print_Node_Header (N);
1339 end Print_Node_Briefly;
1341 -----------------------
1342 -- Print_Node_Header --
1343 -----------------------
1345 procedure Print_Node_Header (N : Node_Id) is
1346 Enumerate : Boolean := False;
1347 -- Flag set when enumerating multiple header flags
1349 procedure Print_Header_Flag (Flag : String);
1350 -- Output one of the flags that appears in a node header. The routine
1351 -- automatically handles enumeration of multiple flags.
1353 -----------------------
1354 -- Print_Header_Flag --
1355 -----------------------
1357 procedure Print_Header_Flag (Flag : String) is
1358 begin
1359 if Enumerate then
1360 Print_Char (',');
1361 else
1362 Enumerate := True;
1363 Print_Char ('(');
1364 end if;
1366 Print_Str (Flag);
1367 end Print_Header_Flag;
1369 -- Start of processing for Print_Node_Header
1371 begin
1372 Print_Node_Ref (N);
1374 if N > Atree_Private_Part.Nodes.Last then
1375 Print_Str (" (no such node)");
1376 Print_Eol;
1377 return;
1378 end if;
1380 Print_Char (' ');
1382 if Comes_From_Source (N) then
1383 Print_Header_Flag ("source");
1384 end if;
1386 if Analyzed (N) then
1387 Print_Header_Flag ("analyzed");
1388 end if;
1390 if Error_Posted (N) then
1391 Print_Header_Flag ("posted");
1392 end if;
1394 if Is_Ignored_Ghost_Node (N) then
1395 Print_Header_Flag ("ignored ghost");
1396 end if;
1398 if Check_Actuals (N) then
1399 Print_Header_Flag ("check actuals");
1400 end if;
1402 if Enumerate then
1403 Print_Char (')');
1404 end if;
1406 Print_Eol;
1407 end Print_Node_Header;
1409 ---------------------
1410 -- Print_Node_Kind --
1411 ---------------------
1413 procedure Print_Node_Kind (N : Node_Id) is
1414 Ucase : Boolean;
1415 S : constant String := Node_Kind'Image (Nkind (N));
1417 begin
1418 if Phase = Printing then
1419 Ucase := True;
1421 -- Note: the call to Fold_Upper in this loop is to get past the GNAT
1422 -- bug of 'Image returning lower case instead of upper case.
1424 for J in S'Range loop
1425 if Ucase then
1426 Write_Char (Fold_Upper (S (J)));
1427 else
1428 Write_Char (Fold_Lower (S (J)));
1429 end if;
1431 Ucase := (S (J) = '_');
1432 end loop;
1433 end if;
1434 end Print_Node_Kind;
1436 --------------------
1437 -- Print_Node_Ref --
1438 --------------------
1440 procedure Print_Node_Ref (N : Node_Id) is
1441 S : Nat;
1443 begin
1444 if Phase /= Printing then
1445 return;
1446 end if;
1448 if N = Empty then
1449 Write_Str ("<empty>");
1451 elsif N = Error then
1452 Write_Str ("<error>");
1454 else
1455 if Printing_Descendants then
1456 S := Serial_Number (Int (N));
1458 if S /= 0 then
1459 Write_Str ("Node");
1460 Write_Str (" #");
1461 Write_Int (S);
1462 Write_Char (' ');
1463 end if;
1464 end if;
1466 Print_Node_Kind (N);
1468 if Nkind (N) in N_Has_Chars then
1469 Write_Char (' ');
1470 Print_Name (Chars (N));
1471 end if;
1473 if Nkind (N) in N_Entity then
1474 Write_Str (" (Entity_Id=");
1475 else
1476 Write_Str (" (Node_Id=");
1477 end if;
1479 Write_Int (Int (N));
1481 if Sloc (N) <= Standard_Location then
1482 Write_Char ('s');
1483 end if;
1485 Write_Char (')');
1487 end if;
1488 end Print_Node_Ref;
1490 ------------------------
1491 -- Print_Node_Subtree --
1492 ------------------------
1494 procedure Print_Node_Subtree (N : Node_Id) is
1495 begin
1496 Print_Init;
1498 Next_Serial_Number := 1;
1499 Phase := Marking;
1500 Visit_Node (N, "", ' ');
1502 Next_Serial_Number := 1;
1503 Phase := Printing;
1504 Visit_Node (N, "", ' ');
1506 Print_Term;
1507 end Print_Node_Subtree;
1509 ---------------
1510 -- Print_Str --
1511 ---------------
1513 procedure Print_Str (S : String) is
1514 begin
1515 if Phase = Printing then
1516 Write_Str (S);
1517 end if;
1518 end Print_Str;
1520 --------------------------
1521 -- Print_Str_Mixed_Case --
1522 --------------------------
1524 procedure Print_Str_Mixed_Case (S : String) is
1525 Ucase : Boolean;
1527 begin
1528 if Phase = Printing then
1529 Ucase := True;
1531 for J in S'Range loop
1532 if Ucase then
1533 Write_Char (S (J));
1534 else
1535 Write_Char (Fold_Lower (S (J)));
1536 end if;
1538 Ucase := (S (J) = '_');
1539 end loop;
1540 end if;
1541 end Print_Str_Mixed_Case;
1543 ----------------
1544 -- Print_Term --
1545 ----------------
1547 procedure Print_Term is
1548 procedure Free is new Unchecked_Deallocation
1549 (Hash_Table_Type, Access_Hash_Table_Type);
1551 begin
1552 Free (Hash_Table);
1553 end Print_Term;
1555 ---------------------
1556 -- Print_Tree_Elist --
1557 ---------------------
1559 procedure Print_Tree_Elist (E : Elist_Id) is
1560 M : Elmt_Id;
1562 begin
1563 Printing_Descendants := False;
1564 Phase := Printing;
1566 Print_Elist_Ref (E);
1567 Print_Eol;
1569 if Present (E) and then not Is_Empty_Elmt_List (E) then
1570 M := First_Elmt (E);
1572 loop
1573 Print_Char ('|');
1574 Print_Eol;
1575 exit when No (Next_Elmt (M));
1576 Print_Node (Node (M), "", '|');
1577 Next_Elmt (M);
1578 end loop;
1580 Print_Node (Node (M), "", ' ');
1581 Print_Eol;
1582 end if;
1583 end Print_Tree_Elist;
1585 ---------------------
1586 -- Print_Tree_List --
1587 ---------------------
1589 procedure Print_Tree_List (L : List_Id) is
1590 N : Node_Id;
1592 begin
1593 Printing_Descendants := False;
1594 Phase := Printing;
1596 Print_List_Ref (L);
1597 Print_Str (" List_Id=");
1598 Print_Int (Int (L));
1599 Print_Eol;
1601 N := First (L);
1603 if N = Empty then
1604 Print_Str ("<empty node list>");
1605 Print_Eol;
1607 else
1608 loop
1609 Print_Char ('|');
1610 Print_Eol;
1611 exit when Next (N) = Empty;
1612 Print_Node (N, "", '|');
1613 Next (N);
1614 end loop;
1616 Print_Node (N, "", ' ');
1617 Print_Eol;
1618 end if;
1619 end Print_Tree_List;
1621 ---------------------
1622 -- Print_Tree_Node --
1623 ---------------------
1625 procedure Print_Tree_Node (N : Node_Id; Label : String := "") is
1626 begin
1627 Printing_Descendants := False;
1628 Phase := Printing;
1629 Print_Node (N, Label, ' ');
1630 end Print_Tree_Node;
1632 --------
1633 -- pt --
1634 --------
1636 procedure pt (N : Union_Id) is
1637 begin
1638 case N is
1639 when List_Low_Bound .. List_High_Bound - 1 =>
1640 Print_List_Subtree (List_Id (N));
1642 when Node_Range =>
1643 Print_Node_Subtree (Node_Id (N));
1645 when Elist_Range =>
1646 Print_Elist_Subtree (Elist_Id (N));
1648 when others =>
1649 pp (N);
1650 end case;
1651 end pt;
1653 -------------------
1654 -- Serial_Number --
1655 -------------------
1657 -- The hashing algorithm is to use the remainder of the ID value divided
1658 -- by the hash table length as the starting point in the table, and then
1659 -- handle collisions by serial searching wrapping at the end of the table.
1661 Hash_Slot : Nat;
1662 -- Set by an unsuccessful call to Serial_Number (one which returns zero)
1663 -- to save the slot that should be used if Set_Serial_Number is called.
1665 function Serial_Number (Id : Int) return Nat is
1666 H : Int := Id mod Hash_Table_Len;
1668 begin
1669 while Hash_Table (H).Serial /= 0 loop
1671 if Id = Hash_Table (H).Id then
1672 return Hash_Table (H).Serial;
1673 end if;
1675 H := H + 1;
1677 if H > Hash_Table'Last then
1678 H := 0;
1679 end if;
1680 end loop;
1682 -- Entry was not found, save slot number for possible subsequent call
1683 -- to Set_Serial_Number, and unconditionally save the Id in this slot
1684 -- in case of such a call (the Id field is never read if the serial
1685 -- number of the slot is zero, so this is harmless in the case where
1686 -- Set_Serial_Number is not subsequently called).
1688 Hash_Slot := H;
1689 Hash_Table (H).Id := Id;
1690 return 0;
1691 end Serial_Number;
1693 -----------------------
1694 -- Set_Serial_Number --
1695 -----------------------
1697 procedure Set_Serial_Number is
1698 begin
1699 Hash_Table (Hash_Slot).Serial := Next_Serial_Number;
1700 Next_Serial_Number := Next_Serial_Number + 1;
1701 end Set_Serial_Number;
1703 ---------------
1704 -- Tree_Dump --
1705 ---------------
1707 procedure Tree_Dump is
1708 procedure Underline;
1709 -- Put underline under string we just printed
1711 procedure Underline is
1712 Col : constant Int := Column;
1714 begin
1715 Write_Eol;
1717 while Col > Column loop
1718 Write_Char ('-');
1719 end loop;
1721 Write_Eol;
1722 end Underline;
1724 -- Start of processing for Tree_Dump. Note that we turn off the tree dump
1725 -- flags immediately, before starting the dump. This avoids generating two
1726 -- copies of the dump if an abort occurs after printing the dump, and more
1727 -- importantly, avoids an infinite loop if an abort occurs during the dump.
1729 -- Note: unlike in the source print case (in Sprint), we do not output
1730 -- separate trees for each unit. Instead the -df debug switch causes the
1731 -- tree that is output from the main unit to trace references into other
1732 -- units (normally such references are not traced). Since all other units
1733 -- are linked to the main unit by at least one reference, this causes all
1734 -- tree nodes to be included in the output tree.
1736 begin
1737 if Debug_Flag_Y then
1738 Debug_Flag_Y := False;
1739 Write_Eol;
1740 Write_Str ("Tree created for Standard (spec) ");
1741 Underline;
1742 Print_Node_Subtree (Standard_Package_Node);
1743 Write_Eol;
1744 end if;
1746 if Debug_Flag_T then
1747 Debug_Flag_T := False;
1749 Write_Eol;
1750 Write_Str ("Tree created for ");
1751 Write_Unit_Name (Unit_Name (Main_Unit));
1752 Underline;
1753 Print_Node_Subtree (Cunit (Main_Unit));
1754 Write_Eol;
1755 end if;
1756 end Tree_Dump;
1758 -----------------
1759 -- Visit_Elist --
1760 -----------------
1762 procedure Visit_Elist (E : Elist_Id; Prefix_Str : String) is
1763 M : Elmt_Id;
1764 N : Node_Id;
1765 S : constant Nat := Serial_Number (Int (E));
1767 begin
1768 -- In marking phase, return if already marked, otherwise set next
1769 -- serial number in hash table for later reference.
1771 if Phase = Marking then
1772 if S /= 0 then
1773 return; -- already visited
1774 else
1775 Set_Serial_Number;
1776 end if;
1778 -- In printing phase, if already printed, then return, otherwise we
1779 -- are printing the next item, so increment the serial number.
1781 else
1782 if S < Next_Serial_Number then
1783 return; -- already printed
1784 else
1785 Next_Serial_Number := Next_Serial_Number + 1;
1786 end if;
1787 end if;
1789 -- Now process the list (Print calls have no effect in marking phase)
1791 Print_Str (Prefix_Str);
1792 Print_Elist_Ref (E);
1793 Print_Eol;
1795 if Is_Empty_Elmt_List (E) then
1796 Print_Str (Prefix_Str);
1797 Print_Str ("(Empty element list)");
1798 Print_Eol;
1799 Print_Eol;
1801 else
1802 if Phase = Printing then
1803 M := First_Elmt (E);
1804 while Present (M) loop
1805 N := Node (M);
1806 Print_Str (Prefix_Str);
1807 Print_Str (" ");
1808 Print_Node_Ref (N);
1809 Print_Eol;
1810 Next_Elmt (M);
1811 end loop;
1813 Print_Str (Prefix_Str);
1814 Print_Eol;
1815 end if;
1817 M := First_Elmt (E);
1818 while Present (M) loop
1819 Visit_Node (Node (M), Prefix_Str, ' ');
1820 Next_Elmt (M);
1821 end loop;
1822 end if;
1823 end Visit_Elist;
1825 ----------------
1826 -- Visit_List --
1827 ----------------
1829 procedure Visit_List (L : List_Id; Prefix_Str : String) is
1830 N : Node_Id;
1831 S : constant Nat := Serial_Number (Int (L));
1833 begin
1834 -- In marking phase, return if already marked, otherwise set next
1835 -- serial number in hash table for later reference.
1837 if Phase = Marking then
1838 if S /= 0 then
1839 return;
1840 else
1841 Set_Serial_Number;
1842 end if;
1844 -- In printing phase, if already printed, then return, otherwise we
1845 -- are printing the next item, so increment the serial number.
1847 else
1848 if S < Next_Serial_Number then
1849 return; -- already printed
1850 else
1851 Next_Serial_Number := Next_Serial_Number + 1;
1852 end if;
1853 end if;
1855 -- Now process the list (Print calls have no effect in marking phase)
1857 Print_Str (Prefix_Str);
1858 Print_List_Ref (L);
1859 Print_Eol;
1861 Print_Str (Prefix_Str);
1862 Print_Str ("|Parent = ");
1863 Print_Node_Ref (Parent (L));
1864 Print_Eol;
1866 N := First (L);
1868 if N = Empty then
1869 Print_Str (Prefix_Str);
1870 Print_Str ("(Empty list)");
1871 Print_Eol;
1872 Print_Eol;
1874 else
1875 Print_Str (Prefix_Str);
1876 Print_Char ('|');
1877 Print_Eol;
1879 while Next (N) /= Empty loop
1880 Visit_Node (N, Prefix_Str, '|');
1881 Next (N);
1882 end loop;
1883 end if;
1885 Visit_Node (N, Prefix_Str, ' ');
1886 end Visit_List;
1888 ----------------
1889 -- Visit_Node --
1890 ----------------
1892 procedure Visit_Node
1893 (N : Node_Id;
1894 Prefix_Str : String;
1895 Prefix_Char : Character)
1897 New_Prefix : String (Prefix_Str'First .. Prefix_Str'Last + 2);
1898 -- Prefix string for printing referenced fields
1900 procedure Visit_Descendant
1901 (D : Union_Id;
1902 No_Indent : Boolean := False);
1903 -- This procedure tests the given value of one of the Fields referenced
1904 -- by the current node to determine whether to visit it recursively.
1905 -- Normally No_Indent is false, which means that the visited node will
1906 -- be indented using New_Prefix. If No_Indent is set to True, then
1907 -- this indentation is skipped, and Prefix_Str is used for the call
1908 -- to print the descendant. No_Indent is effective only if the
1909 -- referenced descendant is a node.
1911 ----------------------
1912 -- Visit_Descendant --
1913 ----------------------
1915 procedure Visit_Descendant
1916 (D : Union_Id;
1917 No_Indent : Boolean := False)
1919 begin
1920 -- Case of descendant is a node
1922 if D in Node_Range then
1924 -- Don't bother about Empty or Error descendants
1926 if D <= Union_Id (Empty_Or_Error) then
1927 return;
1928 end if;
1930 declare
1931 Nod : constant Node_Or_Entity_Id := Node_Or_Entity_Id (D);
1933 begin
1934 -- Descendants in one of the standardly compiled internal
1935 -- packages are normally ignored, unless the parent is also
1936 -- in such a package (happens when Standard itself is output)
1937 -- or if the -df switch is set which causes all links to be
1938 -- followed, even into package standard.
1940 if Sloc (Nod) <= Standard_Location then
1941 if Sloc (N) > Standard_Location
1942 and then not Debug_Flag_F
1943 then
1944 return;
1945 end if;
1947 -- Don't bother about a descendant in a different unit than
1948 -- the node we came from unless the -df switch is set. Note
1949 -- that we know at this point that Sloc (D) > Standard_Location
1951 -- Note: the tests for No_Location here just make sure that we
1952 -- don't blow up on a node which is missing an Sloc value. This
1953 -- should not normally happen.
1955 else
1956 if (Sloc (N) <= Standard_Location
1957 or else Sloc (N) = No_Location
1958 or else Sloc (Nod) = No_Location
1959 or else not In_Same_Source_Unit (Nod, N))
1960 and then not Debug_Flag_F
1961 then
1962 return;
1963 end if;
1964 end if;
1966 -- Don't bother visiting a source node that has a parent which
1967 -- is not the node we came from. We prefer to trace such nodes
1968 -- from their real parents. This causes the tree to be printed
1969 -- in a more coherent order, e.g. a defining identifier listed
1970 -- next to its corresponding declaration, instead of next to
1971 -- some semantic reference.
1973 -- This test is skipped for nodes in standard packages unless
1974 -- the -dy option is set (which outputs the tree for standard)
1976 -- Also, always follow pointers to Is_Itype entities,
1977 -- since we want to list these when they are first referenced.
1979 if Parent (Nod) /= Empty
1980 and then Comes_From_Source (Nod)
1981 and then Parent (Nod) /= N
1982 and then (Sloc (N) > Standard_Location or else Debug_Flag_Y)
1983 then
1984 return;
1985 end if;
1987 -- If we successfully fall through all the above tests (which
1988 -- execute a return if the node is not to be visited), we can
1989 -- go ahead and visit the node.
1991 if No_Indent then
1992 Visit_Node (Nod, Prefix_Str, Prefix_Char);
1993 else
1994 Visit_Node (Nod, New_Prefix, ' ');
1995 end if;
1996 end;
1998 -- Case of descendant is a list
2000 elsif D in List_Range then
2002 -- Don't bother with a missing list, empty list or error list
2004 pragma Assert (D /= Union_Id (No_List));
2005 -- Because No_List = Empty, which is in Node_Range above
2007 if D = Union_Id (Error_List)
2008 or else Is_Empty_List (List_Id (D))
2009 then
2010 return;
2012 -- Otherwise we can visit the list. Note that we don't bother to
2013 -- do the parent test that we did for the node case, because it
2014 -- just does not happen that lists are referenced more than one
2015 -- place in the tree. We aren't counting on this being the case
2016 -- to generate valid output, it is just that we don't need in
2017 -- practice to worry about listing the list at a place that is
2018 -- inconvenient.
2020 else
2021 Visit_List (List_Id (D), New_Prefix);
2022 end if;
2024 -- Case of descendant is an element list
2026 elsif D in Elist_Range then
2028 -- Don't bother with a missing list, or an empty list
2030 if D = Union_Id (No_Elist)
2031 or else Is_Empty_Elmt_List (Elist_Id (D))
2032 then
2033 return;
2035 -- Otherwise, visit the referenced element list
2037 else
2038 Visit_Elist (Elist_Id (D), New_Prefix);
2039 end if;
2041 -- For all other kinds of descendants (strings, names, uints etc),
2042 -- there is nothing to visit (the contents of the field will be
2043 -- printed when we print the containing node, but what concerns
2044 -- us now is looking for descendants in the tree.
2046 else
2047 null;
2048 end if;
2049 end Visit_Descendant;
2051 -- Start of processing for Visit_Node
2053 begin
2054 if N = Empty then
2055 return;
2056 end if;
2058 -- Set fatal error node in case we get a blow up during the trace
2060 Current_Error_Node := N;
2062 New_Prefix (Prefix_Str'Range) := Prefix_Str;
2063 New_Prefix (Prefix_Str'Last + 1) := Prefix_Char;
2064 New_Prefix (Prefix_Str'Last + 2) := ' ';
2066 -- In the marking phase, all we do is to set the serial number
2068 if Phase = Marking then
2069 if Serial_Number (Int (N)) /= 0 then
2070 return; -- already visited
2071 else
2072 Set_Serial_Number;
2073 end if;
2075 -- In the printing phase, we print the node
2077 else
2078 if Serial_Number (Int (N)) < Next_Serial_Number then
2080 -- Here we have already visited the node, but if it is in a list,
2081 -- we still want to print the reference, so that it is clear that
2082 -- it belongs to the list.
2084 if Is_List_Member (N) then
2085 Print_Str (Prefix_Str);
2086 Print_Node_Ref (N);
2087 Print_Eol;
2088 Print_Str (Prefix_Str);
2089 Print_Char (Prefix_Char);
2090 Print_Str ("(already output)");
2091 Print_Eol;
2092 Print_Str (Prefix_Str);
2093 Print_Char (Prefix_Char);
2094 Print_Eol;
2095 end if;
2097 return;
2099 else
2100 Print_Node (N, Prefix_Str, Prefix_Char);
2101 Print_Str (Prefix_Str);
2102 Print_Char (Prefix_Char);
2103 Print_Eol;
2104 Next_Serial_Number := Next_Serial_Number + 1;
2105 end if;
2106 end if;
2108 -- Visit all descendants of this node
2110 if Nkind (N) not in N_Entity then
2111 Visit_Descendant (Field1 (N));
2112 Visit_Descendant (Field2 (N));
2113 Visit_Descendant (Field3 (N));
2114 Visit_Descendant (Field4 (N));
2115 Visit_Descendant (Field5 (N));
2117 if Has_Aspects (N) then
2118 Visit_Descendant (Union_Id (Aspect_Specifications (N)));
2119 end if;
2121 -- Entity case
2123 else
2124 Visit_Descendant (Field1 (N));
2125 Visit_Descendant (Field3 (N));
2126 Visit_Descendant (Field4 (N));
2127 Visit_Descendant (Field5 (N));
2128 Visit_Descendant (Field6 (N));
2129 Visit_Descendant (Field7 (N));
2130 Visit_Descendant (Field8 (N));
2131 Visit_Descendant (Field9 (N));
2132 Visit_Descendant (Field10 (N));
2133 Visit_Descendant (Field11 (N));
2134 Visit_Descendant (Field12 (N));
2135 Visit_Descendant (Field13 (N));
2136 Visit_Descendant (Field14 (N));
2137 Visit_Descendant (Field15 (N));
2138 Visit_Descendant (Field16 (N));
2139 Visit_Descendant (Field17 (N));
2140 Visit_Descendant (Field18 (N));
2141 Visit_Descendant (Field19 (N));
2142 Visit_Descendant (Field20 (N));
2143 Visit_Descendant (Field21 (N));
2144 Visit_Descendant (Field22 (N));
2145 Visit_Descendant (Field23 (N));
2147 -- Now an interesting special case. Normally parents are always
2148 -- printed since we traverse the tree in a downwards direction.
2149 -- However, there is an exception to this rule, which is the
2150 -- case where a parent is constructed by the compiler and is not
2151 -- referenced elsewhere in the tree. The following catches this case.
2153 if not Comes_From_Source (N) then
2154 Visit_Descendant (Union_Id (Parent (N)));
2155 end if;
2157 -- You may be wondering why we omitted Field2 above. The answer
2158 -- is that this is the Next_Entity field, and we want to treat
2159 -- it rather specially. Why? Because a Next_Entity link does not
2160 -- correspond to a level deeper in the tree, and we do not want
2161 -- the tree to march off to the right of the page due to bogus
2162 -- indentations coming from this effect.
2164 -- To prevent this, what we do is to control references via
2165 -- Next_Entity only from the first entity on a given scope chain,
2166 -- and we keep them all at the same level. Of course if an entity
2167 -- has already been referenced it is not printed.
2169 if Present (Next_Entity (N))
2170 and then Present (Scope (N))
2171 and then First_Entity (Scope (N)) = N
2172 then
2173 declare
2174 Nod : Node_Id;
2176 begin
2177 Nod := N;
2178 while Present (Nod) loop
2179 Visit_Descendant (Union_Id (Next_Entity (Nod)));
2180 Nod := Next_Entity (Nod);
2181 end loop;
2182 end;
2183 end if;
2184 end if;
2185 end Visit_Node;
2187 end Treepr;