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1 706 jeremybenn
------------------------------------------------------------------------------
2
--                                                                          --
3
--                         GNAT COMPILER COMPONENTS                         --
4
--                                                                          --
5
--                               T R E E P R                                --
6
--                                                                          --
7
--                                 B o d y                                  --
8
--                                                                          --
9
--          Copyright (C) 1992-2011, 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
------------------------------------------------------------------------------
25
 
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;
48
 
49
package body Treepr is
50
 
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!)
55
 
56
   ----------------------------------
57
   -- Approach Used for Tree Print --
58
   ----------------------------------
59
 
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.
69
 
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.
75
 
76
   ----------------------
77
   -- Global Variables --
78
   ----------------------
79
 
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.
84
 
85
      Id : Int;
86
      --  If serial number field is non-zero, contains corresponding Id value
87
   end record;
88
 
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
93
 
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.
97
 
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!)
104
 
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.
109
 
110
   type Phase_Type is (Marking, Printing);
111
   --  Type for Phase variable
112
 
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.
118
 
119
   ----------------------
120
   -- Local Procedures --
121
   ----------------------
122
 
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.
127
 
128
   procedure Print_Init;
129
   --  Initialize for printing of tree with descendents
130
 
131
   procedure Print_Term;
132
   --  Clean up after printing of tree with descendents
133
 
134
   procedure Print_Char (C : Character);
135
   --  Print character C if currently in print phase, noop if in marking phase
136
 
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.
140
 
141
   procedure Print_Node_Header (N : Node_Id);
142
   --  Print header line used by Print_Node and Print_Node_Briefly
143
 
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.
147
 
148
   procedure Print_Str (S : String);
149
   --  Print string S if currently in print phase, noop if in marking phase
150
 
151
   procedure Print_Str_Mixed_Case (S : String);
152
   --  Like Print_Str, except that the string is printed in mixed case mode
153
 
154
   procedure Print_Int (I : Int);
155
   --  Print integer I if currently in print phase, noop if in marking phase
156
 
157
   procedure Print_Eol;
158
   --  Print end of line if currently in print phase, noop if in marking phase
159
 
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.
163
 
164
   procedure Print_List_Ref (L : List_Id);
165
   --  Print "<no list>", or "<empty node list>" or "Node list #nnn"
166
 
167
   procedure Print_Elist_Ref (E : Elist_Id);
168
   --  Print "<no elist>", or "<empty element list>" or "Element list #nnn"
169
 
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.
173
 
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).
178
 
179
   procedure Print_Flag (F : Boolean);
180
   --  Print True or False
181
 
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.
190
 
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.
194
 
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.
200
 
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 descendents are to
206
   --  be printed before every line, and Prefix_Char added to all lines
207
   --  except the header line for the node.
208
 
209
   procedure Visit_List (L : List_Id; Prefix_Str : String);
210
   --  Visit_List is called to process a list in the case where descendents
211
   --  are to be printed. Prefix_Str is to be added to all printed lines.
212
 
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
   --  descendents are to be printed. Prefix_Str is to be added to all
216
   --  printed lines.
217
 
218
   --------
219
   -- pe --
220
   --------
221
 
222
   procedure pe (E : Elist_Id) is
223
   begin
224
      Print_Tree_Elist (E);
225
   end pe;
226
 
227
   --------
228
   -- pl --
229
   --------
230
 
231
   procedure pl (L : Int) is
232
      Lid : Int;
233
 
234
   begin
235
      if L < 0 then
236
         Lid := L;
237
 
238
      --  This is the case where we transform e.g. +36 to -99999936
239
 
240
      else
241
         if L <= 9 then
242
            Lid := -(99999990 + L);
243
         elsif L <= 99 then
244
            Lid := -(99999900 + L);
245
         elsif L <= 999 then
246
            Lid := -(99999000 + L);
247
         elsif L <= 9999 then
248
            Lid := -(99990000 + L);
249
         elsif L <= 99999 then
250
            Lid := -(99900000 + L);
251
         elsif L <= 999999 then
252
            Lid := -(99000000 + L);
253
         elsif L <= 9999999 then
254
            Lid := -(90000000 + L);
255
         else
256
            Lid := -L;
257
         end if;
258
      end if;
259
 
260
      --  Now output the list
261
 
262
      Print_Tree_List (List_Id (Lid));
263
   end pl;
264
 
265
   --------
266
   -- pn --
267
   --------
268
 
269
   procedure pn (N : Union_Id) is
270
   begin
271
      case N is
272
         when List_Low_Bound .. List_High_Bound - 1 =>
273
            pl (Int (N));
274
         when Node_Range =>
275
            Print_Tree_Node (Node_Id (N));
276
         when Elist_Range =>
277
            Print_Tree_Elist (Elist_Id (N));
278
         when Elmt_Range =>
279
            declare
280
               Id : constant Elmt_Id := Elmt_Id (N);
281
            begin
282
               if No (Id) then
283
                  Write_Str ("No_Elmt");
284
                  Write_Eol;
285
               else
286
                  Write_Str ("Elmt_Id --> ");
287
                  Print_Tree_Node (Node (Id));
288
               end if;
289
            end;
290
         when Names_Range =>
291
            Namet.wn (Name_Id (N));
292
         when Strings_Range =>
293
            Write_String_Table_Entry (String_Id (N));
294
         when Uint_Range =>
295
            Uintp.pid (From_Union (N));
296
         when Ureal_Range =>
297
            Urealp.pr (From_Union (N));
298
         when others =>
299
            Write_Str ("Invalid Union_Id: ");
300
            Write_Int (Int (N));
301
            Write_Eol;
302
      end case;
303
   end pn;
304
 
305
   --------
306
   -- pp --
307
   --------
308
 
309
   procedure pp (N : Union_Id) is
310
   begin
311
      pn (N);
312
   end pp;
313
 
314
   ----------------
315
   -- Print_Char --
316
   ----------------
317
 
318
   procedure Print_Char (C : Character) is
319
   begin
320
      if Phase = Printing then
321
         Write_Char (C);
322
      end if;
323
   end Print_Char;
324
 
325
   ---------------------
326
   -- Print_Elist_Ref --
327
   ---------------------
328
 
329
   procedure Print_Elist_Ref (E : Elist_Id) is
330
   begin
331
      if Phase /= Printing then
332
         return;
333
      end if;
334
 
335
      if E = No_Elist then
336
         Write_Str ("<no elist>");
337
 
338
      elsif Is_Empty_Elmt_List (E) then
339
         Write_Str ("Empty elist, (Elist_Id=");
340
         Write_Int (Int (E));
341
         Write_Char (')');
342
 
343
      else
344
         Write_Str ("(Elist_Id=");
345
         Write_Int (Int (E));
346
         Write_Char (')');
347
 
348
         if Printing_Descendants then
349
            Write_Str (" #");
350
            Write_Int (Serial_Number (Int (E)));
351
         end if;
352
      end if;
353
   end Print_Elist_Ref;
354
 
355
   -------------------------
356
   -- Print_Elist_Subtree --
357
   -------------------------
358
 
359
   procedure Print_Elist_Subtree (E : Elist_Id) is
360
   begin
361
      Print_Init;
362
 
363
      Next_Serial_Number := 1;
364
      Phase := Marking;
365
      Visit_Elist (E, "");
366
 
367
      Next_Serial_Number := 1;
368
      Phase := Printing;
369
      Visit_Elist (E, "");
370
 
371
      Print_Term;
372
   end Print_Elist_Subtree;
373
 
374
   --------------------
375
   -- Print_End_Span --
376
   --------------------
377
 
378
   procedure Print_End_Span (N : Node_Id) is
379
      Val : constant Uint := End_Span (N);
380
 
381
   begin
382
      UI_Write (Val);
383
      Write_Str (" (Uint = ");
384
      Write_Int (Int (Field5 (N)));
385
      Write_Str (")  ");
386
 
387
      if Val /= No_Uint then
388
         Write_Location (End_Location (N));
389
      end if;
390
   end Print_End_Span;
391
 
392
   -----------------------
393
   -- Print_Entity_Info --
394
   -----------------------
395
 
396
   procedure Print_Entity_Info (Ent : Entity_Id; Prefix : String) is
397
      function Field_Present (U : Union_Id) return Boolean;
398
      --  Returns False unless the value U represents a missing value
399
      --  (Empty, No_Uint, No_Ureal or No_String)
400
 
401
      function Field_Present (U : Union_Id) return Boolean is
402
      begin
403
         return
404
            U /= Union_Id (Empty)    and then
405
            U /= To_Union (No_Uint)  and then
406
            U /= To_Union (No_Ureal) and then
407
            U /= Union_Id (No_String);
408
      end Field_Present;
409
 
410
   --  Start of processing for Print_Entity_Info
411
 
412
   begin
413
      Print_Str (Prefix);
414
      Print_Str ("Ekind = ");
415
      Print_Str_Mixed_Case (Entity_Kind'Image (Ekind (Ent)));
416
      Print_Eol;
417
 
418
      Print_Str (Prefix);
419
      Print_Str ("Etype = ");
420
      Print_Node_Ref (Etype (Ent));
421
      Print_Eol;
422
 
423
      if Convention (Ent) /= Convention_Ada then
424
         Print_Str (Prefix);
425
         Print_Str ("Convention = ");
426
 
427
         --  Print convention name skipping the Convention_ at the start
428
 
429
         declare
430
            S : constant String := Convention_Id'Image (Convention (Ent));
431
 
432
         begin
433
            Print_Str_Mixed_Case (S (12 .. S'Last));
434
            Print_Eol;
435
         end;
436
      end if;
437
 
438
      if Field_Present (Field6 (Ent)) then
439
         Print_Str (Prefix);
440
         Write_Field6_Name (Ent);
441
         Write_Str (" = ");
442
         Print_Field (Field6 (Ent));
443
         Print_Eol;
444
      end if;
445
 
446
      if Field_Present (Field7 (Ent)) then
447
         Print_Str (Prefix);
448
         Write_Field7_Name (Ent);
449
         Write_Str (" = ");
450
         Print_Field (Field7 (Ent));
451
         Print_Eol;
452
      end if;
453
 
454
      if Field_Present (Field8 (Ent)) then
455
         Print_Str (Prefix);
456
         Write_Field8_Name (Ent);
457
         Write_Str (" = ");
458
         Print_Field (Field8 (Ent));
459
         Print_Eol;
460
      end if;
461
 
462
      if Field_Present (Field9 (Ent)) then
463
         Print_Str (Prefix);
464
         Write_Field9_Name (Ent);
465
         Write_Str (" = ");
466
         Print_Field (Field9 (Ent));
467
         Print_Eol;
468
      end if;
469
 
470
      if Field_Present (Field10 (Ent)) then
471
         Print_Str (Prefix);
472
         Write_Field10_Name (Ent);
473
         Write_Str (" = ");
474
         Print_Field (Field10 (Ent));
475
         Print_Eol;
476
      end if;
477
 
478
      if Field_Present (Field11 (Ent)) then
479
         Print_Str (Prefix);
480
         Write_Field11_Name (Ent);
481
         Write_Str (" = ");
482
         Print_Field (Field11 (Ent));
483
         Print_Eol;
484
      end if;
485
 
486
      if Field_Present (Field12 (Ent)) then
487
         Print_Str (Prefix);
488
         Write_Field12_Name (Ent);
489
         Write_Str (" = ");
490
         Print_Field (Field12 (Ent));
491
         Print_Eol;
492
      end if;
493
 
494
      if Field_Present (Field13 (Ent)) then
495
         Print_Str (Prefix);
496
         Write_Field13_Name (Ent);
497
         Write_Str (" = ");
498
         Print_Field (Field13 (Ent));
499
         Print_Eol;
500
      end if;
501
 
502
      if Field_Present (Field14 (Ent)) then
503
         Print_Str (Prefix);
504
         Write_Field14_Name (Ent);
505
         Write_Str (" = ");
506
         Print_Field (Field14 (Ent));
507
         Print_Eol;
508
      end if;
509
 
510
      if Field_Present (Field15 (Ent)) then
511
         Print_Str (Prefix);
512
         Write_Field15_Name (Ent);
513
         Write_Str (" = ");
514
         Print_Field (Field15 (Ent));
515
         Print_Eol;
516
      end if;
517
 
518
      if Field_Present (Field16 (Ent)) then
519
         Print_Str (Prefix);
520
         Write_Field16_Name (Ent);
521
         Write_Str (" = ");
522
         Print_Field (Field16 (Ent));
523
         Print_Eol;
524
      end if;
525
 
526
      if Field_Present (Field17 (Ent)) then
527
         Print_Str (Prefix);
528
         Write_Field17_Name (Ent);
529
         Write_Str (" = ");
530
         Print_Field (Field17 (Ent));
531
         Print_Eol;
532
      end if;
533
 
534
      if Field_Present (Field18 (Ent)) then
535
         Print_Str (Prefix);
536
         Write_Field18_Name (Ent);
537
         Write_Str (" = ");
538
         Print_Field (Field18 (Ent));
539
         Print_Eol;
540
      end if;
541
 
542
      if Field_Present (Field19 (Ent)) then
543
         Print_Str (Prefix);
544
         Write_Field19_Name (Ent);
545
         Write_Str (" = ");
546
         Print_Field (Field19 (Ent));
547
         Print_Eol;
548
      end if;
549
 
550
      if Field_Present (Field20 (Ent)) then
551
         Print_Str (Prefix);
552
         Write_Field20_Name (Ent);
553
         Write_Str (" = ");
554
         Print_Field (Field20 (Ent));
555
         Print_Eol;
556
      end if;
557
 
558
      if Field_Present (Field21 (Ent)) then
559
         Print_Str (Prefix);
560
         Write_Field21_Name (Ent);
561
         Write_Str (" = ");
562
         Print_Field (Field21 (Ent));
563
         Print_Eol;
564
      end if;
565
 
566
      if Field_Present (Field22 (Ent)) then
567
         Print_Str (Prefix);
568
         Write_Field22_Name (Ent);
569
         Write_Str (" = ");
570
 
571
         --  Mechanism case has to be handled specially
572
 
573
         if Ekind (Ent) = E_Function or else Is_Formal (Ent) then
574
            declare
575
               M : constant Mechanism_Type := Mechanism (Ent);
576
 
577
            begin
578
               case M is
579
                  when Default_Mechanism
580
                                    => Write_Str ("Default");
581
                  when By_Copy
582
                                    => Write_Str ("By_Copy");
583
                  when By_Reference
584
                                    => Write_Str ("By_Reference");
585
                  when By_Descriptor
586
                                    => Write_Str ("By_Descriptor");
587
                  when By_Descriptor_UBS
588
                                    => Write_Str ("By_Descriptor_UBS");
589
                  when By_Descriptor_UBSB
590
                                    => Write_Str ("By_Descriptor_UBSB");
591
                  when By_Descriptor_UBA
592
                                    => Write_Str ("By_Descriptor_UBA");
593
                  when By_Descriptor_S
594
                                    => Write_Str ("By_Descriptor_S");
595
                  when By_Descriptor_SB
596
                                    => Write_Str ("By_Descriptor_SB");
597
                  when By_Descriptor_A
598
                                    => Write_Str ("By_Descriptor_A");
599
                  when By_Descriptor_NCA
600
                                    => Write_Str ("By_Descriptor_NCA");
601
                  when By_Short_Descriptor
602
                                    => Write_Str ("By_Short_Descriptor");
603
                  when By_Short_Descriptor_UBS
604
                                    => Write_Str ("By_Short_Descriptor_UBS");
605
                  when By_Short_Descriptor_UBSB
606
                                    => Write_Str ("By_Short_Descriptor_UBSB");
607
                  when By_Short_Descriptor_UBA
608
                                    => Write_Str ("By_Short_Descriptor_UBA");
609
                  when By_Short_Descriptor_S
610
                                    => Write_Str ("By_Short_Descriptor_S");
611
                  when By_Short_Descriptor_SB
612
                                    => Write_Str ("By_Short_Descriptor_SB");
613
                  when By_Short_Descriptor_A
614
                                    => Write_Str ("By_Short_Descriptor_A");
615
                  when By_Short_Descriptor_NCA
616
                                    => Write_Str ("By_Short_Descriptor_NCA");
617
 
618
                  when 1 .. Mechanism_Type'Last =>
619
                     Write_Str ("By_Copy if size <= ");
620
                     Write_Int (Int (M));
621
 
622
               end case;
623
            end;
624
 
625
         --  Normal case (not Mechanism)
626
 
627
         else
628
            Print_Field (Field22 (Ent));
629
         end if;
630
 
631
         Print_Eol;
632
      end if;
633
 
634
      if Field_Present (Field23 (Ent)) then
635
         Print_Str (Prefix);
636
         Write_Field23_Name (Ent);
637
         Write_Str (" = ");
638
         Print_Field (Field23 (Ent));
639
         Print_Eol;
640
      end if;
641
 
642
      if Field_Present (Field24 (Ent)) then
643
         Print_Str (Prefix);
644
         Write_Field24_Name (Ent);
645
         Write_Str (" = ");
646
         Print_Field (Field24 (Ent));
647
         Print_Eol;
648
      end if;
649
 
650
      if Field_Present (Field25 (Ent)) then
651
         Print_Str (Prefix);
652
         Write_Field25_Name (Ent);
653
         Write_Str (" = ");
654
         Print_Field (Field25 (Ent));
655
         Print_Eol;
656
      end if;
657
 
658
      if Field_Present (Field26 (Ent)) then
659
         Print_Str (Prefix);
660
         Write_Field26_Name (Ent);
661
         Write_Str (" = ");
662
         Print_Field (Field26 (Ent));
663
         Print_Eol;
664
      end if;
665
 
666
      if Field_Present (Field27 (Ent)) then
667
         Print_Str (Prefix);
668
         Write_Field27_Name (Ent);
669
         Write_Str (" = ");
670
         Print_Field (Field27 (Ent));
671
         Print_Eol;
672
      end if;
673
 
674
      if Field_Present (Field28 (Ent)) then
675
         Print_Str (Prefix);
676
         Write_Field28_Name (Ent);
677
         Write_Str (" = ");
678
         Print_Field (Field28 (Ent));
679
         Print_Eol;
680
      end if;
681
 
682
      if Field_Present (Field29 (Ent)) then
683
         Print_Str (Prefix);
684
         Write_Field29_Name (Ent);
685
         Write_Str (" = ");
686
         Print_Field (Field29 (Ent));
687
         Print_Eol;
688
      end if;
689
 
690
      Write_Entity_Flags (Ent, Prefix);
691
   end Print_Entity_Info;
692
 
693
   ---------------
694
   -- Print_Eol --
695
   ---------------
696
 
697
   procedure Print_Eol is
698
   begin
699
      if Phase = Printing then
700
         Write_Eol;
701
      end if;
702
   end Print_Eol;
703
 
704
   -----------------
705
   -- Print_Field --
706
   -----------------
707
 
708
   procedure Print_Field (Val : Union_Id; Format : UI_Format := Auto) is
709
   begin
710
      if Phase /= Printing then
711
         return;
712
      end if;
713
 
714
      if Val in Node_Range then
715
         Print_Node_Ref (Node_Id (Val));
716
 
717
      elsif Val in List_Range then
718
         Print_List_Ref (List_Id (Val));
719
 
720
      elsif Val in Elist_Range then
721
         Print_Elist_Ref (Elist_Id (Val));
722
 
723
      elsif Val in Names_Range then
724
         Print_Name (Name_Id (Val));
725
         Write_Str (" (Name_Id=");
726
         Write_Int (Int (Val));
727
         Write_Char (')');
728
 
729
      elsif Val in Strings_Range then
730
         Write_String_Table_Entry (String_Id (Val));
731
         Write_Str (" (String_Id=");
732
         Write_Int (Int (Val));
733
         Write_Char (')');
734
 
735
      elsif Val in Uint_Range then
736
         UI_Write (From_Union (Val), Format);
737
         Write_Str (" (Uint = ");
738
         Write_Int (Int (Val));
739
         Write_Char (')');
740
 
741
      elsif Val in Ureal_Range then
742
         UR_Write (From_Union (Val));
743
         Write_Str (" (Ureal = ");
744
         Write_Int (Int (Val));
745
         Write_Char (')');
746
 
747
      else
748
         Print_Str ("****** Incorrect value = ");
749
         Print_Int (Int (Val));
750
      end if;
751
   end Print_Field;
752
 
753
   ----------------
754
   -- Print_Flag --
755
   ----------------
756
 
757
   procedure Print_Flag (F : Boolean) is
758
   begin
759
      if F then
760
         Print_Str ("True");
761
      else
762
         Print_Str ("False");
763
      end if;
764
   end Print_Flag;
765
 
766
   ----------------
767
   -- Print_Init --
768
   ----------------
769
 
770
   procedure Print_Init is
771
   begin
772
      Printing_Descendants := True;
773
      Write_Eol;
774
 
775
      --  Allocate and clear serial number hash table. The size is 150% of
776
      --  the maximum possible number of entries, so that the hash table
777
      --  cannot get significantly overloaded.
778
 
779
      Hash_Table_Len := (150 * (Num_Nodes + Num_Lists + Num_Elists)) / 100;
780
      Hash_Table := new Hash_Table_Type  (0 .. Hash_Table_Len - 1);
781
 
782
      for J in Hash_Table'Range loop
783
         Hash_Table (J).Serial := 0;
784
      end loop;
785
 
786
   end Print_Init;
787
 
788
   ---------------
789
   -- Print_Int --
790
   ---------------
791
 
792
   procedure Print_Int (I : Int) is
793
   begin
794
      if Phase = Printing then
795
         Write_Int (I);
796
      end if;
797
   end Print_Int;
798
 
799
   --------------------
800
   -- Print_List_Ref --
801
   --------------------
802
 
803
   procedure Print_List_Ref (L : List_Id) is
804
   begin
805
      if Phase /= Printing then
806
         return;
807
      end if;
808
 
809
      if No (L) then
810
         Write_Str ("<no list>");
811
 
812
      elsif Is_Empty_List (L) then
813
         Write_Str ("<empty list> (List_Id=");
814
         Write_Int (Int (L));
815
         Write_Char (')');
816
 
817
      else
818
         Write_Str ("List");
819
 
820
         if Printing_Descendants then
821
            Write_Str (" #");
822
            Write_Int (Serial_Number (Int (L)));
823
         end if;
824
 
825
         Write_Str (" (List_Id=");
826
         Write_Int (Int (L));
827
         Write_Char (')');
828
      end if;
829
   end Print_List_Ref;
830
 
831
   ------------------------
832
   -- Print_List_Subtree --
833
   ------------------------
834
 
835
   procedure Print_List_Subtree (L : List_Id) is
836
   begin
837
      Print_Init;
838
 
839
      Next_Serial_Number := 1;
840
      Phase := Marking;
841
      Visit_List (L, "");
842
 
843
      Next_Serial_Number := 1;
844
      Phase := Printing;
845
      Visit_List (L, "");
846
 
847
      Print_Term;
848
   end Print_List_Subtree;
849
 
850
   ----------------
851
   -- Print_Name --
852
   ----------------
853
 
854
   procedure Print_Name (N : Name_Id) is
855
   begin
856
      if Phase = Printing then
857
         if N = No_Name then
858
            Print_Str ("<No_Name>");
859
 
860
         elsif N = Error_Name then
861
            Print_Str ("<Error_Name>");
862
 
863
         elsif Is_Valid_Name (N) then
864
            Get_Name_String (N);
865
            Print_Char ('"');
866
            Write_Name (N);
867
            Print_Char ('"');
868
 
869
         else
870
            Print_Str ("<invalid name ???>");
871
         end if;
872
      end if;
873
   end Print_Name;
874
 
875
   ----------------
876
   -- Print_Node --
877
   ----------------
878
 
879
   procedure Print_Node
880
     (N           : Node_Id;
881
      Prefix_Str  : String;
882
      Prefix_Char : Character)
883
   is
884
      F : Fchar;
885
      P : Natural := Pchar_Pos (Nkind (N));
886
 
887
      Field_To_Be_Printed : Boolean;
888
      Prefix_Str_Char     : String (Prefix_Str'First .. Prefix_Str'Last + 1);
889
 
890
      Sfile : Source_File_Index;
891
      Fmt   : UI_Format;
892
 
893
   begin
894
      if Phase /= Printing then
895
         return;
896
      end if;
897
 
898
      if Nkind (N) = N_Integer_Literal and then Print_In_Hex (N) then
899
         Fmt := Hex;
900
      else
901
         Fmt := Auto;
902
      end if;
903
 
904
      Prefix_Str_Char (Prefix_Str'Range)    := Prefix_Str;
905
      Prefix_Str_Char (Prefix_Str'Last + 1) := Prefix_Char;
906
 
907
      --  Print header line
908
 
909
      Print_Str (Prefix_Str);
910
      Print_Node_Header (N);
911
 
912
      if Is_Rewrite_Substitution (N) then
913
         Print_Str (Prefix_Str);
914
         Print_Str (" Rewritten: original node = ");
915
         Print_Node_Ref (Original_Node (N));
916
         Print_Eol;
917
      end if;
918
 
919
      if N = Empty then
920
         return;
921
      end if;
922
 
923
      if not Is_List_Member (N) then
924
         Print_Str (Prefix_Str);
925
         Print_Str (" Parent = ");
926
         Print_Node_Ref (Parent (N));
927
         Print_Eol;
928
      end if;
929
 
930
      --  Print Sloc field if it is set
931
 
932
      if Sloc (N) /= No_Location then
933
         Print_Str (Prefix_Str_Char);
934
         Print_Str ("Sloc = ");
935
 
936
         if Sloc (N) = Standard_Location then
937
            Print_Str ("Standard_Location");
938
 
939
         elsif Sloc (N) = Standard_ASCII_Location then
940
            Print_Str ("Standard_ASCII_Location");
941
 
942
         else
943
            Sfile := Get_Source_File_Index (Sloc (N));
944
            Print_Int (Int (Sloc (N)) - Int (Source_Text (Sfile)'First));
945
            Write_Str ("  ");
946
            Write_Location (Sloc (N));
947
         end if;
948
 
949
         Print_Eol;
950
      end if;
951
 
952
      --  Print Chars field if present
953
 
954
      if Nkind (N) in N_Has_Chars and then Chars (N) /= No_Name then
955
         Print_Str (Prefix_Str_Char);
956
         Print_Str ("Chars = ");
957
         Print_Name (Chars (N));
958
         Write_Str (" (Name_Id=");
959
         Write_Int (Int (Chars (N)));
960
         Write_Char (')');
961
         Print_Eol;
962
      end if;
963
 
964
      --  Special field print operations for non-entity nodes
965
 
966
      if Nkind (N) not in N_Entity then
967
 
968
         --  Deal with Left_Opnd and Right_Opnd fields
969
 
970
         if Nkind (N) in N_Op
971
           or else Nkind (N) in N_Short_Circuit
972
           or else Nkind (N) in N_Membership_Test
973
         then
974
            --  Print Left_Opnd if present
975
 
976
            if Nkind (N) not in N_Unary_Op then
977
               Print_Str (Prefix_Str_Char);
978
               Print_Str ("Left_Opnd = ");
979
               Print_Node_Ref (Left_Opnd (N));
980
               Print_Eol;
981
            end if;
982
 
983
            --  Print Right_Opnd
984
 
985
            Print_Str (Prefix_Str_Char);
986
            Print_Str ("Right_Opnd = ");
987
            Print_Node_Ref (Right_Opnd (N));
988
            Print_Eol;
989
         end if;
990
 
991
         --  Print Entity field if operator (other cases of Entity
992
         --  are in the table, so are handled in the normal circuit)
993
 
994
         if Nkind (N) in N_Op and then Present (Entity (N)) then
995
            Print_Str (Prefix_Str_Char);
996
            Print_Str ("Entity = ");
997
            Print_Node_Ref (Entity (N));
998
            Print_Eol;
999
         end if;
1000
 
1001
         --  Print special fields if we have a subexpression
1002
 
1003
         if Nkind (N) in N_Subexpr then
1004
 
1005
            if Assignment_OK (N) then
1006
               Print_Str (Prefix_Str_Char);
1007
               Print_Str ("Assignment_OK = True");
1008
               Print_Eol;
1009
            end if;
1010
 
1011
            if Do_Range_Check (N) then
1012
               Print_Str (Prefix_Str_Char);
1013
               Print_Str ("Do_Range_Check = True");
1014
               Print_Eol;
1015
            end if;
1016
 
1017
            if Has_Dynamic_Length_Check (N) then
1018
               Print_Str (Prefix_Str_Char);
1019
               Print_Str ("Has_Dynamic_Length_Check = True");
1020
               Print_Eol;
1021
            end if;
1022
 
1023
            if Has_Aspects (N) then
1024
               Print_Str (Prefix_Str_Char);
1025
               Print_Str ("Has_Aspects = True");
1026
               Print_Eol;
1027
            end if;
1028
 
1029
            if Has_Dynamic_Range_Check (N) then
1030
               Print_Str (Prefix_Str_Char);
1031
               Print_Str ("Has_Dynamic_Range_Check = True");
1032
               Print_Eol;
1033
            end if;
1034
 
1035
            if Is_Controlling_Actual (N) then
1036
               Print_Str (Prefix_Str_Char);
1037
               Print_Str ("Is_Controlling_Actual = True");
1038
               Print_Eol;
1039
            end if;
1040
 
1041
            if Is_Overloaded (N) then
1042
               Print_Str (Prefix_Str_Char);
1043
               Print_Str ("Is_Overloaded = True");
1044
               Print_Eol;
1045
            end if;
1046
 
1047
            if Is_Static_Expression (N) then
1048
               Print_Str (Prefix_Str_Char);
1049
               Print_Str ("Is_Static_Expression = True");
1050
               Print_Eol;
1051
            end if;
1052
 
1053
            if Must_Not_Freeze (N) then
1054
               Print_Str (Prefix_Str_Char);
1055
               Print_Str ("Must_Not_Freeze = True");
1056
               Print_Eol;
1057
            end if;
1058
 
1059
            if Paren_Count (N) /= 0 then
1060
               Print_Str (Prefix_Str_Char);
1061
               Print_Str ("Paren_Count = ");
1062
               Print_Int (Int (Paren_Count (N)));
1063
               Print_Eol;
1064
            end if;
1065
 
1066
            if Raises_Constraint_Error (N) then
1067
               Print_Str (Prefix_Str_Char);
1068
               Print_Str ("Raise_Constraint_Error = True");
1069
               Print_Eol;
1070
            end if;
1071
 
1072
         end if;
1073
 
1074
         --  Print Do_Overflow_Check field if present
1075
 
1076
         if Nkind (N) in N_Op and then Do_Overflow_Check (N) then
1077
            Print_Str (Prefix_Str_Char);
1078
            Print_Str ("Do_Overflow_Check = True");
1079
            Print_Eol;
1080
         end if;
1081
 
1082
         --  Print Etype field if present (printing of this field for entities
1083
         --  is handled by the Print_Entity_Info procedure).
1084
 
1085
         if Nkind (N) in N_Has_Etype and then Present (Etype (N)) then
1086
            Print_Str (Prefix_Str_Char);
1087
            Print_Str ("Etype = ");
1088
            Print_Node_Ref (Etype (N));
1089
            Print_Eol;
1090
         end if;
1091
      end if;
1092
 
1093
      --  Loop to print fields included in Pchars array
1094
 
1095
      while P < Pchar_Pos (Node_Kind'Succ (Nkind (N))) loop
1096
         F := Pchars (P);
1097
         P := P + 1;
1098
 
1099
         --  Check for case of False flag, which we never print, or
1100
         --  an Empty field, which is also never printed
1101
 
1102
         case F is
1103
            when F_Field1 =>
1104
               Field_To_Be_Printed := Field1 (N) /= Union_Id (Empty);
1105
 
1106
            when F_Field2 =>
1107
               Field_To_Be_Printed := Field2 (N) /= Union_Id (Empty);
1108
 
1109
            when F_Field3 =>
1110
               Field_To_Be_Printed := Field3 (N) /= Union_Id (Empty);
1111
 
1112
            when F_Field4 =>
1113
               Field_To_Be_Printed := Field4 (N) /= Union_Id (Empty);
1114
 
1115
            when F_Field5 =>
1116
               Field_To_Be_Printed := Field5 (N) /= Union_Id (Empty);
1117
 
1118
            --  Flag3 is obsolete, so this probably gets removed ???
1119
 
1120
            when F_Flag3 => Field_To_Be_Printed := Has_Aspects (N);
1121
 
1122
            when F_Flag4  => Field_To_Be_Printed := Flag4  (N);
1123
            when F_Flag5  => Field_To_Be_Printed := Flag5  (N);
1124
            when F_Flag6  => Field_To_Be_Printed := Flag6  (N);
1125
            when F_Flag7  => Field_To_Be_Printed := Flag7  (N);
1126
            when F_Flag8  => Field_To_Be_Printed := Flag8  (N);
1127
            when F_Flag9  => Field_To_Be_Printed := Flag9  (N);
1128
            when F_Flag10 => Field_To_Be_Printed := Flag10 (N);
1129
            when F_Flag11 => Field_To_Be_Printed := Flag11 (N);
1130
            when F_Flag12 => Field_To_Be_Printed := Flag12 (N);
1131
            when F_Flag13 => Field_To_Be_Printed := Flag13 (N);
1132
            when F_Flag14 => Field_To_Be_Printed := Flag14 (N);
1133
            when F_Flag15 => Field_To_Be_Printed := Flag15 (N);
1134
            when F_Flag16 => Field_To_Be_Printed := Flag16 (N);
1135
            when F_Flag17 => Field_To_Be_Printed := Flag17 (N);
1136
            when F_Flag18 => Field_To_Be_Printed := Flag18 (N);
1137
 
1138
            --  Flag1,2 are no longer used
1139
 
1140
            when F_Flag1  => raise Program_Error;
1141
            when F_Flag2  => raise Program_Error;
1142
         end case;
1143
 
1144
         --  Print field if it is to be printed
1145
 
1146
         if Field_To_Be_Printed then
1147
            Print_Str (Prefix_Str_Char);
1148
 
1149
            while P < Pchar_Pos (Node_Kind'Succ (Nkind (N)))
1150
              and then Pchars (P) not in Fchar
1151
            loop
1152
               Print_Char (Pchars (P));
1153
               P := P + 1;
1154
            end loop;
1155
 
1156
            Print_Str (" = ");
1157
 
1158
            case F is
1159
               when F_Field1 => Print_Field (Field1 (N), Fmt);
1160
               when F_Field2 => Print_Field (Field2 (N), Fmt);
1161
               when F_Field3 => Print_Field (Field3 (N), Fmt);
1162
               when F_Field4 => Print_Field (Field4 (N), Fmt);
1163
 
1164
               --  Special case End_Span = Uint5
1165
 
1166
               when F_Field5 =>
1167
                  if Nkind (N) = N_Case_Statement
1168
                    or else Nkind (N) = N_If_Statement
1169
                  then
1170
                     Print_End_Span (N);
1171
                  else
1172
                     Print_Field (Field5 (N), Fmt);
1173
                  end if;
1174
 
1175
               when F_Flag4  => Print_Flag  (Flag4 (N));
1176
               when F_Flag5  => Print_Flag  (Flag5 (N));
1177
               when F_Flag6  => Print_Flag  (Flag6 (N));
1178
               when F_Flag7  => Print_Flag  (Flag7 (N));
1179
               when F_Flag8  => Print_Flag  (Flag8 (N));
1180
               when F_Flag9  => Print_Flag  (Flag9 (N));
1181
               when F_Flag10 => Print_Flag  (Flag10 (N));
1182
               when F_Flag11 => Print_Flag  (Flag11 (N));
1183
               when F_Flag12 => Print_Flag  (Flag12 (N));
1184
               when F_Flag13 => Print_Flag  (Flag13 (N));
1185
               when F_Flag14 => Print_Flag  (Flag14 (N));
1186
               when F_Flag15 => Print_Flag  (Flag15 (N));
1187
               when F_Flag16 => Print_Flag  (Flag16 (N));
1188
               when F_Flag17 => Print_Flag  (Flag17 (N));
1189
               when F_Flag18 => Print_Flag  (Flag18 (N));
1190
 
1191
               --  Flag1,2 are no longer used
1192
 
1193
               when F_Flag1  => raise Program_Error;
1194
               when F_Flag2  => raise Program_Error;
1195
 
1196
               --  Not clear why we need the following ???
1197
 
1198
               when F_Flag3  => Print_Flag (Has_Aspects (N));
1199
            end case;
1200
 
1201
            Print_Eol;
1202
 
1203
         --  Field is not to be printed (False flag field)
1204
 
1205
         else
1206
            while P < Pchar_Pos (Node_Kind'Succ (Nkind (N)))
1207
              and then Pchars (P) not in Fchar
1208
            loop
1209
               P := P + 1;
1210
            end loop;
1211
         end if;
1212
      end loop;
1213
 
1214
      --  Print aspects if present
1215
 
1216
      if Has_Aspects (N) then
1217
         Print_Str (Prefix_Str_Char);
1218
         Print_Str ("Aspect_Specifications = ");
1219
         Print_Field (Union_Id (Aspect_Specifications (N)));
1220
         Print_Eol;
1221
      end if;
1222
 
1223
      --  Print entity information for entities
1224
 
1225
      if Nkind (N) in N_Entity then
1226
         Print_Entity_Info (N, Prefix_Str_Char);
1227
      end if;
1228
 
1229
      --  Print the SCIL node (if available)
1230
 
1231
      if Present (Get_SCIL_Node (N)) then
1232
         Print_Str (Prefix_Str_Char);
1233
         Print_Str ("SCIL_Node = ");
1234
         Print_Node_Ref (Get_SCIL_Node (N));
1235
         Print_Eol;
1236
      end if;
1237
   end Print_Node;
1238
 
1239
   ------------------------
1240
   -- Print_Node_Briefly --
1241
   ------------------------
1242
 
1243
   procedure Print_Node_Briefly (N : Node_Id) is
1244
   begin
1245
      Printing_Descendants := False;
1246
      Phase := Printing;
1247
      Print_Node_Header (N);
1248
   end Print_Node_Briefly;
1249
 
1250
   -----------------------
1251
   -- Print_Node_Header --
1252
   -----------------------
1253
 
1254
   procedure Print_Node_Header (N : Node_Id) is
1255
      Notes : Boolean := False;
1256
 
1257
   begin
1258
      Print_Node_Ref (N);
1259
 
1260
      if N > Atree_Private_Part.Nodes.Last then
1261
         Print_Str (" (no such node)");
1262
         Print_Eol;
1263
         return;
1264
      end if;
1265
 
1266
      if Comes_From_Source (N) then
1267
         Notes := True;
1268
         Print_Str (" (source");
1269
      end if;
1270
 
1271
      if Analyzed (N) then
1272
         if not Notes then
1273
            Notes := True;
1274
            Print_Str (" (");
1275
         else
1276
            Print_Str (",");
1277
         end if;
1278
 
1279
         Print_Str ("analyzed");
1280
      end if;
1281
 
1282
      if Error_Posted (N) then
1283
         if not Notes then
1284
            Notes := True;
1285
            Print_Str (" (");
1286
         else
1287
            Print_Str (",");
1288
         end if;
1289
 
1290
         Print_Str ("posted");
1291
      end if;
1292
 
1293
      if Notes then
1294
         Print_Char (')');
1295
      end if;
1296
 
1297
      Print_Eol;
1298
   end Print_Node_Header;
1299
 
1300
   ---------------------
1301
   -- Print_Node_Kind --
1302
   ---------------------
1303
 
1304
   procedure Print_Node_Kind (N : Node_Id) is
1305
      Ucase : Boolean;
1306
      S     : constant String := Node_Kind'Image (Nkind (N));
1307
 
1308
   begin
1309
      if Phase = Printing then
1310
         Ucase := True;
1311
 
1312
         --  Note: the call to Fold_Upper in this loop is to get past the GNAT
1313
         --  bug of 'Image returning lower case instead of upper case.
1314
 
1315
         for J in S'Range loop
1316
            if Ucase then
1317
               Write_Char (Fold_Upper (S (J)));
1318
            else
1319
               Write_Char (Fold_Lower (S (J)));
1320
            end if;
1321
 
1322
            Ucase := (S (J) = '_');
1323
         end loop;
1324
      end if;
1325
   end Print_Node_Kind;
1326
 
1327
   --------------------
1328
   -- Print_Node_Ref --
1329
   --------------------
1330
 
1331
   procedure Print_Node_Ref (N : Node_Id) is
1332
      S : Nat;
1333
 
1334
   begin
1335
      if Phase /= Printing then
1336
         return;
1337
      end if;
1338
 
1339
      if N = Empty then
1340
         Write_Str ("<empty>");
1341
 
1342
      elsif N = Error then
1343
         Write_Str ("<error>");
1344
 
1345
      else
1346
         if Printing_Descendants then
1347
            S := Serial_Number (Int (N));
1348
 
1349
            if S /= 0 then
1350
               Write_Str ("Node");
1351
               Write_Str (" #");
1352
               Write_Int (S);
1353
               Write_Char (' ');
1354
            end if;
1355
         end if;
1356
 
1357
         Print_Node_Kind (N);
1358
 
1359
         if Nkind (N) in N_Has_Chars then
1360
            Write_Char (' ');
1361
            Print_Name (Chars (N));
1362
         end if;
1363
 
1364
         if Nkind (N) in N_Entity then
1365
            Write_Str (" (Entity_Id=");
1366
         else
1367
            Write_Str (" (Node_Id=");
1368
         end if;
1369
 
1370
         Write_Int (Int (N));
1371
 
1372
         if Sloc (N) <= Standard_Location then
1373
            Write_Char ('s');
1374
         end if;
1375
 
1376
         Write_Char (')');
1377
 
1378
      end if;
1379
   end Print_Node_Ref;
1380
 
1381
   ------------------------
1382
   -- Print_Node_Subtree --
1383
   ------------------------
1384
 
1385
   procedure Print_Node_Subtree (N : Node_Id) is
1386
   begin
1387
      Print_Init;
1388
 
1389
      Next_Serial_Number := 1;
1390
      Phase := Marking;
1391
      Visit_Node (N, "", ' ');
1392
 
1393
      Next_Serial_Number := 1;
1394
      Phase := Printing;
1395
      Visit_Node (N, "", ' ');
1396
 
1397
      Print_Term;
1398
   end Print_Node_Subtree;
1399
 
1400
   ---------------
1401
   -- Print_Str --
1402
   ---------------
1403
 
1404
   procedure Print_Str (S : String) is
1405
   begin
1406
      if Phase = Printing then
1407
         Write_Str (S);
1408
      end if;
1409
   end Print_Str;
1410
 
1411
   --------------------------
1412
   -- Print_Str_Mixed_Case --
1413
   --------------------------
1414
 
1415
   procedure Print_Str_Mixed_Case (S : String) is
1416
      Ucase : Boolean;
1417
 
1418
   begin
1419
      if Phase = Printing then
1420
         Ucase := True;
1421
 
1422
         for J in S'Range loop
1423
            if Ucase then
1424
               Write_Char (S (J));
1425
            else
1426
               Write_Char (Fold_Lower (S (J)));
1427
            end if;
1428
 
1429
            Ucase := (S (J) = '_');
1430
         end loop;
1431
      end if;
1432
   end Print_Str_Mixed_Case;
1433
 
1434
   ----------------
1435
   -- Print_Term --
1436
   ----------------
1437
 
1438
   procedure Print_Term is
1439
      procedure Free is new Unchecked_Deallocation
1440
        (Hash_Table_Type, Access_Hash_Table_Type);
1441
 
1442
   begin
1443
      Free (Hash_Table);
1444
   end Print_Term;
1445
 
1446
   ---------------------
1447
   -- Print_Tree_Elist --
1448
   ---------------------
1449
 
1450
   procedure Print_Tree_Elist (E : Elist_Id) is
1451
      M : Elmt_Id;
1452
 
1453
   begin
1454
      Printing_Descendants := False;
1455
      Phase := Printing;
1456
 
1457
      Print_Elist_Ref (E);
1458
      Print_Eol;
1459
 
1460
      M := First_Elmt (E);
1461
 
1462
      if No (M) then
1463
         Print_Str ("<empty element list>");
1464
         Print_Eol;
1465
 
1466
      else
1467
         loop
1468
            Print_Char ('|');
1469
            Print_Eol;
1470
            exit when No (Next_Elmt (M));
1471
            Print_Node (Node (M), "", '|');
1472
            Next_Elmt (M);
1473
         end loop;
1474
 
1475
         Print_Node (Node (M), "", ' ');
1476
         Print_Eol;
1477
      end if;
1478
   end Print_Tree_Elist;
1479
 
1480
   ---------------------
1481
   -- Print_Tree_List --
1482
   ---------------------
1483
 
1484
   procedure Print_Tree_List (L : List_Id) is
1485
      N : Node_Id;
1486
 
1487
   begin
1488
      Printing_Descendants := False;
1489
      Phase := Printing;
1490
 
1491
      Print_List_Ref (L);
1492
      Print_Str (" List_Id=");
1493
      Print_Int (Int (L));
1494
      Print_Eol;
1495
 
1496
      N := First (L);
1497
 
1498
      if N = Empty then
1499
         Print_Str ("<empty node list>");
1500
         Print_Eol;
1501
 
1502
      else
1503
         loop
1504
            Print_Char ('|');
1505
            Print_Eol;
1506
            exit when Next (N) = Empty;
1507
            Print_Node (N, "", '|');
1508
            Next (N);
1509
         end loop;
1510
 
1511
         Print_Node (N, "", ' ');
1512
         Print_Eol;
1513
      end if;
1514
   end Print_Tree_List;
1515
 
1516
   ---------------------
1517
   -- Print_Tree_Node --
1518
   ---------------------
1519
 
1520
   procedure Print_Tree_Node (N : Node_Id; Label : String := "") is
1521
   begin
1522
      Printing_Descendants := False;
1523
      Phase := Printing;
1524
      Print_Node (N, Label, ' ');
1525
   end Print_Tree_Node;
1526
 
1527
   --------
1528
   -- pt --
1529
   --------
1530
 
1531
   procedure pt (N : Node_Id) is
1532
   begin
1533
      Print_Node_Subtree (N);
1534
   end pt;
1535
 
1536
   ---------
1537
   -- ppp --
1538
   ---------
1539
 
1540
   procedure ppp (N : Node_Id) is
1541
   begin
1542
      pt (N);
1543
   end ppp;
1544
 
1545
   -------------------
1546
   -- Serial_Number --
1547
   -------------------
1548
 
1549
   --  The hashing algorithm is to use the remainder of the ID value divided
1550
   --  by the hash table length as the starting point in the table, and then
1551
   --  handle collisions by serial searching wrapping at the end of the table.
1552
 
1553
   Hash_Slot : Nat;
1554
   --  Set by an unsuccessful call to Serial_Number (one which returns zero)
1555
   --  to save the slot that should be used if Set_Serial_Number is called.
1556
 
1557
   function Serial_Number (Id : Int) return Nat is
1558
      H : Int := Id mod Hash_Table_Len;
1559
 
1560
   begin
1561
      while Hash_Table (H).Serial /= 0 loop
1562
 
1563
         if Id = Hash_Table (H).Id then
1564
            return Hash_Table (H).Serial;
1565
         end if;
1566
 
1567
         H := H + 1;
1568
 
1569
         if H > Hash_Table'Last then
1570
            H := 0;
1571
         end if;
1572
      end loop;
1573
 
1574
      --  Entry was not found, save slot number for possible subsequent call
1575
      --  to Set_Serial_Number, and unconditionally save the Id in this slot
1576
      --  in case of such a call (the Id field is never read if the serial
1577
      --  number of the slot is zero, so this is harmless in the case where
1578
      --  Set_Serial_Number is not subsequently called).
1579
 
1580
      Hash_Slot := H;
1581
      Hash_Table (H).Id := Id;
1582
      return 0;
1583
 
1584
   end Serial_Number;
1585
 
1586
   -----------------------
1587
   -- Set_Serial_Number --
1588
   -----------------------
1589
 
1590
   procedure Set_Serial_Number is
1591
   begin
1592
      Hash_Table (Hash_Slot).Serial := Next_Serial_Number;
1593
      Next_Serial_Number := Next_Serial_Number + 1;
1594
   end Set_Serial_Number;
1595
 
1596
   ---------------
1597
   -- Tree_Dump --
1598
   ---------------
1599
 
1600
   procedure Tree_Dump is
1601
      procedure Underline;
1602
      --  Put underline under string we just printed
1603
 
1604
      procedure Underline is
1605
         Col : constant Int := Column;
1606
 
1607
      begin
1608
         Write_Eol;
1609
 
1610
         while Col > Column loop
1611
            Write_Char ('-');
1612
         end loop;
1613
 
1614
         Write_Eol;
1615
      end Underline;
1616
 
1617
   --  Start of processing for Tree_Dump. Note that we turn off the tree dump
1618
   --  flags immediately, before starting the dump. This avoids generating two
1619
   --  copies of the dump if an abort occurs after printing the dump, and more
1620
   --  importantly, avoids an infinite loop if an abort occurs during the dump.
1621
 
1622
   --  Note: unlike in the source print case (in Sprint), we do not output
1623
   --  separate trees for each unit. Instead the -df debug switch causes the
1624
   --  tree that is output from the main unit to trace references into other
1625
   --  units (normally such references are not traced). Since all other units
1626
   --  are linked to the main unit by at least one reference, this causes all
1627
   --  tree nodes to be included in the output tree.
1628
 
1629
   begin
1630
      if Debug_Flag_Y then
1631
         Debug_Flag_Y := False;
1632
         Write_Eol;
1633
         Write_Str ("Tree created for Standard (spec) ");
1634
         Underline;
1635
         Print_Node_Subtree (Standard_Package_Node);
1636
         Write_Eol;
1637
      end if;
1638
 
1639
      if Debug_Flag_T then
1640
         Debug_Flag_T := False;
1641
 
1642
         Write_Eol;
1643
         Write_Str ("Tree created for ");
1644
         Write_Unit_Name (Unit_Name (Main_Unit));
1645
         Underline;
1646
         Print_Node_Subtree (Cunit (Main_Unit));
1647
         Write_Eol;
1648
      end if;
1649
 
1650
   end Tree_Dump;
1651
 
1652
   -----------------
1653
   -- Visit_Elist --
1654
   -----------------
1655
 
1656
   procedure Visit_Elist (E : Elist_Id; Prefix_Str : String) is
1657
      M : Elmt_Id;
1658
      N : Node_Id;
1659
      S : constant Nat := Serial_Number (Int (E));
1660
 
1661
   begin
1662
      --  In marking phase, return if already marked, otherwise set next
1663
      --  serial number in hash table for later reference.
1664
 
1665
      if Phase = Marking then
1666
         if S /= 0 then
1667
            return; -- already visited
1668
         else
1669
            Set_Serial_Number;
1670
         end if;
1671
 
1672
      --  In printing phase, if already printed, then return, otherwise we
1673
      --  are printing the next item, so increment the serial number.
1674
 
1675
      else
1676
         if S < Next_Serial_Number then
1677
            return; -- already printed
1678
         else
1679
            Next_Serial_Number := Next_Serial_Number + 1;
1680
         end if;
1681
      end if;
1682
 
1683
      --  Now process the list (Print calls have no effect in marking phase)
1684
 
1685
      Print_Str (Prefix_Str);
1686
      Print_Elist_Ref (E);
1687
      Print_Eol;
1688
 
1689
      if Is_Empty_Elmt_List (E) then
1690
         Print_Str (Prefix_Str);
1691
         Print_Str ("(Empty element list)");
1692
         Print_Eol;
1693
         Print_Eol;
1694
 
1695
      else
1696
         if Phase = Printing then
1697
            M := First_Elmt (E);
1698
            while Present (M) loop
1699
               N := Node (M);
1700
               Print_Str (Prefix_Str);
1701
               Print_Str (" ");
1702
               Print_Node_Ref (N);
1703
               Print_Eol;
1704
               Next_Elmt (M);
1705
            end loop;
1706
 
1707
            Print_Str (Prefix_Str);
1708
            Print_Eol;
1709
         end if;
1710
 
1711
         M := First_Elmt (E);
1712
         while Present (M) loop
1713
            Visit_Node (Node (M), Prefix_Str, ' ');
1714
            Next_Elmt (M);
1715
         end loop;
1716
      end if;
1717
   end Visit_Elist;
1718
 
1719
   ----------------
1720
   -- Visit_List --
1721
   ----------------
1722
 
1723
   procedure Visit_List (L : List_Id; Prefix_Str : String) is
1724
      N : Node_Id;
1725
      S : constant Nat := Serial_Number (Int (L));
1726
 
1727
   begin
1728
      --  In marking phase, return if already marked, otherwise set next
1729
      --  serial number in hash table for later reference.
1730
 
1731
      if Phase = Marking then
1732
         if S /= 0 then
1733
            return;
1734
         else
1735
            Set_Serial_Number;
1736
         end if;
1737
 
1738
      --  In printing phase, if already printed, then return, otherwise we
1739
      --  are printing the next item, so increment the serial number.
1740
 
1741
      else
1742
         if S < Next_Serial_Number then
1743
            return; -- already printed
1744
         else
1745
            Next_Serial_Number := Next_Serial_Number + 1;
1746
         end if;
1747
      end if;
1748
 
1749
      --  Now process the list (Print calls have no effect in marking phase)
1750
 
1751
      Print_Str (Prefix_Str);
1752
      Print_List_Ref (L);
1753
      Print_Eol;
1754
 
1755
      Print_Str (Prefix_Str);
1756
      Print_Str ("|Parent = ");
1757
      Print_Node_Ref (Parent (L));
1758
      Print_Eol;
1759
 
1760
      N := First (L);
1761
 
1762
      if N = Empty then
1763
         Print_Str (Prefix_Str);
1764
         Print_Str ("(Empty list)");
1765
         Print_Eol;
1766
         Print_Eol;
1767
 
1768
      else
1769
         Print_Str (Prefix_Str);
1770
         Print_Char ('|');
1771
         Print_Eol;
1772
 
1773
         while Next (N) /= Empty loop
1774
            Visit_Node (N, Prefix_Str, '|');
1775
            Next (N);
1776
         end loop;
1777
      end if;
1778
 
1779
      Visit_Node (N, Prefix_Str, ' ');
1780
   end Visit_List;
1781
 
1782
   ----------------
1783
   -- Visit_Node --
1784
   ----------------
1785
 
1786
   procedure Visit_Node
1787
     (N           : Node_Id;
1788
      Prefix_Str  : String;
1789
      Prefix_Char : Character)
1790
   is
1791
      New_Prefix : String (Prefix_Str'First .. Prefix_Str'Last + 2);
1792
      --  Prefix string for printing referenced fields
1793
 
1794
      procedure Visit_Descendent
1795
        (D         : Union_Id;
1796
         No_Indent : Boolean := False);
1797
      --  This procedure tests the given value of one of the Fields referenced
1798
      --  by the current node to determine whether to visit it recursively.
1799
      --  Normally No_Indent is false, which means that the visited node will
1800
      --  be indented using New_Prefix. If No_Indent is set to True, then
1801
      --  this indentation is skipped, and Prefix_Str is used for the call
1802
      --  to print the descendent. No_Indent is effective only if the
1803
      --  referenced descendent is a node.
1804
 
1805
      ----------------------
1806
      -- Visit_Descendent --
1807
      ----------------------
1808
 
1809
      procedure Visit_Descendent
1810
        (D         : Union_Id;
1811
         No_Indent : Boolean := False)
1812
      is
1813
      begin
1814
         --  Case of descendent is a node
1815
 
1816
         if D in Node_Range then
1817
 
1818
            --  Don't bother about Empty or Error descendents
1819
 
1820
            if D <= Union_Id (Empty_Or_Error) then
1821
               return;
1822
            end if;
1823
 
1824
            declare
1825
               Nod : constant Node_Or_Entity_Id := Node_Or_Entity_Id (D);
1826
 
1827
            begin
1828
               --  Descendents in one of the standardly compiled internal
1829
               --  packages are normally ignored, unless the parent is also
1830
               --  in such a package (happens when Standard itself is output)
1831
               --  or if the -df switch is set which causes all links to be
1832
               --  followed, even into package standard.
1833
 
1834
               if Sloc (Nod) <= Standard_Location then
1835
                  if Sloc (N) > Standard_Location
1836
                    and then not Debug_Flag_F
1837
                  then
1838
                     return;
1839
                  end if;
1840
 
1841
               --  Don't bother about a descendent in a different unit than
1842
               --  the node we came from unless the -df switch is set. Note
1843
               --  that we know at this point that Sloc (D) > Standard_Location
1844
 
1845
               --  Note: the tests for No_Location here just make sure that we
1846
               --  don't blow up on a node which is missing an Sloc value. This
1847
               --  should not normally happen.
1848
 
1849
               else
1850
                  if (Sloc (N) <= Standard_Location
1851
                        or else Sloc (N) = No_Location
1852
                        or else Sloc (Nod) = No_Location
1853
                        or else not In_Same_Source_Unit (Nod, N))
1854
                    and then not Debug_Flag_F
1855
                  then
1856
                     return;
1857
                  end if;
1858
               end if;
1859
 
1860
               --  Don't bother visiting a source node that has a parent which
1861
               --  is not the node we came from. We prefer to trace such nodes
1862
               --  from their real parents. This causes the tree to be printed
1863
               --  in a more coherent order, e.g. a defining identifier listed
1864
               --  next to its corresponding declaration, instead of next to
1865
               --  some semantic reference.
1866
 
1867
               --  This test is skipped for nodes in standard packages unless
1868
               --  the -dy option is set (which outputs the tree for standard)
1869
 
1870
               --  Also, always follow pointers to Is_Itype entities,
1871
               --  since we want to list these when they are first referenced.
1872
 
1873
               if Parent (Nod) /= Empty
1874
                 and then Comes_From_Source (Nod)
1875
                 and then Parent (Nod) /= N
1876
                 and then (Sloc (N) > Standard_Location or else Debug_Flag_Y)
1877
               then
1878
                  return;
1879
               end if;
1880
 
1881
               --  If we successfully fall through all the above tests (which
1882
               --  execute a return if the node is not to be visited), we can
1883
               --  go ahead and visit the node!
1884
 
1885
               if No_Indent then
1886
                  Visit_Node (Nod, Prefix_Str, Prefix_Char);
1887
               else
1888
                  Visit_Node (Nod, New_Prefix, ' ');
1889
               end if;
1890
            end;
1891
 
1892
         --  Case of descendent is a list
1893
 
1894
         elsif D in List_Range then
1895
 
1896
            --  Don't bother with a missing list, empty list or error list
1897
 
1898
            if D = Union_Id (No_List)
1899
              or else D = Union_Id (Error_List)
1900
              or else Is_Empty_List (List_Id (D))
1901
            then
1902
               return;
1903
 
1904
            --  Otherwise we can visit the list. Note that we don't bother
1905
            --  to do the parent test that we did for the node case, because
1906
            --  it just does not happen that lists are referenced more than
1907
            --  one place in the tree. We aren't counting on this being the
1908
            --  case to generate valid output, it is just that we don't need
1909
            --  in practice to worry about listing the list at a place that
1910
            --  is inconvenient.
1911
 
1912
            else
1913
               Visit_List (List_Id (D), New_Prefix);
1914
            end if;
1915
 
1916
         --  Case of descendent is an element list
1917
 
1918
         elsif D in Elist_Range then
1919
 
1920
            --  Don't bother with a missing list, or an empty list
1921
 
1922
            if D = Union_Id (No_Elist)
1923
              or else Is_Empty_Elmt_List (Elist_Id (D))
1924
            then
1925
               return;
1926
 
1927
            --  Otherwise, visit the referenced element list
1928
 
1929
            else
1930
               Visit_Elist (Elist_Id (D), New_Prefix);
1931
            end if;
1932
 
1933
         --  For all other kinds of descendents (strings, names, uints etc),
1934
         --  there is nothing to visit (the contents of the field will be
1935
         --  printed when we print the containing node, but what concerns
1936
         --  us now is looking for descendents in the tree.
1937
 
1938
         else
1939
            null;
1940
         end if;
1941
      end Visit_Descendent;
1942
 
1943
   --  Start of processing for Visit_Node
1944
 
1945
   begin
1946
      if N = Empty then
1947
         return;
1948
      end if;
1949
 
1950
      --  Set fatal error node in case we get a blow up during the trace
1951
 
1952
      Current_Error_Node := N;
1953
 
1954
      New_Prefix (Prefix_Str'Range)    := Prefix_Str;
1955
      New_Prefix (Prefix_Str'Last + 1) := Prefix_Char;
1956
      New_Prefix (Prefix_Str'Last + 2) := ' ';
1957
 
1958
      --  In the marking phase, all we do is to set the serial number
1959
 
1960
      if Phase = Marking then
1961
         if Serial_Number (Int (N)) /= 0 then
1962
            return; -- already visited
1963
         else
1964
            Set_Serial_Number;
1965
         end if;
1966
 
1967
      --  In the printing phase, we print the node
1968
 
1969
      else
1970
         if Serial_Number (Int (N)) < Next_Serial_Number then
1971
 
1972
            --  Here we have already visited the node, but if it is in
1973
            --  a list, we still want to print the reference, so that
1974
            --  it is clear that it belongs to the list.
1975
 
1976
            if Is_List_Member (N) then
1977
               Print_Str (Prefix_Str);
1978
               Print_Node_Ref (N);
1979
               Print_Eol;
1980
               Print_Str (Prefix_Str);
1981
               Print_Char (Prefix_Char);
1982
               Print_Str ("(already output)");
1983
               Print_Eol;
1984
               Print_Str (Prefix_Str);
1985
               Print_Char (Prefix_Char);
1986
               Print_Eol;
1987
            end if;
1988
 
1989
            return;
1990
 
1991
         else
1992
            Print_Node (N, Prefix_Str, Prefix_Char);
1993
            Print_Str (Prefix_Str);
1994
            Print_Char (Prefix_Char);
1995
            Print_Eol;
1996
            Next_Serial_Number := Next_Serial_Number + 1;
1997
         end if;
1998
      end if;
1999
 
2000
      --  Visit all descendents of this node
2001
 
2002
      if Nkind (N) not in N_Entity then
2003
         Visit_Descendent (Field1 (N));
2004
         Visit_Descendent (Field2 (N));
2005
         Visit_Descendent (Field3 (N));
2006
         Visit_Descendent (Field4 (N));
2007
         Visit_Descendent (Field5 (N));
2008
 
2009
         if Has_Aspects (N) then
2010
            Visit_Descendent (Union_Id (Aspect_Specifications (N)));
2011
         end if;
2012
 
2013
      --  Entity case
2014
 
2015
      else
2016
         Visit_Descendent (Field1 (N));
2017
         Visit_Descendent (Field3 (N));
2018
         Visit_Descendent (Field4 (N));
2019
         Visit_Descendent (Field5 (N));
2020
         Visit_Descendent (Field6 (N));
2021
         Visit_Descendent (Field7 (N));
2022
         Visit_Descendent (Field8 (N));
2023
         Visit_Descendent (Field9 (N));
2024
         Visit_Descendent (Field10 (N));
2025
         Visit_Descendent (Field11 (N));
2026
         Visit_Descendent (Field12 (N));
2027
         Visit_Descendent (Field13 (N));
2028
         Visit_Descendent (Field14 (N));
2029
         Visit_Descendent (Field15 (N));
2030
         Visit_Descendent (Field16 (N));
2031
         Visit_Descendent (Field17 (N));
2032
         Visit_Descendent (Field18 (N));
2033
         Visit_Descendent (Field19 (N));
2034
         Visit_Descendent (Field20 (N));
2035
         Visit_Descendent (Field21 (N));
2036
         Visit_Descendent (Field22 (N));
2037
         Visit_Descendent (Field23 (N));
2038
 
2039
         --  Now an interesting kludge. Normally parents are always printed
2040
         --  since we traverse the tree in a downwards direction. There is
2041
         --  however an exception to this rule, which is the case where a
2042
         --  parent is constructed by the compiler and is not referenced
2043
         --  elsewhere in the tree. The following catches this case
2044
 
2045
         if not Comes_From_Source (N) then
2046
            Visit_Descendent (Union_Id (Parent (N)));
2047
         end if;
2048
 
2049
         --  You may be wondering why we omitted Field2 above. The answer
2050
         --  is that this is the Next_Entity field, and we want to treat
2051
         --  it rather specially. Why? Because a Next_Entity link does not
2052
         --  correspond to a level deeper in the tree, and we do not want
2053
         --  the tree to march off to the right of the page due to bogus
2054
         --  indentations coming from this effect.
2055
 
2056
         --  To prevent this, what we do is to control references via
2057
         --  Next_Entity only from the first entity on a given scope
2058
         --  chain, and we keep them all at the same level. Of course
2059
         --  if an entity has already been referenced it is not printed.
2060
 
2061
         if Present (Next_Entity (N))
2062
           and then Present (Scope (N))
2063
           and then First_Entity (Scope (N)) = N
2064
         then
2065
            declare
2066
               Nod : Node_Id;
2067
 
2068
            begin
2069
               Nod := N;
2070
               while Present (Nod) loop
2071
                  Visit_Descendent (Union_Id (Next_Entity (Nod)));
2072
                  Nod := Next_Entity (Nod);
2073
               end loop;
2074
            end;
2075
         end if;
2076
      end if;
2077
   end Visit_Node;
2078
 
2079
end Treepr;

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