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1 706 jeremybenn
------------------------------------------------------------------------------
2
--                                                                          --
3
--                         GNAT COMPILER COMPONENTS                         --
4
--                                                                          --
5
--                             S E M _ U T I L                              --
6
--                                                                          --
7
--                                 B o d y                                  --
8
--                                                                          --
9
--          Copyright (C) 1992-2012, 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 Atree;    use Atree;
27
with Casing;   use Casing;
28
with Checks;   use Checks;
29
with Debug;    use Debug;
30
with Errout;   use Errout;
31
with Elists;   use Elists;
32
with Exp_Ch11; use Exp_Ch11;
33
with Exp_Disp; use Exp_Disp;
34
with Exp_Util; use Exp_Util;
35
with Fname;    use Fname;
36
with Freeze;   use Freeze;
37
with Lib;      use Lib;
38
with Lib.Xref; use Lib.Xref;
39
with Nlists;   use Nlists;
40
with Output;   use Output;
41
with Opt;      use Opt;
42
with Restrict; use Restrict;
43
with Rident;   use Rident;
44
with Rtsfind;  use Rtsfind;
45
with Sem;      use Sem;
46
with Sem_Aux;  use Sem_Aux;
47
with Sem_Attr; use Sem_Attr;
48
with Sem_Ch8;  use Sem_Ch8;
49
with Sem_Disp; use Sem_Disp;
50
with Sem_Eval; use Sem_Eval;
51
with Sem_Res;  use Sem_Res;
52
with Sem_Type; use Sem_Type;
53
with Sinfo;    use Sinfo;
54
with Sinput;   use Sinput;
55
with Stand;    use Stand;
56
with Style;
57
with Stringt;  use Stringt;
58
with Table;
59
with Targparm; use Targparm;
60
with Tbuild;   use Tbuild;
61
with Ttypes;   use Ttypes;
62
with Uname;    use Uname;
63
 
64
with GNAT.HTable; use GNAT.HTable;
65
 
66
package body Sem_Util is
67
 
68
   ----------------------------------------
69
   -- Global_Variables for New_Copy_Tree --
70
   ----------------------------------------
71
 
72
   --  These global variables are used by New_Copy_Tree. See description
73
   --  of the body of this subprogram for details. Global variables can be
74
   --  safely used by New_Copy_Tree, since there is no case of a recursive
75
   --  call from the processing inside New_Copy_Tree.
76
 
77
   NCT_Hash_Threshold : constant := 20;
78
   --  If there are more than this number of pairs of entries in the
79
   --  map, then Hash_Tables_Used will be set, and the hash tables will
80
   --  be initialized and used for the searches.
81
 
82
   NCT_Hash_Tables_Used : Boolean := False;
83
   --  Set to True if hash tables are in use
84
 
85
   NCT_Table_Entries : Nat;
86
   --  Count entries in table to see if threshold is reached
87
 
88
   NCT_Hash_Table_Setup : Boolean := False;
89
   --  Set to True if hash table contains data. We set this True if we
90
   --  setup the hash table with data, and leave it set permanently
91
   --  from then on, this is a signal that second and subsequent users
92
   --  of the hash table must clear the old entries before reuse.
93
 
94
   subtype NCT_Header_Num is Int range 0 .. 511;
95
   --  Defines range of headers in hash tables (512 headers)
96
 
97
   ----------------------------------
98
   -- Order Dependence (AI05-0144) --
99
   ----------------------------------
100
 
101
   --  Each actual in a call is entered into the table below. A flag indicates
102
   --  whether the corresponding formal is OUT or IN OUT. Each top-level call
103
   --  (procedure call, condition, assignment) examines all the actuals for a
104
   --  possible order dependence. The table is reset after each such check.
105
   --  The actuals to be checked in a call to Check_Order_Dependence are at
106
   --  positions 1 .. Last.
107
 
108
   type Actual_Name is record
109
      Act         : Node_Id;
110
      Is_Writable : Boolean;
111
   end record;
112
 
113
   package Actuals_In_Call is new Table.Table (
114
      Table_Component_Type => Actual_Name,
115
      Table_Index_Type     => Int,
116
      Table_Low_Bound      => 0,
117
      Table_Initial        => 10,
118
      Table_Increment      => 100,
119
      Table_Name           => "Actuals");
120
 
121
   -----------------------
122
   -- Local Subprograms --
123
   -----------------------
124
 
125
   function Build_Component_Subtype
126
     (C   : List_Id;
127
      Loc : Source_Ptr;
128
      T   : Entity_Id) return Node_Id;
129
   --  This function builds the subtype for Build_Actual_Subtype_Of_Component
130
   --  and Build_Discriminal_Subtype_Of_Component. C is a list of constraints,
131
   --  Loc is the source location, T is the original subtype.
132
 
133
   function Is_Fully_Initialized_Variant (Typ : Entity_Id) return Boolean;
134
   --  Subsidiary to Is_Fully_Initialized_Type. For an unconstrained type
135
   --  with discriminants whose default values are static, examine only the
136
   --  components in the selected variant to determine whether all of them
137
   --  have a default.
138
 
139
   function Has_Null_Extension (T : Entity_Id) return Boolean;
140
   --  T is a derived tagged type. Check whether the type extension is null.
141
   --  If the parent type is fully initialized, T can be treated as such.
142
 
143
   ------------------------------
144
   --  Abstract_Interface_List --
145
   ------------------------------
146
 
147
   function Abstract_Interface_List (Typ : Entity_Id) return List_Id is
148
      Nod : Node_Id;
149
 
150
   begin
151
      if Is_Concurrent_Type (Typ) then
152
 
153
         --  If we are dealing with a synchronized subtype, go to the base
154
         --  type, whose declaration has the interface list.
155
 
156
         --  Shouldn't this be Declaration_Node???
157
 
158
         Nod := Parent (Base_Type (Typ));
159
 
160
         if Nkind (Nod) = N_Full_Type_Declaration then
161
            return Empty_List;
162
         end if;
163
 
164
      elsif Ekind (Typ) = E_Record_Type_With_Private then
165
         if Nkind (Parent (Typ)) = N_Full_Type_Declaration then
166
            Nod := Type_Definition (Parent (Typ));
167
 
168
         elsif Nkind (Parent (Typ)) = N_Private_Type_Declaration then
169
            if Present (Full_View (Typ))
170
              and then Nkind (Parent (Full_View (Typ)))
171
                         = N_Full_Type_Declaration
172
            then
173
               Nod := Type_Definition (Parent (Full_View (Typ)));
174
 
175
            --  If the full-view is not available we cannot do anything else
176
            --  here (the source has errors).
177
 
178
            else
179
               return Empty_List;
180
            end if;
181
 
182
         --  Support for generic formals with interfaces is still missing ???
183
 
184
         elsif Nkind (Parent (Typ)) = N_Formal_Type_Declaration then
185
            return Empty_List;
186
 
187
         else
188
            pragma Assert
189
              (Nkind (Parent (Typ)) = N_Private_Extension_Declaration);
190
            Nod := Parent (Typ);
191
         end if;
192
 
193
      elsif Ekind (Typ) = E_Record_Subtype then
194
         Nod := Type_Definition (Parent (Etype (Typ)));
195
 
196
      elsif Ekind (Typ) = E_Record_Subtype_With_Private then
197
 
198
         --  Recurse, because parent may still be a private extension. Also
199
         --  note that the full view of the subtype or the full view of its
200
         --  base type may (both) be unavailable.
201
 
202
         return Abstract_Interface_List (Etype (Typ));
203
 
204
      else pragma Assert ((Ekind (Typ)) = E_Record_Type);
205
         if Nkind (Parent (Typ)) = N_Formal_Type_Declaration then
206
            Nod := Formal_Type_Definition (Parent (Typ));
207
         else
208
            Nod := Type_Definition (Parent (Typ));
209
         end if;
210
      end if;
211
 
212
      return Interface_List (Nod);
213
   end Abstract_Interface_List;
214
 
215
   --------------------------------
216
   -- Add_Access_Type_To_Process --
217
   --------------------------------
218
 
219
   procedure Add_Access_Type_To_Process (E : Entity_Id; A : Entity_Id) is
220
      L : Elist_Id;
221
 
222
   begin
223
      Ensure_Freeze_Node (E);
224
      L := Access_Types_To_Process (Freeze_Node (E));
225
 
226
      if No (L) then
227
         L := New_Elmt_List;
228
         Set_Access_Types_To_Process (Freeze_Node (E), L);
229
      end if;
230
 
231
      Append_Elmt (A, L);
232
   end Add_Access_Type_To_Process;
233
 
234
   ----------------------------
235
   -- Add_Global_Declaration --
236
   ----------------------------
237
 
238
   procedure Add_Global_Declaration (N : Node_Id) is
239
      Aux_Node : constant Node_Id := Aux_Decls_Node (Cunit (Current_Sem_Unit));
240
 
241
   begin
242
      if No (Declarations (Aux_Node)) then
243
         Set_Declarations (Aux_Node, New_List);
244
      end if;
245
 
246
      Append_To (Declarations (Aux_Node), N);
247
      Analyze (N);
248
   end Add_Global_Declaration;
249
 
250
   -----------------
251
   -- Addressable --
252
   -----------------
253
 
254
   --  For now, just 8/16/32/64. but analyze later if AAMP is special???
255
 
256
   function Addressable (V : Uint) return Boolean is
257
   begin
258
      return V = Uint_8  or else
259
             V = Uint_16 or else
260
             V = Uint_32 or else
261
             V = Uint_64;
262
   end Addressable;
263
 
264
   function Addressable (V : Int) return Boolean is
265
   begin
266
      return V = 8  or else
267
             V = 16 or else
268
             V = 32 or else
269
             V = 64;
270
   end Addressable;
271
 
272
   -----------------------
273
   -- Alignment_In_Bits --
274
   -----------------------
275
 
276
   function Alignment_In_Bits (E : Entity_Id) return Uint is
277
   begin
278
      return Alignment (E) * System_Storage_Unit;
279
   end Alignment_In_Bits;
280
 
281
   -----------------------------------------
282
   -- Apply_Compile_Time_Constraint_Error --
283
   -----------------------------------------
284
 
285
   procedure Apply_Compile_Time_Constraint_Error
286
     (N      : Node_Id;
287
      Msg    : String;
288
      Reason : RT_Exception_Code;
289
      Ent    : Entity_Id  := Empty;
290
      Typ    : Entity_Id  := Empty;
291
      Loc    : Source_Ptr := No_Location;
292
      Rep    : Boolean    := True;
293
      Warn   : Boolean    := False)
294
   is
295
      Stat   : constant Boolean := Is_Static_Expression (N);
296
      R_Stat : constant Node_Id :=
297
                 Make_Raise_Constraint_Error (Sloc (N), Reason => Reason);
298
      Rtyp   : Entity_Id;
299
 
300
   begin
301
      if No (Typ) then
302
         Rtyp := Etype (N);
303
      else
304
         Rtyp := Typ;
305
      end if;
306
 
307
      Discard_Node
308
        (Compile_Time_Constraint_Error (N, Msg, Ent, Loc, Warn => Warn));
309
 
310
      if not Rep then
311
         return;
312
      end if;
313
 
314
      --  Now we replace the node by an N_Raise_Constraint_Error node
315
      --  This does not need reanalyzing, so set it as analyzed now.
316
 
317
      Rewrite (N, R_Stat);
318
      Set_Analyzed (N, True);
319
 
320
      Set_Etype (N, Rtyp);
321
      Set_Raises_Constraint_Error (N);
322
 
323
      --  Now deal with possible local raise handling
324
 
325
      Possible_Local_Raise (N, Standard_Constraint_Error);
326
 
327
      --  If the original expression was marked as static, the result is
328
      --  still marked as static, but the Raises_Constraint_Error flag is
329
      --  always set so that further static evaluation is not attempted.
330
 
331
      if Stat then
332
         Set_Is_Static_Expression (N);
333
      end if;
334
   end Apply_Compile_Time_Constraint_Error;
335
 
336
   --------------------------------------
337
   -- Available_Full_View_Of_Component --
338
   --------------------------------------
339
 
340
   function Available_Full_View_Of_Component (T : Entity_Id) return Boolean is
341
      ST  : constant Entity_Id := Scope (T);
342
      SCT : constant Entity_Id := Scope (Component_Type (T));
343
   begin
344
      return In_Open_Scopes (ST)
345
        and then In_Open_Scopes (SCT)
346
        and then Scope_Depth (ST) >= Scope_Depth (SCT);
347
   end Available_Full_View_Of_Component;
348
 
349
   --------------------------------
350
   -- Bad_Predicated_Subtype_Use --
351
   --------------------------------
352
 
353
   procedure Bad_Predicated_Subtype_Use
354
     (Msg : String;
355
      N   : Node_Id;
356
      Typ : Entity_Id)
357
   is
358
   begin
359
      if Has_Predicates (Typ) then
360
         if Is_Generic_Actual_Type (Typ) then
361
            Error_Msg_FE (Msg & '?', N, Typ);
362
            Error_Msg_F ("\Program_Error will be raised at run time?", N);
363
            Insert_Action (N,
364
              Make_Raise_Program_Error (Sloc (N),
365
                Reason => PE_Bad_Predicated_Generic_Type));
366
 
367
         else
368
            Error_Msg_FE (Msg, N, Typ);
369
         end if;
370
      end if;
371
   end Bad_Predicated_Subtype_Use;
372
 
373
   --------------------------
374
   -- Build_Actual_Subtype --
375
   --------------------------
376
 
377
   function Build_Actual_Subtype
378
     (T : Entity_Id;
379
      N : Node_Or_Entity_Id) return Node_Id
380
   is
381
      Loc : Source_Ptr;
382
      --  Normally Sloc (N), but may point to corresponding body in some cases
383
 
384
      Constraints : List_Id;
385
      Decl        : Node_Id;
386
      Discr       : Entity_Id;
387
      Hi          : Node_Id;
388
      Lo          : Node_Id;
389
      Subt        : Entity_Id;
390
      Disc_Type   : Entity_Id;
391
      Obj         : Node_Id;
392
 
393
   begin
394
      Loc := Sloc (N);
395
 
396
      if Nkind (N) = N_Defining_Identifier then
397
         Obj := New_Reference_To (N, Loc);
398
 
399
         --  If this is a formal parameter of a subprogram declaration, and
400
         --  we are compiling the body, we want the declaration for the
401
         --  actual subtype to carry the source position of the body, to
402
         --  prevent anomalies in gdb when stepping through the code.
403
 
404
         if Is_Formal (N) then
405
            declare
406
               Decl : constant Node_Id := Unit_Declaration_Node (Scope (N));
407
            begin
408
               if Nkind (Decl) = N_Subprogram_Declaration
409
                 and then Present (Corresponding_Body (Decl))
410
               then
411
                  Loc := Sloc (Corresponding_Body (Decl));
412
               end if;
413
            end;
414
         end if;
415
 
416
      else
417
         Obj := N;
418
      end if;
419
 
420
      if Is_Array_Type (T) then
421
         Constraints := New_List;
422
         for J in 1 .. Number_Dimensions (T) loop
423
 
424
            --  Build an array subtype declaration with the nominal subtype and
425
            --  the bounds of the actual. Add the declaration in front of the
426
            --  local declarations for the subprogram, for analysis before any
427
            --  reference to the formal in the body.
428
 
429
            Lo :=
430
              Make_Attribute_Reference (Loc,
431
                Prefix         =>
432
                  Duplicate_Subexpr_No_Checks (Obj, Name_Req => True),
433
                Attribute_Name => Name_First,
434
                Expressions    => New_List (
435
                  Make_Integer_Literal (Loc, J)));
436
 
437
            Hi :=
438
              Make_Attribute_Reference (Loc,
439
                Prefix         =>
440
                  Duplicate_Subexpr_No_Checks (Obj, Name_Req => True),
441
                Attribute_Name => Name_Last,
442
                Expressions    => New_List (
443
                  Make_Integer_Literal (Loc, J)));
444
 
445
            Append (Make_Range (Loc, Lo, Hi), Constraints);
446
         end loop;
447
 
448
      --  If the type has unknown discriminants there is no constrained
449
      --  subtype to build. This is never called for a formal or for a
450
      --  lhs, so returning the type is ok ???
451
 
452
      elsif Has_Unknown_Discriminants (T) then
453
         return T;
454
 
455
      else
456
         Constraints := New_List;
457
 
458
         --  Type T is a generic derived type, inherit the discriminants from
459
         --  the parent type.
460
 
461
         if Is_Private_Type (T)
462
           and then No (Full_View (T))
463
 
464
            --  T was flagged as an error if it was declared as a formal
465
            --  derived type with known discriminants. In this case there
466
            --  is no need to look at the parent type since T already carries
467
            --  its own discriminants.
468
 
469
           and then not Error_Posted (T)
470
         then
471
            Disc_Type := Etype (Base_Type (T));
472
         else
473
            Disc_Type := T;
474
         end if;
475
 
476
         Discr := First_Discriminant (Disc_Type);
477
         while Present (Discr) loop
478
            Append_To (Constraints,
479
              Make_Selected_Component (Loc,
480
                Prefix =>
481
                  Duplicate_Subexpr_No_Checks (Obj),
482
                Selector_Name => New_Occurrence_Of (Discr, Loc)));
483
            Next_Discriminant (Discr);
484
         end loop;
485
      end if;
486
 
487
      Subt := Make_Temporary (Loc, 'S', Related_Node => N);
488
      Set_Is_Internal (Subt);
489
 
490
      Decl :=
491
        Make_Subtype_Declaration (Loc,
492
          Defining_Identifier => Subt,
493
          Subtype_Indication =>
494
            Make_Subtype_Indication (Loc,
495
              Subtype_Mark => New_Reference_To (T,  Loc),
496
              Constraint  =>
497
                Make_Index_Or_Discriminant_Constraint (Loc,
498
                  Constraints => Constraints)));
499
 
500
      Mark_Rewrite_Insertion (Decl);
501
      return Decl;
502
   end Build_Actual_Subtype;
503
 
504
   ---------------------------------------
505
   -- Build_Actual_Subtype_Of_Component --
506
   ---------------------------------------
507
 
508
   function Build_Actual_Subtype_Of_Component
509
     (T : Entity_Id;
510
      N : Node_Id) return Node_Id
511
   is
512
      Loc       : constant Source_Ptr := Sloc (N);
513
      P         : constant Node_Id    := Prefix (N);
514
      D         : Elmt_Id;
515
      Id        : Node_Id;
516
      Index_Typ : Entity_Id;
517
 
518
      Desig_Typ : Entity_Id;
519
      --  This is either a copy of T, or if T is an access type, then it is
520
      --  the directly designated type of this access type.
521
 
522
      function Build_Actual_Array_Constraint return List_Id;
523
      --  If one or more of the bounds of the component depends on
524
      --  discriminants, build  actual constraint using the discriminants
525
      --  of the prefix.
526
 
527
      function Build_Actual_Record_Constraint return List_Id;
528
      --  Similar to previous one, for discriminated components constrained
529
      --  by the discriminant of the enclosing object.
530
 
531
      -----------------------------------
532
      -- Build_Actual_Array_Constraint --
533
      -----------------------------------
534
 
535
      function Build_Actual_Array_Constraint return List_Id is
536
         Constraints : constant List_Id := New_List;
537
         Indx        : Node_Id;
538
         Hi          : Node_Id;
539
         Lo          : Node_Id;
540
         Old_Hi      : Node_Id;
541
         Old_Lo      : Node_Id;
542
 
543
      begin
544
         Indx := First_Index (Desig_Typ);
545
         while Present (Indx) loop
546
            Old_Lo := Type_Low_Bound  (Etype (Indx));
547
            Old_Hi := Type_High_Bound (Etype (Indx));
548
 
549
            if Denotes_Discriminant (Old_Lo) then
550
               Lo :=
551
                 Make_Selected_Component (Loc,
552
                   Prefix => New_Copy_Tree (P),
553
                   Selector_Name => New_Occurrence_Of (Entity (Old_Lo), Loc));
554
 
555
            else
556
               Lo := New_Copy_Tree (Old_Lo);
557
 
558
               --  The new bound will be reanalyzed in the enclosing
559
               --  declaration. For literal bounds that come from a type
560
               --  declaration, the type of the context must be imposed, so
561
               --  insure that analysis will take place. For non-universal
562
               --  types this is not strictly necessary.
563
 
564
               Set_Analyzed (Lo, False);
565
            end if;
566
 
567
            if Denotes_Discriminant (Old_Hi) then
568
               Hi :=
569
                 Make_Selected_Component (Loc,
570
                   Prefix => New_Copy_Tree (P),
571
                   Selector_Name => New_Occurrence_Of (Entity (Old_Hi), Loc));
572
 
573
            else
574
               Hi := New_Copy_Tree (Old_Hi);
575
               Set_Analyzed (Hi, False);
576
            end if;
577
 
578
            Append (Make_Range (Loc, Lo, Hi), Constraints);
579
            Next_Index (Indx);
580
         end loop;
581
 
582
         return Constraints;
583
      end Build_Actual_Array_Constraint;
584
 
585
      ------------------------------------
586
      -- Build_Actual_Record_Constraint --
587
      ------------------------------------
588
 
589
      function Build_Actual_Record_Constraint return List_Id is
590
         Constraints : constant List_Id := New_List;
591
         D           : Elmt_Id;
592
         D_Val       : Node_Id;
593
 
594
      begin
595
         D := First_Elmt (Discriminant_Constraint (Desig_Typ));
596
         while Present (D) loop
597
            if Denotes_Discriminant (Node (D)) then
598
               D_Val :=  Make_Selected_Component (Loc,
599
                 Prefix => New_Copy_Tree (P),
600
                Selector_Name => New_Occurrence_Of (Entity (Node (D)), Loc));
601
 
602
            else
603
               D_Val := New_Copy_Tree (Node (D));
604
            end if;
605
 
606
            Append (D_Val, Constraints);
607
            Next_Elmt (D);
608
         end loop;
609
 
610
         return Constraints;
611
      end Build_Actual_Record_Constraint;
612
 
613
   --  Start of processing for Build_Actual_Subtype_Of_Component
614
 
615
   begin
616
      --  Why the test for Spec_Expression mode here???
617
 
618
      if In_Spec_Expression then
619
         return Empty;
620
 
621
      --  More comments for the rest of this body would be good ???
622
 
623
      elsif Nkind (N) = N_Explicit_Dereference then
624
         if Is_Composite_Type (T)
625
           and then not Is_Constrained (T)
626
           and then not (Is_Class_Wide_Type (T)
627
                          and then Is_Constrained (Root_Type (T)))
628
           and then not Has_Unknown_Discriminants (T)
629
         then
630
            --  If the type of the dereference is already constrained, it is an
631
            --  actual subtype.
632
 
633
            if Is_Array_Type (Etype (N))
634
              and then Is_Constrained (Etype (N))
635
            then
636
               return Empty;
637
            else
638
               Remove_Side_Effects (P);
639
               return Build_Actual_Subtype (T, N);
640
            end if;
641
         else
642
            return Empty;
643
         end if;
644
      end if;
645
 
646
      if Ekind (T) = E_Access_Subtype then
647
         Desig_Typ := Designated_Type (T);
648
      else
649
         Desig_Typ := T;
650
      end if;
651
 
652
      if Ekind (Desig_Typ) = E_Array_Subtype then
653
         Id := First_Index (Desig_Typ);
654
         while Present (Id) loop
655
            Index_Typ := Underlying_Type (Etype (Id));
656
 
657
            if Denotes_Discriminant (Type_Low_Bound  (Index_Typ))
658
                 or else
659
               Denotes_Discriminant (Type_High_Bound (Index_Typ))
660
            then
661
               Remove_Side_Effects (P);
662
               return
663
                 Build_Component_Subtype
664
                   (Build_Actual_Array_Constraint, Loc, Base_Type (T));
665
            end if;
666
 
667
            Next_Index (Id);
668
         end loop;
669
 
670
      elsif Is_Composite_Type (Desig_Typ)
671
        and then Has_Discriminants (Desig_Typ)
672
        and then not Has_Unknown_Discriminants (Desig_Typ)
673
      then
674
         if Is_Private_Type (Desig_Typ)
675
           and then No (Discriminant_Constraint (Desig_Typ))
676
         then
677
            Desig_Typ := Full_View (Desig_Typ);
678
         end if;
679
 
680
         D := First_Elmt (Discriminant_Constraint (Desig_Typ));
681
         while Present (D) loop
682
            if Denotes_Discriminant (Node (D)) then
683
               Remove_Side_Effects (P);
684
               return
685
                 Build_Component_Subtype (
686
                   Build_Actual_Record_Constraint, Loc, Base_Type (T));
687
            end if;
688
 
689
            Next_Elmt (D);
690
         end loop;
691
      end if;
692
 
693
      --  If none of the above, the actual and nominal subtypes are the same
694
 
695
      return Empty;
696
   end Build_Actual_Subtype_Of_Component;
697
 
698
   -----------------------------
699
   -- Build_Component_Subtype --
700
   -----------------------------
701
 
702
   function Build_Component_Subtype
703
     (C   : List_Id;
704
      Loc : Source_Ptr;
705
      T   : Entity_Id) return Node_Id
706
   is
707
      Subt : Entity_Id;
708
      Decl : Node_Id;
709
 
710
   begin
711
      --  Unchecked_Union components do not require component subtypes
712
 
713
      if Is_Unchecked_Union (T) then
714
         return Empty;
715
      end if;
716
 
717
      Subt := Make_Temporary (Loc, 'S');
718
      Set_Is_Internal (Subt);
719
 
720
      Decl :=
721
        Make_Subtype_Declaration (Loc,
722
          Defining_Identifier => Subt,
723
          Subtype_Indication =>
724
            Make_Subtype_Indication (Loc,
725
              Subtype_Mark => New_Reference_To (Base_Type (T),  Loc),
726
              Constraint  =>
727
                Make_Index_Or_Discriminant_Constraint (Loc,
728
                  Constraints => C)));
729
 
730
      Mark_Rewrite_Insertion (Decl);
731
      return Decl;
732
   end Build_Component_Subtype;
733
 
734
   ---------------------------
735
   -- Build_Default_Subtype --
736
   ---------------------------
737
 
738
   function Build_Default_Subtype
739
     (T : Entity_Id;
740
      N : Node_Id) return Entity_Id
741
   is
742
      Loc  : constant Source_Ptr := Sloc (N);
743
      Disc : Entity_Id;
744
 
745
   begin
746
      if not Has_Discriminants (T) or else Is_Constrained (T) then
747
         return T;
748
      end if;
749
 
750
      Disc := First_Discriminant (T);
751
 
752
      if No (Discriminant_Default_Value (Disc)) then
753
         return T;
754
      end if;
755
 
756
      declare
757
         Act         : constant Entity_Id := Make_Temporary (Loc, 'S');
758
         Constraints : constant List_Id := New_List;
759
         Decl        : Node_Id;
760
 
761
      begin
762
         while Present (Disc) loop
763
            Append_To (Constraints,
764
              New_Copy_Tree (Discriminant_Default_Value (Disc)));
765
            Next_Discriminant (Disc);
766
         end loop;
767
 
768
         Decl :=
769
           Make_Subtype_Declaration (Loc,
770
             Defining_Identifier => Act,
771
             Subtype_Indication =>
772
               Make_Subtype_Indication (Loc,
773
                 Subtype_Mark => New_Occurrence_Of (T, Loc),
774
                 Constraint =>
775
                   Make_Index_Or_Discriminant_Constraint (Loc,
776
                     Constraints => Constraints)));
777
 
778
         Insert_Action (N, Decl);
779
         Analyze (Decl);
780
         return Act;
781
      end;
782
   end Build_Default_Subtype;
783
 
784
   --------------------------------------------
785
   -- Build_Discriminal_Subtype_Of_Component --
786
   --------------------------------------------
787
 
788
   function Build_Discriminal_Subtype_Of_Component
789
     (T : Entity_Id) return Node_Id
790
   is
791
      Loc : constant Source_Ptr := Sloc (T);
792
      D   : Elmt_Id;
793
      Id  : Node_Id;
794
 
795
      function Build_Discriminal_Array_Constraint return List_Id;
796
      --  If one or more of the bounds of the component depends on
797
      --  discriminants, build  actual constraint using the discriminants
798
      --  of the prefix.
799
 
800
      function Build_Discriminal_Record_Constraint return List_Id;
801
      --  Similar to previous one, for discriminated components constrained
802
      --  by the discriminant of the enclosing object.
803
 
804
      ----------------------------------------
805
      -- Build_Discriminal_Array_Constraint --
806
      ----------------------------------------
807
 
808
      function Build_Discriminal_Array_Constraint return List_Id is
809
         Constraints : constant List_Id := New_List;
810
         Indx        : Node_Id;
811
         Hi          : Node_Id;
812
         Lo          : Node_Id;
813
         Old_Hi      : Node_Id;
814
         Old_Lo      : Node_Id;
815
 
816
      begin
817
         Indx := First_Index (T);
818
         while Present (Indx) loop
819
            Old_Lo := Type_Low_Bound  (Etype (Indx));
820
            Old_Hi := Type_High_Bound (Etype (Indx));
821
 
822
            if Denotes_Discriminant (Old_Lo) then
823
               Lo := New_Occurrence_Of (Discriminal (Entity (Old_Lo)), Loc);
824
 
825
            else
826
               Lo := New_Copy_Tree (Old_Lo);
827
            end if;
828
 
829
            if Denotes_Discriminant (Old_Hi) then
830
               Hi := New_Occurrence_Of (Discriminal (Entity (Old_Hi)), Loc);
831
 
832
            else
833
               Hi := New_Copy_Tree (Old_Hi);
834
            end if;
835
 
836
            Append (Make_Range (Loc, Lo, Hi), Constraints);
837
            Next_Index (Indx);
838
         end loop;
839
 
840
         return Constraints;
841
      end Build_Discriminal_Array_Constraint;
842
 
843
      -----------------------------------------
844
      -- Build_Discriminal_Record_Constraint --
845
      -----------------------------------------
846
 
847
      function Build_Discriminal_Record_Constraint return List_Id is
848
         Constraints : constant List_Id := New_List;
849
         D           : Elmt_Id;
850
         D_Val       : Node_Id;
851
 
852
      begin
853
         D := First_Elmt (Discriminant_Constraint (T));
854
         while Present (D) loop
855
            if Denotes_Discriminant (Node (D)) then
856
               D_Val :=
857
                 New_Occurrence_Of (Discriminal (Entity (Node (D))), Loc);
858
 
859
            else
860
               D_Val := New_Copy_Tree (Node (D));
861
            end if;
862
 
863
            Append (D_Val, Constraints);
864
            Next_Elmt (D);
865
         end loop;
866
 
867
         return Constraints;
868
      end Build_Discriminal_Record_Constraint;
869
 
870
   --  Start of processing for Build_Discriminal_Subtype_Of_Component
871
 
872
   begin
873
      if Ekind (T) = E_Array_Subtype then
874
         Id := First_Index (T);
875
         while Present (Id) loop
876
            if Denotes_Discriminant (Type_Low_Bound  (Etype (Id))) or else
877
               Denotes_Discriminant (Type_High_Bound (Etype (Id)))
878
            then
879
               return Build_Component_Subtype
880
                 (Build_Discriminal_Array_Constraint, Loc, T);
881
            end if;
882
 
883
            Next_Index (Id);
884
         end loop;
885
 
886
      elsif Ekind (T) = E_Record_Subtype
887
        and then Has_Discriminants (T)
888
        and then not Has_Unknown_Discriminants (T)
889
      then
890
         D := First_Elmt (Discriminant_Constraint (T));
891
         while Present (D) loop
892
            if Denotes_Discriminant (Node (D)) then
893
               return Build_Component_Subtype
894
                 (Build_Discriminal_Record_Constraint, Loc, T);
895
            end if;
896
 
897
            Next_Elmt (D);
898
         end loop;
899
      end if;
900
 
901
      --  If none of the above, the actual and nominal subtypes are the same
902
 
903
      return Empty;
904
   end Build_Discriminal_Subtype_Of_Component;
905
 
906
   ------------------------------
907
   -- Build_Elaboration_Entity --
908
   ------------------------------
909
 
910
   procedure Build_Elaboration_Entity (N : Node_Id; Spec_Id : Entity_Id) is
911
      Loc      : constant Source_Ptr := Sloc (N);
912
      Decl     : Node_Id;
913
      Elab_Ent : Entity_Id;
914
 
915
      procedure Set_Package_Name (Ent : Entity_Id);
916
      --  Given an entity, sets the fully qualified name of the entity in
917
      --  Name_Buffer, with components separated by double underscores. This
918
      --  is a recursive routine that climbs the scope chain to Standard.
919
 
920
      ----------------------
921
      -- Set_Package_Name --
922
      ----------------------
923
 
924
      procedure Set_Package_Name (Ent : Entity_Id) is
925
      begin
926
         if Scope (Ent) /= Standard_Standard then
927
            Set_Package_Name (Scope (Ent));
928
 
929
            declare
930
               Nam : constant String := Get_Name_String (Chars (Ent));
931
            begin
932
               Name_Buffer (Name_Len + 1) := '_';
933
               Name_Buffer (Name_Len + 2) := '_';
934
               Name_Buffer (Name_Len + 3 .. Name_Len + Nam'Length + 2) := Nam;
935
               Name_Len := Name_Len + Nam'Length + 2;
936
            end;
937
 
938
         else
939
            Get_Name_String (Chars (Ent));
940
         end if;
941
      end Set_Package_Name;
942
 
943
   --  Start of processing for Build_Elaboration_Entity
944
 
945
   begin
946
      --  Ignore if already constructed
947
 
948
      if Present (Elaboration_Entity (Spec_Id)) then
949
         return;
950
      end if;
951
 
952
      --  Construct name of elaboration entity as xxx_E, where xxx is the unit
953
      --  name with dots replaced by double underscore. We have to manually
954
      --  construct this name, since it will be elaborated in the outer scope,
955
      --  and thus will not have the unit name automatically prepended.
956
 
957
      Set_Package_Name (Spec_Id);
958
 
959
      --  Append _E
960
 
961
      Name_Buffer (Name_Len + 1) := '_';
962
      Name_Buffer (Name_Len + 2) := 'E';
963
      Name_Len := Name_Len + 2;
964
 
965
      --  Create elaboration counter
966
 
967
      Elab_Ent := Make_Defining_Identifier (Loc, Chars => Name_Find);
968
      Set_Elaboration_Entity (Spec_Id, Elab_Ent);
969
 
970
      Decl :=
971
        Make_Object_Declaration (Loc,
972
          Defining_Identifier => Elab_Ent,
973
          Object_Definition   =>
974
            New_Occurrence_Of (Standard_Short_Integer, Loc),
975
          Expression          => Make_Integer_Literal (Loc, Uint_0));
976
 
977
      Push_Scope (Standard_Standard);
978
      Add_Global_Declaration (Decl);
979
      Pop_Scope;
980
 
981
      --  Reset True_Constant indication, since we will indeed assign a value
982
      --  to the variable in the binder main. We also kill the Current_Value
983
      --  and Last_Assignment fields for the same reason.
984
 
985
      Set_Is_True_Constant (Elab_Ent, False);
986
      Set_Current_Value    (Elab_Ent, Empty);
987
      Set_Last_Assignment  (Elab_Ent, Empty);
988
 
989
      --  We do not want any further qualification of the name (if we did
990
      --  not do this, we would pick up the name of the generic package
991
      --  in the case of a library level generic instantiation).
992
 
993
      Set_Has_Qualified_Name       (Elab_Ent);
994
      Set_Has_Fully_Qualified_Name (Elab_Ent);
995
   end Build_Elaboration_Entity;
996
 
997
   --------------------------------
998
   -- Build_Explicit_Dereference --
999
   --------------------------------
1000
 
1001
   procedure Build_Explicit_Dereference
1002
     (Expr : Node_Id;
1003
      Disc : Entity_Id)
1004
   is
1005
      Loc : constant Source_Ptr := Sloc (Expr);
1006
   begin
1007
      Set_Is_Overloaded (Expr, False);
1008
      Rewrite (Expr,
1009
        Make_Explicit_Dereference (Loc,
1010
          Prefix =>
1011
            Make_Selected_Component (Loc,
1012
              Prefix        => Relocate_Node (Expr),
1013
              Selector_Name => New_Occurrence_Of (Disc, Loc))));
1014
      Set_Etype (Prefix (Expr), Etype (Disc));
1015
      Set_Etype (Expr, Designated_Type (Etype (Disc)));
1016
   end Build_Explicit_Dereference;
1017
 
1018
   -----------------------------------
1019
   -- Cannot_Raise_Constraint_Error --
1020
   -----------------------------------
1021
 
1022
   function Cannot_Raise_Constraint_Error (Expr : Node_Id) return Boolean is
1023
   begin
1024
      if Compile_Time_Known_Value (Expr) then
1025
         return True;
1026
 
1027
      elsif Do_Range_Check (Expr) then
1028
         return False;
1029
 
1030
      elsif Raises_Constraint_Error (Expr) then
1031
         return False;
1032
 
1033
      else
1034
         case Nkind (Expr) is
1035
            when N_Identifier =>
1036
               return True;
1037
 
1038
            when N_Expanded_Name =>
1039
               return True;
1040
 
1041
            when N_Selected_Component =>
1042
               return not Do_Discriminant_Check (Expr);
1043
 
1044
            when N_Attribute_Reference =>
1045
               if Do_Overflow_Check (Expr) then
1046
                  return False;
1047
 
1048
               elsif No (Expressions (Expr)) then
1049
                  return True;
1050
 
1051
               else
1052
                  declare
1053
                     N : Node_Id;
1054
 
1055
                  begin
1056
                     N := First (Expressions (Expr));
1057
                     while Present (N) loop
1058
                        if Cannot_Raise_Constraint_Error (N) then
1059
                           Next (N);
1060
                        else
1061
                           return False;
1062
                        end if;
1063
                     end loop;
1064
 
1065
                     return True;
1066
                  end;
1067
               end if;
1068
 
1069
            when N_Type_Conversion =>
1070
               if Do_Overflow_Check (Expr)
1071
                 or else Do_Length_Check (Expr)
1072
                 or else Do_Tag_Check (Expr)
1073
               then
1074
                  return False;
1075
               else
1076
                  return
1077
                    Cannot_Raise_Constraint_Error (Expression (Expr));
1078
               end if;
1079
 
1080
            when N_Unchecked_Type_Conversion =>
1081
               return Cannot_Raise_Constraint_Error (Expression (Expr));
1082
 
1083
            when N_Unary_Op =>
1084
               if Do_Overflow_Check (Expr) then
1085
                  return False;
1086
               else
1087
                  return
1088
                    Cannot_Raise_Constraint_Error (Right_Opnd (Expr));
1089
               end if;
1090
 
1091
            when N_Op_Divide |
1092
                 N_Op_Mod    |
1093
                 N_Op_Rem
1094
            =>
1095
               if Do_Division_Check (Expr)
1096
                 or else Do_Overflow_Check (Expr)
1097
               then
1098
                  return False;
1099
               else
1100
                  return
1101
                    Cannot_Raise_Constraint_Error (Left_Opnd (Expr))
1102
                      and then
1103
                    Cannot_Raise_Constraint_Error (Right_Opnd (Expr));
1104
               end if;
1105
 
1106
            when N_Op_Add                    |
1107
                 N_Op_And                    |
1108
                 N_Op_Concat                 |
1109
                 N_Op_Eq                     |
1110
                 N_Op_Expon                  |
1111
                 N_Op_Ge                     |
1112
                 N_Op_Gt                     |
1113
                 N_Op_Le                     |
1114
                 N_Op_Lt                     |
1115
                 N_Op_Multiply               |
1116
                 N_Op_Ne                     |
1117
                 N_Op_Or                     |
1118
                 N_Op_Rotate_Left            |
1119
                 N_Op_Rotate_Right           |
1120
                 N_Op_Shift_Left             |
1121
                 N_Op_Shift_Right            |
1122
                 N_Op_Shift_Right_Arithmetic |
1123
                 N_Op_Subtract               |
1124
                 N_Op_Xor
1125
            =>
1126
               if Do_Overflow_Check (Expr) then
1127
                  return False;
1128
               else
1129
                  return
1130
                    Cannot_Raise_Constraint_Error (Left_Opnd (Expr))
1131
                      and then
1132
                    Cannot_Raise_Constraint_Error (Right_Opnd (Expr));
1133
               end if;
1134
 
1135
            when others =>
1136
               return False;
1137
         end case;
1138
      end if;
1139
   end Cannot_Raise_Constraint_Error;
1140
 
1141
   --------------------------------
1142
   -- Check_Implicit_Dereference --
1143
   --------------------------------
1144
 
1145
   procedure Check_Implicit_Dereference (Nam : Node_Id;  Typ : Entity_Id)
1146
   is
1147
      Disc  : Entity_Id;
1148
      Desig : Entity_Id;
1149
 
1150
   begin
1151
      if Ada_Version < Ada_2012
1152
        or else not Has_Implicit_Dereference (Base_Type (Typ))
1153
      then
1154
         return;
1155
 
1156
      elsif not Comes_From_Source (Nam) then
1157
         return;
1158
 
1159
      elsif Is_Entity_Name (Nam)
1160
        and then Is_Type (Entity (Nam))
1161
      then
1162
         null;
1163
 
1164
      else
1165
         Disc := First_Discriminant (Typ);
1166
         while Present (Disc) loop
1167
            if Has_Implicit_Dereference (Disc) then
1168
               Desig := Designated_Type (Etype (Disc));
1169
               Add_One_Interp (Nam, Disc, Desig);
1170
               exit;
1171
            end if;
1172
 
1173
            Next_Discriminant (Disc);
1174
         end loop;
1175
      end if;
1176
   end Check_Implicit_Dereference;
1177
 
1178
   ---------------------------------------
1179
   -- Check_Later_Vs_Basic_Declarations --
1180
   ---------------------------------------
1181
 
1182
   procedure Check_Later_Vs_Basic_Declarations
1183
     (Decls          : List_Id;
1184
      During_Parsing : Boolean)
1185
   is
1186
      Body_Sloc : Source_Ptr;
1187
      Decl      : Node_Id;
1188
 
1189
      function Is_Later_Declarative_Item (Decl : Node_Id) return Boolean;
1190
      --  Return whether Decl is considered as a declarative item.
1191
      --  When During_Parsing is True, the semantics of Ada 83 is followed.
1192
      --  When During_Parsing is False, the semantics of SPARK is followed.
1193
 
1194
      -------------------------------
1195
      -- Is_Later_Declarative_Item --
1196
      -------------------------------
1197
 
1198
      function Is_Later_Declarative_Item (Decl : Node_Id) return Boolean is
1199
      begin
1200
         if Nkind (Decl) in N_Later_Decl_Item then
1201
            return True;
1202
 
1203
         elsif Nkind (Decl) = N_Pragma then
1204
            return True;
1205
 
1206
         elsif During_Parsing then
1207
            return False;
1208
 
1209
         --  In SPARK, a package declaration is not considered as a later
1210
         --  declarative item.
1211
 
1212
         elsif Nkind (Decl) = N_Package_Declaration then
1213
            return False;
1214
 
1215
         --  In SPARK, a renaming is considered as a later declarative item
1216
 
1217
         elsif Nkind (Decl) in N_Renaming_Declaration then
1218
            return True;
1219
 
1220
         else
1221
            return False;
1222
         end if;
1223
      end Is_Later_Declarative_Item;
1224
 
1225
   --  Start of Check_Later_Vs_Basic_Declarations
1226
 
1227
   begin
1228
      Decl := First (Decls);
1229
 
1230
      --  Loop through sequence of basic declarative items
1231
 
1232
      Outer : while Present (Decl) loop
1233
         if Nkind (Decl) /= N_Subprogram_Body
1234
           and then Nkind (Decl) /= N_Package_Body
1235
           and then Nkind (Decl) /= N_Task_Body
1236
           and then Nkind (Decl) not in N_Body_Stub
1237
         then
1238
            Next (Decl);
1239
 
1240
            --  Once a body is encountered, we only allow later declarative
1241
            --  items. The inner loop checks the rest of the list.
1242
 
1243
         else
1244
            Body_Sloc := Sloc (Decl);
1245
 
1246
            Inner : while Present (Decl) loop
1247
               if not Is_Later_Declarative_Item (Decl) then
1248
                  if During_Parsing then
1249
                     if Ada_Version = Ada_83 then
1250
                        Error_Msg_Sloc := Body_Sloc;
1251
                        Error_Msg_N
1252
                          ("(Ada 83) decl cannot appear after body#", Decl);
1253
                     end if;
1254
                  else
1255
                     Error_Msg_Sloc := Body_Sloc;
1256
                     Check_SPARK_Restriction
1257
                       ("decl cannot appear after body#", Decl);
1258
                  end if;
1259
               end if;
1260
 
1261
               Next (Decl);
1262
            end loop Inner;
1263
         end if;
1264
      end loop Outer;
1265
   end Check_Later_Vs_Basic_Declarations;
1266
 
1267
   -----------------------------------------
1268
   -- Check_Dynamically_Tagged_Expression --
1269
   -----------------------------------------
1270
 
1271
   procedure Check_Dynamically_Tagged_Expression
1272
     (Expr        : Node_Id;
1273
      Typ         : Entity_Id;
1274
      Related_Nod : Node_Id)
1275
   is
1276
   begin
1277
      pragma Assert (Is_Tagged_Type (Typ));
1278
 
1279
      --  In order to avoid spurious errors when analyzing the expanded code,
1280
      --  this check is done only for nodes that come from source and for
1281
      --  actuals of generic instantiations.
1282
 
1283
      if (Comes_From_Source (Related_Nod)
1284
           or else In_Generic_Actual (Expr))
1285
        and then (Is_Class_Wide_Type (Etype (Expr))
1286
                   or else Is_Dynamically_Tagged (Expr))
1287
        and then Is_Tagged_Type (Typ)
1288
        and then not Is_Class_Wide_Type (Typ)
1289
      then
1290
         Error_Msg_N ("dynamically tagged expression not allowed!", Expr);
1291
      end if;
1292
   end Check_Dynamically_Tagged_Expression;
1293
 
1294
   --------------------------
1295
   -- Check_Fully_Declared --
1296
   --------------------------
1297
 
1298
   procedure Check_Fully_Declared (T : Entity_Id; N : Node_Id) is
1299
   begin
1300
      if Ekind (T) = E_Incomplete_Type then
1301
 
1302
         --  Ada 2005 (AI-50217): If the type is available through a limited
1303
         --  with_clause, verify that its full view has been analyzed.
1304
 
1305
         if From_With_Type (T)
1306
           and then Present (Non_Limited_View (T))
1307
           and then Ekind (Non_Limited_View (T)) /= E_Incomplete_Type
1308
         then
1309
            --  The non-limited view is fully declared
1310
            null;
1311
 
1312
         else
1313
            Error_Msg_NE
1314
              ("premature usage of incomplete}", N, First_Subtype (T));
1315
         end if;
1316
 
1317
      --  Need comments for these tests ???
1318
 
1319
      elsif Has_Private_Component (T)
1320
        and then not Is_Generic_Type (Root_Type (T))
1321
        and then not In_Spec_Expression
1322
      then
1323
         --  Special case: if T is the anonymous type created for a single
1324
         --  task or protected object, use the name of the source object.
1325
 
1326
         if Is_Concurrent_Type (T)
1327
           and then not Comes_From_Source (T)
1328
           and then Nkind (N) = N_Object_Declaration
1329
         then
1330
            Error_Msg_NE ("type of& has incomplete component", N,
1331
              Defining_Identifier (N));
1332
 
1333
         else
1334
            Error_Msg_NE
1335
              ("premature usage of incomplete}", N, First_Subtype (T));
1336
         end if;
1337
      end if;
1338
   end Check_Fully_Declared;
1339
 
1340
   -------------------------
1341
   -- Check_Nested_Access --
1342
   -------------------------
1343
 
1344
   procedure Check_Nested_Access (Ent : Entity_Id) is
1345
      Scop         : constant Entity_Id := Current_Scope;
1346
      Current_Subp : Entity_Id;
1347
      Enclosing    : Entity_Id;
1348
 
1349
   begin
1350
      --  Currently only enabled for VM back-ends for efficiency, should we
1351
      --  enable it more systematically ???
1352
 
1353
      --  Check for Is_Imported needs commenting below ???
1354
 
1355
      if VM_Target /= No_VM
1356
        and then (Ekind (Ent) = E_Variable
1357
                    or else
1358
                  Ekind (Ent) = E_Constant
1359
                    or else
1360
                  Ekind (Ent) = E_Loop_Parameter)
1361
        and then Scope (Ent) /= Empty
1362
        and then not Is_Library_Level_Entity (Ent)
1363
        and then not Is_Imported (Ent)
1364
      then
1365
         if Is_Subprogram (Scop)
1366
           or else Is_Generic_Subprogram (Scop)
1367
           or else Is_Entry (Scop)
1368
         then
1369
            Current_Subp := Scop;
1370
         else
1371
            Current_Subp := Current_Subprogram;
1372
         end if;
1373
 
1374
         Enclosing := Enclosing_Subprogram (Ent);
1375
 
1376
         if Enclosing /= Empty
1377
           and then Enclosing /= Current_Subp
1378
         then
1379
            Set_Has_Up_Level_Access (Ent, True);
1380
         end if;
1381
      end if;
1382
   end Check_Nested_Access;
1383
 
1384
   ----------------------------
1385
   -- Check_Order_Dependence --
1386
   ----------------------------
1387
 
1388
   procedure Check_Order_Dependence is
1389
      Act1 : Node_Id;
1390
      Act2 : Node_Id;
1391
 
1392
   begin
1393
      if Ada_Version < Ada_2012 then
1394
         return;
1395
      end if;
1396
 
1397
      --  Ada 2012 AI05-0144-2: Dangerous order dependence. Actuals in nested
1398
      --  calls within a construct have been collected. If one of them is
1399
      --  writable and overlaps with another one, evaluation of the enclosing
1400
      --  construct is nondeterministic. This is illegal in Ada 2012, but is
1401
      --  treated as a warning for now.
1402
 
1403
      for J in 1 .. Actuals_In_Call.Last loop
1404
         if Actuals_In_Call.Table (J).Is_Writable then
1405
            Act1 := Actuals_In_Call.Table (J).Act;
1406
 
1407
            if Nkind (Act1) = N_Attribute_Reference then
1408
               Act1 := Prefix (Act1);
1409
            end if;
1410
 
1411
            for K in 1 .. Actuals_In_Call.Last loop
1412
               if K /= J then
1413
                  Act2 := Actuals_In_Call.Table (K).Act;
1414
 
1415
                  if Nkind (Act2) = N_Attribute_Reference then
1416
                     Act2 := Prefix (Act2);
1417
                  end if;
1418
 
1419
                  if Actuals_In_Call.Table (K).Is_Writable
1420
                    and then K < J
1421
                  then
1422
                     --  Already checked
1423
 
1424
                     null;
1425
 
1426
                  elsif Denotes_Same_Object (Act1, Act2)
1427
                    and then Parent (Act1) /= Parent (Act2)
1428
                  then
1429
                     Error_Msg_N
1430
                       ("result may differ if evaluated "
1431
                        & "after other actual in expression?", Act1);
1432
                  end if;
1433
               end if;
1434
            end loop;
1435
         end if;
1436
      end loop;
1437
 
1438
      --  Remove checked actuals from table
1439
 
1440
      Actuals_In_Call.Set_Last (0);
1441
   end Check_Order_Dependence;
1442
 
1443
   ------------------------------------------
1444
   -- Check_Potentially_Blocking_Operation --
1445
   ------------------------------------------
1446
 
1447
   procedure Check_Potentially_Blocking_Operation (N : Node_Id) is
1448
      S : Entity_Id;
1449
 
1450
   begin
1451
      --  N is one of the potentially blocking operations listed in 9.5.1(8).
1452
      --  When pragma Detect_Blocking is active, the run time will raise
1453
      --  Program_Error. Here we only issue a warning, since we generally
1454
      --  support the use of potentially blocking operations in the absence
1455
      --  of the pragma.
1456
 
1457
      --  Indirect blocking through a subprogram call cannot be diagnosed
1458
      --  statically without interprocedural analysis, so we do not attempt
1459
      --  to do it here.
1460
 
1461
      S := Scope (Current_Scope);
1462
      while Present (S) and then S /= Standard_Standard loop
1463
         if Is_Protected_Type (S) then
1464
            Error_Msg_N
1465
              ("potentially blocking operation in protected operation?", N);
1466
            return;
1467
         end if;
1468
 
1469
         S := Scope (S);
1470
      end loop;
1471
   end Check_Potentially_Blocking_Operation;
1472
 
1473
   ------------------------------
1474
   -- Check_Unprotected_Access --
1475
   ------------------------------
1476
 
1477
   procedure Check_Unprotected_Access
1478
     (Context : Node_Id;
1479
      Expr    : Node_Id)
1480
   is
1481
      Cont_Encl_Typ : Entity_Id;
1482
      Pref_Encl_Typ : Entity_Id;
1483
 
1484
      function Enclosing_Protected_Type (Obj : Node_Id) return Entity_Id;
1485
      --  Check whether Obj is a private component of a protected object.
1486
      --  Return the protected type where the component resides, Empty
1487
      --  otherwise.
1488
 
1489
      function Is_Public_Operation return Boolean;
1490
      --  Verify that the enclosing operation is callable from outside the
1491
      --  protected object, to minimize false positives.
1492
 
1493
      ------------------------------
1494
      -- Enclosing_Protected_Type --
1495
      ------------------------------
1496
 
1497
      function Enclosing_Protected_Type (Obj : Node_Id) return Entity_Id is
1498
      begin
1499
         if Is_Entity_Name (Obj) then
1500
            declare
1501
               Ent : Entity_Id := Entity (Obj);
1502
 
1503
            begin
1504
               --  The object can be a renaming of a private component, use
1505
               --  the original record component.
1506
 
1507
               if Is_Prival (Ent) then
1508
                  Ent := Prival_Link (Ent);
1509
               end if;
1510
 
1511
               if Is_Protected_Type (Scope (Ent)) then
1512
                  return Scope (Ent);
1513
               end if;
1514
            end;
1515
         end if;
1516
 
1517
         --  For indexed and selected components, recursively check the prefix
1518
 
1519
         if Nkind_In (Obj, N_Indexed_Component, N_Selected_Component) then
1520
            return Enclosing_Protected_Type (Prefix (Obj));
1521
 
1522
         --  The object does not denote a protected component
1523
 
1524
         else
1525
            return Empty;
1526
         end if;
1527
      end Enclosing_Protected_Type;
1528
 
1529
      -------------------------
1530
      -- Is_Public_Operation --
1531
      -------------------------
1532
 
1533
      function Is_Public_Operation return Boolean is
1534
         S : Entity_Id;
1535
         E : Entity_Id;
1536
 
1537
      begin
1538
         S := Current_Scope;
1539
         while Present (S)
1540
           and then S /= Pref_Encl_Typ
1541
         loop
1542
            if Scope (S) = Pref_Encl_Typ then
1543
               E := First_Entity (Pref_Encl_Typ);
1544
               while Present (E)
1545
                 and then E /= First_Private_Entity (Pref_Encl_Typ)
1546
               loop
1547
                  if E = S then
1548
                     return True;
1549
                  end if;
1550
                  Next_Entity (E);
1551
               end loop;
1552
            end if;
1553
 
1554
            S := Scope (S);
1555
         end loop;
1556
 
1557
         return False;
1558
      end Is_Public_Operation;
1559
 
1560
   --  Start of processing for Check_Unprotected_Access
1561
 
1562
   begin
1563
      if Nkind (Expr) = N_Attribute_Reference
1564
        and then Attribute_Name (Expr) = Name_Unchecked_Access
1565
      then
1566
         Cont_Encl_Typ := Enclosing_Protected_Type (Context);
1567
         Pref_Encl_Typ := Enclosing_Protected_Type (Prefix (Expr));
1568
 
1569
         --  Check whether we are trying to export a protected component to a
1570
         --  context with an equal or lower access level.
1571
 
1572
         if Present (Pref_Encl_Typ)
1573
           and then No (Cont_Encl_Typ)
1574
           and then Is_Public_Operation
1575
           and then Scope_Depth (Pref_Encl_Typ) >=
1576
                      Object_Access_Level (Context)
1577
         then
1578
            Error_Msg_N
1579
              ("?possible unprotected access to protected data", Expr);
1580
         end if;
1581
      end if;
1582
   end Check_Unprotected_Access;
1583
 
1584
   ---------------
1585
   -- Check_VMS --
1586
   ---------------
1587
 
1588
   procedure Check_VMS (Construct : Node_Id) is
1589
   begin
1590
      if not OpenVMS_On_Target then
1591
         Error_Msg_N
1592
           ("this construct is allowed only in Open'V'M'S", Construct);
1593
      end if;
1594
   end Check_VMS;
1595
 
1596
   ------------------------
1597
   -- Collect_Interfaces --
1598
   ------------------------
1599
 
1600
   procedure Collect_Interfaces
1601
     (T               : Entity_Id;
1602
      Ifaces_List     : out Elist_Id;
1603
      Exclude_Parents : Boolean := False;
1604
      Use_Full_View   : Boolean := True)
1605
   is
1606
      procedure Collect (Typ : Entity_Id);
1607
      --  Subsidiary subprogram used to traverse the whole list
1608
      --  of directly and indirectly implemented interfaces
1609
 
1610
      -------------
1611
      -- Collect --
1612
      -------------
1613
 
1614
      procedure Collect (Typ : Entity_Id) is
1615
         Ancestor   : Entity_Id;
1616
         Full_T     : Entity_Id;
1617
         Id         : Node_Id;
1618
         Iface      : Entity_Id;
1619
 
1620
      begin
1621
         Full_T := Typ;
1622
 
1623
         --  Handle private types
1624
 
1625
         if Use_Full_View
1626
           and then Is_Private_Type (Typ)
1627
           and then Present (Full_View (Typ))
1628
         then
1629
            Full_T := Full_View (Typ);
1630
         end if;
1631
 
1632
         --  Include the ancestor if we are generating the whole list of
1633
         --  abstract interfaces.
1634
 
1635
         if Etype (Full_T) /= Typ
1636
 
1637
            --  Protect the frontend against wrong sources. For example:
1638
 
1639
            --    package P is
1640
            --      type A is tagged null record;
1641
            --      type B is new A with private;
1642
            --      type C is new A with private;
1643
            --    private
1644
            --      type B is new C with null record;
1645
            --      type C is new B with null record;
1646
            --    end P;
1647
 
1648
           and then Etype (Full_T) /= T
1649
         then
1650
            Ancestor := Etype (Full_T);
1651
            Collect (Ancestor);
1652
 
1653
            if Is_Interface (Ancestor)
1654
              and then not Exclude_Parents
1655
            then
1656
               Append_Unique_Elmt (Ancestor, Ifaces_List);
1657
            end if;
1658
         end if;
1659
 
1660
         --  Traverse the graph of ancestor interfaces
1661
 
1662
         if Is_Non_Empty_List (Abstract_Interface_List (Full_T)) then
1663
            Id := First (Abstract_Interface_List (Full_T));
1664
            while Present (Id) loop
1665
               Iface := Etype (Id);
1666
 
1667
               --  Protect against wrong uses. For example:
1668
               --    type I is interface;
1669
               --    type O is tagged null record;
1670
               --    type Wrong is new I and O with null record; -- ERROR
1671
 
1672
               if Is_Interface (Iface) then
1673
                  if Exclude_Parents
1674
                    and then Etype (T) /= T
1675
                    and then Interface_Present_In_Ancestor (Etype (T), Iface)
1676
                  then
1677
                     null;
1678
                  else
1679
                     Collect (Iface);
1680
                     Append_Unique_Elmt (Iface, Ifaces_List);
1681
                  end if;
1682
               end if;
1683
 
1684
               Next (Id);
1685
            end loop;
1686
         end if;
1687
      end Collect;
1688
 
1689
   --  Start of processing for Collect_Interfaces
1690
 
1691
   begin
1692
      pragma Assert (Is_Tagged_Type (T) or else Is_Concurrent_Type (T));
1693
      Ifaces_List := New_Elmt_List;
1694
      Collect (T);
1695
   end Collect_Interfaces;
1696
 
1697
   ----------------------------------
1698
   -- Collect_Interface_Components --
1699
   ----------------------------------
1700
 
1701
   procedure Collect_Interface_Components
1702
     (Tagged_Type     : Entity_Id;
1703
      Components_List : out Elist_Id)
1704
   is
1705
      procedure Collect (Typ : Entity_Id);
1706
      --  Subsidiary subprogram used to climb to the parents
1707
 
1708
      -------------
1709
      -- Collect --
1710
      -------------
1711
 
1712
      procedure Collect (Typ : Entity_Id) is
1713
         Tag_Comp   : Entity_Id;
1714
         Parent_Typ : Entity_Id;
1715
 
1716
      begin
1717
         --  Handle private types
1718
 
1719
         if Present (Full_View (Etype (Typ))) then
1720
            Parent_Typ := Full_View (Etype (Typ));
1721
         else
1722
            Parent_Typ := Etype (Typ);
1723
         end if;
1724
 
1725
         if Parent_Typ /= Typ
1726
 
1727
            --  Protect the frontend against wrong sources. For example:
1728
 
1729
            --    package P is
1730
            --      type A is tagged null record;
1731
            --      type B is new A with private;
1732
            --      type C is new A with private;
1733
            --    private
1734
            --      type B is new C with null record;
1735
            --      type C is new B with null record;
1736
            --    end P;
1737
 
1738
           and then Parent_Typ /= Tagged_Type
1739
         then
1740
            Collect (Parent_Typ);
1741
         end if;
1742
 
1743
         --  Collect the components containing tags of secondary dispatch
1744
         --  tables.
1745
 
1746
         Tag_Comp := Next_Tag_Component (First_Tag_Component (Typ));
1747
         while Present (Tag_Comp) loop
1748
            pragma Assert (Present (Related_Type (Tag_Comp)));
1749
            Append_Elmt (Tag_Comp, Components_List);
1750
 
1751
            Tag_Comp := Next_Tag_Component (Tag_Comp);
1752
         end loop;
1753
      end Collect;
1754
 
1755
   --  Start of processing for Collect_Interface_Components
1756
 
1757
   begin
1758
      pragma Assert (Ekind (Tagged_Type) = E_Record_Type
1759
        and then Is_Tagged_Type (Tagged_Type));
1760
 
1761
      Components_List := New_Elmt_List;
1762
      Collect (Tagged_Type);
1763
   end Collect_Interface_Components;
1764
 
1765
   -----------------------------
1766
   -- Collect_Interfaces_Info --
1767
   -----------------------------
1768
 
1769
   procedure Collect_Interfaces_Info
1770
     (T               : Entity_Id;
1771
      Ifaces_List     : out Elist_Id;
1772
      Components_List : out Elist_Id;
1773
      Tags_List       : out Elist_Id)
1774
   is
1775
      Comps_List : Elist_Id;
1776
      Comp_Elmt  : Elmt_Id;
1777
      Comp_Iface : Entity_Id;
1778
      Iface_Elmt : Elmt_Id;
1779
      Iface      : Entity_Id;
1780
 
1781
      function Search_Tag (Iface : Entity_Id) return Entity_Id;
1782
      --  Search for the secondary tag associated with the interface type
1783
      --  Iface that is implemented by T.
1784
 
1785
      ----------------
1786
      -- Search_Tag --
1787
      ----------------
1788
 
1789
      function Search_Tag (Iface : Entity_Id) return Entity_Id is
1790
         ADT : Elmt_Id;
1791
      begin
1792
         if not Is_CPP_Class (T) then
1793
            ADT := Next_Elmt (Next_Elmt (First_Elmt (Access_Disp_Table (T))));
1794
         else
1795
            ADT := Next_Elmt (First_Elmt (Access_Disp_Table (T)));
1796
         end if;
1797
 
1798
         while Present (ADT)
1799
            and then Is_Tag (Node (ADT))
1800
            and then Related_Type (Node (ADT)) /= Iface
1801
         loop
1802
            --  Skip secondary dispatch table referencing thunks to user
1803
            --  defined primitives covered by this interface.
1804
 
1805
            pragma Assert (Has_Suffix (Node (ADT), 'P'));
1806
            Next_Elmt (ADT);
1807
 
1808
            --  Skip secondary dispatch tables of Ada types
1809
 
1810
            if not Is_CPP_Class (T) then
1811
 
1812
               --  Skip secondary dispatch table referencing thunks to
1813
               --  predefined primitives.
1814
 
1815
               pragma Assert (Has_Suffix (Node (ADT), 'Y'));
1816
               Next_Elmt (ADT);
1817
 
1818
               --  Skip secondary dispatch table referencing user-defined
1819
               --  primitives covered by this interface.
1820
 
1821
               pragma Assert (Has_Suffix (Node (ADT), 'D'));
1822
               Next_Elmt (ADT);
1823
 
1824
               --  Skip secondary dispatch table referencing predefined
1825
               --  primitives.
1826
 
1827
               pragma Assert (Has_Suffix (Node (ADT), 'Z'));
1828
               Next_Elmt (ADT);
1829
            end if;
1830
         end loop;
1831
 
1832
         pragma Assert (Is_Tag (Node (ADT)));
1833
         return Node (ADT);
1834
      end Search_Tag;
1835
 
1836
   --  Start of processing for Collect_Interfaces_Info
1837
 
1838
   begin
1839
      Collect_Interfaces (T, Ifaces_List);
1840
      Collect_Interface_Components (T, Comps_List);
1841
 
1842
      --  Search for the record component and tag associated with each
1843
      --  interface type of T.
1844
 
1845
      Components_List := New_Elmt_List;
1846
      Tags_List       := New_Elmt_List;
1847
 
1848
      Iface_Elmt := First_Elmt (Ifaces_List);
1849
      while Present (Iface_Elmt) loop
1850
         Iface := Node (Iface_Elmt);
1851
 
1852
         --  Associate the primary tag component and the primary dispatch table
1853
         --  with all the interfaces that are parents of T
1854
 
1855
         if Is_Ancestor (Iface, T, Use_Full_View => True) then
1856
            Append_Elmt (First_Tag_Component (T), Components_List);
1857
            Append_Elmt (Node (First_Elmt (Access_Disp_Table (T))), Tags_List);
1858
 
1859
         --  Otherwise search for the tag component and secondary dispatch
1860
         --  table of Iface
1861
 
1862
         else
1863
            Comp_Elmt := First_Elmt (Comps_List);
1864
            while Present (Comp_Elmt) loop
1865
               Comp_Iface := Related_Type (Node (Comp_Elmt));
1866
 
1867
               if Comp_Iface = Iface
1868
                 or else Is_Ancestor (Iface, Comp_Iface, Use_Full_View => True)
1869
               then
1870
                  Append_Elmt (Node (Comp_Elmt), Components_List);
1871
                  Append_Elmt (Search_Tag (Comp_Iface), Tags_List);
1872
                  exit;
1873
               end if;
1874
 
1875
               Next_Elmt (Comp_Elmt);
1876
            end loop;
1877
            pragma Assert (Present (Comp_Elmt));
1878
         end if;
1879
 
1880
         Next_Elmt (Iface_Elmt);
1881
      end loop;
1882
   end Collect_Interfaces_Info;
1883
 
1884
   ---------------------
1885
   -- Collect_Parents --
1886
   ---------------------
1887
 
1888
   procedure Collect_Parents
1889
     (T             : Entity_Id;
1890
      List          : out Elist_Id;
1891
      Use_Full_View : Boolean := True)
1892
   is
1893
      Current_Typ : Entity_Id := T;
1894
      Parent_Typ  : Entity_Id;
1895
 
1896
   begin
1897
      List := New_Elmt_List;
1898
 
1899
      --  No action if the if the type has no parents
1900
 
1901
      if T = Etype (T) then
1902
         return;
1903
      end if;
1904
 
1905
      loop
1906
         Parent_Typ := Etype (Current_Typ);
1907
 
1908
         if Is_Private_Type (Parent_Typ)
1909
           and then Present (Full_View (Parent_Typ))
1910
           and then Use_Full_View
1911
         then
1912
            Parent_Typ := Full_View (Base_Type (Parent_Typ));
1913
         end if;
1914
 
1915
         Append_Elmt (Parent_Typ, List);
1916
 
1917
         exit when Parent_Typ = Current_Typ;
1918
         Current_Typ := Parent_Typ;
1919
      end loop;
1920
   end Collect_Parents;
1921
 
1922
   ----------------------------------
1923
   -- Collect_Primitive_Operations --
1924
   ----------------------------------
1925
 
1926
   function Collect_Primitive_Operations (T : Entity_Id) return Elist_Id is
1927
      B_Type         : constant Entity_Id := Base_Type (T);
1928
      B_Decl         : constant Node_Id   := Original_Node (Parent (B_Type));
1929
      B_Scope        : Entity_Id          := Scope (B_Type);
1930
      Op_List        : Elist_Id;
1931
      Formal         : Entity_Id;
1932
      Is_Prim        : Boolean;
1933
      Formal_Derived : Boolean := False;
1934
      Id             : Entity_Id;
1935
 
1936
      function Match (E : Entity_Id) return Boolean;
1937
      --  True if E's base type is B_Type, or E is of an anonymous access type
1938
      --  and the base type of its designated type is B_Type.
1939
 
1940
      -----------
1941
      -- Match --
1942
      -----------
1943
 
1944
      function Match (E : Entity_Id) return Boolean is
1945
         Etyp : Entity_Id := Etype (E);
1946
 
1947
      begin
1948
         if Ekind (Etyp) = E_Anonymous_Access_Type then
1949
            Etyp := Designated_Type (Etyp);
1950
         end if;
1951
 
1952
         return Base_Type (Etyp) = B_Type;
1953
      end Match;
1954
 
1955
   --  Start of processing for Collect_Primitive_Operations
1956
 
1957
   begin
1958
      --  For tagged types, the primitive operations are collected as they
1959
      --  are declared, and held in an explicit list which is simply returned.
1960
 
1961
      if Is_Tagged_Type (B_Type) then
1962
         return Primitive_Operations (B_Type);
1963
 
1964
      --  An untagged generic type that is a derived type inherits the
1965
      --  primitive operations of its parent type. Other formal types only
1966
      --  have predefined operators, which are not explicitly represented.
1967
 
1968
      elsif Is_Generic_Type (B_Type) then
1969
         if Nkind (B_Decl) = N_Formal_Type_Declaration
1970
           and then Nkind (Formal_Type_Definition (B_Decl))
1971
             = N_Formal_Derived_Type_Definition
1972
         then
1973
            Formal_Derived := True;
1974
         else
1975
            return New_Elmt_List;
1976
         end if;
1977
      end if;
1978
 
1979
      Op_List := New_Elmt_List;
1980
 
1981
      if B_Scope = Standard_Standard then
1982
         if B_Type = Standard_String then
1983
            Append_Elmt (Standard_Op_Concat, Op_List);
1984
 
1985
         elsif B_Type = Standard_Wide_String then
1986
            Append_Elmt (Standard_Op_Concatw, Op_List);
1987
 
1988
         else
1989
            null;
1990
         end if;
1991
 
1992
      elsif (Is_Package_Or_Generic_Package (B_Scope)
1993
              and then
1994
                Nkind (Parent (Declaration_Node (First_Subtype (T)))) /=
1995
                                                            N_Package_Body)
1996
        or else Is_Derived_Type (B_Type)
1997
      then
1998
         --  The primitive operations appear after the base type, except
1999
         --  if the derivation happens within the private part of B_Scope
2000
         --  and the type is a private type, in which case both the type
2001
         --  and some primitive operations may appear before the base
2002
         --  type, and the list of candidates starts after the type.
2003
 
2004
         if In_Open_Scopes (B_Scope)
2005
           and then Scope (T) = B_Scope
2006
           and then In_Private_Part (B_Scope)
2007
         then
2008
            Id := Next_Entity (T);
2009
         else
2010
            Id := Next_Entity (B_Type);
2011
         end if;
2012
 
2013
         while Present (Id) loop
2014
 
2015
            --  Note that generic formal subprograms are not
2016
            --  considered to be primitive operations and thus
2017
            --  are never inherited.
2018
 
2019
            if Is_Overloadable (Id)
2020
              and then Nkind (Parent (Parent (Id)))
2021
                         not in N_Formal_Subprogram_Declaration
2022
            then
2023
               Is_Prim := False;
2024
 
2025
               if Match (Id) then
2026
                  Is_Prim := True;
2027
 
2028
               else
2029
                  Formal := First_Formal (Id);
2030
                  while Present (Formal) loop
2031
                     if Match (Formal) then
2032
                        Is_Prim := True;
2033
                        exit;
2034
                     end if;
2035
 
2036
                     Next_Formal (Formal);
2037
                  end loop;
2038
               end if;
2039
 
2040
               --  For a formal derived type, the only primitives are the
2041
               --  ones inherited from the parent type. Operations appearing
2042
               --  in the package declaration are not primitive for it.
2043
 
2044
               if Is_Prim
2045
                 and then (not Formal_Derived
2046
                            or else Present (Alias (Id)))
2047
               then
2048
                  --  In the special case of an equality operator aliased to
2049
                  --  an overriding dispatching equality belonging to the same
2050
                  --  type, we don't include it in the list of primitives.
2051
                  --  This avoids inheriting multiple equality operators when
2052
                  --  deriving from untagged private types whose full type is
2053
                  --  tagged, which can otherwise cause ambiguities. Note that
2054
                  --  this should only happen for this kind of untagged parent
2055
                  --  type, since normally dispatching operations are inherited
2056
                  --  using the type's Primitive_Operations list.
2057
 
2058
                  if Chars (Id) = Name_Op_Eq
2059
                    and then Is_Dispatching_Operation (Id)
2060
                    and then Present (Alias (Id))
2061
                    and then Present (Overridden_Operation (Alias (Id)))
2062
                    and then Base_Type (Etype (First_Entity (Id))) =
2063
                               Base_Type (Etype (First_Entity (Alias (Id))))
2064
                  then
2065
                     null;
2066
 
2067
                  --  Include the subprogram in the list of primitives
2068
 
2069
                  else
2070
                     Append_Elmt (Id, Op_List);
2071
                  end if;
2072
               end if;
2073
            end if;
2074
 
2075
            Next_Entity (Id);
2076
 
2077
            --  For a type declared in System, some of its operations may
2078
            --  appear in the target-specific extension to System.
2079
 
2080
            if No (Id)
2081
              and then B_Scope = RTU_Entity (System)
2082
              and then Present_System_Aux
2083
            then
2084
               B_Scope := System_Aux_Id;
2085
               Id := First_Entity (System_Aux_Id);
2086
            end if;
2087
         end loop;
2088
      end if;
2089
 
2090
      return Op_List;
2091
   end Collect_Primitive_Operations;
2092
 
2093
   -----------------------------------
2094
   -- Compile_Time_Constraint_Error --
2095
   -----------------------------------
2096
 
2097
   function Compile_Time_Constraint_Error
2098
     (N    : Node_Id;
2099
      Msg  : String;
2100
      Ent  : Entity_Id  := Empty;
2101
      Loc  : Source_Ptr := No_Location;
2102
      Warn : Boolean    := False) return Node_Id
2103
   is
2104
      Msgc : String (1 .. Msg'Length + 2);
2105
      --  Copy of message, with room for possible ? and ! at end
2106
 
2107
      Msgl : Natural;
2108
      Wmsg : Boolean;
2109
      P    : Node_Id;
2110
      OldP : Node_Id;
2111
      Msgs : Boolean;
2112
      Eloc : Source_Ptr;
2113
 
2114
   begin
2115
      --  A static constraint error in an instance body is not a fatal error.
2116
      --  we choose to inhibit the message altogether, because there is no
2117
      --  obvious node (for now) on which to post it. On the other hand the
2118
      --  offending node must be replaced with a constraint_error in any case.
2119
 
2120
      --  No messages are generated if we already posted an error on this node
2121
 
2122
      if not Error_Posted (N) then
2123
         if Loc /= No_Location then
2124
            Eloc := Loc;
2125
         else
2126
            Eloc := Sloc (N);
2127
         end if;
2128
 
2129
         Msgc (1 .. Msg'Length) := Msg;
2130
         Msgl := Msg'Length;
2131
 
2132
         --  Message is a warning, even in Ada 95 case
2133
 
2134
         if Msg (Msg'Last) = '?' then
2135
            Wmsg := True;
2136
 
2137
         --  In Ada 83, all messages are warnings. In the private part and
2138
         --  the body of an instance, constraint_checks are only warnings.
2139
         --  We also make this a warning if the Warn parameter is set.
2140
 
2141
         elsif Warn
2142
           or else (Ada_Version = Ada_83 and then Comes_From_Source (N))
2143
         then
2144
            Msgl := Msgl + 1;
2145
            Msgc (Msgl) := '?';
2146
            Wmsg := True;
2147
 
2148
         elsif In_Instance_Not_Visible then
2149
            Msgl := Msgl + 1;
2150
            Msgc (Msgl) := '?';
2151
            Wmsg := True;
2152
 
2153
         --  Otherwise we have a real error message (Ada 95 static case)
2154
         --  and we make this an unconditional message. Note that in the
2155
         --  warning case we do not make the message unconditional, it seems
2156
         --  quite reasonable to delete messages like this (about exceptions
2157
         --  that will be raised) in dead code.
2158
 
2159
         else
2160
            Wmsg := False;
2161
            Msgl := Msgl + 1;
2162
            Msgc (Msgl) := '!';
2163
         end if;
2164
 
2165
         --  Should we generate a warning? The answer is not quite yes. The
2166
         --  very annoying exception occurs in the case of a short circuit
2167
         --  operator where the left operand is static and decisive. Climb
2168
         --  parents to see if that is the case we have here. Conditional
2169
         --  expressions with decisive conditions are a similar situation.
2170
 
2171
         Msgs := True;
2172
         P := N;
2173
         loop
2174
            OldP := P;
2175
            P := Parent (P);
2176
 
2177
            --  And then with False as left operand
2178
 
2179
            if Nkind (P) = N_And_Then
2180
              and then Compile_Time_Known_Value (Left_Opnd (P))
2181
              and then Is_False (Expr_Value (Left_Opnd (P)))
2182
            then
2183
               Msgs := False;
2184
               exit;
2185
 
2186
            --  OR ELSE with True as left operand
2187
 
2188
            elsif Nkind (P) = N_Or_Else
2189
              and then Compile_Time_Known_Value (Left_Opnd (P))
2190
              and then Is_True (Expr_Value (Left_Opnd (P)))
2191
            then
2192
               Msgs := False;
2193
               exit;
2194
 
2195
            --  Conditional expression
2196
 
2197
            elsif Nkind (P) = N_Conditional_Expression then
2198
               declare
2199
                  Cond : constant Node_Id := First (Expressions (P));
2200
                  Texp : constant Node_Id := Next (Cond);
2201
                  Fexp : constant Node_Id := Next (Texp);
2202
 
2203
               begin
2204
                  if Compile_Time_Known_Value (Cond) then
2205
 
2206
                     --  Condition is True and we are in the right operand
2207
 
2208
                     if Is_True (Expr_Value (Cond))
2209
                       and then OldP = Fexp
2210
                     then
2211
                        Msgs := False;
2212
                        exit;
2213
 
2214
                     --  Condition is False and we are in the left operand
2215
 
2216
                     elsif Is_False (Expr_Value (Cond))
2217
                       and then OldP = Texp
2218
                     then
2219
                        Msgs := False;
2220
                        exit;
2221
                     end if;
2222
                  end if;
2223
               end;
2224
 
2225
            --  Special case for component association in aggregates, where
2226
            --  we want to keep climbing up to the parent aggregate.
2227
 
2228
            elsif Nkind (P) = N_Component_Association
2229
              and then Nkind (Parent (P)) = N_Aggregate
2230
            then
2231
               null;
2232
 
2233
            --  Keep going if within subexpression
2234
 
2235
            else
2236
               exit when Nkind (P) not in N_Subexpr;
2237
            end if;
2238
         end loop;
2239
 
2240
         if Msgs then
2241
            if Present (Ent) then
2242
               Error_Msg_NEL (Msgc (1 .. Msgl), N, Ent, Eloc);
2243
            else
2244
               Error_Msg_NEL (Msgc (1 .. Msgl), N, Etype (N), Eloc);
2245
            end if;
2246
 
2247
            if Wmsg then
2248
               if Inside_Init_Proc then
2249
                  Error_Msg_NEL
2250
                    ("\?& will be raised for objects of this type",
2251
                     N, Standard_Constraint_Error, Eloc);
2252
               else
2253
                  Error_Msg_NEL
2254
                    ("\?& will be raised at run time",
2255
                     N, Standard_Constraint_Error, Eloc);
2256
               end if;
2257
 
2258
            else
2259
               Error_Msg
2260
                 ("\static expression fails Constraint_Check", Eloc);
2261
               Set_Error_Posted (N);
2262
            end if;
2263
         end if;
2264
      end if;
2265
 
2266
      return N;
2267
   end Compile_Time_Constraint_Error;
2268
 
2269
   -----------------------
2270
   -- Conditional_Delay --
2271
   -----------------------
2272
 
2273
   procedure Conditional_Delay (New_Ent, Old_Ent : Entity_Id) is
2274
   begin
2275
      if Has_Delayed_Freeze (Old_Ent) and then not Is_Frozen (Old_Ent) then
2276
         Set_Has_Delayed_Freeze (New_Ent);
2277
      end if;
2278
   end Conditional_Delay;
2279
 
2280
   -------------------------
2281
   -- Copy_Component_List --
2282
   -------------------------
2283
 
2284
   function Copy_Component_List
2285
     (R_Typ : Entity_Id;
2286
      Loc   : Source_Ptr) return List_Id
2287
   is
2288
      Comp  : Node_Id;
2289
      Comps : constant List_Id := New_List;
2290
 
2291
   begin
2292
      Comp := First_Component (Underlying_Type (R_Typ));
2293
      while Present (Comp) loop
2294
         if Comes_From_Source (Comp) then
2295
            declare
2296
               Comp_Decl : constant Node_Id := Declaration_Node (Comp);
2297
            begin
2298
               Append_To (Comps,
2299
                 Make_Component_Declaration (Loc,
2300
                   Defining_Identifier =>
2301
                     Make_Defining_Identifier (Loc, Chars (Comp)),
2302
                   Component_Definition =>
2303
                     New_Copy_Tree
2304
                       (Component_Definition (Comp_Decl), New_Sloc => Loc)));
2305
            end;
2306
         end if;
2307
 
2308
         Next_Component (Comp);
2309
      end loop;
2310
 
2311
      return Comps;
2312
   end Copy_Component_List;
2313
 
2314
   -------------------------
2315
   -- Copy_Parameter_List --
2316
   -------------------------
2317
 
2318
   function Copy_Parameter_List (Subp_Id : Entity_Id) return List_Id is
2319
      Loc    : constant Source_Ptr := Sloc (Subp_Id);
2320
      Plist  : List_Id;
2321
      Formal : Entity_Id;
2322
 
2323
   begin
2324
      if No (First_Formal (Subp_Id)) then
2325
         return No_List;
2326
      else
2327
         Plist := New_List;
2328
         Formal := First_Formal (Subp_Id);
2329
         while Present (Formal) loop
2330
            Append
2331
              (Make_Parameter_Specification (Loc,
2332
                Defining_Identifier =>
2333
                  Make_Defining_Identifier (Sloc (Formal),
2334
                    Chars => Chars (Formal)),
2335
                In_Present  => In_Present (Parent (Formal)),
2336
                Out_Present => Out_Present (Parent (Formal)),
2337
             Parameter_Type =>
2338
                  New_Reference_To (Etype (Formal), Loc),
2339
                Expression =>
2340
                  New_Copy_Tree (Expression (Parent (Formal)))),
2341
              Plist);
2342
 
2343
            Next_Formal (Formal);
2344
         end loop;
2345
      end if;
2346
 
2347
      return Plist;
2348
   end Copy_Parameter_List;
2349
 
2350
   --------------------
2351
   -- Current_Entity --
2352
   --------------------
2353
 
2354
   --  The currently visible definition for a given identifier is the
2355
   --  one most chained at the start of the visibility chain, i.e. the
2356
   --  one that is referenced by the Node_Id value of the name of the
2357
   --  given identifier.
2358
 
2359
   function Current_Entity (N : Node_Id) return Entity_Id is
2360
   begin
2361
      return Get_Name_Entity_Id (Chars (N));
2362
   end Current_Entity;
2363
 
2364
   -----------------------------
2365
   -- Current_Entity_In_Scope --
2366
   -----------------------------
2367
 
2368
   function Current_Entity_In_Scope (N : Node_Id) return Entity_Id is
2369
      E  : Entity_Id;
2370
      CS : constant Entity_Id := Current_Scope;
2371
 
2372
      Transient_Case : constant Boolean := Scope_Is_Transient;
2373
 
2374
   begin
2375
      E := Get_Name_Entity_Id (Chars (N));
2376
      while Present (E)
2377
        and then Scope (E) /= CS
2378
        and then (not Transient_Case or else Scope (E) /= Scope (CS))
2379
      loop
2380
         E := Homonym (E);
2381
      end loop;
2382
 
2383
      return E;
2384
   end Current_Entity_In_Scope;
2385
 
2386
   -------------------
2387
   -- Current_Scope --
2388
   -------------------
2389
 
2390
   function Current_Scope return Entity_Id is
2391
   begin
2392
      if Scope_Stack.Last = -1 then
2393
         return Standard_Standard;
2394
      else
2395
         declare
2396
            C : constant Entity_Id :=
2397
                  Scope_Stack.Table (Scope_Stack.Last).Entity;
2398
         begin
2399
            if Present (C) then
2400
               return C;
2401
            else
2402
               return Standard_Standard;
2403
            end if;
2404
         end;
2405
      end if;
2406
   end Current_Scope;
2407
 
2408
   ------------------------
2409
   -- Current_Subprogram --
2410
   ------------------------
2411
 
2412
   function Current_Subprogram return Entity_Id is
2413
      Scop : constant Entity_Id := Current_Scope;
2414
   begin
2415
      if Is_Subprogram (Scop) or else Is_Generic_Subprogram (Scop) then
2416
         return Scop;
2417
      else
2418
         return Enclosing_Subprogram (Scop);
2419
      end if;
2420
   end Current_Subprogram;
2421
 
2422
   ----------------------------------
2423
   -- Deepest_Type_Access_Level --
2424
   ----------------------------------
2425
 
2426
   function Deepest_Type_Access_Level (Typ : Entity_Id) return Uint is
2427
   begin
2428
      if Ekind (Typ) = E_Anonymous_Access_Type
2429
        and then not Is_Local_Anonymous_Access (Typ)
2430
        and then Nkind (Associated_Node_For_Itype (Typ)) = N_Object_Declaration
2431
      then
2432
         --  Typ is the type of an Ada 2012 stand-alone object of an anonymous
2433
         --  access type.
2434
 
2435
         return
2436
           Scope_Depth (Enclosing_Dynamic_Scope
2437
                         (Defining_Identifier
2438
                           (Associated_Node_For_Itype (Typ))));
2439
 
2440
      --  For generic formal type, return Int'Last (infinite).
2441
      --  See comment preceding Is_Generic_Type call in Type_Access_Level.
2442
 
2443
      elsif Is_Generic_Type (Root_Type (Typ)) then
2444
         return UI_From_Int (Int'Last);
2445
 
2446
      else
2447
         return Type_Access_Level (Typ);
2448
      end if;
2449
   end Deepest_Type_Access_Level;
2450
 
2451
   ---------------------
2452
   -- Defining_Entity --
2453
   ---------------------
2454
 
2455
   function Defining_Entity (N : Node_Id) return Entity_Id is
2456
      K   : constant Node_Kind := Nkind (N);
2457
      Err : Entity_Id := Empty;
2458
 
2459
   begin
2460
      case K is
2461
         when
2462
           N_Subprogram_Declaration                 |
2463
           N_Abstract_Subprogram_Declaration        |
2464
           N_Subprogram_Body                        |
2465
           N_Package_Declaration                    |
2466
           N_Subprogram_Renaming_Declaration        |
2467
           N_Subprogram_Body_Stub                   |
2468
           N_Generic_Subprogram_Declaration         |
2469
           N_Generic_Package_Declaration            |
2470
           N_Formal_Subprogram_Declaration          |
2471
           N_Expression_Function
2472
         =>
2473
            return Defining_Entity (Specification (N));
2474
 
2475
         when
2476
           N_Component_Declaration                  |
2477
           N_Defining_Program_Unit_Name             |
2478
           N_Discriminant_Specification             |
2479
           N_Entry_Body                             |
2480
           N_Entry_Declaration                      |
2481
           N_Entry_Index_Specification              |
2482
           N_Exception_Declaration                  |
2483
           N_Exception_Renaming_Declaration         |
2484
           N_Formal_Object_Declaration              |
2485
           N_Formal_Package_Declaration             |
2486
           N_Formal_Type_Declaration                |
2487
           N_Full_Type_Declaration                  |
2488
           N_Implicit_Label_Declaration             |
2489
           N_Incomplete_Type_Declaration            |
2490
           N_Loop_Parameter_Specification           |
2491
           N_Number_Declaration                     |
2492
           N_Object_Declaration                     |
2493
           N_Object_Renaming_Declaration            |
2494
           N_Package_Body_Stub                      |
2495
           N_Parameter_Specification                |
2496
           N_Private_Extension_Declaration          |
2497
           N_Private_Type_Declaration               |
2498
           N_Protected_Body                         |
2499
           N_Protected_Body_Stub                    |
2500
           N_Protected_Type_Declaration             |
2501
           N_Single_Protected_Declaration           |
2502
           N_Single_Task_Declaration                |
2503
           N_Subtype_Declaration                    |
2504
           N_Task_Body                              |
2505
           N_Task_Body_Stub                         |
2506
           N_Task_Type_Declaration
2507
         =>
2508
            return Defining_Identifier (N);
2509
 
2510
         when N_Subunit =>
2511
            return Defining_Entity (Proper_Body (N));
2512
 
2513
         when
2514
           N_Function_Instantiation                 |
2515
           N_Function_Specification                 |
2516
           N_Generic_Function_Renaming_Declaration  |
2517
           N_Generic_Package_Renaming_Declaration   |
2518
           N_Generic_Procedure_Renaming_Declaration |
2519
           N_Package_Body                           |
2520
           N_Package_Instantiation                  |
2521
           N_Package_Renaming_Declaration           |
2522
           N_Package_Specification                  |
2523
           N_Procedure_Instantiation                |
2524
           N_Procedure_Specification
2525
         =>
2526
            declare
2527
               Nam : constant Node_Id := Defining_Unit_Name (N);
2528
 
2529
            begin
2530
               if Nkind (Nam) in N_Entity then
2531
                  return Nam;
2532
 
2533
               --  For Error, make up a name and attach to declaration
2534
               --  so we can continue semantic analysis
2535
 
2536
               elsif Nam = Error then
2537
                  Err := Make_Temporary (Sloc (N), 'T');
2538
                  Set_Defining_Unit_Name (N, Err);
2539
 
2540
                  return Err;
2541
               --  If not an entity, get defining identifier
2542
 
2543
               else
2544
                  return Defining_Identifier (Nam);
2545
               end if;
2546
            end;
2547
 
2548
         when N_Block_Statement =>
2549
            return Entity (Identifier (N));
2550
 
2551
         when others =>
2552
            raise Program_Error;
2553
 
2554
      end case;
2555
   end Defining_Entity;
2556
 
2557
   --------------------------
2558
   -- Denotes_Discriminant --
2559
   --------------------------
2560
 
2561
   function Denotes_Discriminant
2562
     (N                : Node_Id;
2563
      Check_Concurrent : Boolean := False) return Boolean
2564
   is
2565
      E : Entity_Id;
2566
   begin
2567
      if not Is_Entity_Name (N)
2568
        or else No (Entity (N))
2569
      then
2570
         return False;
2571
      else
2572
         E := Entity (N);
2573
      end if;
2574
 
2575
      --  If we are checking for a protected type, the discriminant may have
2576
      --  been rewritten as the corresponding discriminal of the original type
2577
      --  or of the corresponding concurrent record, depending on whether we
2578
      --  are in the spec or body of the protected type.
2579
 
2580
      return Ekind (E) = E_Discriminant
2581
        or else
2582
          (Check_Concurrent
2583
            and then Ekind (E) = E_In_Parameter
2584
            and then Present (Discriminal_Link (E))
2585
            and then
2586
              (Is_Concurrent_Type (Scope (Discriminal_Link (E)))
2587
                or else
2588
                  Is_Concurrent_Record_Type (Scope (Discriminal_Link (E)))));
2589
 
2590
   end Denotes_Discriminant;
2591
 
2592
   -------------------------
2593
   -- Denotes_Same_Object --
2594
   -------------------------
2595
 
2596
   function Denotes_Same_Object (A1, A2 : Node_Id) return Boolean is
2597
      Obj1 : Node_Id := A1;
2598
      Obj2 : Node_Id := A2;
2599
 
2600
      procedure Check_Renaming (Obj : in out Node_Id);
2601
      --  If an object is a renaming, examine renamed object. If it is a
2602
      --  dereference of a variable, or an indexed expression with non-constant
2603
      --  indexes, no overlap check can be reported.
2604
 
2605
      --------------------
2606
      -- Check_Renaming --
2607
      --------------------
2608
 
2609
      procedure Check_Renaming (Obj : in out Node_Id) is
2610
      begin
2611
         if Is_Entity_Name (Obj)
2612
           and then Present (Renamed_Entity (Entity (Obj)))
2613
         then
2614
            Obj := Renamed_Entity (Entity (Obj));
2615
            if Nkind (Obj) = N_Explicit_Dereference
2616
              and then Is_Variable (Prefix (Obj))
2617
            then
2618
               Obj := Empty;
2619
 
2620
            elsif Nkind (Obj) = N_Indexed_Component then
2621
               declare
2622
                  Indx : Node_Id;
2623
 
2624
               begin
2625
                  Indx := First (Expressions (Obj));
2626
                  while Present (Indx) loop
2627
                     if not Is_OK_Static_Expression (Indx) then
2628
                        Obj := Empty;
2629
                        exit;
2630
                     end if;
2631
 
2632
                     Next_Index (Indx);
2633
                  end loop;
2634
               end;
2635
            end if;
2636
         end if;
2637
      end Check_Renaming;
2638
 
2639
   --  Start of processing for Denotes_Same_Object
2640
 
2641
   begin
2642
      Check_Renaming (Obj1);
2643
      Check_Renaming (Obj2);
2644
 
2645
      if No (Obj1)
2646
        or else No (Obj2)
2647
      then
2648
         return False;
2649
      end if;
2650
 
2651
      --  If we have entity names, then must be same entity
2652
 
2653
      if Is_Entity_Name (Obj1) then
2654
         if Is_Entity_Name (Obj2) then
2655
            return Entity (Obj1) = Entity (Obj2);
2656
         else
2657
            return False;
2658
         end if;
2659
 
2660
      --  No match if not same node kind
2661
 
2662
      elsif Nkind (Obj1) /= Nkind (Obj2) then
2663
         return False;
2664
 
2665
      --  For selected components, must have same prefix and selector
2666
 
2667
      elsif Nkind (Obj1) = N_Selected_Component then
2668
         return Denotes_Same_Object (Prefix (Obj1), Prefix (Obj2))
2669
           and then
2670
         Entity (Selector_Name (Obj1)) = Entity (Selector_Name (Obj2));
2671
 
2672
      --  For explicit dereferences, prefixes must be same
2673
 
2674
      elsif Nkind (Obj1) = N_Explicit_Dereference then
2675
         return Denotes_Same_Object (Prefix (Obj1), Prefix (Obj2));
2676
 
2677
      --  For indexed components, prefixes and all subscripts must be the same
2678
 
2679
      elsif Nkind (Obj1) = N_Indexed_Component then
2680
         if Denotes_Same_Object (Prefix (Obj1), Prefix (Obj2)) then
2681
            declare
2682
               Indx1 : Node_Id;
2683
               Indx2 : Node_Id;
2684
 
2685
            begin
2686
               Indx1 := First (Expressions (Obj1));
2687
               Indx2 := First (Expressions (Obj2));
2688
               while Present (Indx1) loop
2689
 
2690
                  --  Indexes must denote the same static value or same object
2691
 
2692
                  if Is_OK_Static_Expression (Indx1) then
2693
                     if not Is_OK_Static_Expression (Indx2) then
2694
                        return False;
2695
 
2696
                     elsif Expr_Value (Indx1) /= Expr_Value (Indx2) then
2697
                        return False;
2698
                     end if;
2699
 
2700
                  elsif not Denotes_Same_Object (Indx1, Indx2) then
2701
                     return False;
2702
                  end if;
2703
 
2704
                  Next (Indx1);
2705
                  Next (Indx2);
2706
               end loop;
2707
 
2708
               return True;
2709
            end;
2710
         else
2711
            return False;
2712
         end if;
2713
 
2714
      --  For slices, prefixes must match and bounds must match
2715
 
2716
      elsif Nkind (Obj1) = N_Slice
2717
        and then Denotes_Same_Object (Prefix (Obj1), Prefix (Obj2))
2718
      then
2719
         declare
2720
            Lo1, Lo2, Hi1, Hi2 : Node_Id;
2721
 
2722
         begin
2723
            Get_Index_Bounds (Etype (Obj1), Lo1, Hi1);
2724
            Get_Index_Bounds (Etype (Obj2), Lo2, Hi2);
2725
 
2726
            --  Check whether bounds are statically identical. There is no
2727
            --  attempt to detect partial overlap of slices.
2728
 
2729
            return Denotes_Same_Object (Lo1, Lo2)
2730
              and then Denotes_Same_Object (Hi1, Hi2);
2731
         end;
2732
 
2733
         --  Literals will appear as indexes. Isn't this where we should check
2734
         --  Known_At_Compile_Time at least if we are generating warnings ???
2735
 
2736
      elsif Nkind (Obj1) = N_Integer_Literal then
2737
         return Intval (Obj1) = Intval (Obj2);
2738
 
2739
      else
2740
         return False;
2741
      end if;
2742
   end Denotes_Same_Object;
2743
 
2744
   -------------------------
2745
   -- Denotes_Same_Prefix --
2746
   -------------------------
2747
 
2748
   function Denotes_Same_Prefix (A1, A2 : Node_Id) return Boolean is
2749
 
2750
   begin
2751
      if Is_Entity_Name (A1) then
2752
         if Nkind_In (A2, N_Selected_Component, N_Indexed_Component)
2753
           and then not Is_Access_Type (Etype (A1))
2754
         then
2755
            return Denotes_Same_Object (A1, Prefix (A2))
2756
              or else Denotes_Same_Prefix (A1, Prefix (A2));
2757
         else
2758
            return False;
2759
         end if;
2760
 
2761
      elsif Is_Entity_Name (A2) then
2762
         return Denotes_Same_Prefix (A1 => A2, A2 => A1);
2763
 
2764
      elsif Nkind_In (A1, N_Selected_Component, N_Indexed_Component, N_Slice)
2765
              and then
2766
            Nkind_In (A2, N_Selected_Component, N_Indexed_Component, N_Slice)
2767
      then
2768
         declare
2769
            Root1, Root2 : Node_Id;
2770
            Depth1, Depth2 : Int := 0;
2771
 
2772
         begin
2773
            Root1 := Prefix (A1);
2774
            while not Is_Entity_Name (Root1) loop
2775
               if not Nkind_In
2776
                 (Root1, N_Selected_Component, N_Indexed_Component)
2777
               then
2778
                  return False;
2779
               else
2780
                  Root1 := Prefix (Root1);
2781
               end if;
2782
 
2783
               Depth1 := Depth1 + 1;
2784
            end loop;
2785
 
2786
            Root2 := Prefix (A2);
2787
            while not Is_Entity_Name (Root2) loop
2788
               if not Nkind_In
2789
                 (Root2, N_Selected_Component, N_Indexed_Component)
2790
               then
2791
                  return False;
2792
               else
2793
                  Root2 := Prefix (Root2);
2794
               end if;
2795
 
2796
               Depth2 := Depth2 + 1;
2797
            end loop;
2798
 
2799
            --  If both have the same depth and they do not denote the same
2800
            --  object, they are disjoint and not warning is needed.
2801
 
2802
            if Depth1 = Depth2 then
2803
               return False;
2804
 
2805
            elsif Depth1 > Depth2 then
2806
               Root1 := Prefix (A1);
2807
               for I in 1 .. Depth1 - Depth2 - 1 loop
2808
                  Root1 := Prefix (Root1);
2809
               end loop;
2810
 
2811
               return Denotes_Same_Object (Root1, A2);
2812
 
2813
            else
2814
               Root2 := Prefix (A2);
2815
               for I in 1 .. Depth2 - Depth1 - 1 loop
2816
                  Root2 := Prefix (Root2);
2817
               end loop;
2818
 
2819
               return Denotes_Same_Object (A1, Root2);
2820
            end if;
2821
         end;
2822
 
2823
      else
2824
         return False;
2825
      end if;
2826
   end Denotes_Same_Prefix;
2827
 
2828
   ----------------------
2829
   -- Denotes_Variable --
2830
   ----------------------
2831
 
2832
   function Denotes_Variable (N : Node_Id) return Boolean is
2833
   begin
2834
      return Is_Variable (N) and then Paren_Count (N) = 0;
2835
   end Denotes_Variable;
2836
 
2837
   -----------------------------
2838
   -- Depends_On_Discriminant --
2839
   -----------------------------
2840
 
2841
   function Depends_On_Discriminant (N : Node_Id) return Boolean is
2842
      L : Node_Id;
2843
      H : Node_Id;
2844
 
2845
   begin
2846
      Get_Index_Bounds (N, L, H);
2847
      return Denotes_Discriminant (L) or else Denotes_Discriminant (H);
2848
   end Depends_On_Discriminant;
2849
 
2850
   -------------------------
2851
   -- Designate_Same_Unit --
2852
   -------------------------
2853
 
2854
   function Designate_Same_Unit
2855
     (Name1 : Node_Id;
2856
      Name2 : Node_Id) return Boolean
2857
   is
2858
      K1 : constant Node_Kind := Nkind (Name1);
2859
      K2 : constant Node_Kind := Nkind (Name2);
2860
 
2861
      function Prefix_Node (N : Node_Id) return Node_Id;
2862
      --  Returns the parent unit name node of a defining program unit name
2863
      --  or the prefix if N is a selected component or an expanded name.
2864
 
2865
      function Select_Node (N : Node_Id) return Node_Id;
2866
      --  Returns the defining identifier node of a defining program unit
2867
      --  name or  the selector node if N is a selected component or an
2868
      --  expanded name.
2869
 
2870
      -----------------
2871
      -- Prefix_Node --
2872
      -----------------
2873
 
2874
      function Prefix_Node (N : Node_Id) return Node_Id is
2875
      begin
2876
         if Nkind (N) = N_Defining_Program_Unit_Name then
2877
            return Name (N);
2878
 
2879
         else
2880
            return Prefix (N);
2881
         end if;
2882
      end Prefix_Node;
2883
 
2884
      -----------------
2885
      -- Select_Node --
2886
      -----------------
2887
 
2888
      function Select_Node (N : Node_Id) return Node_Id is
2889
      begin
2890
         if Nkind (N) = N_Defining_Program_Unit_Name then
2891
            return Defining_Identifier (N);
2892
 
2893
         else
2894
            return Selector_Name (N);
2895
         end if;
2896
      end Select_Node;
2897
 
2898
   --  Start of processing for Designate_Next_Unit
2899
 
2900
   begin
2901
      if (K1 = N_Identifier or else
2902
          K1 = N_Defining_Identifier)
2903
        and then
2904
         (K2 = N_Identifier or else
2905
          K2 = N_Defining_Identifier)
2906
      then
2907
         return Chars (Name1) = Chars (Name2);
2908
 
2909
      elsif
2910
         (K1 = N_Expanded_Name      or else
2911
          K1 = N_Selected_Component or else
2912
          K1 = N_Defining_Program_Unit_Name)
2913
        and then
2914
         (K2 = N_Expanded_Name      or else
2915
          K2 = N_Selected_Component or else
2916
          K2 = N_Defining_Program_Unit_Name)
2917
      then
2918
         return
2919
           (Chars (Select_Node (Name1)) = Chars (Select_Node (Name2)))
2920
             and then
2921
               Designate_Same_Unit (Prefix_Node (Name1), Prefix_Node (Name2));
2922
 
2923
      else
2924
         return False;
2925
      end if;
2926
   end Designate_Same_Unit;
2927
 
2928
   ------------------------------------------
2929
   -- function Dynamic_Accessibility_Level --
2930
   ------------------------------------------
2931
 
2932
   function Dynamic_Accessibility_Level (Expr : Node_Id) return Node_Id is
2933
      E : Entity_Id;
2934
      Loc : constant Source_Ptr := Sloc (Expr);
2935
 
2936
      function Make_Level_Literal (Level : Uint) return Node_Id;
2937
      --  Construct an integer literal representing an accessibility level
2938
      --  with its type set to Natural.
2939
 
2940
      ------------------------
2941
      -- Make_Level_Literal --
2942
      ------------------------
2943
 
2944
      function Make_Level_Literal (Level : Uint) return Node_Id is
2945
         Result : constant Node_Id := Make_Integer_Literal (Loc, Level);
2946
      begin
2947
         Set_Etype (Result, Standard_Natural);
2948
         return Result;
2949
      end Make_Level_Literal;
2950
 
2951
   --  Start of processing for Dynamic_Accessibility_Level
2952
 
2953
   begin
2954
      if Is_Entity_Name (Expr) then
2955
         E := Entity (Expr);
2956
 
2957
         if Present (Renamed_Object (E)) then
2958
            return Dynamic_Accessibility_Level (Renamed_Object (E));
2959
         end if;
2960
 
2961
         if Is_Formal (E) or else Ekind_In (E, E_Variable, E_Constant) then
2962
            if Present (Extra_Accessibility (E)) then
2963
               return New_Occurrence_Of (Extra_Accessibility (E), Loc);
2964
            end if;
2965
         end if;
2966
      end if;
2967
 
2968
      --  Unimplemented: Ptr.all'Access, where Ptr has Extra_Accessibility ???
2969
 
2970
      case Nkind (Expr) is
2971
 
2972
         --  For access discriminant, the level of the enclosing object
2973
 
2974
         when N_Selected_Component =>
2975
            if Ekind (Entity (Selector_Name (Expr))) = E_Discriminant
2976
              and then Ekind (Etype (Entity (Selector_Name (Expr)))) =
2977
                                            E_Anonymous_Access_Type
2978
            then
2979
               return Make_Level_Literal (Object_Access_Level (Expr));
2980
            end if;
2981
 
2982
         when N_Attribute_Reference =>
2983
            case Get_Attribute_Id (Attribute_Name (Expr)) is
2984
 
2985
               --  For X'Access, the level of the prefix X
2986
 
2987
               when Attribute_Access =>
2988
                  return Make_Level_Literal
2989
                           (Object_Access_Level (Prefix (Expr)));
2990
 
2991
               --  Treat the unchecked attributes as library-level
2992
 
2993
               when Attribute_Unchecked_Access    |
2994
                    Attribute_Unrestricted_Access =>
2995
                  return Make_Level_Literal (Scope_Depth (Standard_Standard));
2996
 
2997
               --  No other access-valued attributes
2998
 
2999
               when others =>
3000
                  raise Program_Error;
3001
            end case;
3002
 
3003
         when N_Allocator =>
3004
 
3005
            --  Unimplemented: depends on context. As an actual parameter where
3006
            --  formal type is anonymous, use
3007
            --    Scope_Depth (Current_Scope) + 1.
3008
            --  For other cases, see 3.10.2(14/3) and following. ???
3009
 
3010
            null;
3011
 
3012
         when N_Type_Conversion =>
3013
            if not Is_Local_Anonymous_Access (Etype (Expr)) then
3014
 
3015
               --  Handle type conversions introduced for a rename of an
3016
               --  Ada 2012 stand-alone object of an anonymous access type.
3017
 
3018
               return Dynamic_Accessibility_Level (Expression (Expr));
3019
            end if;
3020
 
3021
         when others =>
3022
            null;
3023
      end case;
3024
 
3025
      return Make_Level_Literal (Type_Access_Level (Etype (Expr)));
3026
   end Dynamic_Accessibility_Level;
3027
 
3028
   -----------------------------------
3029
   -- Effective_Extra_Accessibility --
3030
   -----------------------------------
3031
 
3032
   function Effective_Extra_Accessibility (Id : Entity_Id) return Entity_Id is
3033
   begin
3034
      if Present (Renamed_Object (Id))
3035
        and then Is_Entity_Name (Renamed_Object (Id))
3036
      then
3037
         return Effective_Extra_Accessibility (Entity (Renamed_Object (Id)));
3038
      end if;
3039
 
3040
      return Extra_Accessibility (Id);
3041
   end Effective_Extra_Accessibility;
3042
 
3043
   --------------------------
3044
   -- Enclosing_CPP_Parent --
3045
   --------------------------
3046
 
3047
   function Enclosing_CPP_Parent (Typ : Entity_Id) return Entity_Id is
3048
      Parent_Typ : Entity_Id := Typ;
3049
 
3050
   begin
3051
      while not Is_CPP_Class (Parent_Typ)
3052
         and then Etype (Parent_Typ) /= Parent_Typ
3053
      loop
3054
         Parent_Typ := Etype (Parent_Typ);
3055
 
3056
         if Is_Private_Type (Parent_Typ) then
3057
            Parent_Typ := Full_View (Base_Type (Parent_Typ));
3058
         end if;
3059
      end loop;
3060
 
3061
      pragma Assert (Is_CPP_Class (Parent_Typ));
3062
      return Parent_Typ;
3063
   end Enclosing_CPP_Parent;
3064
 
3065
   ----------------------------
3066
   -- Enclosing_Generic_Body --
3067
   ----------------------------
3068
 
3069
   function Enclosing_Generic_Body
3070
     (N : Node_Id) return Node_Id
3071
   is
3072
      P    : Node_Id;
3073
      Decl : Node_Id;
3074
      Spec : Node_Id;
3075
 
3076
   begin
3077
      P := Parent (N);
3078
      while Present (P) loop
3079
         if Nkind (P) = N_Package_Body
3080
           or else Nkind (P) = N_Subprogram_Body
3081
         then
3082
            Spec := Corresponding_Spec (P);
3083
 
3084
            if Present (Spec) then
3085
               Decl := Unit_Declaration_Node (Spec);
3086
 
3087
               if Nkind (Decl) = N_Generic_Package_Declaration
3088
                 or else Nkind (Decl) = N_Generic_Subprogram_Declaration
3089
               then
3090
                  return P;
3091
               end if;
3092
            end if;
3093
         end if;
3094
 
3095
         P := Parent (P);
3096
      end loop;
3097
 
3098
      return Empty;
3099
   end Enclosing_Generic_Body;
3100
 
3101
   ----------------------------
3102
   -- Enclosing_Generic_Unit --
3103
   ----------------------------
3104
 
3105
   function Enclosing_Generic_Unit
3106
     (N : Node_Id) return Node_Id
3107
   is
3108
      P    : Node_Id;
3109
      Decl : Node_Id;
3110
      Spec : Node_Id;
3111
 
3112
   begin
3113
      P := Parent (N);
3114
      while Present (P) loop
3115
         if Nkind (P) = N_Generic_Package_Declaration
3116
           or else Nkind (P) = N_Generic_Subprogram_Declaration
3117
         then
3118
            return P;
3119
 
3120
         elsif Nkind (P) = N_Package_Body
3121
           or else Nkind (P) = N_Subprogram_Body
3122
         then
3123
            Spec := Corresponding_Spec (P);
3124
 
3125
            if Present (Spec) then
3126
               Decl := Unit_Declaration_Node (Spec);
3127
 
3128
               if Nkind (Decl) = N_Generic_Package_Declaration
3129
                 or else Nkind (Decl) = N_Generic_Subprogram_Declaration
3130
               then
3131
                  return Decl;
3132
               end if;
3133
            end if;
3134
         end if;
3135
 
3136
         P := Parent (P);
3137
      end loop;
3138
 
3139
      return Empty;
3140
   end Enclosing_Generic_Unit;
3141
 
3142
   -------------------------------
3143
   -- Enclosing_Lib_Unit_Entity --
3144
   -------------------------------
3145
 
3146
   function Enclosing_Lib_Unit_Entity return Entity_Id is
3147
      Unit_Entity : Entity_Id;
3148
 
3149
   begin
3150
      --  Look for enclosing library unit entity by following scope links.
3151
      --  Equivalent to, but faster than indexing through the scope stack.
3152
 
3153
      Unit_Entity := Current_Scope;
3154
      while (Present (Scope (Unit_Entity))
3155
        and then Scope (Unit_Entity) /= Standard_Standard)
3156
        and not Is_Child_Unit (Unit_Entity)
3157
      loop
3158
         Unit_Entity := Scope (Unit_Entity);
3159
      end loop;
3160
 
3161
      return Unit_Entity;
3162
   end Enclosing_Lib_Unit_Entity;
3163
 
3164
   -----------------------------
3165
   -- Enclosing_Lib_Unit_Node --
3166
   -----------------------------
3167
 
3168
   function Enclosing_Lib_Unit_Node (N : Node_Id) return Node_Id is
3169
      Current_Node : Node_Id;
3170
 
3171
   begin
3172
      Current_Node := N;
3173
      while Present (Current_Node)
3174
        and then Nkind (Current_Node) /= N_Compilation_Unit
3175
      loop
3176
         Current_Node := Parent (Current_Node);
3177
      end loop;
3178
 
3179
      if Nkind (Current_Node) /= N_Compilation_Unit then
3180
         return Empty;
3181
      end if;
3182
 
3183
      return Current_Node;
3184
   end Enclosing_Lib_Unit_Node;
3185
 
3186
   -----------------------
3187
   -- Enclosing_Package --
3188
   -----------------------
3189
 
3190
   function Enclosing_Package (E : Entity_Id) return Entity_Id is
3191
      Dynamic_Scope : constant Entity_Id := Enclosing_Dynamic_Scope (E);
3192
 
3193
   begin
3194
      if Dynamic_Scope = Standard_Standard then
3195
         return Standard_Standard;
3196
 
3197
      elsif Dynamic_Scope = Empty then
3198
         return Empty;
3199
 
3200
      elsif Ekind_In (Dynamic_Scope, E_Package, E_Package_Body,
3201
                      E_Generic_Package)
3202
      then
3203
         return Dynamic_Scope;
3204
 
3205
      else
3206
         return Enclosing_Package (Dynamic_Scope);
3207
      end if;
3208
   end Enclosing_Package;
3209
 
3210
   --------------------------
3211
   -- Enclosing_Subprogram --
3212
   --------------------------
3213
 
3214
   function Enclosing_Subprogram (E : Entity_Id) return Entity_Id is
3215
      Dynamic_Scope : constant Entity_Id := Enclosing_Dynamic_Scope (E);
3216
 
3217
   begin
3218
      if Dynamic_Scope = Standard_Standard then
3219
         return Empty;
3220
 
3221
      elsif Dynamic_Scope = Empty then
3222
         return Empty;
3223
 
3224
      elsif Ekind (Dynamic_Scope) = E_Subprogram_Body then
3225
         return Corresponding_Spec (Parent (Parent (Dynamic_Scope)));
3226
 
3227
      elsif Ekind (Dynamic_Scope) = E_Block
3228
        or else Ekind (Dynamic_Scope) = E_Return_Statement
3229
      then
3230
         return Enclosing_Subprogram (Dynamic_Scope);
3231
 
3232
      elsif Ekind (Dynamic_Scope) = E_Task_Type then
3233
         return Get_Task_Body_Procedure (Dynamic_Scope);
3234
 
3235
      elsif Ekind (Dynamic_Scope) = E_Limited_Private_Type
3236
        and then Present (Full_View (Dynamic_Scope))
3237
        and then Ekind (Full_View (Dynamic_Scope)) = E_Task_Type
3238
      then
3239
         return Get_Task_Body_Procedure (Full_View (Dynamic_Scope));
3240
 
3241
      --  No body is generated if the protected operation is eliminated
3242
 
3243
      elsif Convention (Dynamic_Scope) = Convention_Protected
3244
        and then not Is_Eliminated (Dynamic_Scope)
3245
        and then Present (Protected_Body_Subprogram (Dynamic_Scope))
3246
      then
3247
         return Protected_Body_Subprogram (Dynamic_Scope);
3248
 
3249
      else
3250
         return Dynamic_Scope;
3251
      end if;
3252
   end Enclosing_Subprogram;
3253
 
3254
   ------------------------
3255
   -- Ensure_Freeze_Node --
3256
   ------------------------
3257
 
3258
   procedure Ensure_Freeze_Node (E : Entity_Id) is
3259
      FN : Node_Id;
3260
 
3261
   begin
3262
      if No (Freeze_Node (E)) then
3263
         FN := Make_Freeze_Entity (Sloc (E));
3264
         Set_Has_Delayed_Freeze (E);
3265
         Set_Freeze_Node (E, FN);
3266
         Set_Access_Types_To_Process (FN, No_Elist);
3267
         Set_TSS_Elist (FN, No_Elist);
3268
         Set_Entity (FN, E);
3269
      end if;
3270
   end Ensure_Freeze_Node;
3271
 
3272
   ----------------
3273
   -- Enter_Name --
3274
   ----------------
3275
 
3276
   procedure Enter_Name (Def_Id : Entity_Id) is
3277
      C : constant Entity_Id := Current_Entity (Def_Id);
3278
      E : constant Entity_Id := Current_Entity_In_Scope (Def_Id);
3279
      S : constant Entity_Id := Current_Scope;
3280
 
3281
   begin
3282
      Generate_Definition (Def_Id);
3283
 
3284
      --  Add new name to current scope declarations. Check for duplicate
3285
      --  declaration, which may or may not be a genuine error.
3286
 
3287
      if Present (E) then
3288
 
3289
         --  Case of previous entity entered because of a missing declaration
3290
         --  or else a bad subtype indication. Best is to use the new entity,
3291
         --  and make the previous one invisible.
3292
 
3293
         if Etype (E) = Any_Type then
3294
            Set_Is_Immediately_Visible (E, False);
3295
 
3296
         --  Case of renaming declaration constructed for package instances.
3297
         --  if there is an explicit declaration with the same identifier,
3298
         --  the renaming is not immediately visible any longer, but remains
3299
         --  visible through selected component notation.
3300
 
3301
         elsif Nkind (Parent (E)) = N_Package_Renaming_Declaration
3302
           and then not Comes_From_Source (E)
3303
         then
3304
            Set_Is_Immediately_Visible (E, False);
3305
 
3306
         --  The new entity may be the package renaming, which has the same
3307
         --  same name as a generic formal which has been seen already.
3308
 
3309
         elsif Nkind (Parent (Def_Id)) = N_Package_Renaming_Declaration
3310
            and then not Comes_From_Source (Def_Id)
3311
         then
3312
            Set_Is_Immediately_Visible (E, False);
3313
 
3314
         --  For a fat pointer corresponding to a remote access to subprogram,
3315
         --  we use the same identifier as the RAS type, so that the proper
3316
         --  name appears in the stub. This type is only retrieved through
3317
         --  the RAS type and never by visibility, and is not added to the
3318
         --  visibility list (see below).
3319
 
3320
         elsif Nkind (Parent (Def_Id)) = N_Full_Type_Declaration
3321
           and then Present (Corresponding_Remote_Type (Def_Id))
3322
         then
3323
            null;
3324
 
3325
         --  Case of an implicit operation or derived literal. The new entity
3326
         --  hides the implicit one,  which is removed from all visibility,
3327
         --  i.e. the entity list of its scope, and homonym chain of its name.
3328
 
3329
         elsif (Is_Overloadable (E) and then Is_Inherited_Operation (E))
3330
           or else Is_Internal (E)
3331
         then
3332
            declare
3333
               Prev     : Entity_Id;
3334
               Prev_Vis : Entity_Id;
3335
               Decl     : constant Node_Id := Parent (E);
3336
 
3337
            begin
3338
               --  If E is an implicit declaration, it cannot be the first
3339
               --  entity in the scope.
3340
 
3341
               Prev := First_Entity (Current_Scope);
3342
               while Present (Prev)
3343
                 and then Next_Entity (Prev) /= E
3344
               loop
3345
                  Next_Entity (Prev);
3346
               end loop;
3347
 
3348
               if No (Prev) then
3349
 
3350
                  --  If E is not on the entity chain of the current scope,
3351
                  --  it is an implicit declaration in the generic formal
3352
                  --  part of a generic subprogram. When analyzing the body,
3353
                  --  the generic formals are visible but not on the entity
3354
                  --  chain of the subprogram. The new entity will become
3355
                  --  the visible one in the body.
3356
 
3357
                  pragma Assert
3358
                    (Nkind (Parent (Decl)) = N_Generic_Subprogram_Declaration);
3359
                  null;
3360
 
3361
               else
3362
                  Set_Next_Entity (Prev, Next_Entity (E));
3363
 
3364
                  if No (Next_Entity (Prev)) then
3365
                     Set_Last_Entity (Current_Scope, Prev);
3366
                  end if;
3367
 
3368
                  if E = Current_Entity (E) then
3369
                     Prev_Vis := Empty;
3370
 
3371
                  else
3372
                     Prev_Vis := Current_Entity (E);
3373
                     while Homonym (Prev_Vis) /= E loop
3374
                        Prev_Vis := Homonym (Prev_Vis);
3375
                     end loop;
3376
                  end if;
3377
 
3378
                  if Present (Prev_Vis)  then
3379
 
3380
                     --  Skip E in the visibility chain
3381
 
3382
                     Set_Homonym (Prev_Vis, Homonym (E));
3383
 
3384
                  else
3385
                     Set_Name_Entity_Id (Chars (E), Homonym (E));
3386
                  end if;
3387
               end if;
3388
            end;
3389
 
3390
         --  This section of code could use a comment ???
3391
 
3392
         elsif Present (Etype (E))
3393
           and then Is_Concurrent_Type (Etype (E))
3394
           and then E = Def_Id
3395
         then
3396
            return;
3397
 
3398
         --  If the homograph is a protected component renaming, it should not
3399
         --  be hiding the current entity. Such renamings are treated as weak
3400
         --  declarations.
3401
 
3402
         elsif Is_Prival (E) then
3403
            Set_Is_Immediately_Visible (E, False);
3404
 
3405
         --  In this case the current entity is a protected component renaming.
3406
         --  Perform minimal decoration by setting the scope and return since
3407
         --  the prival should not be hiding other visible entities.
3408
 
3409
         elsif Is_Prival (Def_Id) then
3410
            Set_Scope (Def_Id, Current_Scope);
3411
            return;
3412
 
3413
         --  Analogous to privals, the discriminal generated for an entry index
3414
         --  parameter acts as a weak declaration. Perform minimal decoration
3415
         --  to avoid bogus errors.
3416
 
3417
         elsif Is_Discriminal (Def_Id)
3418
           and then Ekind (Discriminal_Link (Def_Id)) = E_Entry_Index_Parameter
3419
         then
3420
            Set_Scope (Def_Id, Current_Scope);
3421
            return;
3422
 
3423
         --  In the body or private part of an instance, a type extension may
3424
         --  introduce a component with the same name as that of an actual. The
3425
         --  legality rule is not enforced, but the semantics of the full type
3426
         --  with two components of same name are not clear at this point???
3427
 
3428
         elsif In_Instance_Not_Visible then
3429
            null;
3430
 
3431
         --  When compiling a package body, some child units may have become
3432
         --  visible. They cannot conflict with local entities that hide them.
3433
 
3434
         elsif Is_Child_Unit (E)
3435
           and then In_Open_Scopes (Scope (E))
3436
           and then not Is_Immediately_Visible (E)
3437
         then
3438
            null;
3439
 
3440
         --  Conversely, with front-end inlining we may compile the parent body
3441
         --  first, and a child unit subsequently. The context is now the
3442
         --  parent spec, and body entities are not visible.
3443
 
3444
         elsif Is_Child_Unit (Def_Id)
3445
           and then Is_Package_Body_Entity (E)
3446
           and then not In_Package_Body (Current_Scope)
3447
         then
3448
            null;
3449
 
3450
         --  Case of genuine duplicate declaration
3451
 
3452
         else
3453
            Error_Msg_Sloc := Sloc (E);
3454
 
3455
            --  If the previous declaration is an incomplete type declaration
3456
            --  this may be an attempt to complete it with a private type. The
3457
            --  following avoids confusing cascaded errors.
3458
 
3459
            if Nkind (Parent (E)) = N_Incomplete_Type_Declaration
3460
              and then Nkind (Parent (Def_Id)) = N_Private_Type_Declaration
3461
            then
3462
               Error_Msg_N
3463
                 ("incomplete type cannot be completed with a private " &
3464
                  "declaration", Parent (Def_Id));
3465
               Set_Is_Immediately_Visible (E, False);
3466
               Set_Full_View (E, Def_Id);
3467
 
3468
            --  An inherited component of a record conflicts with a new
3469
            --  discriminant. The discriminant is inserted first in the scope,
3470
            --  but the error should be posted on it, not on the component.
3471
 
3472
            elsif Ekind (E) = E_Discriminant
3473
              and then Present (Scope (Def_Id))
3474
              and then Scope (Def_Id) /= Current_Scope
3475
            then
3476
               Error_Msg_Sloc := Sloc (Def_Id);
3477
               Error_Msg_N ("& conflicts with declaration#", E);
3478
               return;
3479
 
3480
            --  If the name of the unit appears in its own context clause, a
3481
            --  dummy package with the name has already been created, and the
3482
            --  error emitted. Try to continue quietly.
3483
 
3484
            elsif Error_Posted (E)
3485
              and then Sloc (E) = No_Location
3486
              and then Nkind (Parent (E)) = N_Package_Specification
3487
              and then Current_Scope = Standard_Standard
3488
            then
3489
               Set_Scope (Def_Id, Current_Scope);
3490
               return;
3491
 
3492
            else
3493
               Error_Msg_N ("& conflicts with declaration#", Def_Id);
3494
 
3495
               --  Avoid cascaded messages with duplicate components in
3496
               --  derived types.
3497
 
3498
               if Ekind_In (E, E_Component, E_Discriminant) then
3499
                  return;
3500
               end if;
3501
            end if;
3502
 
3503
            if Nkind (Parent (Parent (Def_Id))) =
3504
                N_Generic_Subprogram_Declaration
3505
              and then Def_Id =
3506
                Defining_Entity (Specification (Parent (Parent (Def_Id))))
3507
            then
3508
               Error_Msg_N ("\generic units cannot be overloaded", Def_Id);
3509
            end if;
3510
 
3511
            --  If entity is in standard, then we are in trouble, because it
3512
            --  means that we have a library package with a duplicated name.
3513
            --  That's hard to recover from, so abort!
3514
 
3515
            if S = Standard_Standard then
3516
               raise Unrecoverable_Error;
3517
 
3518
            --  Otherwise we continue with the declaration. Having two
3519
            --  identical declarations should not cause us too much trouble!
3520
 
3521
            else
3522
               null;
3523
            end if;
3524
         end if;
3525
      end if;
3526
 
3527
      --  If we fall through, declaration is OK, at least OK enough to continue
3528
 
3529
      --  If Def_Id is a discriminant or a record component we are in the midst
3530
      --  of inheriting components in a derived record definition. Preserve
3531
      --  their Ekind and Etype.
3532
 
3533
      if Ekind_In (Def_Id, E_Discriminant, E_Component) then
3534
         null;
3535
 
3536
      --  If a type is already set, leave it alone (happens when a type
3537
      --  declaration is reanalyzed following a call to the optimizer).
3538
 
3539
      elsif Present (Etype (Def_Id)) then
3540
         null;
3541
 
3542
      --  Otherwise, the kind E_Void insures that premature uses of the entity
3543
      --  will be detected. Any_Type insures that no cascaded errors will occur
3544
 
3545
      else
3546
         Set_Ekind (Def_Id, E_Void);
3547
         Set_Etype (Def_Id, Any_Type);
3548
      end if;
3549
 
3550
      --  Inherited discriminants and components in derived record types are
3551
      --  immediately visible. Itypes are not.
3552
 
3553
      if Ekind_In (Def_Id, E_Discriminant, E_Component)
3554
        or else (No (Corresponding_Remote_Type (Def_Id))
3555
                 and then not Is_Itype (Def_Id))
3556
      then
3557
         Set_Is_Immediately_Visible (Def_Id);
3558
         Set_Current_Entity         (Def_Id);
3559
      end if;
3560
 
3561
      Set_Homonym       (Def_Id, C);
3562
      Append_Entity     (Def_Id, S);
3563
      Set_Public_Status (Def_Id);
3564
 
3565
      --  Declaring a homonym is not allowed in SPARK ...
3566
 
3567
      if Present (C)
3568
        and then Restriction_Check_Required (SPARK)
3569
      then
3570
 
3571
         declare
3572
            Enclosing_Subp : constant Node_Id := Enclosing_Subprogram (Def_Id);
3573
            Enclosing_Pack : constant Node_Id := Enclosing_Package (Def_Id);
3574
            Other_Scope    : constant Node_Id := Enclosing_Dynamic_Scope (C);
3575
         begin
3576
 
3577
            --  ... unless the new declaration is in a subprogram, and the
3578
            --  visible declaration is a variable declaration or a parameter
3579
            --  specification outside that subprogram.
3580
 
3581
            if Present (Enclosing_Subp)
3582
              and then Nkind_In (Parent (C), N_Object_Declaration,
3583
                                 N_Parameter_Specification)
3584
              and then not Scope_Within_Or_Same (Other_Scope, Enclosing_Subp)
3585
            then
3586
               null;
3587
 
3588
            --  ... or the new declaration is in a package, and the visible
3589
            --  declaration occurs outside that package.
3590
 
3591
            elsif Present (Enclosing_Pack)
3592
              and then not Scope_Within_Or_Same (Other_Scope, Enclosing_Pack)
3593
            then
3594
               null;
3595
 
3596
            --  ... or the new declaration is a component declaration in a
3597
            --  record type definition.
3598
 
3599
            elsif Nkind (Parent (Def_Id)) = N_Component_Declaration then
3600
               null;
3601
 
3602
            --  Don't issue error for non-source entities
3603
 
3604
            elsif Comes_From_Source (Def_Id)
3605
              and then Comes_From_Source (C)
3606
            then
3607
               Error_Msg_Sloc := Sloc (C);
3608
               Check_SPARK_Restriction
3609
                 ("redeclaration of identifier &#", Def_Id);
3610
            end if;
3611
         end;
3612
      end if;
3613
 
3614
      --  Warn if new entity hides an old one
3615
 
3616
      if Warn_On_Hiding and then Present (C)
3617
 
3618
         --  Don't warn for record components since they always have a well
3619
         --  defined scope which does not confuse other uses. Note that in
3620
         --  some cases, Ekind has not been set yet.
3621
 
3622
         and then Ekind (C) /= E_Component
3623
         and then Ekind (C) /= E_Discriminant
3624
         and then Nkind (Parent (C)) /= N_Component_Declaration
3625
         and then Ekind (Def_Id) /= E_Component
3626
         and then Ekind (Def_Id) /= E_Discriminant
3627
         and then Nkind (Parent (Def_Id)) /= N_Component_Declaration
3628
 
3629
         --  Don't warn for one character variables. It is too common to use
3630
         --  such variables as locals and will just cause too many false hits.
3631
 
3632
         and then Length_Of_Name (Chars (C)) /= 1
3633
 
3634
         --  Don't warn for non-source entities
3635
 
3636
         and then Comes_From_Source (C)
3637
         and then Comes_From_Source (Def_Id)
3638
 
3639
         --  Don't warn unless entity in question is in extended main source
3640
 
3641
         and then In_Extended_Main_Source_Unit (Def_Id)
3642
 
3643
         --  Finally, the hidden entity must be either immediately visible or
3644
         --  use visible (i.e. from a used package).
3645
 
3646
         and then
3647
           (Is_Immediately_Visible (C)
3648
              or else
3649
            Is_Potentially_Use_Visible (C))
3650
      then
3651
         Error_Msg_Sloc := Sloc (C);
3652
         Error_Msg_N ("declaration hides &#?", Def_Id);
3653
      end if;
3654
   end Enter_Name;
3655
 
3656
   --------------------------
3657
   -- Explain_Limited_Type --
3658
   --------------------------
3659
 
3660
   procedure Explain_Limited_Type (T : Entity_Id; N : Node_Id) is
3661
      C : Entity_Id;
3662
 
3663
   begin
3664
      --  For array, component type must be limited
3665
 
3666
      if Is_Array_Type (T) then
3667
         Error_Msg_Node_2 := T;
3668
         Error_Msg_NE
3669
           ("\component type& of type& is limited", N, Component_Type (T));
3670
         Explain_Limited_Type (Component_Type (T), N);
3671
 
3672
      elsif Is_Record_Type (T) then
3673
 
3674
         --  No need for extra messages if explicit limited record
3675
 
3676
         if Is_Limited_Record (Base_Type (T)) then
3677
            return;
3678
         end if;
3679
 
3680
         --  Otherwise find a limited component. Check only components that
3681
         --  come from source, or inherited components that appear in the
3682
         --  source of the ancestor.
3683
 
3684
         C := First_Component (T);
3685
         while Present (C) loop
3686
            if Is_Limited_Type (Etype (C))
3687
              and then
3688
                (Comes_From_Source (C)
3689
                   or else
3690
                     (Present (Original_Record_Component (C))
3691
                       and then
3692
                         Comes_From_Source (Original_Record_Component (C))))
3693
            then
3694
               Error_Msg_Node_2 := T;
3695
               Error_Msg_NE ("\component& of type& has limited type", N, C);
3696
               Explain_Limited_Type (Etype (C), N);
3697
               return;
3698
            end if;
3699
 
3700
            Next_Component (C);
3701
         end loop;
3702
 
3703
         --  The type may be declared explicitly limited, even if no component
3704
         --  of it is limited, in which case we fall out of the loop.
3705
         return;
3706
      end if;
3707
   end Explain_Limited_Type;
3708
 
3709
   -----------------
3710
   -- Find_Actual --
3711
   -----------------
3712
 
3713
   procedure Find_Actual
3714
     (N        : Node_Id;
3715
      Formal   : out Entity_Id;
3716
      Call     : out Node_Id)
3717
   is
3718
      Parnt  : constant Node_Id := Parent (N);
3719
      Actual : Node_Id;
3720
 
3721
   begin
3722
      if (Nkind (Parnt) = N_Indexed_Component
3723
            or else
3724
          Nkind (Parnt) = N_Selected_Component)
3725
        and then N = Prefix (Parnt)
3726
      then
3727
         Find_Actual (Parnt, Formal, Call);
3728
         return;
3729
 
3730
      elsif Nkind (Parnt) = N_Parameter_Association
3731
        and then N = Explicit_Actual_Parameter (Parnt)
3732
      then
3733
         Call := Parent (Parnt);
3734
 
3735
      elsif Nkind_In (Parnt, N_Procedure_Call_Statement, N_Function_Call) then
3736
         Call := Parnt;
3737
 
3738
      else
3739
         Formal := Empty;
3740
         Call   := Empty;
3741
         return;
3742
      end if;
3743
 
3744
      --  If we have a call to a subprogram look for the parameter. Note that
3745
      --  we exclude overloaded calls, since we don't know enough to be sure
3746
      --  of giving the right answer in this case.
3747
 
3748
      if Is_Entity_Name (Name (Call))
3749
        and then Present (Entity (Name (Call)))
3750
        and then Is_Overloadable (Entity (Name (Call)))
3751
        and then not Is_Overloaded (Name (Call))
3752
      then
3753
         --  Fall here if we are definitely a parameter
3754
 
3755
         Actual := First_Actual (Call);
3756
         Formal := First_Formal (Entity (Name (Call)));
3757
         while Present (Formal) and then Present (Actual) loop
3758
            if Actual = N then
3759
               return;
3760
            else
3761
               Actual := Next_Actual (Actual);
3762
               Formal := Next_Formal (Formal);
3763
            end if;
3764
         end loop;
3765
      end if;
3766
 
3767
      --  Fall through here if we did not find matching actual
3768
 
3769
      Formal := Empty;
3770
      Call   := Empty;
3771
   end Find_Actual;
3772
 
3773
   ---------------------------
3774
   -- Find_Body_Discriminal --
3775
   ---------------------------
3776
 
3777
   function Find_Body_Discriminal
3778
     (Spec_Discriminant : Entity_Id) return Entity_Id
3779
   is
3780
      Tsk  : Entity_Id;
3781
      Disc : Entity_Id;
3782
 
3783
   begin
3784
      --  If expansion is suppressed, then the scope can be the concurrent type
3785
      --  itself rather than a corresponding concurrent record type.
3786
 
3787
      if Is_Concurrent_Type (Scope (Spec_Discriminant)) then
3788
         Tsk := Scope (Spec_Discriminant);
3789
 
3790
      else
3791
         pragma Assert (Is_Concurrent_Record_Type (Scope (Spec_Discriminant)));
3792
 
3793
         Tsk := Corresponding_Concurrent_Type (Scope (Spec_Discriminant));
3794
      end if;
3795
 
3796
      --  Find discriminant of original concurrent type, and use its current
3797
      --  discriminal, which is the renaming within the task/protected body.
3798
 
3799
      Disc := First_Discriminant (Tsk);
3800
      while Present (Disc) loop
3801
         if Chars (Disc) = Chars (Spec_Discriminant) then
3802
            return Discriminal (Disc);
3803
         end if;
3804
 
3805
         Next_Discriminant (Disc);
3806
      end loop;
3807
 
3808
      --  That loop should always succeed in finding a matching entry and
3809
      --  returning. Fatal error if not.
3810
 
3811
      raise Program_Error;
3812
   end Find_Body_Discriminal;
3813
 
3814
   -------------------------------------
3815
   -- Find_Corresponding_Discriminant --
3816
   -------------------------------------
3817
 
3818
   function Find_Corresponding_Discriminant
3819
     (Id  : Node_Id;
3820
      Typ : Entity_Id) return Entity_Id
3821
   is
3822
      Par_Disc : Entity_Id;
3823
      Old_Disc : Entity_Id;
3824
      New_Disc : Entity_Id;
3825
 
3826
   begin
3827
      Par_Disc := Original_Record_Component (Original_Discriminant (Id));
3828
 
3829
      --  The original type may currently be private, and the discriminant
3830
      --  only appear on its full view.
3831
 
3832
      if Is_Private_Type (Scope (Par_Disc))
3833
        and then not Has_Discriminants (Scope (Par_Disc))
3834
        and then Present (Full_View (Scope (Par_Disc)))
3835
      then
3836
         Old_Disc := First_Discriminant (Full_View (Scope (Par_Disc)));
3837
      else
3838
         Old_Disc := First_Discriminant (Scope (Par_Disc));
3839
      end if;
3840
 
3841
      if Is_Class_Wide_Type (Typ) then
3842
         New_Disc := First_Discriminant (Root_Type (Typ));
3843
      else
3844
         New_Disc := First_Discriminant (Typ);
3845
      end if;
3846
 
3847
      while Present (Old_Disc) and then Present (New_Disc) loop
3848
         if Old_Disc = Par_Disc  then
3849
            return New_Disc;
3850
         else
3851
            Next_Discriminant (Old_Disc);
3852
            Next_Discriminant (New_Disc);
3853
         end if;
3854
      end loop;
3855
 
3856
      --  Should always find it
3857
 
3858
      raise Program_Error;
3859
   end Find_Corresponding_Discriminant;
3860
 
3861
   --------------------------
3862
   -- Find_Overlaid_Entity --
3863
   --------------------------
3864
 
3865
   procedure Find_Overlaid_Entity
3866
     (N   : Node_Id;
3867
      Ent : out Entity_Id;
3868
      Off : out Boolean)
3869
   is
3870
      Expr : Node_Id;
3871
 
3872
   begin
3873
      --  We are looking for one of the two following forms:
3874
 
3875
      --    for X'Address use Y'Address
3876
 
3877
      --  or
3878
 
3879
      --    Const : constant Address := expr;
3880
      --    ...
3881
      --    for X'Address use Const;
3882
 
3883
      --  In the second case, the expr is either Y'Address, or recursively a
3884
      --  constant that eventually references Y'Address.
3885
 
3886
      Ent := Empty;
3887
      Off := False;
3888
 
3889
      if Nkind (N) = N_Attribute_Definition_Clause
3890
        and then Chars (N) = Name_Address
3891
      then
3892
         Expr := Expression (N);
3893
 
3894
         --  This loop checks the form of the expression for Y'Address,
3895
         --  using recursion to deal with intermediate constants.
3896
 
3897
         loop
3898
            --  Check for Y'Address
3899
 
3900
            if Nkind (Expr) = N_Attribute_Reference
3901
              and then Attribute_Name (Expr) = Name_Address
3902
            then
3903
               Expr := Prefix (Expr);
3904
               exit;
3905
 
3906
               --  Check for Const where Const is a constant entity
3907
 
3908
            elsif Is_Entity_Name (Expr)
3909
              and then Ekind (Entity (Expr)) = E_Constant
3910
            then
3911
               Expr := Constant_Value (Entity (Expr));
3912
 
3913
            --  Anything else does not need checking
3914
 
3915
            else
3916
               return;
3917
            end if;
3918
         end loop;
3919
 
3920
         --  This loop checks the form of the prefix for an entity, using
3921
         --  recursion to deal with intermediate components.
3922
 
3923
         loop
3924
            --  Check for Y where Y is an entity
3925
 
3926
            if Is_Entity_Name (Expr) then
3927
               Ent := Entity (Expr);
3928
               return;
3929
 
3930
            --  Check for components
3931
 
3932
            elsif
3933
              Nkind_In (Expr, N_Selected_Component, N_Indexed_Component)
3934
            then
3935
               Expr := Prefix (Expr);
3936
               Off := True;
3937
 
3938
            --  Anything else does not need checking
3939
 
3940
            else
3941
               return;
3942
            end if;
3943
         end loop;
3944
      end if;
3945
   end Find_Overlaid_Entity;
3946
 
3947
   -------------------------
3948
   -- Find_Parameter_Type --
3949
   -------------------------
3950
 
3951
   function Find_Parameter_Type (Param : Node_Id) return Entity_Id is
3952
   begin
3953
      if Nkind (Param) /= N_Parameter_Specification then
3954
         return Empty;
3955
 
3956
      --  For an access parameter, obtain the type from the formal entity
3957
      --  itself, because access to subprogram nodes do not carry a type.
3958
      --  Shouldn't we always use the formal entity ???
3959
 
3960
      elsif Nkind (Parameter_Type (Param)) = N_Access_Definition then
3961
         return Etype (Defining_Identifier (Param));
3962
 
3963
      else
3964
         return Etype (Parameter_Type (Param));
3965
      end if;
3966
   end Find_Parameter_Type;
3967
 
3968
   -----------------------------
3969
   -- Find_Static_Alternative --
3970
   -----------------------------
3971
 
3972
   function Find_Static_Alternative (N : Node_Id) return Node_Id is
3973
      Expr   : constant Node_Id := Expression (N);
3974
      Val    : constant Uint    := Expr_Value (Expr);
3975
      Alt    : Node_Id;
3976
      Choice : Node_Id;
3977
 
3978
   begin
3979
      Alt := First (Alternatives (N));
3980
 
3981
      Search : loop
3982
         if Nkind (Alt) /= N_Pragma then
3983
            Choice := First (Discrete_Choices (Alt));
3984
            while Present (Choice) loop
3985
 
3986
               --  Others choice, always matches
3987
 
3988
               if Nkind (Choice) = N_Others_Choice then
3989
                  exit Search;
3990
 
3991
               --  Range, check if value is in the range
3992
 
3993
               elsif Nkind (Choice) = N_Range then
3994
                  exit Search when
3995
                    Val >= Expr_Value (Low_Bound (Choice))
3996
                      and then
3997
                    Val <= Expr_Value (High_Bound (Choice));
3998
 
3999
               --  Choice is a subtype name. Note that we know it must
4000
               --  be a static subtype, since otherwise it would have
4001
               --  been diagnosed as illegal.
4002
 
4003
               elsif Is_Entity_Name (Choice)
4004
                 and then Is_Type (Entity (Choice))
4005
               then
4006
                  exit Search when Is_In_Range (Expr, Etype (Choice),
4007
                                                Assume_Valid => False);
4008
 
4009
               --  Choice is a subtype indication
4010
 
4011
               elsif Nkind (Choice) = N_Subtype_Indication then
4012
                  declare
4013
                     C : constant Node_Id := Constraint (Choice);
4014
                     R : constant Node_Id := Range_Expression (C);
4015
 
4016
                  begin
4017
                     exit Search when
4018
                       Val >= Expr_Value (Low_Bound (R))
4019
                         and then
4020
                       Val <= Expr_Value (High_Bound (R));
4021
                  end;
4022
 
4023
               --  Choice is a simple expression
4024
 
4025
               else
4026
                  exit Search when Val = Expr_Value (Choice);
4027
               end if;
4028
 
4029
               Next (Choice);
4030
            end loop;
4031
         end if;
4032
 
4033
         Next (Alt);
4034
         pragma Assert (Present (Alt));
4035
      end loop Search;
4036
 
4037
      --  The above loop *must* terminate by finding a match, since
4038
      --  we know the case statement is valid, and the value of the
4039
      --  expression is known at compile time. When we fall out of
4040
      --  the loop, Alt points to the alternative that we know will
4041
      --  be selected at run time.
4042
 
4043
      return Alt;
4044
   end Find_Static_Alternative;
4045
 
4046
   ------------------
4047
   -- First_Actual --
4048
   ------------------
4049
 
4050
   function First_Actual (Node : Node_Id) return Node_Id is
4051
      N : Node_Id;
4052
 
4053
   begin
4054
      if No (Parameter_Associations (Node)) then
4055
         return Empty;
4056
      end if;
4057
 
4058
      N := First (Parameter_Associations (Node));
4059
 
4060
      if Nkind (N) = N_Parameter_Association then
4061
         return First_Named_Actual (Node);
4062
      else
4063
         return N;
4064
      end if;
4065
   end First_Actual;
4066
 
4067
   -----------------------
4068
   -- Gather_Components --
4069
   -----------------------
4070
 
4071
   procedure Gather_Components
4072
     (Typ           : Entity_Id;
4073
      Comp_List     : Node_Id;
4074
      Governed_By   : List_Id;
4075
      Into          : Elist_Id;
4076
      Report_Errors : out Boolean)
4077
   is
4078
      Assoc           : Node_Id;
4079
      Variant         : Node_Id;
4080
      Discrete_Choice : Node_Id;
4081
      Comp_Item       : Node_Id;
4082
 
4083
      Discrim       : Entity_Id;
4084
      Discrim_Name  : Node_Id;
4085
      Discrim_Value : Node_Id;
4086
 
4087
   begin
4088
      Report_Errors := False;
4089
 
4090
      if No (Comp_List) or else Null_Present (Comp_List) then
4091
         return;
4092
 
4093
      elsif Present (Component_Items (Comp_List)) then
4094
         Comp_Item := First (Component_Items (Comp_List));
4095
 
4096
      else
4097
         Comp_Item := Empty;
4098
      end if;
4099
 
4100
      while Present (Comp_Item) loop
4101
 
4102
         --  Skip the tag of a tagged record, the interface tags, as well
4103
         --  as all items that are not user components (anonymous types,
4104
         --  rep clauses, Parent field, controller field).
4105
 
4106
         if Nkind (Comp_Item) = N_Component_Declaration then
4107
            declare
4108
               Comp : constant Entity_Id := Defining_Identifier (Comp_Item);
4109
            begin
4110
               if not Is_Tag (Comp)
4111
                 and then Chars (Comp) /= Name_uParent
4112
               then
4113
                  Append_Elmt (Comp, Into);
4114
               end if;
4115
            end;
4116
         end if;
4117
 
4118
         Next (Comp_Item);
4119
      end loop;
4120
 
4121
      if No (Variant_Part (Comp_List)) then
4122
         return;
4123
      else
4124
         Discrim_Name := Name (Variant_Part (Comp_List));
4125
         Variant := First_Non_Pragma (Variants (Variant_Part (Comp_List)));
4126
      end if;
4127
 
4128
      --  Look for the discriminant that governs this variant part.
4129
      --  The discriminant *must* be in the Governed_By List
4130
 
4131
      Assoc := First (Governed_By);
4132
      Find_Constraint : loop
4133
         Discrim := First (Choices (Assoc));
4134
         exit Find_Constraint when Chars (Discrim_Name) = Chars (Discrim)
4135
           or else (Present (Corresponding_Discriminant (Entity (Discrim)))
4136
                      and then
4137
                    Chars (Corresponding_Discriminant (Entity (Discrim)))
4138
                         = Chars  (Discrim_Name))
4139
           or else Chars (Original_Record_Component (Entity (Discrim)))
4140
                         = Chars (Discrim_Name);
4141
 
4142
         if No (Next (Assoc)) then
4143
            if not Is_Constrained (Typ)
4144
              and then Is_Derived_Type (Typ)
4145
              and then Present (Stored_Constraint (Typ))
4146
            then
4147
               --  If the type is a tagged type with inherited discriminants,
4148
               --  use the stored constraint on the parent in order to find
4149
               --  the values of discriminants that are otherwise hidden by an
4150
               --  explicit constraint. Renamed discriminants are handled in
4151
               --  the code above.
4152
 
4153
               --  If several parent discriminants are renamed by a single
4154
               --  discriminant of the derived type, the call to obtain the
4155
               --  Corresponding_Discriminant field only retrieves the last
4156
               --  of them. We recover the constraint on the others from the
4157
               --  Stored_Constraint as well.
4158
 
4159
               declare
4160
                  D : Entity_Id;
4161
                  C : Elmt_Id;
4162
 
4163
               begin
4164
                  D := First_Discriminant (Etype (Typ));
4165
                  C := First_Elmt (Stored_Constraint (Typ));
4166
                  while Present (D) and then Present (C) loop
4167
                     if Chars (Discrim_Name) = Chars (D) then
4168
                        if Is_Entity_Name (Node (C))
4169
                          and then Entity (Node (C)) = Entity (Discrim)
4170
                        then
4171
                           --  D is renamed by Discrim, whose value is given in
4172
                           --  Assoc.
4173
 
4174
                           null;
4175
 
4176
                        else
4177
                           Assoc :=
4178
                             Make_Component_Association (Sloc (Typ),
4179
                               New_List
4180
                                 (New_Occurrence_Of (D, Sloc (Typ))),
4181
                                  Duplicate_Subexpr_No_Checks (Node (C)));
4182
                        end if;
4183
                        exit Find_Constraint;
4184
                     end if;
4185
 
4186
                     Next_Discriminant (D);
4187
                     Next_Elmt (C);
4188
                  end loop;
4189
               end;
4190
            end if;
4191
         end if;
4192
 
4193
         if No (Next (Assoc)) then
4194
            Error_Msg_NE (" missing value for discriminant&",
4195
              First (Governed_By), Discrim_Name);
4196
            Report_Errors := True;
4197
            return;
4198
         end if;
4199
 
4200
         Next (Assoc);
4201
      end loop Find_Constraint;
4202
 
4203
      Discrim_Value := Expression (Assoc);
4204
 
4205
      if not Is_OK_Static_Expression (Discrim_Value) then
4206
         Error_Msg_FE
4207
           ("value for discriminant & must be static!",
4208
            Discrim_Value, Discrim);
4209
         Why_Not_Static (Discrim_Value);
4210
         Report_Errors := True;
4211
         return;
4212
      end if;
4213
 
4214
      Search_For_Discriminant_Value : declare
4215
         Low  : Node_Id;
4216
         High : Node_Id;
4217
 
4218
         UI_High          : Uint;
4219
         UI_Low           : Uint;
4220
         UI_Discrim_Value : constant Uint := Expr_Value (Discrim_Value);
4221
 
4222
      begin
4223
         Find_Discrete_Value : while Present (Variant) loop
4224
            Discrete_Choice := First (Discrete_Choices (Variant));
4225
            while Present (Discrete_Choice) loop
4226
 
4227
               exit Find_Discrete_Value when
4228
                 Nkind (Discrete_Choice) = N_Others_Choice;
4229
 
4230
               Get_Index_Bounds (Discrete_Choice, Low, High);
4231
 
4232
               UI_Low  := Expr_Value (Low);
4233
               UI_High := Expr_Value (High);
4234
 
4235
               exit Find_Discrete_Value when
4236
                 UI_Low <= UI_Discrim_Value
4237
                   and then
4238
                 UI_High >= UI_Discrim_Value;
4239
 
4240
               Next (Discrete_Choice);
4241
            end loop;
4242
 
4243
            Next_Non_Pragma (Variant);
4244
         end loop Find_Discrete_Value;
4245
      end Search_For_Discriminant_Value;
4246
 
4247
      if No (Variant) then
4248
         Error_Msg_NE
4249
           ("value of discriminant & is out of range", Discrim_Value, Discrim);
4250
         Report_Errors := True;
4251
         return;
4252
      end  if;
4253
 
4254
      --  If we have found the corresponding choice, recursively add its
4255
      --  components to the Into list.
4256
 
4257
      Gather_Components (Empty,
4258
        Component_List (Variant), Governed_By, Into, Report_Errors);
4259
   end Gather_Components;
4260
 
4261
   ------------------------
4262
   -- Get_Actual_Subtype --
4263
   ------------------------
4264
 
4265
   function Get_Actual_Subtype (N : Node_Id) return Entity_Id is
4266
      Typ  : constant Entity_Id := Etype (N);
4267
      Utyp : Entity_Id := Underlying_Type (Typ);
4268
      Decl : Node_Id;
4269
      Atyp : Entity_Id;
4270
 
4271
   begin
4272
      if No (Utyp) then
4273
         Utyp := Typ;
4274
      end if;
4275
 
4276
      --  If what we have is an identifier that references a subprogram
4277
      --  formal, or a variable or constant object, then we get the actual
4278
      --  subtype from the referenced entity if one has been built.
4279
 
4280
      if Nkind (N) = N_Identifier
4281
        and then
4282
          (Is_Formal (Entity (N))
4283
            or else Ekind (Entity (N)) = E_Constant
4284
            or else Ekind (Entity (N)) = E_Variable)
4285
        and then Present (Actual_Subtype (Entity (N)))
4286
      then
4287
         return Actual_Subtype (Entity (N));
4288
 
4289
      --  Actual subtype of unchecked union is always itself. We never need
4290
      --  the "real" actual subtype. If we did, we couldn't get it anyway
4291
      --  because the discriminant is not available. The restrictions on
4292
      --  Unchecked_Union are designed to make sure that this is OK.
4293
 
4294
      elsif Is_Unchecked_Union (Base_Type (Utyp)) then
4295
         return Typ;
4296
 
4297
      --  Here for the unconstrained case, we must find actual subtype
4298
      --  No actual subtype is available, so we must build it on the fly.
4299
 
4300
      --  Checking the type, not the underlying type, for constrainedness
4301
      --  seems to be necessary. Maybe all the tests should be on the type???
4302
 
4303
      elsif (not Is_Constrained (Typ))
4304
           and then (Is_Array_Type (Utyp)
4305
                      or else (Is_Record_Type (Utyp)
4306
                                and then Has_Discriminants (Utyp)))
4307
           and then not Has_Unknown_Discriminants (Utyp)
4308
           and then not (Ekind (Utyp) = E_String_Literal_Subtype)
4309
      then
4310
         --  Nothing to do if in spec expression (why not???)
4311
 
4312
         if In_Spec_Expression then
4313
            return Typ;
4314
 
4315
         elsif Is_Private_Type (Typ)
4316
           and then not Has_Discriminants (Typ)
4317
         then
4318
            --  If the type has no discriminants, there is no subtype to
4319
            --  build, even if the underlying type is discriminated.
4320
 
4321
            return Typ;
4322
 
4323
         --  Else build the actual subtype
4324
 
4325
         else
4326
            Decl := Build_Actual_Subtype (Typ, N);
4327
            Atyp := Defining_Identifier (Decl);
4328
 
4329
            --  If Build_Actual_Subtype generated a new declaration then use it
4330
 
4331
            if Atyp /= Typ then
4332
 
4333
               --  The actual subtype is an Itype, so analyze the declaration,
4334
               --  but do not attach it to the tree, to get the type defined.
4335
 
4336
               Set_Parent (Decl, N);
4337
               Set_Is_Itype (Atyp);
4338
               Analyze (Decl, Suppress => All_Checks);
4339
               Set_Associated_Node_For_Itype (Atyp, N);
4340
               Set_Has_Delayed_Freeze (Atyp, False);
4341
 
4342
               --  We need to freeze the actual subtype immediately. This is
4343
               --  needed, because otherwise this Itype will not get frozen
4344
               --  at all, and it is always safe to freeze on creation because
4345
               --  any associated types must be frozen at this point.
4346
 
4347
               Freeze_Itype (Atyp, N);
4348
               return Atyp;
4349
 
4350
            --  Otherwise we did not build a declaration, so return original
4351
 
4352
            else
4353
               return Typ;
4354
            end if;
4355
         end if;
4356
 
4357
      --  For all remaining cases, the actual subtype is the same as
4358
      --  the nominal type.
4359
 
4360
      else
4361
         return Typ;
4362
      end if;
4363
   end Get_Actual_Subtype;
4364
 
4365
   -------------------------------------
4366
   -- Get_Actual_Subtype_If_Available --
4367
   -------------------------------------
4368
 
4369
   function Get_Actual_Subtype_If_Available (N : Node_Id) return Entity_Id is
4370
      Typ  : constant Entity_Id := Etype (N);
4371
 
4372
   begin
4373
      --  If what we have is an identifier that references a subprogram
4374
      --  formal, or a variable or constant object, then we get the actual
4375
      --  subtype from the referenced entity if one has been built.
4376
 
4377
      if Nkind (N) = N_Identifier
4378
        and then
4379
          (Is_Formal (Entity (N))
4380
            or else Ekind (Entity (N)) = E_Constant
4381
            or else Ekind (Entity (N)) = E_Variable)
4382
        and then Present (Actual_Subtype (Entity (N)))
4383
      then
4384
         return Actual_Subtype (Entity (N));
4385
 
4386
      --  Otherwise the Etype of N is returned unchanged
4387
 
4388
      else
4389
         return Typ;
4390
      end if;
4391
   end Get_Actual_Subtype_If_Available;
4392
 
4393
   ------------------------
4394
   -- Get_Body_From_Stub --
4395
   ------------------------
4396
 
4397
   function Get_Body_From_Stub (N : Node_Id) return Node_Id is
4398
   begin
4399
      return Proper_Body (Unit (Library_Unit (N)));
4400
   end Get_Body_From_Stub;
4401
 
4402
   -------------------------------
4403
   -- Get_Default_External_Name --
4404
   -------------------------------
4405
 
4406
   function Get_Default_External_Name (E : Node_Or_Entity_Id) return Node_Id is
4407
   begin
4408
      Get_Decoded_Name_String (Chars (E));
4409
 
4410
      if Opt.External_Name_Imp_Casing = Uppercase then
4411
         Set_Casing (All_Upper_Case);
4412
      else
4413
         Set_Casing (All_Lower_Case);
4414
      end if;
4415
 
4416
      return
4417
        Make_String_Literal (Sloc (E),
4418
          Strval => String_From_Name_Buffer);
4419
   end Get_Default_External_Name;
4420
 
4421
   --------------------------
4422
   -- Get_Enclosing_Object --
4423
   --------------------------
4424
 
4425
   function Get_Enclosing_Object (N : Node_Id) return Entity_Id is
4426
   begin
4427
      if Is_Entity_Name (N) then
4428
         return Entity (N);
4429
      else
4430
         case Nkind (N) is
4431
            when N_Indexed_Component  |
4432
                 N_Slice              |
4433
                 N_Selected_Component =>
4434
 
4435
               --  If not generating code, a dereference may be left implicit.
4436
               --  In thoses cases, return Empty.
4437
 
4438
               if Is_Access_Type (Etype (Prefix (N))) then
4439
                  return Empty;
4440
               else
4441
                  return Get_Enclosing_Object (Prefix (N));
4442
               end if;
4443
 
4444
            when N_Type_Conversion =>
4445
               return Get_Enclosing_Object (Expression (N));
4446
 
4447
            when others =>
4448
               return Empty;
4449
         end case;
4450
      end if;
4451
   end Get_Enclosing_Object;
4452
 
4453
   ---------------------------
4454
   -- Get_Enum_Lit_From_Pos --
4455
   ---------------------------
4456
 
4457
   function Get_Enum_Lit_From_Pos
4458
     (T   : Entity_Id;
4459
      Pos : Uint;
4460
      Loc : Source_Ptr) return Node_Id
4461
   is
4462
      Lit : Node_Id;
4463
 
4464
   begin
4465
      --  In the case where the literal is of type Character, Wide_Character
4466
      --  or Wide_Wide_Character or of a type derived from them, there needs
4467
      --  to be some special handling since there is no explicit chain of
4468
      --  literals to search. Instead, an N_Character_Literal node is created
4469
      --  with the appropriate Char_Code and Chars fields.
4470
 
4471
      if Is_Standard_Character_Type (T) then
4472
         Set_Character_Literal_Name (UI_To_CC (Pos));
4473
         return
4474
           Make_Character_Literal (Loc,
4475
             Chars              => Name_Find,
4476
             Char_Literal_Value => Pos);
4477
 
4478
      --  For all other cases, we have a complete table of literals, and
4479
      --  we simply iterate through the chain of literal until the one
4480
      --  with the desired position value is found.
4481
      --
4482
 
4483
      else
4484
         Lit := First_Literal (Base_Type (T));
4485
         for J in 1 .. UI_To_Int (Pos) loop
4486
            Next_Literal (Lit);
4487
         end loop;
4488
 
4489
         return New_Occurrence_Of (Lit, Loc);
4490
      end if;
4491
   end Get_Enum_Lit_From_Pos;
4492
 
4493
   ---------------------------------------
4494
   -- Get_Ensures_From_Test_Case_Pragma --
4495
   ---------------------------------------
4496
 
4497
   function Get_Ensures_From_Test_Case_Pragma (N : Node_Id) return Node_Id is
4498
      Args : constant List_Id := Pragma_Argument_Associations (N);
4499
      Res  : Node_Id;
4500
 
4501
   begin
4502
      if List_Length (Args) = 4 then
4503
         Res := Pick (Args, 4);
4504
 
4505
      elsif List_Length (Args) = 3 then
4506
         Res := Pick (Args, 3);
4507
 
4508
         if Chars (Res) /= Name_Ensures then
4509
            Res := Empty;
4510
         end if;
4511
 
4512
      else
4513
         Res := Empty;
4514
      end if;
4515
 
4516
      return Res;
4517
   end Get_Ensures_From_Test_Case_Pragma;
4518
 
4519
   ------------------------
4520
   -- Get_Generic_Entity --
4521
   ------------------------
4522
 
4523
   function Get_Generic_Entity (N : Node_Id) return Entity_Id is
4524
      Ent : constant Entity_Id := Entity (Name (N));
4525
   begin
4526
      if Present (Renamed_Object (Ent)) then
4527
         return Renamed_Object (Ent);
4528
      else
4529
         return Ent;
4530
      end if;
4531
   end Get_Generic_Entity;
4532
 
4533
   ----------------------
4534
   -- Get_Index_Bounds --
4535
   ----------------------
4536
 
4537
   procedure Get_Index_Bounds (N : Node_Id; L, H : out Node_Id) is
4538
      Kind : constant Node_Kind := Nkind (N);
4539
      R    : Node_Id;
4540
 
4541
   begin
4542
      if Kind = N_Range then
4543
         L := Low_Bound (N);
4544
         H := High_Bound (N);
4545
 
4546
      elsif Kind = N_Subtype_Indication then
4547
         R := Range_Expression (Constraint (N));
4548
 
4549
         if R = Error then
4550
            L := Error;
4551
            H := Error;
4552
            return;
4553
 
4554
         else
4555
            L := Low_Bound  (Range_Expression (Constraint (N)));
4556
            H := High_Bound (Range_Expression (Constraint (N)));
4557
         end if;
4558
 
4559
      elsif Is_Entity_Name (N) and then Is_Type (Entity (N)) then
4560
         if Error_Posted (Scalar_Range (Entity (N))) then
4561
            L := Error;
4562
            H := Error;
4563
 
4564
         elsif Nkind (Scalar_Range (Entity (N))) = N_Subtype_Indication then
4565
            Get_Index_Bounds (Scalar_Range (Entity (N)), L, H);
4566
 
4567
         else
4568
            L := Low_Bound  (Scalar_Range (Entity (N)));
4569
            H := High_Bound (Scalar_Range (Entity (N)));
4570
         end if;
4571
 
4572
      else
4573
         --  N is an expression, indicating a range with one value
4574
 
4575
         L := N;
4576
         H := N;
4577
      end if;
4578
   end Get_Index_Bounds;
4579
 
4580
   ----------------------------------
4581
   -- Get_Library_Unit_Name_string --
4582
   ----------------------------------
4583
 
4584
   procedure Get_Library_Unit_Name_String (Decl_Node : Node_Id) is
4585
      Unit_Name_Id : constant Unit_Name_Type := Get_Unit_Name (Decl_Node);
4586
 
4587
   begin
4588
      Get_Unit_Name_String (Unit_Name_Id);
4589
 
4590
      --  Remove seven last character (" (spec)" or " (body)")
4591
 
4592
      Name_Len := Name_Len - 7;
4593
      pragma Assert (Name_Buffer (Name_Len + 1) = ' ');
4594
   end Get_Library_Unit_Name_String;
4595
 
4596
   ------------------------
4597
   -- Get_Name_Entity_Id --
4598
   ------------------------
4599
 
4600
   function Get_Name_Entity_Id (Id : Name_Id) return Entity_Id is
4601
   begin
4602
      return Entity_Id (Get_Name_Table_Info (Id));
4603
   end Get_Name_Entity_Id;
4604
 
4605
   ------------------------------------
4606
   -- Get_Name_From_Test_Case_Pragma --
4607
   ------------------------------------
4608
 
4609
   function Get_Name_From_Test_Case_Pragma (N : Node_Id) return String_Id is
4610
      Arg : constant Node_Id :=
4611
              Get_Pragma_Arg (First (Pragma_Argument_Associations (N)));
4612
   begin
4613
      return Strval (Expr_Value_S (Arg));
4614
   end Get_Name_From_Test_Case_Pragma;
4615
 
4616
   -------------------
4617
   -- Get_Pragma_Id --
4618
   -------------------
4619
 
4620
   function Get_Pragma_Id (N : Node_Id) return Pragma_Id is
4621
   begin
4622
      return Get_Pragma_Id (Pragma_Name (N));
4623
   end Get_Pragma_Id;
4624
 
4625
   ---------------------------
4626
   -- Get_Referenced_Object --
4627
   ---------------------------
4628
 
4629
   function Get_Referenced_Object (N : Node_Id) return Node_Id is
4630
      R : Node_Id;
4631
 
4632
   begin
4633
      R := N;
4634
      while Is_Entity_Name (R)
4635
        and then Present (Renamed_Object (Entity (R)))
4636
      loop
4637
         R := Renamed_Object (Entity (R));
4638
      end loop;
4639
 
4640
      return R;
4641
   end Get_Referenced_Object;
4642
 
4643
   ------------------------
4644
   -- Get_Renamed_Entity --
4645
   ------------------------
4646
 
4647
   function Get_Renamed_Entity (E : Entity_Id) return Entity_Id is
4648
      R : Entity_Id;
4649
 
4650
   begin
4651
      R := E;
4652
      while Present (Renamed_Entity (R)) loop
4653
         R := Renamed_Entity (R);
4654
      end loop;
4655
 
4656
      return R;
4657
   end Get_Renamed_Entity;
4658
 
4659
   ----------------------------------------
4660
   -- Get_Requires_From_Test_Case_Pragma --
4661
   ----------------------------------------
4662
 
4663
   function Get_Requires_From_Test_Case_Pragma (N : Node_Id) return Node_Id is
4664
      Args : constant List_Id := Pragma_Argument_Associations (N);
4665
      Res  : Node_Id;
4666
 
4667
   begin
4668
      if List_Length (Args) >= 3 then
4669
         Res := Pick (Args, 3);
4670
 
4671
         if Chars (Res) /= Name_Requires then
4672
            Res := Empty;
4673
         end if;
4674
 
4675
      else
4676
         Res := Empty;
4677
      end if;
4678
 
4679
      return Res;
4680
   end Get_Requires_From_Test_Case_Pragma;
4681
 
4682
   -------------------------
4683
   -- Get_Subprogram_Body --
4684
   -------------------------
4685
 
4686
   function Get_Subprogram_Body (E : Entity_Id) return Node_Id is
4687
      Decl : Node_Id;
4688
 
4689
   begin
4690
      Decl := Unit_Declaration_Node (E);
4691
 
4692
      if Nkind (Decl) = N_Subprogram_Body then
4693
         return Decl;
4694
 
4695
      --  The below comment is bad, because it is possible for
4696
      --  Nkind (Decl) to be an N_Subprogram_Body_Stub ???
4697
 
4698
      else           --  Nkind (Decl) = N_Subprogram_Declaration
4699
 
4700
         if Present (Corresponding_Body (Decl)) then
4701
            return Unit_Declaration_Node (Corresponding_Body (Decl));
4702
 
4703
         --  Imported subprogram case
4704
 
4705
         else
4706
            return Empty;
4707
         end if;
4708
      end if;
4709
   end Get_Subprogram_Body;
4710
 
4711
   ---------------------------
4712
   -- Get_Subprogram_Entity --
4713
   ---------------------------
4714
 
4715
   function Get_Subprogram_Entity (Nod : Node_Id) return Entity_Id is
4716
      Nam  : Node_Id;
4717
      Proc : Entity_Id;
4718
 
4719
   begin
4720
      if Nkind (Nod) = N_Accept_Statement then
4721
         Nam := Entry_Direct_Name (Nod);
4722
 
4723
      --  For an entry call, the prefix of the call is a selected component.
4724
      --  Need additional code for internal calls ???
4725
 
4726
      elsif Nkind (Nod) = N_Entry_Call_Statement then
4727
         if Nkind (Name (Nod)) = N_Selected_Component then
4728
            Nam := Entity (Selector_Name (Name (Nod)));
4729
         else
4730
            Nam := Empty;
4731
         end if;
4732
 
4733
      else
4734
         Nam := Name (Nod);
4735
      end if;
4736
 
4737
      if Nkind (Nam) = N_Explicit_Dereference then
4738
         Proc := Etype (Prefix (Nam));
4739
      elsif Is_Entity_Name (Nam) then
4740
         Proc := Entity (Nam);
4741
      else
4742
         return Empty;
4743
      end if;
4744
 
4745
      if Is_Object (Proc) then
4746
         Proc := Etype (Proc);
4747
      end if;
4748
 
4749
      if Ekind (Proc) = E_Access_Subprogram_Type then
4750
         Proc := Directly_Designated_Type (Proc);
4751
      end if;
4752
 
4753
      if not Is_Subprogram (Proc)
4754
        and then Ekind (Proc) /= E_Subprogram_Type
4755
      then
4756
         return Empty;
4757
      else
4758
         return Proc;
4759
      end if;
4760
   end Get_Subprogram_Entity;
4761
 
4762
   -----------------------------
4763
   -- Get_Task_Body_Procedure --
4764
   -----------------------------
4765
 
4766
   function Get_Task_Body_Procedure (E : Entity_Id) return Node_Id is
4767
   begin
4768
      --  Note: A task type may be the completion of a private type with
4769
      --  discriminants. When performing elaboration checks on a task
4770
      --  declaration, the current view of the type may be the private one,
4771
      --  and the procedure that holds the body of the task is held in its
4772
      --  underlying type.
4773
 
4774
      --  This is an odd function, why not have Task_Body_Procedure do
4775
      --  the following digging???
4776
 
4777
      return Task_Body_Procedure (Underlying_Type (Root_Type (E)));
4778
   end Get_Task_Body_Procedure;
4779
 
4780
   -----------------------
4781
   -- Has_Access_Values --
4782
   -----------------------
4783
 
4784
   function Has_Access_Values (T : Entity_Id) return Boolean is
4785
      Typ : constant Entity_Id := Underlying_Type (T);
4786
 
4787
   begin
4788
      --  Case of a private type which is not completed yet. This can only
4789
      --  happen in the case of a generic format type appearing directly, or
4790
      --  as a component of the type to which this function is being applied
4791
      --  at the top level. Return False in this case, since we certainly do
4792
      --  not know that the type contains access types.
4793
 
4794
      if No (Typ) then
4795
         return False;
4796
 
4797
      elsif Is_Access_Type (Typ) then
4798
         return True;
4799
 
4800
      elsif Is_Array_Type (Typ) then
4801
         return Has_Access_Values (Component_Type (Typ));
4802
 
4803
      elsif Is_Record_Type (Typ) then
4804
         declare
4805
            Comp : Entity_Id;
4806
 
4807
         begin
4808
            --  Loop to Check components
4809
 
4810
            Comp := First_Component_Or_Discriminant (Typ);
4811
            while Present (Comp) loop
4812
 
4813
               --  Check for access component, tag field does not count, even
4814
               --  though it is implemented internally using an access type.
4815
 
4816
               if Has_Access_Values (Etype (Comp))
4817
                 and then Chars (Comp) /= Name_uTag
4818
               then
4819
                  return True;
4820
               end if;
4821
 
4822
               Next_Component_Or_Discriminant (Comp);
4823
            end loop;
4824
         end;
4825
 
4826
         return False;
4827
 
4828
      else
4829
         return False;
4830
      end if;
4831
   end Has_Access_Values;
4832
 
4833
   ------------------------------
4834
   -- Has_Compatible_Alignment --
4835
   ------------------------------
4836
 
4837
   function Has_Compatible_Alignment
4838
     (Obj  : Entity_Id;
4839
      Expr : Node_Id) return Alignment_Result
4840
   is
4841
      function Has_Compatible_Alignment_Internal
4842
        (Obj     : Entity_Id;
4843
         Expr    : Node_Id;
4844
         Default : Alignment_Result) return Alignment_Result;
4845
      --  This is the internal recursive function that actually does the work.
4846
      --  There is one additional parameter, which says what the result should
4847
      --  be if no alignment information is found, and there is no definite
4848
      --  indication of compatible alignments. At the outer level, this is set
4849
      --  to Unknown, but for internal recursive calls in the case where types
4850
      --  are known to be correct, it is set to Known_Compatible.
4851
 
4852
      ---------------------------------------
4853
      -- Has_Compatible_Alignment_Internal --
4854
      ---------------------------------------
4855
 
4856
      function Has_Compatible_Alignment_Internal
4857
        (Obj     : Entity_Id;
4858
         Expr    : Node_Id;
4859
         Default : Alignment_Result) return Alignment_Result
4860
      is
4861
         Result : Alignment_Result := Known_Compatible;
4862
         --  Holds the current status of the result. Note that once a value of
4863
         --  Known_Incompatible is set, it is sticky and does not get changed
4864
         --  to Unknown (the value in Result only gets worse as we go along,
4865
         --  never better).
4866
 
4867
         Offs : Uint := No_Uint;
4868
         --  Set to a factor of the offset from the base object when Expr is a
4869
         --  selected or indexed component, based on Component_Bit_Offset and
4870
         --  Component_Size respectively. A negative value is used to represent
4871
         --  a value which is not known at compile time.
4872
 
4873
         procedure Check_Prefix;
4874
         --  Checks the prefix recursively in the case where the expression
4875
         --  is an indexed or selected component.
4876
 
4877
         procedure Set_Result (R : Alignment_Result);
4878
         --  If R represents a worse outcome (unknown instead of known
4879
         --  compatible, or known incompatible), then set Result to R.
4880
 
4881
         ------------------
4882
         -- Check_Prefix --
4883
         ------------------
4884
 
4885
         procedure Check_Prefix is
4886
         begin
4887
            --  The subtlety here is that in doing a recursive call to check
4888
            --  the prefix, we have to decide what to do in the case where we
4889
            --  don't find any specific indication of an alignment problem.
4890
 
4891
            --  At the outer level, we normally set Unknown as the result in
4892
            --  this case, since we can only set Known_Compatible if we really
4893
            --  know that the alignment value is OK, but for the recursive
4894
            --  call, in the case where the types match, and we have not
4895
            --  specified a peculiar alignment for the object, we are only
4896
            --  concerned about suspicious rep clauses, the default case does
4897
            --  not affect us, since the compiler will, in the absence of such
4898
            --  rep clauses, ensure that the alignment is correct.
4899
 
4900
            if Default = Known_Compatible
4901
              or else
4902
                (Etype (Obj) = Etype (Expr)
4903
                  and then (Unknown_Alignment (Obj)
4904
                             or else
4905
                               Alignment (Obj) = Alignment (Etype (Obj))))
4906
            then
4907
               Set_Result
4908
                 (Has_Compatible_Alignment_Internal
4909
                    (Obj, Prefix (Expr), Known_Compatible));
4910
 
4911
            --  In all other cases, we need a full check on the prefix
4912
 
4913
            else
4914
               Set_Result
4915
                 (Has_Compatible_Alignment_Internal
4916
                    (Obj, Prefix (Expr), Unknown));
4917
            end if;
4918
         end Check_Prefix;
4919
 
4920
         ----------------
4921
         -- Set_Result --
4922
         ----------------
4923
 
4924
         procedure Set_Result (R : Alignment_Result) is
4925
         begin
4926
            if R > Result then
4927
               Result := R;
4928
            end if;
4929
         end Set_Result;
4930
 
4931
      --  Start of processing for Has_Compatible_Alignment_Internal
4932
 
4933
      begin
4934
         --  If Expr is a selected component, we must make sure there is no
4935
         --  potentially troublesome component clause, and that the record is
4936
         --  not packed.
4937
 
4938
         if Nkind (Expr) = N_Selected_Component then
4939
 
4940
            --  Packed record always generate unknown alignment
4941
 
4942
            if Is_Packed (Etype (Prefix (Expr))) then
4943
               Set_Result (Unknown);
4944
            end if;
4945
 
4946
            --  Check prefix and component offset
4947
 
4948
            Check_Prefix;
4949
            Offs := Component_Bit_Offset (Entity (Selector_Name (Expr)));
4950
 
4951
         --  If Expr is an indexed component, we must make sure there is no
4952
         --  potentially troublesome Component_Size clause and that the array
4953
         --  is not bit-packed.
4954
 
4955
         elsif Nkind (Expr) = N_Indexed_Component then
4956
            declare
4957
               Typ : constant Entity_Id := Etype (Prefix (Expr));
4958
               Ind : constant Node_Id   := First_Index (Typ);
4959
 
4960
            begin
4961
               --  Bit packed array always generates unknown alignment
4962
 
4963
               if Is_Bit_Packed_Array (Typ) then
4964
                  Set_Result (Unknown);
4965
               end if;
4966
 
4967
               --  Check prefix and component offset
4968
 
4969
               Check_Prefix;
4970
               Offs := Component_Size (Typ);
4971
 
4972
               --  Small optimization: compute the full offset when possible
4973
 
4974
               if Offs /= No_Uint
4975
                 and then Offs > Uint_0
4976
                 and then Present (Ind)
4977
                 and then Nkind (Ind) = N_Range
4978
                 and then Compile_Time_Known_Value (Low_Bound (Ind))
4979
                 and then Compile_Time_Known_Value (First (Expressions (Expr)))
4980
               then
4981
                  Offs := Offs * (Expr_Value (First (Expressions (Expr)))
4982
                                    - Expr_Value (Low_Bound ((Ind))));
4983
               end if;
4984
            end;
4985
         end if;
4986
 
4987
         --  If we have a null offset, the result is entirely determined by
4988
         --  the base object and has already been computed recursively.
4989
 
4990
         if Offs = Uint_0 then
4991
            null;
4992
 
4993
         --  Case where we know the alignment of the object
4994
 
4995
         elsif Known_Alignment (Obj) then
4996
            declare
4997
               ObjA : constant Uint := Alignment (Obj);
4998
               ExpA : Uint          := No_Uint;
4999
               SizA : Uint          := No_Uint;
5000
 
5001
            begin
5002
               --  If alignment of Obj is 1, then we are always OK
5003
 
5004
               if ObjA = 1 then
5005
                  Set_Result (Known_Compatible);
5006
 
5007
               --  Alignment of Obj is greater than 1, so we need to check
5008
 
5009
               else
5010
                  --  If we have an offset, see if it is compatible
5011
 
5012
                  if Offs /= No_Uint and Offs > Uint_0 then
5013
                     if Offs mod (System_Storage_Unit * ObjA) /= 0 then
5014
                        Set_Result (Known_Incompatible);
5015
                     end if;
5016
 
5017
                     --  See if Expr is an object with known alignment
5018
 
5019
                  elsif Is_Entity_Name (Expr)
5020
                    and then Known_Alignment (Entity (Expr))
5021
                  then
5022
                     ExpA := Alignment (Entity (Expr));
5023
 
5024
                     --  Otherwise, we can use the alignment of the type of
5025
                     --  Expr given that we already checked for
5026
                     --  discombobulating rep clauses for the cases of indexed
5027
                     --  and selected components above.
5028
 
5029
                  elsif Known_Alignment (Etype (Expr)) then
5030
                     ExpA := Alignment (Etype (Expr));
5031
 
5032
                     --  Otherwise the alignment is unknown
5033
 
5034
                  else
5035
                     Set_Result (Default);
5036
                  end if;
5037
 
5038
                  --  If we got an alignment, see if it is acceptable
5039
 
5040
                  if ExpA /= No_Uint and then ExpA < ObjA then
5041
                     Set_Result (Known_Incompatible);
5042
                  end if;
5043
 
5044
                  --  If Expr is not a piece of a larger object, see if size
5045
                  --  is given. If so, check that it is not too small for the
5046
                  --  required alignment.
5047
 
5048
                  if Offs /= No_Uint then
5049
                     null;
5050
 
5051
                     --  See if Expr is an object with known size
5052
 
5053
                  elsif Is_Entity_Name (Expr)
5054
                    and then Known_Static_Esize (Entity (Expr))
5055
                  then
5056
                     SizA := Esize (Entity (Expr));
5057
 
5058
                     --  Otherwise, we check the object size of the Expr type
5059
 
5060
                  elsif Known_Static_Esize (Etype (Expr)) then
5061
                     SizA := Esize (Etype (Expr));
5062
                  end if;
5063
 
5064
                  --  If we got a size, see if it is a multiple of the Obj
5065
                  --  alignment, if not, then the alignment cannot be
5066
                  --  acceptable, since the size is always a multiple of the
5067
                  --  alignment.
5068
 
5069
                  if SizA /= No_Uint then
5070
                     if SizA mod (ObjA * Ttypes.System_Storage_Unit) /= 0 then
5071
                        Set_Result (Known_Incompatible);
5072
                     end if;
5073
                  end if;
5074
               end if;
5075
            end;
5076
 
5077
         --  If we do not know required alignment, any non-zero offset is a
5078
         --  potential problem (but certainly may be OK, so result is unknown).
5079
 
5080
         elsif Offs /= No_Uint then
5081
            Set_Result (Unknown);
5082
 
5083
         --  If we can't find the result by direct comparison of alignment
5084
         --  values, then there is still one case that we can determine known
5085
         --  result, and that is when we can determine that the types are the
5086
         --  same, and no alignments are specified. Then we known that the
5087
         --  alignments are compatible, even if we don't know the alignment
5088
         --  value in the front end.
5089
 
5090
         elsif Etype (Obj) = Etype (Expr) then
5091
 
5092
            --  Types are the same, but we have to check for possible size
5093
            --  and alignments on the Expr object that may make the alignment
5094
            --  different, even though the types are the same.
5095
 
5096
            if Is_Entity_Name (Expr) then
5097
 
5098
               --  First check alignment of the Expr object. Any alignment less
5099
               --  than Maximum_Alignment is worrisome since this is the case
5100
               --  where we do not know the alignment of Obj.
5101
 
5102
               if Known_Alignment (Entity (Expr))
5103
                 and then
5104
                   UI_To_Int (Alignment (Entity (Expr))) <
5105
                                                    Ttypes.Maximum_Alignment
5106
               then
5107
                  Set_Result (Unknown);
5108
 
5109
                  --  Now check size of Expr object. Any size that is not an
5110
                  --  even multiple of Maximum_Alignment is also worrisome
5111
                  --  since it may cause the alignment of the object to be less
5112
                  --  than the alignment of the type.
5113
 
5114
               elsif Known_Static_Esize (Entity (Expr))
5115
                 and then
5116
                   (UI_To_Int (Esize (Entity (Expr))) mod
5117
                     (Ttypes.Maximum_Alignment * Ttypes.System_Storage_Unit))
5118
                                                                        /= 0
5119
               then
5120
                  Set_Result (Unknown);
5121
 
5122
                  --  Otherwise same type is decisive
5123
 
5124
               else
5125
                  Set_Result (Known_Compatible);
5126
               end if;
5127
            end if;
5128
 
5129
         --  Another case to deal with is when there is an explicit size or
5130
         --  alignment clause when the types are not the same. If so, then the
5131
         --  result is Unknown. We don't need to do this test if the Default is
5132
         --  Unknown, since that result will be set in any case.
5133
 
5134
         elsif Default /= Unknown
5135
           and then (Has_Size_Clause      (Etype (Expr))
5136
                      or else
5137
                     Has_Alignment_Clause (Etype (Expr)))
5138
         then
5139
            Set_Result (Unknown);
5140
 
5141
         --  If no indication found, set default
5142
 
5143
         else
5144
            Set_Result (Default);
5145
         end if;
5146
 
5147
         --  Return worst result found
5148
 
5149
         return Result;
5150
      end Has_Compatible_Alignment_Internal;
5151
 
5152
   --  Start of processing for Has_Compatible_Alignment
5153
 
5154
   begin
5155
      --  If Obj has no specified alignment, then set alignment from the type
5156
      --  alignment. Perhaps we should always do this, but for sure we should
5157
      --  do it when there is an address clause since we can do more if the
5158
      --  alignment is known.
5159
 
5160
      if Unknown_Alignment (Obj) then
5161
         Set_Alignment (Obj, Alignment (Etype (Obj)));
5162
      end if;
5163
 
5164
      --  Now do the internal call that does all the work
5165
 
5166
      return Has_Compatible_Alignment_Internal (Obj, Expr, Unknown);
5167
   end Has_Compatible_Alignment;
5168
 
5169
   ----------------------
5170
   -- Has_Declarations --
5171
   ----------------------
5172
 
5173
   function Has_Declarations (N : Node_Id) return Boolean is
5174
   begin
5175
      return Nkind_In (Nkind (N), N_Accept_Statement,
5176
                                  N_Block_Statement,
5177
                                  N_Compilation_Unit_Aux,
5178
                                  N_Entry_Body,
5179
                                  N_Package_Body,
5180
                                  N_Protected_Body,
5181
                                  N_Subprogram_Body,
5182
                                  N_Task_Body,
5183
                                  N_Package_Specification);
5184
   end Has_Declarations;
5185
 
5186
   -------------------------------------------
5187
   -- Has_Discriminant_Dependent_Constraint --
5188
   -------------------------------------------
5189
 
5190
   function Has_Discriminant_Dependent_Constraint
5191
     (Comp : Entity_Id) return Boolean
5192
   is
5193
      Comp_Decl  : constant Node_Id := Parent (Comp);
5194
      Subt_Indic : constant Node_Id :=
5195
                     Subtype_Indication (Component_Definition (Comp_Decl));
5196
      Constr     : Node_Id;
5197
      Assn       : Node_Id;
5198
 
5199
   begin
5200
      if Nkind (Subt_Indic) = N_Subtype_Indication then
5201
         Constr := Constraint (Subt_Indic);
5202
 
5203
         if Nkind (Constr) = N_Index_Or_Discriminant_Constraint then
5204
            Assn := First (Constraints (Constr));
5205
            while Present (Assn) loop
5206
               case Nkind (Assn) is
5207
                  when N_Subtype_Indication |
5208
                       N_Range              |
5209
                       N_Identifier
5210
                  =>
5211
                     if Depends_On_Discriminant (Assn) then
5212
                        return True;
5213
                     end if;
5214
 
5215
                  when N_Discriminant_Association =>
5216
                     if Depends_On_Discriminant (Expression (Assn)) then
5217
                        return True;
5218
                     end if;
5219
 
5220
                  when others =>
5221
                     null;
5222
 
5223
               end case;
5224
 
5225
               Next (Assn);
5226
            end loop;
5227
         end if;
5228
      end if;
5229
 
5230
      return False;
5231
   end Has_Discriminant_Dependent_Constraint;
5232
 
5233
   --------------------
5234
   -- Has_Infinities --
5235
   --------------------
5236
 
5237
   function Has_Infinities (E : Entity_Id) return Boolean is
5238
   begin
5239
      return
5240
        Is_Floating_Point_Type (E)
5241
          and then Nkind (Scalar_Range (E)) = N_Range
5242
          and then Includes_Infinities (Scalar_Range (E));
5243
   end Has_Infinities;
5244
 
5245
   --------------------
5246
   -- Has_Interfaces --
5247
   --------------------
5248
 
5249
   function Has_Interfaces
5250
     (T             : Entity_Id;
5251
      Use_Full_View : Boolean := True) return Boolean
5252
   is
5253
      Typ : Entity_Id := Base_Type (T);
5254
 
5255
   begin
5256
      --  Handle concurrent types
5257
 
5258
      if Is_Concurrent_Type (Typ) then
5259
         Typ := Corresponding_Record_Type (Typ);
5260
      end if;
5261
 
5262
      if not Present (Typ)
5263
        or else not Is_Record_Type (Typ)
5264
        or else not Is_Tagged_Type (Typ)
5265
      then
5266
         return False;
5267
      end if;
5268
 
5269
      --  Handle private types
5270
 
5271
      if Use_Full_View
5272
        and then Present (Full_View (Typ))
5273
      then
5274
         Typ := Full_View (Typ);
5275
      end if;
5276
 
5277
      --  Handle concurrent record types
5278
 
5279
      if Is_Concurrent_Record_Type (Typ)
5280
        and then Is_Non_Empty_List (Abstract_Interface_List (Typ))
5281
      then
5282
         return True;
5283
      end if;
5284
 
5285
      loop
5286
         if Is_Interface (Typ)
5287
           or else
5288
             (Is_Record_Type (Typ)
5289
               and then Present (Interfaces (Typ))
5290
               and then not Is_Empty_Elmt_List (Interfaces (Typ)))
5291
         then
5292
            return True;
5293
         end if;
5294
 
5295
         exit when Etype (Typ) = Typ
5296
 
5297
            --  Handle private types
5298
 
5299
            or else (Present (Full_View (Etype (Typ)))
5300
                       and then Full_View (Etype (Typ)) = Typ)
5301
 
5302
            --  Protect the frontend against wrong source with cyclic
5303
            --  derivations
5304
 
5305
            or else Etype (Typ) = T;
5306
 
5307
         --  Climb to the ancestor type handling private types
5308
 
5309
         if Present (Full_View (Etype (Typ))) then
5310
            Typ := Full_View (Etype (Typ));
5311
         else
5312
            Typ := Etype (Typ);
5313
         end if;
5314
      end loop;
5315
 
5316
      return False;
5317
   end Has_Interfaces;
5318
 
5319
   ------------------------
5320
   -- Has_Null_Exclusion --
5321
   ------------------------
5322
 
5323
   function Has_Null_Exclusion (N : Node_Id) return Boolean is
5324
   begin
5325
      case Nkind (N) is
5326
         when N_Access_Definition               |
5327
              N_Access_Function_Definition      |
5328
              N_Access_Procedure_Definition     |
5329
              N_Access_To_Object_Definition     |
5330
              N_Allocator                       |
5331
              N_Derived_Type_Definition         |
5332
              N_Function_Specification          |
5333
              N_Subtype_Declaration             =>
5334
            return Null_Exclusion_Present (N);
5335
 
5336
         when N_Component_Definition            |
5337
              N_Formal_Object_Declaration       |
5338
              N_Object_Renaming_Declaration     =>
5339
            if Present (Subtype_Mark (N)) then
5340
               return Null_Exclusion_Present (N);
5341
            else pragma Assert (Present (Access_Definition (N)));
5342
               return Null_Exclusion_Present (Access_Definition (N));
5343
            end if;
5344
 
5345
         when N_Discriminant_Specification =>
5346
            if Nkind (Discriminant_Type (N)) = N_Access_Definition then
5347
               return Null_Exclusion_Present (Discriminant_Type (N));
5348
            else
5349
               return Null_Exclusion_Present (N);
5350
            end if;
5351
 
5352
         when N_Object_Declaration =>
5353
            if Nkind (Object_Definition (N)) = N_Access_Definition then
5354
               return Null_Exclusion_Present (Object_Definition (N));
5355
            else
5356
               return Null_Exclusion_Present (N);
5357
            end if;
5358
 
5359
         when N_Parameter_Specification =>
5360
            if Nkind (Parameter_Type (N)) = N_Access_Definition then
5361
               return Null_Exclusion_Present (Parameter_Type (N));
5362
            else
5363
               return Null_Exclusion_Present (N);
5364
            end if;
5365
 
5366
         when others =>
5367
            return False;
5368
 
5369
      end case;
5370
   end Has_Null_Exclusion;
5371
 
5372
   ------------------------
5373
   -- Has_Null_Extension --
5374
   ------------------------
5375
 
5376
   function Has_Null_Extension (T : Entity_Id) return Boolean is
5377
      B     : constant Entity_Id := Base_Type (T);
5378
      Comps : Node_Id;
5379
      Ext   : Node_Id;
5380
 
5381
   begin
5382
      if Nkind (Parent (B)) = N_Full_Type_Declaration
5383
        and then Present (Record_Extension_Part (Type_Definition (Parent (B))))
5384
      then
5385
         Ext := Record_Extension_Part (Type_Definition (Parent (B)));
5386
 
5387
         if Present (Ext) then
5388
            if Null_Present (Ext) then
5389
               return True;
5390
            else
5391
               Comps := Component_List (Ext);
5392
 
5393
               --  The null component list is rewritten during analysis to
5394
               --  include the parent component. Any other component indicates
5395
               --  that the extension was not originally null.
5396
 
5397
               return Null_Present (Comps)
5398
                 or else No (Next (First (Component_Items (Comps))));
5399
            end if;
5400
         else
5401
            return False;
5402
         end if;
5403
 
5404
      else
5405
         return False;
5406
      end if;
5407
   end Has_Null_Extension;
5408
 
5409
   -------------------------------
5410
   -- Has_Overriding_Initialize --
5411
   -------------------------------
5412
 
5413
   function Has_Overriding_Initialize (T : Entity_Id) return Boolean is
5414
      BT   : constant Entity_Id := Base_Type (T);
5415
      P    : Elmt_Id;
5416
 
5417
   begin
5418
      if Is_Controlled (BT) then
5419
         if Is_RTU (Scope (BT), Ada_Finalization) then
5420
            return False;
5421
 
5422
         elsif Present (Primitive_Operations (BT)) then
5423
            P := First_Elmt (Primitive_Operations (BT));
5424
            while Present (P) loop
5425
               declare
5426
                  Init : constant Entity_Id := Node (P);
5427
                  Formal : constant Entity_Id := First_Formal (Init);
5428
               begin
5429
                  if Ekind (Init) = E_Procedure
5430
                       and then Chars (Init) = Name_Initialize
5431
                       and then Comes_From_Source (Init)
5432
                       and then Present (Formal)
5433
                       and then Etype (Formal) = BT
5434
                       and then No (Next_Formal (Formal))
5435
                       and then (Ada_Version < Ada_2012
5436
                                   or else not Null_Present (Parent (Init)))
5437
                  then
5438
                     return True;
5439
                  end if;
5440
               end;
5441
 
5442
               Next_Elmt (P);
5443
            end loop;
5444
         end if;
5445
 
5446
         --  Here if type itself does not have a non-null Initialize operation:
5447
         --  check immediate ancestor.
5448
 
5449
         if Is_Derived_Type (BT)
5450
           and then Has_Overriding_Initialize (Etype (BT))
5451
         then
5452
            return True;
5453
         end if;
5454
      end if;
5455
 
5456
      return False;
5457
   end Has_Overriding_Initialize;
5458
 
5459
   --------------------------------------
5460
   -- Has_Preelaborable_Initialization --
5461
   --------------------------------------
5462
 
5463
   function Has_Preelaborable_Initialization (E : Entity_Id) return Boolean is
5464
      Has_PE : Boolean;
5465
 
5466
      procedure Check_Components (E : Entity_Id);
5467
      --  Check component/discriminant chain, sets Has_PE False if a component
5468
      --  or discriminant does not meet the preelaborable initialization rules.
5469
 
5470
      ----------------------
5471
      -- Check_Components --
5472
      ----------------------
5473
 
5474
      procedure Check_Components (E : Entity_Id) is
5475
         Ent : Entity_Id;
5476
         Exp : Node_Id;
5477
 
5478
         function Is_Preelaborable_Expression (N : Node_Id) return Boolean;
5479
         --  Returns True if and only if the expression denoted by N does not
5480
         --  violate restrictions on preelaborable constructs (RM-10.2.1(5-9)).
5481
 
5482
         ---------------------------------
5483
         -- Is_Preelaborable_Expression --
5484
         ---------------------------------
5485
 
5486
         function Is_Preelaborable_Expression (N : Node_Id) return Boolean is
5487
            Exp           : Node_Id;
5488
            Assn          : Node_Id;
5489
            Choice        : Node_Id;
5490
            Comp_Type     : Entity_Id;
5491
            Is_Array_Aggr : Boolean;
5492
 
5493
         begin
5494
            if Is_Static_Expression (N) then
5495
               return True;
5496
 
5497
            elsif Nkind (N) = N_Null then
5498
               return True;
5499
 
5500
            --  Attributes are allowed in general, even if their prefix is a
5501
            --  formal type. (It seems that certain attributes known not to be
5502
            --  static might not be allowed, but there are no rules to prevent
5503
            --  them.)
5504
 
5505
            elsif Nkind (N) = N_Attribute_Reference then
5506
               return True;
5507
 
5508
            --  The name of a discriminant evaluated within its parent type is
5509
            --  defined to be preelaborable (10.2.1(8)). Note that we test for
5510
            --  names that denote discriminals as well as discriminants to
5511
            --  catch references occurring within init procs.
5512
 
5513
            elsif Is_Entity_Name (N)
5514
              and then
5515
                (Ekind (Entity (N)) = E_Discriminant
5516
                  or else
5517
                    ((Ekind (Entity (N)) = E_Constant
5518
                       or else Ekind (Entity (N)) = E_In_Parameter)
5519
                     and then Present (Discriminal_Link (Entity (N)))))
5520
            then
5521
               return True;
5522
 
5523
            elsif Nkind (N) = N_Qualified_Expression then
5524
               return Is_Preelaborable_Expression (Expression (N));
5525
 
5526
            --  For aggregates we have to check that each of the associations
5527
            --  is preelaborable.
5528
 
5529
            elsif Nkind (N) = N_Aggregate
5530
              or else Nkind (N) = N_Extension_Aggregate
5531
            then
5532
               Is_Array_Aggr := Is_Array_Type (Etype (N));
5533
 
5534
               if Is_Array_Aggr then
5535
                  Comp_Type := Component_Type (Etype (N));
5536
               end if;
5537
 
5538
               --  Check the ancestor part of extension aggregates, which must
5539
               --  be either the name of a type that has preelaborable init or
5540
               --  an expression that is preelaborable.
5541
 
5542
               if Nkind (N) = N_Extension_Aggregate then
5543
                  declare
5544
                     Anc_Part : constant Node_Id := Ancestor_Part (N);
5545
 
5546
                  begin
5547
                     if Is_Entity_Name (Anc_Part)
5548
                       and then Is_Type (Entity (Anc_Part))
5549
                     then
5550
                        if not Has_Preelaborable_Initialization
5551
                                 (Entity (Anc_Part))
5552
                        then
5553
                           return False;
5554
                        end if;
5555
 
5556
                     elsif not Is_Preelaborable_Expression (Anc_Part) then
5557
                        return False;
5558
                     end if;
5559
                  end;
5560
               end if;
5561
 
5562
               --  Check positional associations
5563
 
5564
               Exp := First (Expressions (N));
5565
               while Present (Exp) loop
5566
                  if not Is_Preelaborable_Expression (Exp) then
5567
                     return False;
5568
                  end if;
5569
 
5570
                  Next (Exp);
5571
               end loop;
5572
 
5573
               --  Check named associations
5574
 
5575
               Assn := First (Component_Associations (N));
5576
               while Present (Assn) loop
5577
                  Choice := First (Choices (Assn));
5578
                  while Present (Choice) loop
5579
                     if Is_Array_Aggr then
5580
                        if Nkind (Choice) = N_Others_Choice then
5581
                           null;
5582
 
5583
                        elsif Nkind (Choice) = N_Range then
5584
                           if not Is_Static_Range (Choice) then
5585
                              return False;
5586
                           end if;
5587
 
5588
                        elsif not Is_Static_Expression (Choice) then
5589
                           return False;
5590
                        end if;
5591
 
5592
                     else
5593
                        Comp_Type := Etype (Choice);
5594
                     end if;
5595
 
5596
                     Next (Choice);
5597
                  end loop;
5598
 
5599
                  --  If the association has a <> at this point, then we have
5600
                  --  to check whether the component's type has preelaborable
5601
                  --  initialization. Note that this only occurs when the
5602
                  --  association's corresponding component does not have a
5603
                  --  default expression, the latter case having already been
5604
                  --  expanded as an expression for the association.
5605
 
5606
                  if Box_Present (Assn) then
5607
                     if not Has_Preelaborable_Initialization (Comp_Type) then
5608
                        return False;
5609
                     end if;
5610
 
5611
                  --  In the expression case we check whether the expression
5612
                  --  is preelaborable.
5613
 
5614
                  elsif
5615
                    not Is_Preelaborable_Expression (Expression (Assn))
5616
                  then
5617
                     return False;
5618
                  end if;
5619
 
5620
                  Next (Assn);
5621
               end loop;
5622
 
5623
               --  If we get here then aggregate as a whole is preelaborable
5624
 
5625
               return True;
5626
 
5627
            --  All other cases are not preelaborable
5628
 
5629
            else
5630
               return False;
5631
            end if;
5632
         end Is_Preelaborable_Expression;
5633
 
5634
      --  Start of processing for Check_Components
5635
 
5636
      begin
5637
         --  Loop through entities of record or protected type
5638
 
5639
         Ent := E;
5640
         while Present (Ent) loop
5641
 
5642
            --  We are interested only in components and discriminants
5643
 
5644
            Exp := Empty;
5645
 
5646
            case Ekind (Ent) is
5647
               when E_Component =>
5648
 
5649
                  --  Get default expression if any. If there is no declaration
5650
                  --  node, it means we have an internal entity. The parent and
5651
                  --  tag fields are examples of such entities. For such cases,
5652
                  --  we just test the type of the entity.
5653
 
5654
                  if Present (Declaration_Node (Ent)) then
5655
                     Exp := Expression (Declaration_Node (Ent));
5656
                  end if;
5657
 
5658
               when E_Discriminant =>
5659
 
5660
                  --  Note: for a renamed discriminant, the Declaration_Node
5661
                  --  may point to the one from the ancestor, and have a
5662
                  --  different expression, so use the proper attribute to
5663
                  --  retrieve the expression from the derived constraint.
5664
 
5665
                  Exp := Discriminant_Default_Value (Ent);
5666
 
5667
               when others =>
5668
                  goto Check_Next_Entity;
5669
            end case;
5670
 
5671
            --  A component has PI if it has no default expression and the
5672
            --  component type has PI.
5673
 
5674
            if No (Exp) then
5675
               if not Has_Preelaborable_Initialization (Etype (Ent)) then
5676
                  Has_PE := False;
5677
                  exit;
5678
               end if;
5679
 
5680
            --  Require the default expression to be preelaborable
5681
 
5682
            elsif not Is_Preelaborable_Expression (Exp) then
5683
               Has_PE := False;
5684
               exit;
5685
            end if;
5686
 
5687
         <<Check_Next_Entity>>
5688
            Next_Entity (Ent);
5689
         end loop;
5690
      end Check_Components;
5691
 
5692
   --  Start of processing for Has_Preelaborable_Initialization
5693
 
5694
   begin
5695
      --  Immediate return if already marked as known preelaborable init. This
5696
      --  covers types for which this function has already been called once
5697
      --  and returned True (in which case the result is cached), and also
5698
      --  types to which a pragma Preelaborable_Initialization applies.
5699
 
5700
      if Known_To_Have_Preelab_Init (E) then
5701
         return True;
5702
      end if;
5703
 
5704
      --  If the type is a subtype representing a generic actual type, then
5705
      --  test whether its base type has preelaborable initialization since
5706
      --  the subtype representing the actual does not inherit this attribute
5707
      --  from the actual or formal. (but maybe it should???)
5708
 
5709
      if Is_Generic_Actual_Type (E) then
5710
         return Has_Preelaborable_Initialization (Base_Type (E));
5711
      end if;
5712
 
5713
      --  All elementary types have preelaborable initialization
5714
 
5715
      if Is_Elementary_Type (E) then
5716
         Has_PE := True;
5717
 
5718
      --  Array types have PI if the component type has PI
5719
 
5720
      elsif Is_Array_Type (E) then
5721
         Has_PE := Has_Preelaborable_Initialization (Component_Type (E));
5722
 
5723
      --  A derived type has preelaborable initialization if its parent type
5724
      --  has preelaborable initialization and (in the case of a derived record
5725
      --  extension) if the non-inherited components all have preelaborable
5726
      --  initialization. However, a user-defined controlled type with an
5727
      --  overriding Initialize procedure does not have preelaborable
5728
      --  initialization.
5729
 
5730
      elsif Is_Derived_Type (E) then
5731
 
5732
         --  If the derived type is a private extension then it doesn't have
5733
         --  preelaborable initialization.
5734
 
5735
         if Ekind (Base_Type (E)) = E_Record_Type_With_Private then
5736
            return False;
5737
         end if;
5738
 
5739
         --  First check whether ancestor type has preelaborable initialization
5740
 
5741
         Has_PE := Has_Preelaborable_Initialization (Etype (Base_Type (E)));
5742
 
5743
         --  If OK, check extension components (if any)
5744
 
5745
         if Has_PE and then Is_Record_Type (E) then
5746
            Check_Components (First_Entity (E));
5747
         end if;
5748
 
5749
         --  Check specifically for 10.2.1(11.4/2) exception: a controlled type
5750
         --  with a user defined Initialize procedure does not have PI.
5751
 
5752
         if Has_PE
5753
           and then Is_Controlled (E)
5754
           and then Has_Overriding_Initialize (E)
5755
         then
5756
            Has_PE := False;
5757
         end if;
5758
 
5759
      --  Private types not derived from a type having preelaborable init and
5760
      --  that are not marked with pragma Preelaborable_Initialization do not
5761
      --  have preelaborable initialization.
5762
 
5763
      elsif Is_Private_Type (E) then
5764
         return False;
5765
 
5766
      --  Record type has PI if it is non private and all components have PI
5767
 
5768
      elsif Is_Record_Type (E) then
5769
         Has_PE := True;
5770
         Check_Components (First_Entity (E));
5771
 
5772
      --  Protected types must not have entries, and components must meet
5773
      --  same set of rules as for record components.
5774
 
5775
      elsif Is_Protected_Type (E) then
5776
         if Has_Entries (E) then
5777
            Has_PE := False;
5778
         else
5779
            Has_PE := True;
5780
            Check_Components (First_Entity (E));
5781
            Check_Components (First_Private_Entity (E));
5782
         end if;
5783
 
5784
      --  Type System.Address always has preelaborable initialization
5785
 
5786
      elsif Is_RTE (E, RE_Address) then
5787
         Has_PE := True;
5788
 
5789
      --  In all other cases, type does not have preelaborable initialization
5790
 
5791
      else
5792
         return False;
5793
      end if;
5794
 
5795
      --  If type has preelaborable initialization, cache result
5796
 
5797
      if Has_PE then
5798
         Set_Known_To_Have_Preelab_Init (E);
5799
      end if;
5800
 
5801
      return Has_PE;
5802
   end Has_Preelaborable_Initialization;
5803
 
5804
   ---------------------------
5805
   -- Has_Private_Component --
5806
   ---------------------------
5807
 
5808
   function Has_Private_Component (Type_Id : Entity_Id) return Boolean is
5809
      Btype     : Entity_Id := Base_Type (Type_Id);
5810
      Component : Entity_Id;
5811
 
5812
   begin
5813
      if Error_Posted (Type_Id)
5814
        or else Error_Posted (Btype)
5815
      then
5816
         return False;
5817
      end if;
5818
 
5819
      if Is_Class_Wide_Type (Btype) then
5820
         Btype := Root_Type (Btype);
5821
      end if;
5822
 
5823
      if Is_Private_Type (Btype) then
5824
         declare
5825
            UT : constant Entity_Id := Underlying_Type (Btype);
5826
         begin
5827
            if No (UT) then
5828
               if No (Full_View (Btype)) then
5829
                  return not Is_Generic_Type (Btype)
5830
                    and then not Is_Generic_Type (Root_Type (Btype));
5831
               else
5832
                  return not Is_Generic_Type (Root_Type (Full_View (Btype)));
5833
               end if;
5834
            else
5835
               return not Is_Frozen (UT) and then Has_Private_Component (UT);
5836
            end if;
5837
         end;
5838
 
5839
      elsif Is_Array_Type (Btype) then
5840
         return Has_Private_Component (Component_Type (Btype));
5841
 
5842
      elsif Is_Record_Type (Btype) then
5843
         Component := First_Component (Btype);
5844
         while Present (Component) loop
5845
            if Has_Private_Component (Etype (Component)) then
5846
               return True;
5847
            end if;
5848
 
5849
            Next_Component (Component);
5850
         end loop;
5851
 
5852
         return False;
5853
 
5854
      elsif Is_Protected_Type (Btype)
5855
        and then Present (Corresponding_Record_Type (Btype))
5856
      then
5857
         return Has_Private_Component (Corresponding_Record_Type (Btype));
5858
 
5859
      else
5860
         return False;
5861
      end if;
5862
   end Has_Private_Component;
5863
 
5864
   -----------------------------
5865
   -- Has_Static_Array_Bounds --
5866
   -----------------------------
5867
 
5868
   function Has_Static_Array_Bounds (Typ : Node_Id) return Boolean is
5869
      Ndims : constant Nat := Number_Dimensions (Typ);
5870
 
5871
      Index : Node_Id;
5872
      Low   : Node_Id;
5873
      High  : Node_Id;
5874
 
5875
   begin
5876
      --  Unconstrained types do not have static bounds
5877
 
5878
      if not Is_Constrained (Typ) then
5879
         return False;
5880
      end if;
5881
 
5882
      --  First treat string literals specially, as the lower bound and length
5883
      --  of string literals are not stored like those of arrays.
5884
 
5885
      --  A string literal always has static bounds
5886
 
5887
      if Ekind (Typ) = E_String_Literal_Subtype then
5888
         return True;
5889
      end if;
5890
 
5891
      --  Treat all dimensions in turn
5892
 
5893
      Index := First_Index (Typ);
5894
      for Indx in 1 .. Ndims loop
5895
 
5896
         --  In case of an erroneous index which is not a discrete type, return
5897
         --  that the type is not static.
5898
 
5899
         if not Is_Discrete_Type (Etype (Index))
5900
           or else Etype (Index) = Any_Type
5901
         then
5902
            return False;
5903
         end if;
5904
 
5905
         Get_Index_Bounds (Index, Low, High);
5906
 
5907
         if Error_Posted (Low) or else Error_Posted (High) then
5908
            return False;
5909
         end if;
5910
 
5911
         if Is_OK_Static_Expression (Low)
5912
              and then
5913
            Is_OK_Static_Expression (High)
5914
         then
5915
            null;
5916
         else
5917
            return False;
5918
         end if;
5919
 
5920
         Next (Index);
5921
      end loop;
5922
 
5923
      --  If we fall through the loop, all indexes matched
5924
 
5925
      return True;
5926
   end Has_Static_Array_Bounds;
5927
 
5928
   ----------------
5929
   -- Has_Stream --
5930
   ----------------
5931
 
5932
   function Has_Stream (T : Entity_Id) return Boolean is
5933
      E : Entity_Id;
5934
 
5935
   begin
5936
      if No (T) then
5937
         return False;
5938
 
5939
      elsif Is_RTE (Root_Type (T), RE_Root_Stream_Type) then
5940
         return True;
5941
 
5942
      elsif Is_Array_Type (T) then
5943
         return Has_Stream (Component_Type (T));
5944
 
5945
      elsif Is_Record_Type (T) then
5946
         E := First_Component (T);
5947
         while Present (E) loop
5948
            if Has_Stream (Etype (E)) then
5949
               return True;
5950
            else
5951
               Next_Component (E);
5952
            end if;
5953
         end loop;
5954
 
5955
         return False;
5956
 
5957
      elsif Is_Private_Type (T) then
5958
         return Has_Stream (Underlying_Type (T));
5959
 
5960
      else
5961
         return False;
5962
      end if;
5963
   end Has_Stream;
5964
 
5965
   ----------------
5966
   -- Has_Suffix --
5967
   ----------------
5968
 
5969
   function Has_Suffix (E : Entity_Id; Suffix : Character) return Boolean is
5970
   begin
5971
      Get_Name_String (Chars (E));
5972
      return Name_Buffer (Name_Len) = Suffix;
5973
   end Has_Suffix;
5974
 
5975
   ----------------
5976
   -- Add_Suffix --
5977
   ----------------
5978
 
5979
   function Add_Suffix (E : Entity_Id; Suffix : Character) return Name_Id is
5980
   begin
5981
      Get_Name_String (Chars (E));
5982
      Add_Char_To_Name_Buffer (Suffix);
5983
      return Name_Find;
5984
   end Add_Suffix;
5985
 
5986
   -------------------
5987
   -- Remove_Suffix --
5988
   -------------------
5989
 
5990
   function Remove_Suffix (E : Entity_Id; Suffix : Character) return Name_Id is
5991
   begin
5992
      pragma Assert (Has_Suffix (E, Suffix));
5993
      Get_Name_String (Chars (E));
5994
      Name_Len := Name_Len - 1;
5995
      return Name_Find;
5996
   end Remove_Suffix;
5997
 
5998
   --------------------------
5999
   -- Has_Tagged_Component --
6000
   --------------------------
6001
 
6002
   function Has_Tagged_Component (Typ : Entity_Id) return Boolean is
6003
      Comp : Entity_Id;
6004
 
6005
   begin
6006
      if Is_Private_Type (Typ)
6007
        and then Present (Underlying_Type (Typ))
6008
      then
6009
         return Has_Tagged_Component (Underlying_Type (Typ));
6010
 
6011
      elsif Is_Array_Type (Typ) then
6012
         return Has_Tagged_Component (Component_Type (Typ));
6013
 
6014
      elsif Is_Tagged_Type (Typ) then
6015
         return True;
6016
 
6017
      elsif Is_Record_Type (Typ) then
6018
         Comp := First_Component (Typ);
6019
         while Present (Comp) loop
6020
            if Has_Tagged_Component (Etype (Comp)) then
6021
               return True;
6022
            end if;
6023
 
6024
            Next_Component (Comp);
6025
         end loop;
6026
 
6027
         return False;
6028
 
6029
      else
6030
         return False;
6031
      end if;
6032
   end Has_Tagged_Component;
6033
 
6034
   -------------------------
6035
   -- Implementation_Kind --
6036
   -------------------------
6037
 
6038
   function Implementation_Kind (Subp : Entity_Id) return Name_Id is
6039
      Impl_Prag : constant Node_Id := Get_Rep_Pragma (Subp, Name_Implemented);
6040
      Arg       : Node_Id;
6041
   begin
6042
      pragma Assert (Present (Impl_Prag));
6043
      Arg := Last (Pragma_Argument_Associations (Impl_Prag));
6044
      return Chars (Get_Pragma_Arg (Arg));
6045
   end Implementation_Kind;
6046
 
6047
   --------------------------
6048
   -- Implements_Interface --
6049
   --------------------------
6050
 
6051
   function Implements_Interface
6052
     (Typ_Ent         : Entity_Id;
6053
      Iface_Ent       : Entity_Id;
6054
      Exclude_Parents : Boolean := False) return Boolean
6055
   is
6056
      Ifaces_List : Elist_Id;
6057
      Elmt        : Elmt_Id;
6058
      Iface       : Entity_Id := Base_Type (Iface_Ent);
6059
      Typ         : Entity_Id := Base_Type (Typ_Ent);
6060
 
6061
   begin
6062
      if Is_Class_Wide_Type (Typ) then
6063
         Typ := Root_Type (Typ);
6064
      end if;
6065
 
6066
      if not Has_Interfaces (Typ) then
6067
         return False;
6068
      end if;
6069
 
6070
      if Is_Class_Wide_Type (Iface) then
6071
         Iface := Root_Type (Iface);
6072
      end if;
6073
 
6074
      Collect_Interfaces (Typ, Ifaces_List);
6075
 
6076
      Elmt := First_Elmt (Ifaces_List);
6077
      while Present (Elmt) loop
6078
         if Is_Ancestor (Node (Elmt), Typ, Use_Full_View => True)
6079
           and then Exclude_Parents
6080
         then
6081
            null;
6082
 
6083
         elsif Node (Elmt) = Iface then
6084
            return True;
6085
         end if;
6086
 
6087
         Next_Elmt (Elmt);
6088
      end loop;
6089
 
6090
      return False;
6091
   end Implements_Interface;
6092
 
6093
   -----------------
6094
   -- In_Instance --
6095
   -----------------
6096
 
6097
   function In_Instance return Boolean is
6098
      Curr_Unit : constant Entity_Id := Cunit_Entity (Current_Sem_Unit);
6099
      S         : Entity_Id;
6100
 
6101
   begin
6102
      S := Current_Scope;
6103
      while Present (S)
6104
        and then S /= Standard_Standard
6105
      loop
6106
         if (Ekind (S) = E_Function
6107
              or else Ekind (S) = E_Package
6108
              or else Ekind (S) = E_Procedure)
6109
           and then Is_Generic_Instance (S)
6110
         then
6111
            --  A child instance is always compiled in the context of a parent
6112
            --  instance. Nevertheless, the actuals are not analyzed in an
6113
            --  instance context. We detect this case by examining the current
6114
            --  compilation unit, which must be a child instance, and checking
6115
            --  that it is not currently on the scope stack.
6116
 
6117
            if Is_Child_Unit (Curr_Unit)
6118
              and then
6119
                Nkind (Unit (Cunit (Current_Sem_Unit)))
6120
                  = N_Package_Instantiation
6121
              and then not In_Open_Scopes (Curr_Unit)
6122
            then
6123
               return False;
6124
            else
6125
               return True;
6126
            end if;
6127
         end if;
6128
 
6129
         S := Scope (S);
6130
      end loop;
6131
 
6132
      return False;
6133
   end In_Instance;
6134
 
6135
   ----------------------
6136
   -- In_Instance_Body --
6137
   ----------------------
6138
 
6139
   function In_Instance_Body return Boolean is
6140
      S : Entity_Id;
6141
 
6142
   begin
6143
      S := Current_Scope;
6144
      while Present (S)
6145
        and then S /= Standard_Standard
6146
      loop
6147
         if (Ekind (S) = E_Function
6148
              or else Ekind (S) = E_Procedure)
6149
           and then Is_Generic_Instance (S)
6150
         then
6151
            return True;
6152
 
6153
         elsif Ekind (S) = E_Package
6154
           and then In_Package_Body (S)
6155
           and then Is_Generic_Instance (S)
6156
         then
6157
            return True;
6158
         end if;
6159
 
6160
         S := Scope (S);
6161
      end loop;
6162
 
6163
      return False;
6164
   end In_Instance_Body;
6165
 
6166
   -----------------------------
6167
   -- In_Instance_Not_Visible --
6168
   -----------------------------
6169
 
6170
   function In_Instance_Not_Visible return Boolean is
6171
      S : Entity_Id;
6172
 
6173
   begin
6174
      S := Current_Scope;
6175
      while Present (S)
6176
        and then S /= Standard_Standard
6177
      loop
6178
         if (Ekind (S) = E_Function
6179
              or else Ekind (S) = E_Procedure)
6180
           and then Is_Generic_Instance (S)
6181
         then
6182
            return True;
6183
 
6184
         elsif Ekind (S) = E_Package
6185
           and then (In_Package_Body (S) or else In_Private_Part (S))
6186
           and then Is_Generic_Instance (S)
6187
         then
6188
            return True;
6189
         end if;
6190
 
6191
         S := Scope (S);
6192
      end loop;
6193
 
6194
      return False;
6195
   end In_Instance_Not_Visible;
6196
 
6197
   ------------------------------
6198
   -- In_Instance_Visible_Part --
6199
   ------------------------------
6200
 
6201
   function In_Instance_Visible_Part return Boolean is
6202
      S : Entity_Id;
6203
 
6204
   begin
6205
      S := Current_Scope;
6206
      while Present (S)
6207
        and then S /= Standard_Standard
6208
      loop
6209
         if Ekind (S) = E_Package
6210
           and then Is_Generic_Instance (S)
6211
           and then not In_Package_Body (S)
6212
           and then not In_Private_Part (S)
6213
         then
6214
            return True;
6215
         end if;
6216
 
6217
         S := Scope (S);
6218
      end loop;
6219
 
6220
      return False;
6221
   end In_Instance_Visible_Part;
6222
 
6223
   ---------------------
6224
   -- In_Package_Body --
6225
   ---------------------
6226
 
6227
   function In_Package_Body return Boolean is
6228
      S : Entity_Id;
6229
 
6230
   begin
6231
      S := Current_Scope;
6232
      while Present (S)
6233
        and then S /= Standard_Standard
6234
      loop
6235
         if Ekind (S) = E_Package
6236
           and then In_Package_Body (S)
6237
         then
6238
            return True;
6239
         else
6240
            S := Scope (S);
6241
         end if;
6242
      end loop;
6243
 
6244
      return False;
6245
   end In_Package_Body;
6246
 
6247
   --------------------------------
6248
   -- In_Parameter_Specification --
6249
   --------------------------------
6250
 
6251
   function In_Parameter_Specification (N : Node_Id) return Boolean is
6252
      PN : Node_Id;
6253
 
6254
   begin
6255
      PN := Parent (N);
6256
      while Present (PN) loop
6257
         if Nkind (PN) = N_Parameter_Specification then
6258
            return True;
6259
         end if;
6260
 
6261
         PN := Parent (PN);
6262
      end loop;
6263
 
6264
      return False;
6265
   end In_Parameter_Specification;
6266
 
6267
   --------------------------------------
6268
   -- In_Subprogram_Or_Concurrent_Unit --
6269
   --------------------------------------
6270
 
6271
   function In_Subprogram_Or_Concurrent_Unit return Boolean is
6272
      E : Entity_Id;
6273
      K : Entity_Kind;
6274
 
6275
   begin
6276
      --  Use scope chain to check successively outer scopes
6277
 
6278
      E := Current_Scope;
6279
      loop
6280
         K := Ekind (E);
6281
 
6282
         if K in Subprogram_Kind
6283
           or else K in Concurrent_Kind
6284
           or else K in Generic_Subprogram_Kind
6285
         then
6286
            return True;
6287
 
6288
         elsif E = Standard_Standard then
6289
            return False;
6290
         end if;
6291
 
6292
         E := Scope (E);
6293
      end loop;
6294
   end In_Subprogram_Or_Concurrent_Unit;
6295
 
6296
   ---------------------
6297
   -- In_Visible_Part --
6298
   ---------------------
6299
 
6300
   function In_Visible_Part (Scope_Id : Entity_Id) return Boolean is
6301
   begin
6302
      return
6303
        Is_Package_Or_Generic_Package (Scope_Id)
6304
          and then In_Open_Scopes (Scope_Id)
6305
          and then not In_Package_Body (Scope_Id)
6306
          and then not In_Private_Part (Scope_Id);
6307
   end In_Visible_Part;
6308
 
6309
   --------------------------------
6310
   -- Incomplete_Or_Private_View --
6311
   --------------------------------
6312
 
6313
   function Incomplete_Or_Private_View (Typ : Entity_Id) return Entity_Id is
6314
      function Inspect_Decls
6315
        (Decls : List_Id;
6316
         Taft  : Boolean := False) return Entity_Id;
6317
      --  Check whether a declarative region contains the incomplete or private
6318
      --  view of Typ.
6319
 
6320
      -------------------
6321
      -- Inspect_Decls --
6322
      -------------------
6323
 
6324
      function Inspect_Decls
6325
        (Decls : List_Id;
6326
         Taft  : Boolean := False) return Entity_Id
6327
      is
6328
         Decl  : Node_Id;
6329
         Match : Node_Id;
6330
 
6331
      begin
6332
         Decl := First (Decls);
6333
         while Present (Decl) loop
6334
            Match := Empty;
6335
 
6336
            if Taft then
6337
               if Nkind (Decl) = N_Incomplete_Type_Declaration then
6338
                  Match := Defining_Identifier (Decl);
6339
               end if;
6340
 
6341
            else
6342
               if Nkind_In (Decl, N_Private_Extension_Declaration,
6343
                                  N_Private_Type_Declaration)
6344
               then
6345
                  Match := Defining_Identifier (Decl);
6346
               end if;
6347
            end if;
6348
 
6349
            if Present (Match)
6350
              and then Present (Full_View (Match))
6351
              and then Full_View (Match) = Typ
6352
            then
6353
               return Match;
6354
            end if;
6355
 
6356
            Next (Decl);
6357
         end loop;
6358
 
6359
         return Empty;
6360
      end Inspect_Decls;
6361
 
6362
      --  Local variables
6363
 
6364
      Prev : Entity_Id;
6365
 
6366
   --  Start of processing for Incomplete_Or_Partial_View
6367
 
6368
   begin
6369
      --  Incomplete type case
6370
 
6371
      Prev := Current_Entity_In_Scope (Typ);
6372
 
6373
      if Present (Prev)
6374
        and then Is_Incomplete_Type (Prev)
6375
        and then Present (Full_View (Prev))
6376
        and then Full_View (Prev) = Typ
6377
      then
6378
         return Prev;
6379
      end if;
6380
 
6381
      --  Private or Taft amendment type case
6382
 
6383
      declare
6384
         Pkg      : constant Entity_Id := Scope (Typ);
6385
         Pkg_Decl : Node_Id := Pkg;
6386
 
6387
      begin
6388
         if Ekind (Pkg) = E_Package then
6389
            while Nkind (Pkg_Decl) /= N_Package_Specification loop
6390
               Pkg_Decl := Parent (Pkg_Decl);
6391
            end loop;
6392
 
6393
            --  It is knows that Typ has a private view, look for it in the
6394
            --  visible declarations of the enclosing scope. A special case
6395
            --  of this is when the two views have been exchanged - the full
6396
            --  appears earlier than the private.
6397
 
6398
            if Has_Private_Declaration (Typ) then
6399
               Prev := Inspect_Decls (Visible_Declarations (Pkg_Decl));
6400
 
6401
               --  Exchanged view case, look in the private declarations
6402
 
6403
               if No (Prev) then
6404
                  Prev := Inspect_Decls (Private_Declarations (Pkg_Decl));
6405
               end if;
6406
 
6407
               return Prev;
6408
 
6409
            --  Otherwise if this is the package body, then Typ is a potential
6410
            --  Taft amendment type. The incomplete view should be located in
6411
            --  the private declarations of the enclosing scope.
6412
 
6413
            elsif In_Package_Body (Pkg) then
6414
               return Inspect_Decls (Private_Declarations (Pkg_Decl), True);
6415
            end if;
6416
         end if;
6417
      end;
6418
 
6419
      --  The type has no incomplete or private view
6420
 
6421
      return Empty;
6422
   end Incomplete_Or_Private_View;
6423
 
6424
   ---------------------------------
6425
   -- Insert_Explicit_Dereference --
6426
   ---------------------------------
6427
 
6428
   procedure Insert_Explicit_Dereference (N : Node_Id) is
6429
      New_Prefix : constant Node_Id := Relocate_Node (N);
6430
      Ent        : Entity_Id := Empty;
6431
      Pref       : Node_Id;
6432
      I          : Interp_Index;
6433
      It         : Interp;
6434
      T          : Entity_Id;
6435
 
6436
   begin
6437
      Save_Interps (N, New_Prefix);
6438
 
6439
      Rewrite (N,
6440
        Make_Explicit_Dereference (Sloc (Parent (N)),
6441
          Prefix => New_Prefix));
6442
 
6443
      Set_Etype (N, Designated_Type (Etype (New_Prefix)));
6444
 
6445
      if Is_Overloaded (New_Prefix) then
6446
 
6447
         --  The dereference is also overloaded, and its interpretations are
6448
         --  the designated types of the interpretations of the original node.
6449
 
6450
         Set_Etype (N, Any_Type);
6451
 
6452
         Get_First_Interp (New_Prefix, I, It);
6453
         while Present (It.Nam) loop
6454
            T := It.Typ;
6455
 
6456
            if Is_Access_Type (T) then
6457
               Add_One_Interp (N, Designated_Type (T), Designated_Type (T));
6458
            end if;
6459
 
6460
            Get_Next_Interp (I, It);
6461
         end loop;
6462
 
6463
         End_Interp_List;
6464
 
6465
      else
6466
         --  Prefix is unambiguous: mark the original prefix (which might
6467
         --  Come_From_Source) as a reference, since the new (relocated) one
6468
         --  won't be taken into account.
6469
 
6470
         if Is_Entity_Name (New_Prefix) then
6471
            Ent := Entity (New_Prefix);
6472
            Pref := New_Prefix;
6473
 
6474
         --  For a retrieval of a subcomponent of some composite object,
6475
         --  retrieve the ultimate entity if there is one.
6476
 
6477
         elsif Nkind (New_Prefix) = N_Selected_Component
6478
           or else Nkind (New_Prefix) = N_Indexed_Component
6479
         then
6480
            Pref := Prefix (New_Prefix);
6481
            while Present (Pref)
6482
              and then
6483
                (Nkind (Pref) = N_Selected_Component
6484
                  or else Nkind (Pref) = N_Indexed_Component)
6485
            loop
6486
               Pref := Prefix (Pref);
6487
            end loop;
6488
 
6489
            if Present (Pref) and then Is_Entity_Name (Pref) then
6490
               Ent := Entity (Pref);
6491
            end if;
6492
         end if;
6493
 
6494
         --  Place the reference on the entity node
6495
 
6496
         if Present (Ent) then
6497
            Generate_Reference (Ent, Pref);
6498
         end if;
6499
      end if;
6500
   end Insert_Explicit_Dereference;
6501
 
6502
   ------------------------------------------
6503
   -- Inspect_Deferred_Constant_Completion --
6504
   ------------------------------------------
6505
 
6506
   procedure Inspect_Deferred_Constant_Completion (Decls : List_Id) is
6507
      Decl   : Node_Id;
6508
 
6509
   begin
6510
      Decl := First (Decls);
6511
      while Present (Decl) loop
6512
 
6513
         --  Deferred constant signature
6514
 
6515
         if Nkind (Decl) = N_Object_Declaration
6516
           and then Constant_Present (Decl)
6517
           and then No (Expression (Decl))
6518
 
6519
            --  No need to check internally generated constants
6520
 
6521
           and then Comes_From_Source (Decl)
6522
 
6523
            --  The constant is not completed. A full object declaration or a
6524
            --  pragma Import complete a deferred constant.
6525
 
6526
           and then not Has_Completion (Defining_Identifier (Decl))
6527
         then
6528
            Error_Msg_N
6529
              ("constant declaration requires initialization expression",
6530
              Defining_Identifier (Decl));
6531
         end if;
6532
 
6533
         Decl := Next (Decl);
6534
      end loop;
6535
   end Inspect_Deferred_Constant_Completion;
6536
 
6537
   -----------------------------
6538
   -- Is_Actual_Out_Parameter --
6539
   -----------------------------
6540
 
6541
   function Is_Actual_Out_Parameter (N : Node_Id) return Boolean is
6542
      Formal : Entity_Id;
6543
      Call   : Node_Id;
6544
   begin
6545
      Find_Actual (N, Formal, Call);
6546
      return Present (Formal) and then Ekind (Formal) = E_Out_Parameter;
6547
   end Is_Actual_Out_Parameter;
6548
 
6549
   -------------------------
6550
   -- Is_Actual_Parameter --
6551
   -------------------------
6552
 
6553
   function Is_Actual_Parameter (N : Node_Id) return Boolean is
6554
      PK : constant Node_Kind := Nkind (Parent (N));
6555
 
6556
   begin
6557
      case PK is
6558
         when N_Parameter_Association =>
6559
            return N = Explicit_Actual_Parameter (Parent (N));
6560
 
6561
         when N_Function_Call | N_Procedure_Call_Statement =>
6562
            return Is_List_Member (N)
6563
              and then
6564
                List_Containing (N) = Parameter_Associations (Parent (N));
6565
 
6566
         when others =>
6567
            return False;
6568
      end case;
6569
   end Is_Actual_Parameter;
6570
 
6571
   --------------------------------
6572
   -- Is_Actual_Tagged_Parameter --
6573
   --------------------------------
6574
 
6575
   function Is_Actual_Tagged_Parameter (N : Node_Id) return Boolean is
6576
      Formal : Entity_Id;
6577
      Call   : Node_Id;
6578
   begin
6579
      Find_Actual (N, Formal, Call);
6580
      return Present (Formal) and then Is_Tagged_Type (Etype (Formal));
6581
   end Is_Actual_Tagged_Parameter;
6582
 
6583
   ---------------------
6584
   -- Is_Aliased_View --
6585
   ---------------------
6586
 
6587
   function Is_Aliased_View (Obj : Node_Id) return Boolean is
6588
      E : Entity_Id;
6589
 
6590
   begin
6591
      if Is_Entity_Name (Obj) then
6592
         E := Entity (Obj);
6593
 
6594
         return
6595
           (Is_Object (E)
6596
             and then
6597
               (Is_Aliased (E)
6598
                 or else (Present (Renamed_Object (E))
6599
                           and then Is_Aliased_View (Renamed_Object (E)))))
6600
 
6601
           or else ((Is_Formal (E)
6602
                      or else Ekind (E) = E_Generic_In_Out_Parameter
6603
                      or else Ekind (E) = E_Generic_In_Parameter)
6604
                    and then Is_Tagged_Type (Etype (E)))
6605
 
6606
           or else (Is_Concurrent_Type (E) and then In_Open_Scopes (E))
6607
 
6608
           --  Current instance of type, either directly or as rewritten
6609
           --  reference to the current object.
6610
 
6611
           or else (Is_Entity_Name (Original_Node (Obj))
6612
                     and then Present (Entity (Original_Node (Obj)))
6613
                     and then Is_Type (Entity (Original_Node (Obj))))
6614
 
6615
           or else (Is_Type (E) and then E = Current_Scope)
6616
 
6617
           or else (Is_Incomplete_Or_Private_Type (E)
6618
                     and then Full_View (E) = Current_Scope)
6619
 
6620
           --  Ada 2012 AI05-0053: the return object of an extended return
6621
           --  statement is aliased if its type is immutably limited.
6622
 
6623
           or else (Is_Return_Object (E)
6624
                     and then Is_Immutably_Limited_Type (Etype (E)));
6625
 
6626
      elsif Nkind (Obj) = N_Selected_Component then
6627
         return Is_Aliased (Entity (Selector_Name (Obj)));
6628
 
6629
      elsif Nkind (Obj) = N_Indexed_Component then
6630
         return Has_Aliased_Components (Etype (Prefix (Obj)))
6631
           or else
6632
             (Is_Access_Type (Etype (Prefix (Obj)))
6633
               and then Has_Aliased_Components
6634
                          (Designated_Type (Etype (Prefix (Obj)))));
6635
 
6636
      elsif Nkind_In (Obj, N_Unchecked_Type_Conversion, N_Type_Conversion) then
6637
         return Is_Tagged_Type (Etype (Obj))
6638
           and then Is_Aliased_View (Expression (Obj));
6639
 
6640
      elsif Nkind (Obj) = N_Explicit_Dereference then
6641
         return Nkind (Original_Node (Obj)) /= N_Function_Call;
6642
 
6643
      else
6644
         return False;
6645
      end if;
6646
   end Is_Aliased_View;
6647
 
6648
   -------------------------
6649
   -- Is_Ancestor_Package --
6650
   -------------------------
6651
 
6652
   function Is_Ancestor_Package
6653
     (E1 : Entity_Id;
6654
      E2 : Entity_Id) return Boolean
6655
   is
6656
      Par : Entity_Id;
6657
 
6658
   begin
6659
      Par := E2;
6660
      while Present (Par)
6661
        and then Par /= Standard_Standard
6662
      loop
6663
         if Par = E1 then
6664
            return True;
6665
         end if;
6666
 
6667
         Par := Scope (Par);
6668
      end loop;
6669
 
6670
      return False;
6671
   end Is_Ancestor_Package;
6672
 
6673
   ----------------------
6674
   -- Is_Atomic_Object --
6675
   ----------------------
6676
 
6677
   function Is_Atomic_Object (N : Node_Id) return Boolean is
6678
 
6679
      function Object_Has_Atomic_Components (N : Node_Id) return Boolean;
6680
      --  Determines if given object has atomic components
6681
 
6682
      function Is_Atomic_Prefix (N : Node_Id) return Boolean;
6683
      --  If prefix is an implicit dereference, examine designated type
6684
 
6685
      ----------------------
6686
      -- Is_Atomic_Prefix --
6687
      ----------------------
6688
 
6689
      function Is_Atomic_Prefix (N : Node_Id) return Boolean is
6690
      begin
6691
         if Is_Access_Type (Etype (N)) then
6692
            return
6693
              Has_Atomic_Components (Designated_Type (Etype (N)));
6694
         else
6695
            return Object_Has_Atomic_Components (N);
6696
         end if;
6697
      end Is_Atomic_Prefix;
6698
 
6699
      ----------------------------------
6700
      -- Object_Has_Atomic_Components --
6701
      ----------------------------------
6702
 
6703
      function Object_Has_Atomic_Components (N : Node_Id) return Boolean is
6704
      begin
6705
         if Has_Atomic_Components (Etype (N))
6706
           or else Is_Atomic (Etype (N))
6707
         then
6708
            return True;
6709
 
6710
         elsif Is_Entity_Name (N)
6711
           and then (Has_Atomic_Components (Entity (N))
6712
                      or else Is_Atomic (Entity (N)))
6713
         then
6714
            return True;
6715
 
6716
         elsif Nkind (N) = N_Indexed_Component
6717
           or else Nkind (N) = N_Selected_Component
6718
         then
6719
            return Is_Atomic_Prefix (Prefix (N));
6720
 
6721
         else
6722
            return False;
6723
         end if;
6724
      end Object_Has_Atomic_Components;
6725
 
6726
   --  Start of processing for Is_Atomic_Object
6727
 
6728
   begin
6729
      --  Predicate is not relevant to subprograms
6730
 
6731
      if Is_Entity_Name (N) and then Is_Overloadable (Entity (N)) then
6732
         return False;
6733
 
6734
      elsif Is_Atomic (Etype (N))
6735
        or else (Is_Entity_Name (N) and then Is_Atomic (Entity (N)))
6736
      then
6737
         return True;
6738
 
6739
      elsif Nkind (N) = N_Indexed_Component
6740
        or else Nkind (N) = N_Selected_Component
6741
      then
6742
         return Is_Atomic_Prefix (Prefix (N));
6743
 
6744
      else
6745
         return False;
6746
      end if;
6747
   end Is_Atomic_Object;
6748
 
6749
   -----------------------------
6750
   -- Is_Concurrent_Interface --
6751
   -----------------------------
6752
 
6753
   function Is_Concurrent_Interface (T : Entity_Id) return Boolean is
6754
   begin
6755
      return
6756
        Is_Interface (T)
6757
          and then
6758
            (Is_Protected_Interface (T)
6759
               or else Is_Synchronized_Interface (T)
6760
               or else Is_Task_Interface (T));
6761
   end Is_Concurrent_Interface;
6762
 
6763
   --------------------------------------
6764
   -- Is_Controlling_Limited_Procedure --
6765
   --------------------------------------
6766
 
6767
   function Is_Controlling_Limited_Procedure
6768
     (Proc_Nam : Entity_Id) return Boolean
6769
   is
6770
      Param_Typ : Entity_Id := Empty;
6771
 
6772
   begin
6773
      if Ekind (Proc_Nam) = E_Procedure
6774
        and then Present (Parameter_Specifications (Parent (Proc_Nam)))
6775
      then
6776
         Param_Typ := Etype (Parameter_Type (First (
6777
                        Parameter_Specifications (Parent (Proc_Nam)))));
6778
 
6779
      --  In this case where an Itype was created, the procedure call has been
6780
      --  rewritten.
6781
 
6782
      elsif Present (Associated_Node_For_Itype (Proc_Nam))
6783
        and then Present (Original_Node (Associated_Node_For_Itype (Proc_Nam)))
6784
        and then
6785
          Present (Parameter_Associations
6786
                     (Associated_Node_For_Itype (Proc_Nam)))
6787
      then
6788
         Param_Typ :=
6789
           Etype (First (Parameter_Associations
6790
                          (Associated_Node_For_Itype (Proc_Nam))));
6791
      end if;
6792
 
6793
      if Present (Param_Typ) then
6794
         return
6795
           Is_Interface (Param_Typ)
6796
             and then Is_Limited_Record (Param_Typ);
6797
      end if;
6798
 
6799
      return False;
6800
   end Is_Controlling_Limited_Procedure;
6801
 
6802
   -----------------------------
6803
   -- Is_CPP_Constructor_Call --
6804
   -----------------------------
6805
 
6806
   function Is_CPP_Constructor_Call (N : Node_Id) return Boolean is
6807
   begin
6808
      return Nkind (N) = N_Function_Call
6809
        and then Is_CPP_Class (Etype (Etype (N)))
6810
        and then Is_Constructor (Entity (Name (N)))
6811
        and then Is_Imported (Entity (Name (N)));
6812
   end Is_CPP_Constructor_Call;
6813
 
6814
   -----------------
6815
   -- Is_Delegate --
6816
   -----------------
6817
 
6818
   function Is_Delegate (T : Entity_Id) return Boolean is
6819
      Desig_Type : Entity_Id;
6820
 
6821
   begin
6822
      if VM_Target /= CLI_Target then
6823
         return False;
6824
      end if;
6825
 
6826
      --  Access-to-subprograms are delegates in CIL
6827
 
6828
      if Ekind (T) = E_Access_Subprogram_Type then
6829
         return True;
6830
      end if;
6831
 
6832
      if Ekind (T) not in Access_Kind then
6833
 
6834
         --  A delegate is a managed pointer. If no designated type is defined
6835
         --  it means that it's not a delegate.
6836
 
6837
         return False;
6838
      end if;
6839
 
6840
      Desig_Type := Etype (Directly_Designated_Type (T));
6841
 
6842
      if not Is_Tagged_Type (Desig_Type) then
6843
         return False;
6844
      end if;
6845
 
6846
      --  Test if the type is inherited from [mscorlib]System.Delegate
6847
 
6848
      while Etype (Desig_Type) /= Desig_Type loop
6849
         if Chars (Scope (Desig_Type)) /= No_Name
6850
           and then Is_Imported (Scope (Desig_Type))
6851
           and then Get_Name_String (Chars (Scope (Desig_Type))) = "delegate"
6852
         then
6853
            return True;
6854
         end if;
6855
 
6856
         Desig_Type := Etype (Desig_Type);
6857
      end loop;
6858
 
6859
      return False;
6860
   end Is_Delegate;
6861
 
6862
   ----------------------------------------------
6863
   -- Is_Dependent_Component_Of_Mutable_Object --
6864
   ----------------------------------------------
6865
 
6866
   function Is_Dependent_Component_Of_Mutable_Object
6867
     (Object : Node_Id) return Boolean
6868
   is
6869
      P           : Node_Id;
6870
      Prefix_Type : Entity_Id;
6871
      P_Aliased   : Boolean := False;
6872
      Comp        : Entity_Id;
6873
 
6874
      function Is_Declared_Within_Variant (Comp : Entity_Id) return Boolean;
6875
      --  Returns True if and only if Comp is declared within a variant part
6876
 
6877
      --------------------------------
6878
      -- Is_Declared_Within_Variant --
6879
      --------------------------------
6880
 
6881
      function Is_Declared_Within_Variant (Comp : Entity_Id) return Boolean is
6882
         Comp_Decl : constant Node_Id   := Parent (Comp);
6883
         Comp_List : constant Node_Id   := Parent (Comp_Decl);
6884
      begin
6885
         return Nkind (Parent (Comp_List)) = N_Variant;
6886
      end Is_Declared_Within_Variant;
6887
 
6888
   --  Start of processing for Is_Dependent_Component_Of_Mutable_Object
6889
 
6890
   begin
6891
      if Is_Variable (Object) then
6892
 
6893
         if Nkind (Object) = N_Selected_Component then
6894
            P := Prefix (Object);
6895
            Prefix_Type := Etype (P);
6896
 
6897
            if Is_Entity_Name (P) then
6898
 
6899
               if Ekind (Entity (P)) = E_Generic_In_Out_Parameter then
6900
                  Prefix_Type := Base_Type (Prefix_Type);
6901
               end if;
6902
 
6903
               if Is_Aliased (Entity (P)) then
6904
                  P_Aliased := True;
6905
               end if;
6906
 
6907
            --  A discriminant check on a selected component may be expanded
6908
            --  into a dereference when removing side-effects. Recover the
6909
            --  original node and its type, which may be unconstrained.
6910
 
6911
            elsif Nkind (P) = N_Explicit_Dereference
6912
              and then not (Comes_From_Source (P))
6913
            then
6914
               P := Original_Node (P);
6915
               Prefix_Type := Etype (P);
6916
 
6917
            else
6918
               --  Check for prefix being an aliased component???
6919
 
6920
               null;
6921
 
6922
            end if;
6923
 
6924
            --  A heap object is constrained by its initial value
6925
 
6926
            --  Ada 2005 (AI-363): Always assume the object could be mutable in
6927
            --  the dereferenced case, since the access value might denote an
6928
            --  unconstrained aliased object, whereas in Ada 95 the designated
6929
            --  object is guaranteed to be constrained. A worst-case assumption
6930
            --  has to apply in Ada 2005 because we can't tell at compile time
6931
            --  whether the object is "constrained by its initial value"
6932
            --  (despite the fact that 3.10.2(26/2) and 8.5.1(5/2) are
6933
            --  semantic rules -- these rules are acknowledged to need fixing).
6934
 
6935
            if Ada_Version < Ada_2005 then
6936
               if Is_Access_Type (Prefix_Type)
6937
                 or else Nkind (P) = N_Explicit_Dereference
6938
               then
6939
                  return False;
6940
               end if;
6941
 
6942
            elsif Ada_Version >= Ada_2005 then
6943
               if Is_Access_Type (Prefix_Type) then
6944
 
6945
                  --  If the access type is pool-specific, and there is no
6946
                  --  constrained partial view of the designated type, then the
6947
                  --  designated object is known to be constrained.
6948
 
6949
                  if Ekind (Prefix_Type) = E_Access_Type
6950
                    and then not Effectively_Has_Constrained_Partial_View
6951
                                   (Typ  => Designated_Type (Prefix_Type),
6952
                                    Scop => Current_Scope)
6953
                  then
6954
                     return False;
6955
 
6956
                  --  Otherwise (general access type, or there is a constrained
6957
                  --  partial view of the designated type), we need to check
6958
                  --  based on the designated type.
6959
 
6960
                  else
6961
                     Prefix_Type := Designated_Type (Prefix_Type);
6962
                  end if;
6963
               end if;
6964
            end if;
6965
 
6966
            Comp :=
6967
              Original_Record_Component (Entity (Selector_Name (Object)));
6968
 
6969
            --  As per AI-0017, the renaming is illegal in a generic body, even
6970
            --  if the subtype is indefinite.
6971
 
6972
            --  Ada 2005 (AI-363): In Ada 2005 an aliased object can be mutable
6973
 
6974
            if not Is_Constrained (Prefix_Type)
6975
              and then (not Is_Indefinite_Subtype (Prefix_Type)
6976
                         or else
6977
                          (Is_Generic_Type (Prefix_Type)
6978
                            and then Ekind (Current_Scope) = E_Generic_Package
6979
                            and then In_Package_Body (Current_Scope)))
6980
 
6981
              and then (Is_Declared_Within_Variant (Comp)
6982
                          or else Has_Discriminant_Dependent_Constraint (Comp))
6983
              and then (not P_Aliased or else Ada_Version >= Ada_2005)
6984
            then
6985
               return True;
6986
 
6987
            else
6988
               return
6989
                 Is_Dependent_Component_Of_Mutable_Object (Prefix (Object));
6990
 
6991
            end if;
6992
 
6993
         elsif Nkind (Object) = N_Indexed_Component
6994
           or else Nkind (Object) = N_Slice
6995
         then
6996
            return Is_Dependent_Component_Of_Mutable_Object (Prefix (Object));
6997
 
6998
         --  A type conversion that Is_Variable is a view conversion:
6999
         --  go back to the denoted object.
7000
 
7001
         elsif Nkind (Object) = N_Type_Conversion then
7002
            return
7003
              Is_Dependent_Component_Of_Mutable_Object (Expression (Object));
7004
         end if;
7005
      end if;
7006
 
7007
      return False;
7008
   end Is_Dependent_Component_Of_Mutable_Object;
7009
 
7010
   ---------------------
7011
   -- Is_Dereferenced --
7012
   ---------------------
7013
 
7014
   function Is_Dereferenced (N : Node_Id) return Boolean is
7015
      P : constant Node_Id := Parent (N);
7016
   begin
7017
      return
7018
         (Nkind (P) = N_Selected_Component
7019
            or else
7020
          Nkind (P) = N_Explicit_Dereference
7021
            or else
7022
          Nkind (P) = N_Indexed_Component
7023
            or else
7024
          Nkind (P) = N_Slice)
7025
        and then Prefix (P) = N;
7026
   end Is_Dereferenced;
7027
 
7028
   ----------------------
7029
   -- Is_Descendent_Of --
7030
   ----------------------
7031
 
7032
   function Is_Descendent_Of (T1 : Entity_Id; T2 : Entity_Id) return Boolean is
7033
      T    : Entity_Id;
7034
      Etyp : Entity_Id;
7035
 
7036
   begin
7037
      pragma Assert (Nkind (T1) in N_Entity);
7038
      pragma Assert (Nkind (T2) in N_Entity);
7039
 
7040
      T := Base_Type (T1);
7041
 
7042
      --  Immediate return if the types match
7043
 
7044
      if T = T2 then
7045
         return True;
7046
 
7047
      --  Comment needed here ???
7048
 
7049
      elsif Ekind (T) = E_Class_Wide_Type then
7050
         return Etype (T) = T2;
7051
 
7052
      --  All other cases
7053
 
7054
      else
7055
         loop
7056
            Etyp := Etype (T);
7057
 
7058
            --  Done if we found the type we are looking for
7059
 
7060
            if Etyp = T2 then
7061
               return True;
7062
 
7063
            --  Done if no more derivations to check
7064
 
7065
            elsif T = T1
7066
              or else T = Etyp
7067
            then
7068
               return False;
7069
 
7070
            --  Following test catches error cases resulting from prev errors
7071
 
7072
            elsif No (Etyp) then
7073
               return False;
7074
 
7075
            elsif Is_Private_Type (T) and then Etyp = Full_View (T) then
7076
               return False;
7077
 
7078
            elsif Is_Private_Type (Etyp) and then Full_View (Etyp) = T then
7079
               return False;
7080
            end if;
7081
 
7082
            T := Base_Type (Etyp);
7083
         end loop;
7084
      end if;
7085
   end Is_Descendent_Of;
7086
 
7087
   ----------------------------
7088
   -- Is_Expression_Function --
7089
   ----------------------------
7090
 
7091
   function Is_Expression_Function (Subp : Entity_Id) return Boolean is
7092
      Decl : constant Node_Id := Unit_Declaration_Node (Subp);
7093
 
7094
   begin
7095
      return Ekind (Subp) = E_Function
7096
        and then Nkind (Decl) = N_Subprogram_Declaration
7097
        and then
7098
          (Nkind (Original_Node (Decl)) = N_Expression_Function
7099
            or else
7100
              (Present (Corresponding_Body (Decl))
7101
                and then
7102
                  Nkind (Original_Node
7103
                     (Unit_Declaration_Node (Corresponding_Body (Decl))))
7104
                 = N_Expression_Function));
7105
   end Is_Expression_Function;
7106
 
7107
   --------------
7108
   -- Is_False --
7109
   --------------
7110
 
7111
   function Is_False (U : Uint) return Boolean is
7112
   begin
7113
      return (U = 0);
7114
   end Is_False;
7115
 
7116
   ---------------------------
7117
   -- Is_Fixed_Model_Number --
7118
   ---------------------------
7119
 
7120
   function Is_Fixed_Model_Number (U : Ureal; T : Entity_Id) return Boolean is
7121
      S : constant Ureal := Small_Value (T);
7122
      M : Urealp.Save_Mark;
7123
      R : Boolean;
7124
   begin
7125
      M := Urealp.Mark;
7126
      R := (U = UR_Trunc (U / S) * S);
7127
      Urealp.Release (M);
7128
      return R;
7129
   end Is_Fixed_Model_Number;
7130
 
7131
   -------------------------------
7132
   -- Is_Fully_Initialized_Type --
7133
   -------------------------------
7134
 
7135
   function Is_Fully_Initialized_Type (Typ : Entity_Id) return Boolean is
7136
   begin
7137
      --  In Ada2012, a scalar type with an aspect Default_Value
7138
      --  is fully initialized.
7139
 
7140
      if Is_Scalar_Type (Typ) then
7141
         return Ada_Version >= Ada_2012 and then Has_Default_Aspect (Typ);
7142
 
7143
      elsif Is_Access_Type (Typ) then
7144
         return True;
7145
 
7146
      elsif Is_Array_Type (Typ) then
7147
         if Is_Fully_Initialized_Type (Component_Type (Typ))
7148
           or else (Ada_Version >= Ada_2012 and then Has_Default_Aspect (Typ))
7149
         then
7150
            return True;
7151
         end if;
7152
 
7153
         --  An interesting case, if we have a constrained type one of whose
7154
         --  bounds is known to be null, then there are no elements to be
7155
         --  initialized, so all the elements are initialized!
7156
 
7157
         if Is_Constrained (Typ) then
7158
            declare
7159
               Indx     : Node_Id;
7160
               Indx_Typ : Entity_Id;
7161
               Lbd, Hbd : Node_Id;
7162
 
7163
            begin
7164
               Indx := First_Index (Typ);
7165
               while Present (Indx) loop
7166
                  if Etype (Indx) = Any_Type then
7167
                     return False;
7168
 
7169
                  --  If index is a range, use directly
7170
 
7171
                  elsif Nkind (Indx) = N_Range then
7172
                     Lbd := Low_Bound  (Indx);
7173
                     Hbd := High_Bound (Indx);
7174
 
7175
                  else
7176
                     Indx_Typ := Etype (Indx);
7177
 
7178
                     if Is_Private_Type (Indx_Typ)  then
7179
                        Indx_Typ := Full_View (Indx_Typ);
7180
                     end if;
7181
 
7182
                     if No (Indx_Typ) or else Etype (Indx_Typ) = Any_Type then
7183
                        return False;
7184
                     else
7185
                        Lbd := Type_Low_Bound  (Indx_Typ);
7186
                        Hbd := Type_High_Bound (Indx_Typ);
7187
                     end if;
7188
                  end if;
7189
 
7190
                  if Compile_Time_Known_Value (Lbd)
7191
                    and then Compile_Time_Known_Value (Hbd)
7192
                  then
7193
                     if Expr_Value (Hbd) < Expr_Value (Lbd) then
7194
                        return True;
7195
                     end if;
7196
                  end if;
7197
 
7198
                  Next_Index (Indx);
7199
               end loop;
7200
            end;
7201
         end if;
7202
 
7203
         --  If no null indexes, then type is not fully initialized
7204
 
7205
         return False;
7206
 
7207
      --  Record types
7208
 
7209
      elsif Is_Record_Type (Typ) then
7210
         if Has_Discriminants (Typ)
7211
           and then
7212
             Present (Discriminant_Default_Value (First_Discriminant (Typ)))
7213
           and then Is_Fully_Initialized_Variant (Typ)
7214
         then
7215
            return True;
7216
         end if;
7217
 
7218
         --  Controlled records are considered to be fully initialized if
7219
         --  there is a user defined Initialize routine. This may not be
7220
         --  entirely correct, but as the spec notes, we are guessing here
7221
         --  what is best from the point of view of issuing warnings.
7222
 
7223
         if Is_Controlled (Typ) then
7224
            declare
7225
               Utyp : constant Entity_Id := Underlying_Type (Typ);
7226
 
7227
            begin
7228
               if Present (Utyp) then
7229
                  declare
7230
                     Init : constant Entity_Id :=
7231
                              (Find_Prim_Op
7232
                                 (Underlying_Type (Typ), Name_Initialize));
7233
 
7234
                  begin
7235
                     if Present (Init)
7236
                       and then Comes_From_Source (Init)
7237
                       and then not
7238
                         Is_Predefined_File_Name
7239
                           (File_Name (Get_Source_File_Index (Sloc (Init))))
7240
                     then
7241
                        return True;
7242
 
7243
                     elsif Has_Null_Extension (Typ)
7244
                        and then
7245
                          Is_Fully_Initialized_Type
7246
                            (Etype (Base_Type (Typ)))
7247
                     then
7248
                        return True;
7249
                     end if;
7250
                  end;
7251
               end if;
7252
            end;
7253
         end if;
7254
 
7255
         --  Otherwise see if all record components are initialized
7256
 
7257
         declare
7258
            Ent : Entity_Id;
7259
 
7260
         begin
7261
            Ent := First_Entity (Typ);
7262
            while Present (Ent) loop
7263
               if Ekind (Ent) = E_Component
7264
                 and then (No (Parent (Ent))
7265
                             or else No (Expression (Parent (Ent))))
7266
                 and then not Is_Fully_Initialized_Type (Etype (Ent))
7267
 
7268
                  --  Special VM case for tag components, which need to be
7269
                  --  defined in this case, but are never initialized as VMs
7270
                  --  are using other dispatching mechanisms. Ignore this
7271
                  --  uninitialized case. Note that this applies both to the
7272
                  --  uTag entry and the main vtable pointer (CPP_Class case).
7273
 
7274
                 and then (Tagged_Type_Expansion or else not Is_Tag (Ent))
7275
               then
7276
                  return False;
7277
               end if;
7278
 
7279
               Next_Entity (Ent);
7280
            end loop;
7281
         end;
7282
 
7283
         --  No uninitialized components, so type is fully initialized.
7284
         --  Note that this catches the case of no components as well.
7285
 
7286
         return True;
7287
 
7288
      elsif Is_Concurrent_Type (Typ) then
7289
         return True;
7290
 
7291
      elsif Is_Private_Type (Typ) then
7292
         declare
7293
            U : constant Entity_Id := Underlying_Type (Typ);
7294
 
7295
         begin
7296
            if No (U) then
7297
               return False;
7298
            else
7299
               return Is_Fully_Initialized_Type (U);
7300
            end if;
7301
         end;
7302
 
7303
      else
7304
         return False;
7305
      end if;
7306
   end Is_Fully_Initialized_Type;
7307
 
7308
   ----------------------------------
7309
   -- Is_Fully_Initialized_Variant --
7310
   ----------------------------------
7311
 
7312
   function Is_Fully_Initialized_Variant (Typ : Entity_Id) return Boolean is
7313
      Loc           : constant Source_Ptr := Sloc (Typ);
7314
      Constraints   : constant List_Id    := New_List;
7315
      Components    : constant Elist_Id   := New_Elmt_List;
7316
      Comp_Elmt     : Elmt_Id;
7317
      Comp_Id       : Node_Id;
7318
      Comp_List     : Node_Id;
7319
      Discr         : Entity_Id;
7320
      Discr_Val     : Node_Id;
7321
 
7322
      Report_Errors : Boolean;
7323
      pragma Warnings (Off, Report_Errors);
7324
 
7325
   begin
7326
      if Serious_Errors_Detected > 0 then
7327
         return False;
7328
      end if;
7329
 
7330
      if Is_Record_Type (Typ)
7331
        and then Nkind (Parent (Typ)) = N_Full_Type_Declaration
7332
        and then Nkind (Type_Definition (Parent (Typ))) = N_Record_Definition
7333
      then
7334
         Comp_List := Component_List (Type_Definition (Parent (Typ)));
7335
 
7336
         Discr := First_Discriminant (Typ);
7337
         while Present (Discr) loop
7338
            if Nkind (Parent (Discr)) = N_Discriminant_Specification then
7339
               Discr_Val := Expression (Parent (Discr));
7340
 
7341
               if Present (Discr_Val)
7342
                 and then Is_OK_Static_Expression (Discr_Val)
7343
               then
7344
                  Append_To (Constraints,
7345
                    Make_Component_Association (Loc,
7346
                      Choices    => New_List (New_Occurrence_Of (Discr, Loc)),
7347
                      Expression => New_Copy (Discr_Val)));
7348
               else
7349
                  return False;
7350
               end if;
7351
            else
7352
               return False;
7353
            end if;
7354
 
7355
            Next_Discriminant (Discr);
7356
         end loop;
7357
 
7358
         Gather_Components
7359
           (Typ           => Typ,
7360
            Comp_List     => Comp_List,
7361
            Governed_By   => Constraints,
7362
            Into          => Components,
7363
            Report_Errors => Report_Errors);
7364
 
7365
         --  Check that each component present is fully initialized
7366
 
7367
         Comp_Elmt := First_Elmt (Components);
7368
         while Present (Comp_Elmt) loop
7369
            Comp_Id := Node (Comp_Elmt);
7370
 
7371
            if Ekind (Comp_Id) = E_Component
7372
              and then (No (Parent (Comp_Id))
7373
                         or else No (Expression (Parent (Comp_Id))))
7374
              and then not Is_Fully_Initialized_Type (Etype (Comp_Id))
7375
            then
7376
               return False;
7377
            end if;
7378
 
7379
            Next_Elmt (Comp_Elmt);
7380
         end loop;
7381
 
7382
         return True;
7383
 
7384
      elsif Is_Private_Type (Typ) then
7385
         declare
7386
            U : constant Entity_Id := Underlying_Type (Typ);
7387
 
7388
         begin
7389
            if No (U) then
7390
               return False;
7391
            else
7392
               return Is_Fully_Initialized_Variant (U);
7393
            end if;
7394
         end;
7395
      else
7396
         return False;
7397
      end if;
7398
   end Is_Fully_Initialized_Variant;
7399
 
7400
   ----------------------------
7401
   -- Is_Inherited_Operation --
7402
   ----------------------------
7403
 
7404
   function Is_Inherited_Operation (E : Entity_Id) return Boolean is
7405
      pragma Assert (Is_Overloadable (E));
7406
      Kind : constant Node_Kind := Nkind (Parent (E));
7407
   begin
7408
      return Kind = N_Full_Type_Declaration
7409
        or else Kind = N_Private_Extension_Declaration
7410
        or else Kind = N_Subtype_Declaration
7411
        or else (Ekind (E) = E_Enumeration_Literal
7412
                  and then Is_Derived_Type (Etype (E)));
7413
   end Is_Inherited_Operation;
7414
 
7415
   -------------------------------------
7416
   -- Is_Inherited_Operation_For_Type --
7417
   -------------------------------------
7418
 
7419
   function Is_Inherited_Operation_For_Type
7420
     (E   : Entity_Id;
7421
      Typ : Entity_Id) return Boolean
7422
   is
7423
   begin
7424
      return Is_Inherited_Operation (E)
7425
        and then Etype (Parent (E)) = Typ;
7426
   end Is_Inherited_Operation_For_Type;
7427
 
7428
   -----------------
7429
   -- Is_Iterator --
7430
   -----------------
7431
 
7432
   function Is_Iterator (Typ : Entity_Id) return Boolean is
7433
      Ifaces_List : Elist_Id;
7434
      Iface_Elmt  : Elmt_Id;
7435
      Iface       : Entity_Id;
7436
 
7437
   begin
7438
      if Is_Class_Wide_Type (Typ)
7439
        and then
7440
          (Chars (Etype (Typ)) = Name_Forward_Iterator
7441
             or else
7442
           Chars (Etype (Typ)) = Name_Reversible_Iterator)
7443
        and then
7444
          Is_Predefined_File_Name
7445
            (Unit_File_Name (Get_Source_Unit (Etype (Typ))))
7446
      then
7447
         return True;
7448
 
7449
      elsif not Is_Tagged_Type (Typ) or else not Is_Derived_Type (Typ) then
7450
         return False;
7451
 
7452
      else
7453
         Collect_Interfaces (Typ, Ifaces_List);
7454
 
7455
         Iface_Elmt := First_Elmt (Ifaces_List);
7456
         while Present (Iface_Elmt) loop
7457
            Iface := Node (Iface_Elmt);
7458
            if Chars (Iface) = Name_Forward_Iterator
7459
              and then
7460
                Is_Predefined_File_Name
7461
                  (Unit_File_Name (Get_Source_Unit (Iface)))
7462
            then
7463
               return True;
7464
            end if;
7465
 
7466
            Next_Elmt (Iface_Elmt);
7467
         end loop;
7468
 
7469
         return False;
7470
      end if;
7471
   end Is_Iterator;
7472
 
7473
   ------------
7474
   -- Is_LHS --
7475
   ------------
7476
 
7477
   --  We seem to have a lot of overlapping functions that do similar things
7478
   --  (testing for left hand sides or lvalues???). Anyway, since this one is
7479
   --  purely syntactic, it should be in Sem_Aux I would think???
7480
 
7481
   function Is_LHS (N : Node_Id) return Boolean is
7482
      P : constant Node_Id := Parent (N);
7483
 
7484
   begin
7485
      if Nkind (P) = N_Assignment_Statement then
7486
         return Name (P) = N;
7487
 
7488
      elsif
7489
        Nkind_In (P, N_Indexed_Component, N_Selected_Component, N_Slice)
7490
      then
7491
         return N = Prefix (P) and then Is_LHS (P);
7492
 
7493
      else
7494
         return False;
7495
      end if;
7496
   end Is_LHS;
7497
 
7498
   -----------------------------
7499
   -- Is_Library_Level_Entity --
7500
   -----------------------------
7501
 
7502
   function Is_Library_Level_Entity (E : Entity_Id) return Boolean is
7503
   begin
7504
      --  The following is a small optimization, and it also properly handles
7505
      --  discriminals, which in task bodies might appear in expressions before
7506
      --  the corresponding procedure has been created, and which therefore do
7507
      --  not have an assigned scope.
7508
 
7509
      if Is_Formal (E) then
7510
         return False;
7511
      end if;
7512
 
7513
      --  Normal test is simply that the enclosing dynamic scope is Standard
7514
 
7515
      return Enclosing_Dynamic_Scope (E) = Standard_Standard;
7516
   end Is_Library_Level_Entity;
7517
 
7518
   --------------------------------
7519
   -- Is_Limited_Class_Wide_Type --
7520
   --------------------------------
7521
 
7522
   function Is_Limited_Class_Wide_Type (Typ : Entity_Id) return Boolean is
7523
   begin
7524
      return
7525
        Is_Class_Wide_Type (Typ)
7526
          and then Is_Limited_Type (Typ);
7527
   end Is_Limited_Class_Wide_Type;
7528
 
7529
   ---------------------------------
7530
   -- Is_Local_Variable_Reference --
7531
   ---------------------------------
7532
 
7533
   function Is_Local_Variable_Reference (Expr : Node_Id) return Boolean is
7534
   begin
7535
      if not Is_Entity_Name (Expr) then
7536
         return False;
7537
 
7538
      else
7539
         declare
7540
            Ent : constant Entity_Id := Entity (Expr);
7541
            Sub : constant Entity_Id := Enclosing_Subprogram (Ent);
7542
         begin
7543
            if not Ekind_In (Ent, E_Variable, E_In_Out_Parameter) then
7544
               return False;
7545
            else
7546
               return Present (Sub) and then Sub = Current_Subprogram;
7547
            end if;
7548
         end;
7549
      end if;
7550
   end Is_Local_Variable_Reference;
7551
 
7552
   -------------------------
7553
   -- Is_Object_Reference --
7554
   -------------------------
7555
 
7556
   function Is_Object_Reference (N : Node_Id) return Boolean is
7557
   begin
7558
      if Is_Entity_Name (N) then
7559
         return Present (Entity (N)) and then Is_Object (Entity (N));
7560
 
7561
      else
7562
         case Nkind (N) is
7563
            when N_Indexed_Component | N_Slice =>
7564
               return
7565
                 Is_Object_Reference (Prefix (N))
7566
                   or else Is_Access_Type (Etype (Prefix (N)));
7567
 
7568
            --  In Ada 95, a function call is a constant object; a procedure
7569
            --  call is not.
7570
 
7571
            when N_Function_Call =>
7572
               return Etype (N) /= Standard_Void_Type;
7573
 
7574
            --  A reference to the stream attribute Input is a function call
7575
 
7576
            when N_Attribute_Reference =>
7577
               return Attribute_Name (N) = Name_Input;
7578
 
7579
            when N_Selected_Component =>
7580
               return
7581
                 Is_Object_Reference (Selector_Name (N))
7582
                   and then
7583
                     (Is_Object_Reference (Prefix (N))
7584
                        or else Is_Access_Type (Etype (Prefix (N))));
7585
 
7586
            when N_Explicit_Dereference =>
7587
               return True;
7588
 
7589
            --  A view conversion of a tagged object is an object reference
7590
 
7591
            when N_Type_Conversion =>
7592
               return Is_Tagged_Type (Etype (Subtype_Mark (N)))
7593
                 and then Is_Tagged_Type (Etype (Expression (N)))
7594
                 and then Is_Object_Reference (Expression (N));
7595
 
7596
            --  An unchecked type conversion is considered to be an object if
7597
            --  the operand is an object (this construction arises only as a
7598
            --  result of expansion activities).
7599
 
7600
            when N_Unchecked_Type_Conversion =>
7601
               return True;
7602
 
7603
            when others =>
7604
               return False;
7605
         end case;
7606
      end if;
7607
   end Is_Object_Reference;
7608
 
7609
   -----------------------------------
7610
   -- Is_OK_Variable_For_Out_Formal --
7611
   -----------------------------------
7612
 
7613
   function Is_OK_Variable_For_Out_Formal (AV : Node_Id) return Boolean is
7614
   begin
7615
      Note_Possible_Modification (AV, Sure => True);
7616
 
7617
      --  We must reject parenthesized variable names. The check for
7618
      --  Comes_From_Source is present because there are currently
7619
      --  cases where the compiler violates this rule (e.g. passing
7620
      --  a task object to its controlled Initialize routine).
7621
 
7622
      if Paren_Count (AV) > 0 and then Comes_From_Source (AV) then
7623
         return False;
7624
 
7625
      --  A variable is always allowed
7626
 
7627
      elsif Is_Variable (AV) then
7628
         return True;
7629
 
7630
      --  Unchecked conversions are allowed only if they come from the
7631
      --  generated code, which sometimes uses unchecked conversions for out
7632
      --  parameters in cases where code generation is unaffected. We tell
7633
      --  source unchecked conversions by seeing if they are rewrites of an
7634
      --  original Unchecked_Conversion function call, or of an explicit
7635
      --  conversion of a function call.
7636
 
7637
      elsif Nkind (AV) = N_Unchecked_Type_Conversion then
7638
         if Nkind (Original_Node (AV)) = N_Function_Call then
7639
            return False;
7640
 
7641
         elsif Comes_From_Source (AV)
7642
           and then Nkind (Original_Node (Expression (AV))) = N_Function_Call
7643
         then
7644
            return False;
7645
 
7646
         elsif Nkind (Original_Node (AV)) = N_Type_Conversion then
7647
            return Is_OK_Variable_For_Out_Formal (Expression (AV));
7648
 
7649
         else
7650
            return True;
7651
         end if;
7652
 
7653
      --  Normal type conversions are allowed if argument is a variable
7654
 
7655
      elsif Nkind (AV) = N_Type_Conversion then
7656
         if Is_Variable (Expression (AV))
7657
           and then Paren_Count (Expression (AV)) = 0
7658
         then
7659
            Note_Possible_Modification (Expression (AV), Sure => True);
7660
            return True;
7661
 
7662
         --  We also allow a non-parenthesized expression that raises
7663
         --  constraint error if it rewrites what used to be a variable
7664
 
7665
         elsif Raises_Constraint_Error (Expression (AV))
7666
            and then Paren_Count (Expression (AV)) = 0
7667
            and then Is_Variable (Original_Node (Expression (AV)))
7668
         then
7669
            return True;
7670
 
7671
         --  Type conversion of something other than a variable
7672
 
7673
         else
7674
            return False;
7675
         end if;
7676
 
7677
      --  If this node is rewritten, then test the original form, if that is
7678
      --  OK, then we consider the rewritten node OK (for example, if the
7679
      --  original node is a conversion, then Is_Variable will not be true
7680
      --  but we still want to allow the conversion if it converts a variable).
7681
 
7682
      elsif Original_Node (AV) /= AV then
7683
 
7684
         --  In Ada 2012, the explicit dereference may be a rewritten call to a
7685
         --  Reference function.
7686
 
7687
         if Ada_Version >= Ada_2012
7688
           and then Nkind (Original_Node (AV)) = N_Function_Call
7689
           and then
7690
             Has_Implicit_Dereference (Etype (Name (Original_Node (AV))))
7691
         then
7692
            return True;
7693
 
7694
         else
7695
            return Is_OK_Variable_For_Out_Formal (Original_Node (AV));
7696
         end if;
7697
 
7698
      --  All other non-variables are rejected
7699
 
7700
      else
7701
         return False;
7702
      end if;
7703
   end Is_OK_Variable_For_Out_Formal;
7704
 
7705
   -----------------------------------
7706
   -- Is_Partially_Initialized_Type --
7707
   -----------------------------------
7708
 
7709
   function Is_Partially_Initialized_Type
7710
     (Typ              : Entity_Id;
7711
      Include_Implicit : Boolean := True) return Boolean
7712
   is
7713
   begin
7714
      if Is_Scalar_Type (Typ) then
7715
         return False;
7716
 
7717
      elsif Is_Access_Type (Typ) then
7718
         return Include_Implicit;
7719
 
7720
      elsif Is_Array_Type (Typ) then
7721
 
7722
         --  If component type is partially initialized, so is array type
7723
 
7724
         if Is_Partially_Initialized_Type
7725
              (Component_Type (Typ), Include_Implicit)
7726
         then
7727
            return True;
7728
 
7729
         --  Otherwise we are only partially initialized if we are fully
7730
         --  initialized (this is the empty array case, no point in us
7731
         --  duplicating that code here).
7732
 
7733
         else
7734
            return Is_Fully_Initialized_Type (Typ);
7735
         end if;
7736
 
7737
      elsif Is_Record_Type (Typ) then
7738
 
7739
         --  A discriminated type is always partially initialized if in
7740
         --  all mode
7741
 
7742
         if Has_Discriminants (Typ) and then Include_Implicit then
7743
            return True;
7744
 
7745
         --  A tagged type is always partially initialized
7746
 
7747
         elsif Is_Tagged_Type (Typ) then
7748
            return True;
7749
 
7750
         --  Case of non-discriminated record
7751
 
7752
         else
7753
            declare
7754
               Ent : Entity_Id;
7755
 
7756
               Component_Present : Boolean := False;
7757
               --  Set True if at least one component is present. If no
7758
               --  components are present, then record type is fully
7759
               --  initialized (another odd case, like the null array).
7760
 
7761
            begin
7762
               --  Loop through components
7763
 
7764
               Ent := First_Entity (Typ);
7765
               while Present (Ent) loop
7766
                  if Ekind (Ent) = E_Component then
7767
                     Component_Present := True;
7768
 
7769
                     --  If a component has an initialization expression then
7770
                     --  the enclosing record type is partially initialized
7771
 
7772
                     if Present (Parent (Ent))
7773
                       and then Present (Expression (Parent (Ent)))
7774
                     then
7775
                        return True;
7776
 
7777
                     --  If a component is of a type which is itself partially
7778
                     --  initialized, then the enclosing record type is also.
7779
 
7780
                     elsif Is_Partially_Initialized_Type
7781
                             (Etype (Ent), Include_Implicit)
7782
                     then
7783
                        return True;
7784
                     end if;
7785
                  end if;
7786
 
7787
                  Next_Entity (Ent);
7788
               end loop;
7789
 
7790
               --  No initialized components found. If we found any components
7791
               --  they were all uninitialized so the result is false.
7792
 
7793
               if Component_Present then
7794
                  return False;
7795
 
7796
               --  But if we found no components, then all the components are
7797
               --  initialized so we consider the type to be initialized.
7798
 
7799
               else
7800
                  return True;
7801
               end if;
7802
            end;
7803
         end if;
7804
 
7805
      --  Concurrent types are always fully initialized
7806
 
7807
      elsif Is_Concurrent_Type (Typ) then
7808
         return True;
7809
 
7810
      --  For a private type, go to underlying type. If there is no underlying
7811
      --  type then just assume this partially initialized. Not clear if this
7812
      --  can happen in a non-error case, but no harm in testing for this.
7813
 
7814
      elsif Is_Private_Type (Typ) then
7815
         declare
7816
            U : constant Entity_Id := Underlying_Type (Typ);
7817
         begin
7818
            if No (U) then
7819
               return True;
7820
            else
7821
               return Is_Partially_Initialized_Type (U, Include_Implicit);
7822
            end if;
7823
         end;
7824
 
7825
      --  For any other type (are there any?) assume partially initialized
7826
 
7827
      else
7828
         return True;
7829
      end if;
7830
   end Is_Partially_Initialized_Type;
7831
 
7832
   ------------------------------------
7833
   -- Is_Potentially_Persistent_Type --
7834
   ------------------------------------
7835
 
7836
   function Is_Potentially_Persistent_Type (T : Entity_Id) return Boolean is
7837
      Comp : Entity_Id;
7838
      Indx : Node_Id;
7839
 
7840
   begin
7841
      --  For private type, test corresponding full type
7842
 
7843
      if Is_Private_Type (T) then
7844
         return Is_Potentially_Persistent_Type (Full_View (T));
7845
 
7846
      --  Scalar types are potentially persistent
7847
 
7848
      elsif Is_Scalar_Type (T) then
7849
         return True;
7850
 
7851
      --  Record type is potentially persistent if not tagged and the types of
7852
      --  all it components are potentially persistent, and no component has
7853
      --  an initialization expression.
7854
 
7855
      elsif Is_Record_Type (T)
7856
        and then not Is_Tagged_Type (T)
7857
        and then not Is_Partially_Initialized_Type (T)
7858
      then
7859
         Comp := First_Component (T);
7860
         while Present (Comp) loop
7861
            if not Is_Potentially_Persistent_Type (Etype (Comp)) then
7862
               return False;
7863
            else
7864
               Next_Entity (Comp);
7865
            end if;
7866
         end loop;
7867
 
7868
         return True;
7869
 
7870
      --  Array type is potentially persistent if its component type is
7871
      --  potentially persistent and if all its constraints are static.
7872
 
7873
      elsif Is_Array_Type (T) then
7874
         if not Is_Potentially_Persistent_Type (Component_Type (T)) then
7875
            return False;
7876
         end if;
7877
 
7878
         Indx := First_Index (T);
7879
         while Present (Indx) loop
7880
            if not Is_OK_Static_Subtype (Etype (Indx)) then
7881
               return False;
7882
            else
7883
               Next_Index (Indx);
7884
            end if;
7885
         end loop;
7886
 
7887
         return True;
7888
 
7889
      --  All other types are not potentially persistent
7890
 
7891
      else
7892
         return False;
7893
      end if;
7894
   end Is_Potentially_Persistent_Type;
7895
 
7896
   ---------------------------------
7897
   -- Is_Protected_Self_Reference --
7898
   ---------------------------------
7899
 
7900
   function Is_Protected_Self_Reference (N : Node_Id) return Boolean is
7901
 
7902
      function In_Access_Definition (N : Node_Id) return Boolean;
7903
      --  Returns true if N belongs to an access definition
7904
 
7905
      --------------------------
7906
      -- In_Access_Definition --
7907
      --------------------------
7908
 
7909
      function In_Access_Definition (N : Node_Id) return Boolean is
7910
         P : Node_Id;
7911
 
7912
      begin
7913
         P := Parent (N);
7914
         while Present (P) loop
7915
            if Nkind (P) = N_Access_Definition then
7916
               return True;
7917
            end if;
7918
 
7919
            P := Parent (P);
7920
         end loop;
7921
 
7922
         return False;
7923
      end In_Access_Definition;
7924
 
7925
   --  Start of processing for Is_Protected_Self_Reference
7926
 
7927
   begin
7928
      --  Verify that prefix is analyzed and has the proper form. Note that
7929
      --  the attributes Elab_Spec, Elab_Body, Elab_Subp_Body and UET_Address,
7930
      --  which also produce the address of an entity, do not analyze their
7931
      --  prefix because they denote entities that are not necessarily visible.
7932
      --  Neither of them can apply to a protected type.
7933
 
7934
      return Ada_Version >= Ada_2005
7935
        and then Is_Entity_Name (N)
7936
        and then Present (Entity (N))
7937
        and then Is_Protected_Type (Entity (N))
7938
        and then In_Open_Scopes (Entity (N))
7939
        and then not In_Access_Definition (N);
7940
   end Is_Protected_Self_Reference;
7941
 
7942
   -----------------------------
7943
   -- Is_RCI_Pkg_Spec_Or_Body --
7944
   -----------------------------
7945
 
7946
   function Is_RCI_Pkg_Spec_Or_Body (Cunit : Node_Id) return Boolean is
7947
 
7948
      function Is_RCI_Pkg_Decl_Cunit (Cunit : Node_Id) return Boolean;
7949
      --  Return True if the unit of Cunit is an RCI package declaration
7950
 
7951
      ---------------------------
7952
      -- Is_RCI_Pkg_Decl_Cunit --
7953
      ---------------------------
7954
 
7955
      function Is_RCI_Pkg_Decl_Cunit (Cunit : Node_Id) return Boolean is
7956
         The_Unit : constant Node_Id := Unit (Cunit);
7957
 
7958
      begin
7959
         if Nkind (The_Unit) /= N_Package_Declaration then
7960
            return False;
7961
         end if;
7962
 
7963
         return Is_Remote_Call_Interface (Defining_Entity (The_Unit));
7964
      end Is_RCI_Pkg_Decl_Cunit;
7965
 
7966
   --  Start of processing for Is_RCI_Pkg_Spec_Or_Body
7967
 
7968
   begin
7969
      return Is_RCI_Pkg_Decl_Cunit (Cunit)
7970
        or else
7971
         (Nkind (Unit (Cunit)) = N_Package_Body
7972
           and then Is_RCI_Pkg_Decl_Cunit (Library_Unit (Cunit)));
7973
   end Is_RCI_Pkg_Spec_Or_Body;
7974
 
7975
   -----------------------------------------
7976
   -- Is_Remote_Access_To_Class_Wide_Type --
7977
   -----------------------------------------
7978
 
7979
   function Is_Remote_Access_To_Class_Wide_Type
7980
     (E : Entity_Id) return Boolean
7981
   is
7982
   begin
7983
      --  A remote access to class-wide type is a general access to object type
7984
      --  declared in the visible part of a Remote_Types or Remote_Call_
7985
      --  Interface unit.
7986
 
7987
      return Ekind (E) = E_General_Access_Type
7988
        and then (Is_Remote_Call_Interface (E) or else Is_Remote_Types (E));
7989
   end Is_Remote_Access_To_Class_Wide_Type;
7990
 
7991
   -----------------------------------------
7992
   -- Is_Remote_Access_To_Subprogram_Type --
7993
   -----------------------------------------
7994
 
7995
   function Is_Remote_Access_To_Subprogram_Type
7996
     (E : Entity_Id) return Boolean
7997
   is
7998
   begin
7999
      return (Ekind (E) = E_Access_Subprogram_Type
8000
                or else (Ekind (E) = E_Record_Type
8001
                           and then Present (Corresponding_Remote_Type (E))))
8002
        and then (Is_Remote_Call_Interface (E) or else Is_Remote_Types (E));
8003
   end Is_Remote_Access_To_Subprogram_Type;
8004
 
8005
   --------------------
8006
   -- Is_Remote_Call --
8007
   --------------------
8008
 
8009
   function Is_Remote_Call (N : Node_Id) return Boolean is
8010
   begin
8011
      if Nkind (N) /= N_Procedure_Call_Statement
8012
        and then Nkind (N) /= N_Function_Call
8013
      then
8014
         --  An entry call cannot be remote
8015
 
8016
         return False;
8017
 
8018
      elsif Nkind (Name (N)) in N_Has_Entity
8019
        and then Is_Remote_Call_Interface (Entity (Name (N)))
8020
      then
8021
         --  A subprogram declared in the spec of a RCI package is remote
8022
 
8023
         return True;
8024
 
8025
      elsif Nkind (Name (N)) = N_Explicit_Dereference
8026
        and then Is_Remote_Access_To_Subprogram_Type
8027
                   (Etype (Prefix (Name (N))))
8028
      then
8029
         --  The dereference of a RAS is a remote call
8030
 
8031
         return True;
8032
 
8033
      elsif Present (Controlling_Argument (N))
8034
        and then Is_Remote_Access_To_Class_Wide_Type
8035
          (Etype (Controlling_Argument (N)))
8036
      then
8037
         --  Any primitive operation call with a controlling argument of
8038
         --  a RACW type is a remote call.
8039
 
8040
         return True;
8041
      end if;
8042
 
8043
      --  All other calls are local calls
8044
 
8045
      return False;
8046
   end Is_Remote_Call;
8047
 
8048
   ----------------------
8049
   -- Is_Renamed_Entry --
8050
   ----------------------
8051
 
8052
   function Is_Renamed_Entry (Proc_Nam : Entity_Id) return Boolean is
8053
      Orig_Node : Node_Id := Empty;
8054
      Subp_Decl : Node_Id := Parent (Parent (Proc_Nam));
8055
 
8056
      function Is_Entry (Nam : Node_Id) return Boolean;
8057
      --  Determine whether Nam is an entry. Traverse selectors if there are
8058
      --  nested selected components.
8059
 
8060
      --------------
8061
      -- Is_Entry --
8062
      --------------
8063
 
8064
      function Is_Entry (Nam : Node_Id) return Boolean is
8065
      begin
8066
         if Nkind (Nam) = N_Selected_Component then
8067
            return Is_Entry (Selector_Name (Nam));
8068
         end if;
8069
 
8070
         return Ekind (Entity (Nam)) = E_Entry;
8071
      end Is_Entry;
8072
 
8073
   --  Start of processing for Is_Renamed_Entry
8074
 
8075
   begin
8076
      if Present (Alias (Proc_Nam)) then
8077
         Subp_Decl := Parent (Parent (Alias (Proc_Nam)));
8078
      end if;
8079
 
8080
      --  Look for a rewritten subprogram renaming declaration
8081
 
8082
      if Nkind (Subp_Decl) = N_Subprogram_Declaration
8083
        and then Present (Original_Node (Subp_Decl))
8084
      then
8085
         Orig_Node := Original_Node (Subp_Decl);
8086
      end if;
8087
 
8088
      --  The rewritten subprogram is actually an entry
8089
 
8090
      if Present (Orig_Node)
8091
        and then Nkind (Orig_Node) = N_Subprogram_Renaming_Declaration
8092
        and then Is_Entry (Name (Orig_Node))
8093
      then
8094
         return True;
8095
      end if;
8096
 
8097
      return False;
8098
   end Is_Renamed_Entry;
8099
 
8100
   ----------------------------
8101
   -- Is_Reversible_Iterator --
8102
   ----------------------------
8103
 
8104
   function Is_Reversible_Iterator (Typ : Entity_Id) return Boolean is
8105
      Ifaces_List : Elist_Id;
8106
      Iface_Elmt  : Elmt_Id;
8107
      Iface       : Entity_Id;
8108
 
8109
   begin
8110
      if Is_Class_Wide_Type (Typ)
8111
        and then  Chars (Etype (Typ)) = Name_Reversible_Iterator
8112
        and then
8113
          Is_Predefined_File_Name
8114
            (Unit_File_Name (Get_Source_Unit (Etype (Typ))))
8115
      then
8116
         return True;
8117
 
8118
      elsif not Is_Tagged_Type (Typ)
8119
        or else not Is_Derived_Type (Typ)
8120
      then
8121
         return False;
8122
 
8123
      else
8124
         Collect_Interfaces (Typ, Ifaces_List);
8125
 
8126
         Iface_Elmt := First_Elmt (Ifaces_List);
8127
         while Present (Iface_Elmt) loop
8128
            Iface := Node (Iface_Elmt);
8129
            if Chars (Iface) = Name_Reversible_Iterator
8130
              and then
8131
                Is_Predefined_File_Name
8132
                  (Unit_File_Name (Get_Source_Unit (Iface)))
8133
            then
8134
               return True;
8135
            end if;
8136
 
8137
            Next_Elmt (Iface_Elmt);
8138
         end loop;
8139
      end if;
8140
 
8141
      return False;
8142
   end Is_Reversible_Iterator;
8143
 
8144
   ----------------------
8145
   -- Is_Selector_Name --
8146
   ----------------------
8147
 
8148
   function Is_Selector_Name (N : Node_Id) return Boolean is
8149
   begin
8150
      if not Is_List_Member (N) then
8151
         declare
8152
            P : constant Node_Id   := Parent (N);
8153
            K : constant Node_Kind := Nkind (P);
8154
         begin
8155
            return
8156
              (K = N_Expanded_Name          or else
8157
               K = N_Generic_Association    or else
8158
               K = N_Parameter_Association  or else
8159
               K = N_Selected_Component)
8160
              and then Selector_Name (P) = N;
8161
         end;
8162
 
8163
      else
8164
         declare
8165
            L : constant List_Id := List_Containing (N);
8166
            P : constant Node_Id := Parent (L);
8167
         begin
8168
            return (Nkind (P) = N_Discriminant_Association
8169
                     and then Selector_Names (P) = L)
8170
              or else
8171
                   (Nkind (P) = N_Component_Association
8172
                     and then Choices (P) = L);
8173
         end;
8174
      end if;
8175
   end Is_Selector_Name;
8176
 
8177
   ----------------------------------
8178
   -- Is_SPARK_Initialization_Expr --
8179
   ----------------------------------
8180
 
8181
   function Is_SPARK_Initialization_Expr (N : Node_Id) return Boolean is
8182
      Is_Ok     : Boolean;
8183
      Expr      : Node_Id;
8184
      Comp_Assn : Node_Id;
8185
      Orig_N    : constant Node_Id := Original_Node (N);
8186
 
8187
   begin
8188
      Is_Ok := True;
8189
 
8190
      if not Comes_From_Source (Orig_N) then
8191
         goto Done;
8192
      end if;
8193
 
8194
      pragma Assert (Nkind (Orig_N) in N_Subexpr);
8195
 
8196
      case Nkind (Orig_N) is
8197
         when N_Character_Literal |
8198
              N_Integer_Literal   |
8199
              N_Real_Literal      |
8200
              N_String_Literal    =>
8201
            null;
8202
 
8203
         when N_Identifier    |
8204
              N_Expanded_Name =>
8205
            if Is_Entity_Name (Orig_N)
8206
              and then Present (Entity (Orig_N))  --  needed in some cases
8207
            then
8208
               case Ekind (Entity (Orig_N)) is
8209
                  when E_Constant            |
8210
                       E_Enumeration_Literal |
8211
                       E_Named_Integer       |
8212
                       E_Named_Real          =>
8213
                     null;
8214
                  when others =>
8215
                     if Is_Type (Entity (Orig_N)) then
8216
                        null;
8217
                     else
8218
                        Is_Ok := False;
8219
                     end if;
8220
               end case;
8221
            end if;
8222
 
8223
         when N_Qualified_Expression |
8224
              N_Type_Conversion      =>
8225
            Is_Ok := Is_SPARK_Initialization_Expr (Expression (Orig_N));
8226
 
8227
         when N_Unary_Op =>
8228
            Is_Ok := Is_SPARK_Initialization_Expr (Right_Opnd (Orig_N));
8229
 
8230
         when N_Binary_Op       |
8231
              N_Short_Circuit   |
8232
              N_Membership_Test =>
8233
            Is_Ok := Is_SPARK_Initialization_Expr (Left_Opnd (Orig_N))
8234
              and then Is_SPARK_Initialization_Expr (Right_Opnd (Orig_N));
8235
 
8236
         when N_Aggregate           |
8237
              N_Extension_Aggregate =>
8238
            if Nkind (Orig_N) = N_Extension_Aggregate then
8239
               Is_Ok := Is_SPARK_Initialization_Expr (Ancestor_Part (Orig_N));
8240
            end if;
8241
 
8242
            Expr := First (Expressions (Orig_N));
8243
            while Present (Expr) loop
8244
               if not Is_SPARK_Initialization_Expr (Expr) then
8245
                  Is_Ok := False;
8246
                  goto Done;
8247
               end if;
8248
 
8249
               Next (Expr);
8250
            end loop;
8251
 
8252
            Comp_Assn := First (Component_Associations (Orig_N));
8253
            while Present (Comp_Assn) loop
8254
               Expr := Expression (Comp_Assn);
8255
               if Present (Expr)  --  needed for box association
8256
                 and then not Is_SPARK_Initialization_Expr (Expr)
8257
               then
8258
                  Is_Ok := False;
8259
                  goto Done;
8260
               end if;
8261
 
8262
               Next (Comp_Assn);
8263
            end loop;
8264
 
8265
         when N_Attribute_Reference =>
8266
            if Nkind (Prefix (Orig_N)) in N_Subexpr then
8267
               Is_Ok := Is_SPARK_Initialization_Expr (Prefix (Orig_N));
8268
            end if;
8269
 
8270
            Expr := First (Expressions (Orig_N));
8271
            while Present (Expr) loop
8272
               if not Is_SPARK_Initialization_Expr (Expr) then
8273
                  Is_Ok := False;
8274
                  goto Done;
8275
               end if;
8276
 
8277
               Next (Expr);
8278
            end loop;
8279
 
8280
         --  Selected components might be expanded named not yet resolved, so
8281
         --  default on the safe side. (Eg on sparklex.ads)
8282
 
8283
         when N_Selected_Component =>
8284
            null;
8285
 
8286
         when others =>
8287
            Is_Ok := False;
8288
      end case;
8289
 
8290
   <<Done>>
8291
      return Is_Ok;
8292
   end Is_SPARK_Initialization_Expr;
8293
 
8294
   -------------------------------
8295
   -- Is_SPARK_Object_Reference --
8296
   -------------------------------
8297
 
8298
   function Is_SPARK_Object_Reference (N : Node_Id) return Boolean is
8299
   begin
8300
      if Is_Entity_Name (N) then
8301
         return Present (Entity (N))
8302
           and then
8303
             (Ekind_In (Entity (N), E_Constant, E_Variable)
8304
              or else Ekind (Entity (N)) in Formal_Kind);
8305
 
8306
      else
8307
         case Nkind (N) is
8308
            when N_Selected_Component =>
8309
               return Is_SPARK_Object_Reference (Prefix (N));
8310
 
8311
            when others =>
8312
               return False;
8313
         end case;
8314
      end if;
8315
   end Is_SPARK_Object_Reference;
8316
 
8317
   ------------------
8318
   -- Is_Statement --
8319
   ------------------
8320
 
8321
   function Is_Statement (N : Node_Id) return Boolean is
8322
   begin
8323
      return
8324
        Nkind (N) in N_Statement_Other_Than_Procedure_Call
8325
          or else Nkind (N) = N_Procedure_Call_Statement;
8326
   end Is_Statement;
8327
 
8328
   --------------------------------------------------
8329
   -- Is_Subprogram_Stub_Without_Prior_Declaration --
8330
   --------------------------------------------------
8331
 
8332
   function Is_Subprogram_Stub_Without_Prior_Declaration
8333
     (N : Node_Id) return Boolean
8334
   is
8335
   begin
8336
      --  A subprogram stub without prior declaration serves as declaration for
8337
      --  the actual subprogram body. As such, it has an attached defining
8338
      --  entity of E_[Generic_]Function or E_[Generic_]Procedure.
8339
 
8340
      return Nkind (N) = N_Subprogram_Body_Stub
8341
        and then Ekind (Defining_Entity (N)) /= E_Subprogram_Body;
8342
   end Is_Subprogram_Stub_Without_Prior_Declaration;
8343
 
8344
   ---------------------------------
8345
   -- Is_Synchronized_Tagged_Type --
8346
   ---------------------------------
8347
 
8348
   function Is_Synchronized_Tagged_Type (E : Entity_Id) return Boolean is
8349
      Kind : constant Entity_Kind := Ekind (Base_Type (E));
8350
 
8351
   begin
8352
      --  A task or protected type derived from an interface is a tagged type.
8353
      --  Such a tagged type is called a synchronized tagged type, as are
8354
      --  synchronized interfaces and private extensions whose declaration
8355
      --  includes the reserved word synchronized.
8356
 
8357
      return (Is_Tagged_Type (E)
8358
                and then (Kind = E_Task_Type
8359
                           or else Kind = E_Protected_Type))
8360
            or else
8361
             (Is_Interface (E)
8362
                and then Is_Synchronized_Interface (E))
8363
            or else
8364
             (Ekind (E) = E_Record_Type_With_Private
8365
                and then Nkind (Parent (E)) = N_Private_Extension_Declaration
8366
                and then (Synchronized_Present (Parent (E))
8367
                           or else Is_Synchronized_Interface (Etype (E))));
8368
   end Is_Synchronized_Tagged_Type;
8369
 
8370
   -----------------
8371
   -- Is_Transfer --
8372
   -----------------
8373
 
8374
   function Is_Transfer (N : Node_Id) return Boolean is
8375
      Kind : constant Node_Kind := Nkind (N);
8376
 
8377
   begin
8378
      if Kind = N_Simple_Return_Statement
8379
           or else
8380
         Kind = N_Extended_Return_Statement
8381
           or else
8382
         Kind = N_Goto_Statement
8383
           or else
8384
         Kind = N_Raise_Statement
8385
           or else
8386
         Kind = N_Requeue_Statement
8387
      then
8388
         return True;
8389
 
8390
      elsif (Kind = N_Exit_Statement or else Kind in N_Raise_xxx_Error)
8391
        and then No (Condition (N))
8392
      then
8393
         return True;
8394
 
8395
      elsif Kind = N_Procedure_Call_Statement
8396
        and then Is_Entity_Name (Name (N))
8397
        and then Present (Entity (Name (N)))
8398
        and then No_Return (Entity (Name (N)))
8399
      then
8400
         return True;
8401
 
8402
      elsif Nkind (Original_Node (N)) = N_Raise_Statement then
8403
         return True;
8404
 
8405
      else
8406
         return False;
8407
      end if;
8408
   end Is_Transfer;
8409
 
8410
   -------------
8411
   -- Is_True --
8412
   -------------
8413
 
8414
   function Is_True (U : Uint) return Boolean is
8415
   begin
8416
      return (U /= 0);
8417
   end Is_True;
8418
 
8419
   -------------------------------
8420
   -- Is_Universal_Numeric_Type --
8421
   -------------------------------
8422
 
8423
   function Is_Universal_Numeric_Type (T : Entity_Id) return Boolean is
8424
   begin
8425
      return T = Universal_Integer or else T = Universal_Real;
8426
   end Is_Universal_Numeric_Type;
8427
 
8428
   -------------------
8429
   -- Is_Value_Type --
8430
   -------------------
8431
 
8432
   function Is_Value_Type (T : Entity_Id) return Boolean is
8433
   begin
8434
      return VM_Target = CLI_Target
8435
        and then Nkind (T) in N_Has_Chars
8436
        and then Chars (T) /= No_Name
8437
        and then Get_Name_String (Chars (T)) = "valuetype";
8438
   end Is_Value_Type;
8439
 
8440
   ---------------------
8441
   -- Is_VMS_Operator --
8442
   ---------------------
8443
 
8444
   function Is_VMS_Operator (Op : Entity_Id) return Boolean is
8445
   begin
8446
      --  The VMS operators are declared in a child of System that is loaded
8447
      --  through pragma Extend_System. In some rare cases a program is run
8448
      --  with this extension but without indicating that the target is VMS.
8449
 
8450
      return Ekind (Op) = E_Function
8451
        and then Is_Intrinsic_Subprogram (Op)
8452
        and then
8453
          ((Present_System_Aux
8454
            and then Scope (Op) = System_Aux_Id)
8455
           or else
8456
           (True_VMS_Target
8457
             and then Scope (Scope (Op)) = RTU_Entity (System)));
8458
   end Is_VMS_Operator;
8459
 
8460
   -----------------
8461
   -- Is_Variable --
8462
   -----------------
8463
 
8464
   function Is_Variable
8465
     (N                 : Node_Id;
8466
      Use_Original_Node : Boolean := True) return Boolean
8467
   is
8468
      Orig_Node : Node_Id;
8469
 
8470
      function In_Protected_Function (E : Entity_Id) return Boolean;
8471
      --  Within a protected function, the private components of the enclosing
8472
      --  protected type are constants. A function nested within a (protected)
8473
      --  procedure is not itself protected.
8474
 
8475
      function Is_Variable_Prefix (P : Node_Id) return Boolean;
8476
      --  Prefixes can involve implicit dereferences, in which case we must
8477
      --  test for the case of a reference of a constant access type, which can
8478
      --  can never be a variable.
8479
 
8480
      ---------------------------
8481
      -- In_Protected_Function --
8482
      ---------------------------
8483
 
8484
      function In_Protected_Function (E : Entity_Id) return Boolean is
8485
         Prot : constant Entity_Id := Scope (E);
8486
         S    : Entity_Id;
8487
 
8488
      begin
8489
         if not Is_Protected_Type (Prot) then
8490
            return False;
8491
         else
8492
            S := Current_Scope;
8493
            while Present (S) and then S /= Prot loop
8494
               if Ekind (S) = E_Function and then Scope (S) = Prot then
8495
                  return True;
8496
               end if;
8497
 
8498
               S := Scope (S);
8499
            end loop;
8500
 
8501
            return False;
8502
         end if;
8503
      end In_Protected_Function;
8504
 
8505
      ------------------------
8506
      -- Is_Variable_Prefix --
8507
      ------------------------
8508
 
8509
      function Is_Variable_Prefix (P : Node_Id) return Boolean is
8510
      begin
8511
         if Is_Access_Type (Etype (P)) then
8512
            return not Is_Access_Constant (Root_Type (Etype (P)));
8513
 
8514
         --  For the case of an indexed component whose prefix has a packed
8515
         --  array type, the prefix has been rewritten into a type conversion.
8516
         --  Determine variable-ness from the converted expression.
8517
 
8518
         elsif Nkind (P) = N_Type_Conversion
8519
           and then not Comes_From_Source (P)
8520
           and then Is_Array_Type (Etype (P))
8521
           and then Is_Packed (Etype (P))
8522
         then
8523
            return Is_Variable (Expression (P));
8524
 
8525
         else
8526
            return Is_Variable (P);
8527
         end if;
8528
      end Is_Variable_Prefix;
8529
 
8530
   --  Start of processing for Is_Variable
8531
 
8532
   begin
8533
      --  Check if we perform the test on the original node since this may be a
8534
      --  test of syntactic categories which must not be disturbed by whatever
8535
      --  rewriting might have occurred. For example, an aggregate, which is
8536
      --  certainly NOT a variable, could be turned into a variable by
8537
      --  expansion.
8538
 
8539
      if Use_Original_Node then
8540
         Orig_Node := Original_Node (N);
8541
      else
8542
         Orig_Node := N;
8543
      end if;
8544
 
8545
      --  Definitely OK if Assignment_OK is set. Since this is something that
8546
      --  only gets set for expanded nodes, the test is on N, not Orig_Node.
8547
 
8548
      if Nkind (N) in N_Subexpr and then Assignment_OK (N) then
8549
         return True;
8550
 
8551
      --  Normally we go to the original node, but there is one exception where
8552
      --  we use the rewritten node, namely when it is an explicit dereference.
8553
      --  The generated code may rewrite a prefix which is an access type with
8554
      --  an explicit dereference. The dereference is a variable, even though
8555
      --  the original node may not be (since it could be a constant of the
8556
      --  access type).
8557
 
8558
      --  In Ada 2005 we have a further case to consider: the prefix may be a
8559
      --  function call given in prefix notation. The original node appears to
8560
      --  be a selected component, but we need to examine the call.
8561
 
8562
      elsif Nkind (N) = N_Explicit_Dereference
8563
        and then Nkind (Orig_Node) /= N_Explicit_Dereference
8564
        and then Present (Etype (Orig_Node))
8565
        and then Is_Access_Type (Etype (Orig_Node))
8566
      then
8567
         --  Note that if the prefix is an explicit dereference that does not
8568
         --  come from source, we must check for a rewritten function call in
8569
         --  prefixed notation before other forms of rewriting, to prevent a
8570
         --  compiler crash.
8571
 
8572
         return
8573
           (Nkind (Orig_Node) = N_Function_Call
8574
             and then not Is_Access_Constant (Etype (Prefix (N))))
8575
           or else
8576
             Is_Variable_Prefix (Original_Node (Prefix (N)));
8577
 
8578
      --  A function call is never a variable
8579
 
8580
      elsif Nkind (N) = N_Function_Call then
8581
         return False;
8582
 
8583
      --  All remaining checks use the original node
8584
 
8585
      elsif Is_Entity_Name (Orig_Node)
8586
        and then Present (Entity (Orig_Node))
8587
      then
8588
         declare
8589
            E : constant Entity_Id := Entity (Orig_Node);
8590
            K : constant Entity_Kind := Ekind (E);
8591
 
8592
         begin
8593
            return (K = E_Variable
8594
                      and then Nkind (Parent (E)) /= N_Exception_Handler)
8595
              or else  (K = E_Component
8596
                          and then not In_Protected_Function (E))
8597
              or else  K = E_Out_Parameter
8598
              or else  K = E_In_Out_Parameter
8599
              or else  K = E_Generic_In_Out_Parameter
8600
 
8601
               --  Current instance of type
8602
 
8603
              or else (Is_Type (E) and then In_Open_Scopes (E))
8604
              or else (Is_Incomplete_Or_Private_Type (E)
8605
                        and then In_Open_Scopes (Full_View (E)));
8606
         end;
8607
 
8608
      else
8609
         case Nkind (Orig_Node) is
8610
            when N_Indexed_Component | N_Slice =>
8611
               return Is_Variable_Prefix (Prefix (Orig_Node));
8612
 
8613
            when N_Selected_Component =>
8614
               return Is_Variable_Prefix (Prefix (Orig_Node))
8615
                 and then Is_Variable (Selector_Name (Orig_Node));
8616
 
8617
            --  For an explicit dereference, the type of the prefix cannot
8618
            --  be an access to constant or an access to subprogram.
8619
 
8620
            when N_Explicit_Dereference =>
8621
               declare
8622
                  Typ : constant Entity_Id := Etype (Prefix (Orig_Node));
8623
               begin
8624
                  return Is_Access_Type (Typ)
8625
                    and then not Is_Access_Constant (Root_Type (Typ))
8626
                    and then Ekind (Typ) /= E_Access_Subprogram_Type;
8627
               end;
8628
 
8629
            --  The type conversion is the case where we do not deal with the
8630
            --  context dependent special case of an actual parameter. Thus
8631
            --  the type conversion is only considered a variable for the
8632
            --  purposes of this routine if the target type is tagged. However,
8633
            --  a type conversion is considered to be a variable if it does not
8634
            --  come from source (this deals for example with the conversions
8635
            --  of expressions to their actual subtypes).
8636
 
8637
            when N_Type_Conversion =>
8638
               return Is_Variable (Expression (Orig_Node))
8639
                 and then
8640
                   (not Comes_From_Source (Orig_Node)
8641
                      or else
8642
                        (Is_Tagged_Type (Etype (Subtype_Mark (Orig_Node)))
8643
                          and then
8644
                         Is_Tagged_Type (Etype (Expression (Orig_Node)))));
8645
 
8646
            --  GNAT allows an unchecked type conversion as a variable. This
8647
            --  only affects the generation of internal expanded code, since
8648
            --  calls to instantiations of Unchecked_Conversion are never
8649
            --  considered variables (since they are function calls).
8650
            --  This is also true for expression actions.
8651
 
8652
            when N_Unchecked_Type_Conversion =>
8653
               return Is_Variable (Expression (Orig_Node));
8654
 
8655
            when others =>
8656
               return False;
8657
         end case;
8658
      end if;
8659
   end Is_Variable;
8660
 
8661
   ---------------------------
8662
   -- Is_Visibly_Controlled --
8663
   ---------------------------
8664
 
8665
   function Is_Visibly_Controlled (T : Entity_Id) return Boolean is
8666
      Root : constant Entity_Id := Root_Type (T);
8667
   begin
8668
      return Chars (Scope (Root)) = Name_Finalization
8669
        and then Chars (Scope (Scope (Root))) = Name_Ada
8670
        and then Scope (Scope (Scope (Root))) = Standard_Standard;
8671
   end Is_Visibly_Controlled;
8672
 
8673
   ------------------------
8674
   -- Is_Volatile_Object --
8675
   ------------------------
8676
 
8677
   function Is_Volatile_Object (N : Node_Id) return Boolean is
8678
 
8679
      function Object_Has_Volatile_Components (N : Node_Id) return Boolean;
8680
      --  Determines if given object has volatile components
8681
 
8682
      function Is_Volatile_Prefix (N : Node_Id) return Boolean;
8683
      --  If prefix is an implicit dereference, examine designated type
8684
 
8685
      ------------------------
8686
      -- Is_Volatile_Prefix --
8687
      ------------------------
8688
 
8689
      function Is_Volatile_Prefix (N : Node_Id) return Boolean is
8690
         Typ  : constant Entity_Id := Etype (N);
8691
 
8692
      begin
8693
         if Is_Access_Type (Typ) then
8694
            declare
8695
               Dtyp : constant Entity_Id := Designated_Type (Typ);
8696
 
8697
            begin
8698
               return Is_Volatile (Dtyp)
8699
                 or else Has_Volatile_Components (Dtyp);
8700
            end;
8701
 
8702
         else
8703
            return Object_Has_Volatile_Components (N);
8704
         end if;
8705
      end Is_Volatile_Prefix;
8706
 
8707
      ------------------------------------
8708
      -- Object_Has_Volatile_Components --
8709
      ------------------------------------
8710
 
8711
      function Object_Has_Volatile_Components (N : Node_Id) return Boolean is
8712
         Typ : constant Entity_Id := Etype (N);
8713
 
8714
      begin
8715
         if Is_Volatile (Typ)
8716
           or else Has_Volatile_Components (Typ)
8717
         then
8718
            return True;
8719
 
8720
         elsif Is_Entity_Name (N)
8721
           and then (Has_Volatile_Components (Entity (N))
8722
                      or else Is_Volatile (Entity (N)))
8723
         then
8724
            return True;
8725
 
8726
         elsif Nkind (N) = N_Indexed_Component
8727
           or else Nkind (N) = N_Selected_Component
8728
         then
8729
            return Is_Volatile_Prefix (Prefix (N));
8730
 
8731
         else
8732
            return False;
8733
         end if;
8734
      end Object_Has_Volatile_Components;
8735
 
8736
   --  Start of processing for Is_Volatile_Object
8737
 
8738
   begin
8739
      if Is_Volatile (Etype (N))
8740
        or else (Is_Entity_Name (N) and then Is_Volatile (Entity (N)))
8741
      then
8742
         return True;
8743
 
8744
      elsif Nkind_In (N, N_Indexed_Component, N_Selected_Component)
8745
        and then Is_Volatile_Prefix (Prefix (N))
8746
      then
8747
         return True;
8748
 
8749
      elsif Nkind (N) = N_Selected_Component
8750
        and then Is_Volatile (Entity (Selector_Name (N)))
8751
      then
8752
         return True;
8753
 
8754
      else
8755
         return False;
8756
      end if;
8757
   end Is_Volatile_Object;
8758
 
8759
   ---------------------------
8760
   -- Itype_Has_Declaration --
8761
   ---------------------------
8762
 
8763
   function Itype_Has_Declaration (Id : Entity_Id) return Boolean is
8764
   begin
8765
      pragma Assert (Is_Itype (Id));
8766
      return Present (Parent (Id))
8767
        and then Nkind_In (Parent (Id), N_Full_Type_Declaration,
8768
                                        N_Subtype_Declaration)
8769
        and then Defining_Entity (Parent (Id)) = Id;
8770
   end Itype_Has_Declaration;
8771
 
8772
   -------------------------
8773
   -- Kill_Current_Values --
8774
   -------------------------
8775
 
8776
   procedure Kill_Current_Values
8777
     (Ent                  : Entity_Id;
8778
      Last_Assignment_Only : Boolean := False)
8779
   is
8780
   begin
8781
      --  ??? do we have to worry about clearing cached checks?
8782
 
8783
      if Is_Assignable (Ent) then
8784
         Set_Last_Assignment (Ent, Empty);
8785
      end if;
8786
 
8787
      if Is_Object (Ent) then
8788
         if not Last_Assignment_Only then
8789
            Kill_Checks (Ent);
8790
            Set_Current_Value (Ent, Empty);
8791
 
8792
            if not Can_Never_Be_Null (Ent) then
8793
               Set_Is_Known_Non_Null (Ent, False);
8794
            end if;
8795
 
8796
            Set_Is_Known_Null (Ent, False);
8797
 
8798
            --  Reset Is_Known_Valid unless type is always valid, or if we have
8799
            --  a loop parameter (loop parameters are always valid, since their
8800
            --  bounds are defined by the bounds given in the loop header).
8801
 
8802
            if not Is_Known_Valid (Etype (Ent))
8803
              and then Ekind (Ent) /= E_Loop_Parameter
8804
            then
8805
               Set_Is_Known_Valid (Ent, False);
8806
            end if;
8807
         end if;
8808
      end if;
8809
   end Kill_Current_Values;
8810
 
8811
   procedure Kill_Current_Values (Last_Assignment_Only : Boolean := False) is
8812
      S : Entity_Id;
8813
 
8814
      procedure Kill_Current_Values_For_Entity_Chain (E : Entity_Id);
8815
      --  Clear current value for entity E and all entities chained to E
8816
 
8817
      ------------------------------------------
8818
      -- Kill_Current_Values_For_Entity_Chain --
8819
      ------------------------------------------
8820
 
8821
      procedure Kill_Current_Values_For_Entity_Chain (E : Entity_Id) is
8822
         Ent : Entity_Id;
8823
      begin
8824
         Ent := E;
8825
         while Present (Ent) loop
8826
            Kill_Current_Values (Ent, Last_Assignment_Only);
8827
            Next_Entity (Ent);
8828
         end loop;
8829
      end Kill_Current_Values_For_Entity_Chain;
8830
 
8831
   --  Start of processing for Kill_Current_Values
8832
 
8833
   begin
8834
      --  Kill all saved checks, a special case of killing saved values
8835
 
8836
      if not Last_Assignment_Only then
8837
         Kill_All_Checks;
8838
      end if;
8839
 
8840
      --  Loop through relevant scopes, which includes the current scope and
8841
      --  any parent scopes if the current scope is a block or a package.
8842
 
8843
      S := Current_Scope;
8844
      Scope_Loop : loop
8845
 
8846
         --  Clear current values of all entities in current scope
8847
 
8848
         Kill_Current_Values_For_Entity_Chain (First_Entity (S));
8849
 
8850
         --  If scope is a package, also clear current values of all private
8851
         --  entities in the scope.
8852
 
8853
         if Is_Package_Or_Generic_Package (S)
8854
           or else Is_Concurrent_Type (S)
8855
         then
8856
            Kill_Current_Values_For_Entity_Chain (First_Private_Entity (S));
8857
         end if;
8858
 
8859
         --  If this is a not a subprogram, deal with parents
8860
 
8861
         if not Is_Subprogram (S) then
8862
            S := Scope (S);
8863
            exit Scope_Loop when S = Standard_Standard;
8864
         else
8865
            exit Scope_Loop;
8866
         end if;
8867
      end loop Scope_Loop;
8868
   end Kill_Current_Values;
8869
 
8870
   --------------------------
8871
   -- Kill_Size_Check_Code --
8872
   --------------------------
8873
 
8874
   procedure Kill_Size_Check_Code (E : Entity_Id) is
8875
   begin
8876
      if (Ekind (E) = E_Constant or else Ekind (E) = E_Variable)
8877
        and then Present (Size_Check_Code (E))
8878
      then
8879
         Remove (Size_Check_Code (E));
8880
         Set_Size_Check_Code (E, Empty);
8881
      end if;
8882
   end Kill_Size_Check_Code;
8883
 
8884
   --------------------------
8885
   -- Known_To_Be_Assigned --
8886
   --------------------------
8887
 
8888
   function Known_To_Be_Assigned (N : Node_Id) return Boolean is
8889
      P : constant Node_Id := Parent (N);
8890
 
8891
   begin
8892
      case Nkind (P) is
8893
 
8894
         --  Test left side of assignment
8895
 
8896
         when N_Assignment_Statement =>
8897
            return N = Name (P);
8898
 
8899
            --  Function call arguments are never lvalues
8900
 
8901
         when N_Function_Call =>
8902
            return False;
8903
 
8904
         --  Positional parameter for procedure or accept call
8905
 
8906
         when N_Procedure_Call_Statement |
8907
              N_Accept_Statement
8908
          =>
8909
            declare
8910
               Proc : Entity_Id;
8911
               Form : Entity_Id;
8912
               Act  : Node_Id;
8913
 
8914
            begin
8915
               Proc := Get_Subprogram_Entity (P);
8916
 
8917
               if No (Proc) then
8918
                  return False;
8919
               end if;
8920
 
8921
               --  If we are not a list member, something is strange, so
8922
               --  be conservative and return False.
8923
 
8924
               if not Is_List_Member (N) then
8925
                  return False;
8926
               end if;
8927
 
8928
               --  We are going to find the right formal by stepping forward
8929
               --  through the formals, as we step backwards in the actuals.
8930
 
8931
               Form := First_Formal (Proc);
8932
               Act  := N;
8933
               loop
8934
                  --  If no formal, something is weird, so be conservative
8935
                  --  and return False.
8936
 
8937
                  if No (Form) then
8938
                     return False;
8939
                  end if;
8940
 
8941
                  Prev (Act);
8942
                  exit when No (Act);
8943
                  Next_Formal (Form);
8944
               end loop;
8945
 
8946
               return Ekind (Form) /= E_In_Parameter;
8947
            end;
8948
 
8949
         --  Named parameter for procedure or accept call
8950
 
8951
         when N_Parameter_Association =>
8952
            declare
8953
               Proc : Entity_Id;
8954
               Form : Entity_Id;
8955
 
8956
            begin
8957
               Proc := Get_Subprogram_Entity (Parent (P));
8958
 
8959
               if No (Proc) then
8960
                  return False;
8961
               end if;
8962
 
8963
               --  Loop through formals to find the one that matches
8964
 
8965
               Form := First_Formal (Proc);
8966
               loop
8967
                  --  If no matching formal, that's peculiar, some kind of
8968
                  --  previous error, so return False to be conservative.
8969
 
8970
                  if No (Form) then
8971
                     return False;
8972
                  end if;
8973
 
8974
                  --  Else test for match
8975
 
8976
                  if Chars (Form) = Chars (Selector_Name (P)) then
8977
                     return Ekind (Form) /= E_In_Parameter;
8978
                  end if;
8979
 
8980
                  Next_Formal (Form);
8981
               end loop;
8982
            end;
8983
 
8984
         --  Test for appearing in a conversion that itself appears
8985
         --  in an lvalue context, since this should be an lvalue.
8986
 
8987
         when N_Type_Conversion =>
8988
            return Known_To_Be_Assigned (P);
8989
 
8990
         --  All other references are definitely not known to be modifications
8991
 
8992
         when others =>
8993
            return False;
8994
 
8995
      end case;
8996
   end Known_To_Be_Assigned;
8997
 
8998
   ---------------------------
8999
   -- Last_Source_Statement --
9000
   ---------------------------
9001
 
9002
   function Last_Source_Statement (HSS : Node_Id) return Node_Id is
9003
      N : Node_Id;
9004
 
9005
   begin
9006
      N := Last (Statements (HSS));
9007
      while Present (N) loop
9008
         exit when Comes_From_Source (N);
9009
         Prev (N);
9010
      end loop;
9011
 
9012
      return N;
9013
   end Last_Source_Statement;
9014
 
9015
   ----------------------------------
9016
   -- Matching_Static_Array_Bounds --
9017
   ----------------------------------
9018
 
9019
   function Matching_Static_Array_Bounds
9020
     (L_Typ : Node_Id;
9021
      R_Typ : Node_Id) return Boolean
9022
   is
9023
      L_Ndims : constant Nat := Number_Dimensions (L_Typ);
9024
      R_Ndims : constant Nat := Number_Dimensions (R_Typ);
9025
 
9026
      L_Index : Node_Id;
9027
      R_Index : Node_Id;
9028
      L_Low   : Node_Id;
9029
      L_High  : Node_Id;
9030
      L_Len   : Uint;
9031
      R_Low   : Node_Id;
9032
      R_High  : Node_Id;
9033
      R_Len   : Uint;
9034
 
9035
   begin
9036
      if L_Ndims /= R_Ndims then
9037
         return False;
9038
      end if;
9039
 
9040
      --  Unconstrained types do not have static bounds
9041
 
9042
      if not Is_Constrained (L_Typ) or else not Is_Constrained (R_Typ) then
9043
         return False;
9044
      end if;
9045
 
9046
      --  First treat specially the first dimension, as the lower bound and
9047
      --  length of string literals are not stored like those of arrays.
9048
 
9049
      if Ekind (L_Typ) = E_String_Literal_Subtype then
9050
         L_Low := String_Literal_Low_Bound (L_Typ);
9051
         L_Len := String_Literal_Length (L_Typ);
9052
      else
9053
         L_Index := First_Index (L_Typ);
9054
         Get_Index_Bounds (L_Index, L_Low, L_High);
9055
 
9056
         if         Is_OK_Static_Expression (L_Low)
9057
           and then Is_OK_Static_Expression (L_High)
9058
         then
9059
            if Expr_Value (L_High) < Expr_Value (L_Low) then
9060
               L_Len := Uint_0;
9061
            else
9062
               L_Len := (Expr_Value (L_High) - Expr_Value (L_Low)) + 1;
9063
            end if;
9064
         else
9065
            return False;
9066
         end if;
9067
      end if;
9068
 
9069
      if Ekind (R_Typ) = E_String_Literal_Subtype then
9070
         R_Low := String_Literal_Low_Bound (R_Typ);
9071
         R_Len := String_Literal_Length (R_Typ);
9072
      else
9073
         R_Index := First_Index (R_Typ);
9074
         Get_Index_Bounds (R_Index, R_Low, R_High);
9075
 
9076
         if         Is_OK_Static_Expression (R_Low)
9077
           and then Is_OK_Static_Expression (R_High)
9078
         then
9079
            if Expr_Value (R_High) < Expr_Value (R_Low) then
9080
               R_Len := Uint_0;
9081
            else
9082
               R_Len := (Expr_Value (R_High) - Expr_Value (R_Low)) + 1;
9083
            end if;
9084
         else
9085
            return False;
9086
         end if;
9087
      end if;
9088
 
9089
      if         Is_OK_Static_Expression (L_Low)
9090
        and then Is_OK_Static_Expression (R_Low)
9091
        and then Expr_Value (L_Low) = Expr_Value (R_Low)
9092
        and then L_Len = R_Len
9093
      then
9094
         null;
9095
      else
9096
         return False;
9097
      end if;
9098
 
9099
      --  Then treat all other dimensions
9100
 
9101
      for Indx in 2 .. L_Ndims loop
9102
         Next (L_Index);
9103
         Next (R_Index);
9104
 
9105
         Get_Index_Bounds (L_Index, L_Low, L_High);
9106
         Get_Index_Bounds (R_Index, R_Low, R_High);
9107
 
9108
         if         Is_OK_Static_Expression (L_Low)
9109
           and then Is_OK_Static_Expression (L_High)
9110
           and then Is_OK_Static_Expression (R_Low)
9111
           and then Is_OK_Static_Expression (R_High)
9112
           and then Expr_Value (L_Low)  = Expr_Value (R_Low)
9113
           and then Expr_Value (L_High) = Expr_Value (R_High)
9114
         then
9115
            null;
9116
         else
9117
            return False;
9118
         end if;
9119
      end loop;
9120
 
9121
      --  If we fall through the loop, all indexes matched
9122
 
9123
      return True;
9124
   end Matching_Static_Array_Bounds;
9125
 
9126
   -------------------
9127
   -- May_Be_Lvalue --
9128
   -------------------
9129
 
9130
   function May_Be_Lvalue (N : Node_Id) return Boolean is
9131
      P : constant Node_Id := Parent (N);
9132
 
9133
   begin
9134
      case Nkind (P) is
9135
 
9136
         --  Test left side of assignment
9137
 
9138
         when N_Assignment_Statement =>
9139
            return N = Name (P);
9140
 
9141
         --  Test prefix of component or attribute. Note that the prefix of an
9142
         --  explicit or implicit dereference cannot be an l-value.
9143
 
9144
         when N_Attribute_Reference =>
9145
            return N = Prefix (P)
9146
              and then Name_Implies_Lvalue_Prefix (Attribute_Name (P));
9147
 
9148
         --  For an expanded name, the name is an lvalue if the expanded name
9149
         --  is an lvalue, but the prefix is never an lvalue, since it is just
9150
         --  the scope where the name is found.
9151
 
9152
         when N_Expanded_Name =>
9153
            if N = Prefix (P) then
9154
               return May_Be_Lvalue (P);
9155
            else
9156
               return False;
9157
            end if;
9158
 
9159
         --  For a selected component A.B, A is certainly an lvalue if A.B is.
9160
         --  B is a little interesting, if we have A.B := 3, there is some
9161
         --  discussion as to whether B is an lvalue or not, we choose to say
9162
         --  it is. Note however that A is not an lvalue if it is of an access
9163
         --  type since this is an implicit dereference.
9164
 
9165
         when N_Selected_Component =>
9166
            if N = Prefix (P)
9167
              and then Present (Etype (N))
9168
              and then Is_Access_Type (Etype (N))
9169
            then
9170
               return False;
9171
            else
9172
               return May_Be_Lvalue (P);
9173
            end if;
9174
 
9175
         --  For an indexed component or slice, the index or slice bounds is
9176
         --  never an lvalue. The prefix is an lvalue if the indexed component
9177
         --  or slice is an lvalue, except if it is an access type, where we
9178
         --  have an implicit dereference.
9179
 
9180
         when N_Indexed_Component | N_Slice =>
9181
            if N /= Prefix (P)
9182
              or else (Present (Etype (N)) and then Is_Access_Type (Etype (N)))
9183
            then
9184
               return False;
9185
            else
9186
               return May_Be_Lvalue (P);
9187
            end if;
9188
 
9189
         --  Prefix of a reference is an lvalue if the reference is an lvalue
9190
 
9191
         when N_Reference =>
9192
            return May_Be_Lvalue (P);
9193
 
9194
         --  Prefix of explicit dereference is never an lvalue
9195
 
9196
         when N_Explicit_Dereference =>
9197
            return False;
9198
 
9199
         --  Positional parameter for subprogram, entry, or accept call.
9200
         --  In older versions of Ada function call arguments are never
9201
         --  lvalues. In Ada 2012 functions can have in-out parameters.
9202
 
9203
         when N_Function_Call            |
9204
              N_Procedure_Call_Statement |
9205
              N_Entry_Call_Statement     |
9206
              N_Accept_Statement
9207
         =>
9208
            if Nkind (P) = N_Function_Call and then Ada_Version < Ada_2012 then
9209
               return False;
9210
            end if;
9211
 
9212
            --  The following mechanism is clumsy and fragile. A single flag
9213
            --  set in Resolve_Actuals would be preferable ???
9214
 
9215
            declare
9216
               Proc : Entity_Id;
9217
               Form : Entity_Id;
9218
               Act  : Node_Id;
9219
 
9220
            begin
9221
               Proc := Get_Subprogram_Entity (P);
9222
 
9223
               if No (Proc) then
9224
                  return True;
9225
               end if;
9226
 
9227
               --  If we are not a list member, something is strange, so be
9228
               --  conservative and return True.
9229
 
9230
               if not Is_List_Member (N) then
9231
                  return True;
9232
               end if;
9233
 
9234
               --  We are going to find the right formal by stepping forward
9235
               --  through the formals, as we step backwards in the actuals.
9236
 
9237
               Form := First_Formal (Proc);
9238
               Act  := N;
9239
               loop
9240
                  --  If no formal, something is weird, so be conservative and
9241
                  --  return True.
9242
 
9243
                  if No (Form) then
9244
                     return True;
9245
                  end if;
9246
 
9247
                  Prev (Act);
9248
                  exit when No (Act);
9249
                  Next_Formal (Form);
9250
               end loop;
9251
 
9252
               return Ekind (Form) /= E_In_Parameter;
9253
            end;
9254
 
9255
         --  Named parameter for procedure or accept call
9256
 
9257
         when N_Parameter_Association =>
9258
            declare
9259
               Proc : Entity_Id;
9260
               Form : Entity_Id;
9261
 
9262
            begin
9263
               Proc := Get_Subprogram_Entity (Parent (P));
9264
 
9265
               if No (Proc) then
9266
                  return True;
9267
               end if;
9268
 
9269
               --  Loop through formals to find the one that matches
9270
 
9271
               Form := First_Formal (Proc);
9272
               loop
9273
                  --  If no matching formal, that's peculiar, some kind of
9274
                  --  previous error, so return True to be conservative.
9275
 
9276
                  if No (Form) then
9277
                     return True;
9278
                  end if;
9279
 
9280
                  --  Else test for match
9281
 
9282
                  if Chars (Form) = Chars (Selector_Name (P)) then
9283
                     return Ekind (Form) /= E_In_Parameter;
9284
                  end if;
9285
 
9286
                  Next_Formal (Form);
9287
               end loop;
9288
            end;
9289
 
9290
         --  Test for appearing in a conversion that itself appears in an
9291
         --  lvalue context, since this should be an lvalue.
9292
 
9293
         when N_Type_Conversion =>
9294
            return May_Be_Lvalue (P);
9295
 
9296
         --  Test for appearance in object renaming declaration
9297
 
9298
         when N_Object_Renaming_Declaration =>
9299
            return True;
9300
 
9301
         --  All other references are definitely not lvalues
9302
 
9303
         when others =>
9304
            return False;
9305
 
9306
      end case;
9307
   end May_Be_Lvalue;
9308
 
9309
   -----------------------
9310
   -- Mark_Coextensions --
9311
   -----------------------
9312
 
9313
   procedure Mark_Coextensions (Context_Nod : Node_Id; Root_Nod : Node_Id) is
9314
      Is_Dynamic : Boolean;
9315
      --  Indicates whether the context causes nested coextensions to be
9316
      --  dynamic or static
9317
 
9318
      function Mark_Allocator (N : Node_Id) return Traverse_Result;
9319
      --  Recognize an allocator node and label it as a dynamic coextension
9320
 
9321
      --------------------
9322
      -- Mark_Allocator --
9323
      --------------------
9324
 
9325
      function Mark_Allocator (N : Node_Id) return Traverse_Result is
9326
      begin
9327
         if Nkind (N) = N_Allocator then
9328
            if Is_Dynamic then
9329
               Set_Is_Dynamic_Coextension (N);
9330
 
9331
            --  If the allocator expression is potentially dynamic, it may
9332
            --  be expanded out of order and require dynamic allocation
9333
            --  anyway, so we treat the coextension itself as dynamic.
9334
            --  Potential optimization ???
9335
 
9336
            elsif Nkind (Expression (N)) = N_Qualified_Expression
9337
              and then Nkind (Expression (Expression (N))) = N_Op_Concat
9338
            then
9339
               Set_Is_Dynamic_Coextension (N);
9340
            else
9341
               Set_Is_Static_Coextension (N);
9342
            end if;
9343
         end if;
9344
 
9345
         return OK;
9346
      end Mark_Allocator;
9347
 
9348
      procedure Mark_Allocators is new Traverse_Proc (Mark_Allocator);
9349
 
9350
   --  Start of processing Mark_Coextensions
9351
 
9352
   begin
9353
      case Nkind (Context_Nod) is
9354
 
9355
         --  Comment here ???
9356
 
9357
         when N_Assignment_Statement    =>
9358
            Is_Dynamic := Nkind (Expression (Context_Nod)) = N_Allocator;
9359
 
9360
         --  An allocator that is a component of a returned aggregate
9361
         --  must be dynamic.
9362
 
9363
         when N_Simple_Return_Statement =>
9364
            declare
9365
               Expr : constant Node_Id := Expression (Context_Nod);
9366
            begin
9367
               Is_Dynamic :=
9368
                 Nkind (Expr) = N_Allocator
9369
                   or else
9370
                     (Nkind (Expr) = N_Qualified_Expression
9371
                       and then Nkind (Expression (Expr)) = N_Aggregate);
9372
            end;
9373
 
9374
         --  An alloctor within an object declaration in an extended return
9375
         --  statement is of necessity dynamic.
9376
 
9377
         when N_Object_Declaration =>
9378
            Is_Dynamic := Nkind (Root_Nod) = N_Allocator
9379
              or else
9380
                Nkind (Parent (Context_Nod)) = N_Extended_Return_Statement;
9381
 
9382
         --  This routine should not be called for constructs which may not
9383
         --  contain coextensions.
9384
 
9385
         when others =>
9386
            raise Program_Error;
9387
      end case;
9388
 
9389
      Mark_Allocators (Root_Nod);
9390
   end Mark_Coextensions;
9391
 
9392
   ----------------------
9393
   -- Needs_One_Actual --
9394
   ----------------------
9395
 
9396
   function Needs_One_Actual (E : Entity_Id) return Boolean is
9397
      Formal : Entity_Id;
9398
 
9399
   begin
9400
      --  Ada 2005 or later, and formals present
9401
 
9402
      if Ada_Version >= Ada_2005 and then Present (First_Formal (E)) then
9403
         Formal := Next_Formal (First_Formal (E));
9404
         while Present (Formal) loop
9405
            if No (Default_Value (Formal)) then
9406
               return False;
9407
            end if;
9408
 
9409
            Next_Formal (Formal);
9410
         end loop;
9411
 
9412
         return True;
9413
 
9414
      --  Ada 83/95 or no formals
9415
 
9416
      else
9417
         return False;
9418
      end if;
9419
   end Needs_One_Actual;
9420
 
9421
   ------------------------
9422
   -- New_Copy_List_Tree --
9423
   ------------------------
9424
 
9425
   function New_Copy_List_Tree (List : List_Id) return List_Id is
9426
      NL : List_Id;
9427
      E  : Node_Id;
9428
 
9429
   begin
9430
      if List = No_List then
9431
         return No_List;
9432
 
9433
      else
9434
         NL := New_List;
9435
         E := First (List);
9436
 
9437
         while Present (E) loop
9438
            Append (New_Copy_Tree (E), NL);
9439
            E := Next (E);
9440
         end loop;
9441
 
9442
         return NL;
9443
      end if;
9444
   end New_Copy_List_Tree;
9445
 
9446
   -------------------
9447
   -- New_Copy_Tree --
9448
   -------------------
9449
 
9450
   use Atree.Unchecked_Access;
9451
   use Atree_Private_Part;
9452
 
9453
   --  Our approach here requires a two pass traversal of the tree. The
9454
   --  first pass visits all nodes that eventually will be copied looking
9455
   --  for defining Itypes. If any defining Itypes are found, then they are
9456
   --  copied, and an entry is added to the replacement map. In the second
9457
   --  phase, the tree is copied, using the replacement map to replace any
9458
   --  Itype references within the copied tree.
9459
 
9460
   --  The following hash tables are used if the Map supplied has more
9461
   --  than hash threshold entries to speed up access to the map. If
9462
   --  there are fewer entries, then the map is searched sequentially
9463
   --  (because setting up a hash table for only a few entries takes
9464
   --  more time than it saves.
9465
 
9466
   function New_Copy_Hash (E : Entity_Id) return NCT_Header_Num;
9467
   --  Hash function used for hash operations
9468
 
9469
   -------------------
9470
   -- New_Copy_Hash --
9471
   -------------------
9472
 
9473
   function New_Copy_Hash (E : Entity_Id) return NCT_Header_Num is
9474
   begin
9475
      return Nat (E) mod (NCT_Header_Num'Last + 1);
9476
   end New_Copy_Hash;
9477
 
9478
   ---------------
9479
   -- NCT_Assoc --
9480
   ---------------
9481
 
9482
   --  The hash table NCT_Assoc associates old entities in the table
9483
   --  with their corresponding new entities (i.e. the pairs of entries
9484
   --  presented in the original Map argument are Key-Element pairs).
9485
 
9486
   package NCT_Assoc is new Simple_HTable (
9487
     Header_Num => NCT_Header_Num,
9488
     Element    => Entity_Id,
9489
     No_Element => Empty,
9490
     Key        => Entity_Id,
9491
     Hash       => New_Copy_Hash,
9492
     Equal      => Types."=");
9493
 
9494
   ---------------------
9495
   -- NCT_Itype_Assoc --
9496
   ---------------------
9497
 
9498
   --  The hash table NCT_Itype_Assoc contains entries only for those
9499
   --  old nodes which have a non-empty Associated_Node_For_Itype set.
9500
   --  The key is the associated node, and the element is the new node
9501
   --  itself (NOT the associated node for the new node).
9502
 
9503
   package NCT_Itype_Assoc is new Simple_HTable (
9504
     Header_Num => NCT_Header_Num,
9505
     Element    => Entity_Id,
9506
     No_Element => Empty,
9507
     Key        => Entity_Id,
9508
     Hash       => New_Copy_Hash,
9509
     Equal      => Types."=");
9510
 
9511
   --  Start of processing for New_Copy_Tree function
9512
 
9513
   function New_Copy_Tree
9514
     (Source    : Node_Id;
9515
      Map       : Elist_Id := No_Elist;
9516
      New_Sloc  : Source_Ptr := No_Location;
9517
      New_Scope : Entity_Id := Empty) return Node_Id
9518
   is
9519
      Actual_Map : Elist_Id := Map;
9520
      --  This is the actual map for the copy. It is initialized with the
9521
      --  given elements, and then enlarged as required for Itypes that are
9522
      --  copied during the first phase of the copy operation. The visit
9523
      --  procedures add elements to this map as Itypes are encountered.
9524
      --  The reason we cannot use Map directly, is that it may well be
9525
      --  (and normally is) initialized to No_Elist, and if we have mapped
9526
      --  entities, we have to reset it to point to a real Elist.
9527
 
9528
      function Assoc (N : Node_Or_Entity_Id) return Node_Id;
9529
      --  Called during second phase to map entities into their corresponding
9530
      --  copies using Actual_Map. If the argument is not an entity, or is not
9531
      --  in Actual_Map, then it is returned unchanged.
9532
 
9533
      procedure Build_NCT_Hash_Tables;
9534
      --  Builds hash tables (number of elements >= threshold value)
9535
 
9536
      function Copy_Elist_With_Replacement
9537
        (Old_Elist : Elist_Id) return Elist_Id;
9538
      --  Called during second phase to copy element list doing replacements
9539
 
9540
      procedure Copy_Itype_With_Replacement (New_Itype : Entity_Id);
9541
      --  Called during the second phase to process a copied Itype. The actual
9542
      --  copy happened during the first phase (so that we could make the entry
9543
      --  in the mapping), but we still have to deal with the descendents of
9544
      --  the copied Itype and copy them where necessary.
9545
 
9546
      function Copy_List_With_Replacement (Old_List : List_Id) return List_Id;
9547
      --  Called during second phase to copy list doing replacements
9548
 
9549
      function Copy_Node_With_Replacement (Old_Node : Node_Id) return Node_Id;
9550
      --  Called during second phase to copy node doing replacements
9551
 
9552
      procedure Visit_Elist (E : Elist_Id);
9553
      --  Called during first phase to visit all elements of an Elist
9554
 
9555
      procedure Visit_Field (F : Union_Id; N : Node_Id);
9556
      --  Visit a single field, recursing to call Visit_Node or Visit_List
9557
      --  if the field is a syntactic descendent of the current node (i.e.
9558
      --  its parent is Node N).
9559
 
9560
      procedure Visit_Itype (Old_Itype : Entity_Id);
9561
      --  Called during first phase to visit subsidiary fields of a defining
9562
      --  Itype, and also create a copy and make an entry in the replacement
9563
      --  map for the new copy.
9564
 
9565
      procedure Visit_List (L : List_Id);
9566
      --  Called during first phase to visit all elements of a List
9567
 
9568
      procedure Visit_Node (N : Node_Or_Entity_Id);
9569
      --  Called during first phase to visit a node and all its subtrees
9570
 
9571
      -----------
9572
      -- Assoc --
9573
      -----------
9574
 
9575
      function Assoc (N : Node_Or_Entity_Id) return Node_Id is
9576
         E   : Elmt_Id;
9577
         Ent : Entity_Id;
9578
 
9579
      begin
9580
         if not Has_Extension (N) or else No (Actual_Map) then
9581
            return N;
9582
 
9583
         elsif NCT_Hash_Tables_Used then
9584
            Ent := NCT_Assoc.Get (Entity_Id (N));
9585
 
9586
            if Present (Ent) then
9587
               return Ent;
9588
            else
9589
               return N;
9590
            end if;
9591
 
9592
         --  No hash table used, do serial search
9593
 
9594
         else
9595
            E := First_Elmt (Actual_Map);
9596
            while Present (E) loop
9597
               if Node (E) = N then
9598
                  return Node (Next_Elmt (E));
9599
               else
9600
                  E := Next_Elmt (Next_Elmt (E));
9601
               end if;
9602
            end loop;
9603
         end if;
9604
 
9605
         return N;
9606
      end Assoc;
9607
 
9608
      ---------------------------
9609
      -- Build_NCT_Hash_Tables --
9610
      ---------------------------
9611
 
9612
      procedure Build_NCT_Hash_Tables is
9613
         Elmt : Elmt_Id;
9614
         Ent  : Entity_Id;
9615
      begin
9616
         if NCT_Hash_Table_Setup then
9617
            NCT_Assoc.Reset;
9618
            NCT_Itype_Assoc.Reset;
9619
         end if;
9620
 
9621
         Elmt := First_Elmt (Actual_Map);
9622
         while Present (Elmt) loop
9623
            Ent := Node (Elmt);
9624
 
9625
            --  Get new entity, and associate old and new
9626
 
9627
            Next_Elmt (Elmt);
9628
            NCT_Assoc.Set (Ent, Node (Elmt));
9629
 
9630
            if Is_Type (Ent) then
9631
               declare
9632
                  Anode : constant Entity_Id :=
9633
                            Associated_Node_For_Itype (Ent);
9634
 
9635
               begin
9636
                  if Present (Anode) then
9637
 
9638
                     --  Enter a link between the associated node of the
9639
                     --  old Itype and the new Itype, for updating later
9640
                     --  when node is copied.
9641
 
9642
                     NCT_Itype_Assoc.Set (Anode, Node (Elmt));
9643
                  end if;
9644
               end;
9645
            end if;
9646
 
9647
            Next_Elmt (Elmt);
9648
         end loop;
9649
 
9650
         NCT_Hash_Tables_Used := True;
9651
         NCT_Hash_Table_Setup := True;
9652
      end Build_NCT_Hash_Tables;
9653
 
9654
      ---------------------------------
9655
      -- Copy_Elist_With_Replacement --
9656
      ---------------------------------
9657
 
9658
      function Copy_Elist_With_Replacement
9659
        (Old_Elist : Elist_Id) return Elist_Id
9660
      is
9661
         M         : Elmt_Id;
9662
         New_Elist : Elist_Id;
9663
 
9664
      begin
9665
         if No (Old_Elist) then
9666
            return No_Elist;
9667
 
9668
         else
9669
            New_Elist := New_Elmt_List;
9670
 
9671
            M := First_Elmt (Old_Elist);
9672
            while Present (M) loop
9673
               Append_Elmt (Copy_Node_With_Replacement (Node (M)), New_Elist);
9674
               Next_Elmt (M);
9675
            end loop;
9676
         end if;
9677
 
9678
         return New_Elist;
9679
      end Copy_Elist_With_Replacement;
9680
 
9681
      ---------------------------------
9682
      -- Copy_Itype_With_Replacement --
9683
      ---------------------------------
9684
 
9685
      --  This routine exactly parallels its phase one analog Visit_Itype,
9686
 
9687
      procedure Copy_Itype_With_Replacement (New_Itype : Entity_Id) is
9688
      begin
9689
         --  Translate Next_Entity, Scope and Etype fields, in case they
9690
         --  reference entities that have been mapped into copies.
9691
 
9692
         Set_Next_Entity (New_Itype, Assoc (Next_Entity (New_Itype)));
9693
         Set_Etype       (New_Itype, Assoc (Etype       (New_Itype)));
9694
 
9695
         if Present (New_Scope) then
9696
            Set_Scope    (New_Itype, New_Scope);
9697
         else
9698
            Set_Scope    (New_Itype, Assoc (Scope       (New_Itype)));
9699
         end if;
9700
 
9701
         --  Copy referenced fields
9702
 
9703
         if Is_Discrete_Type (New_Itype) then
9704
            Set_Scalar_Range (New_Itype,
9705
              Copy_Node_With_Replacement (Scalar_Range (New_Itype)));
9706
 
9707
         elsif Has_Discriminants (Base_Type (New_Itype)) then
9708
            Set_Discriminant_Constraint (New_Itype,
9709
              Copy_Elist_With_Replacement
9710
                (Discriminant_Constraint (New_Itype)));
9711
 
9712
         elsif Is_Array_Type (New_Itype) then
9713
            if Present (First_Index (New_Itype)) then
9714
               Set_First_Index (New_Itype,
9715
                 First (Copy_List_With_Replacement
9716
                         (List_Containing (First_Index (New_Itype)))));
9717
            end if;
9718
 
9719
            if Is_Packed (New_Itype) then
9720
               Set_Packed_Array_Type (New_Itype,
9721
                 Copy_Node_With_Replacement
9722
                   (Packed_Array_Type (New_Itype)));
9723
            end if;
9724
         end if;
9725
      end Copy_Itype_With_Replacement;
9726
 
9727
      --------------------------------
9728
      -- Copy_List_With_Replacement --
9729
      --------------------------------
9730
 
9731
      function Copy_List_With_Replacement
9732
        (Old_List : List_Id) return List_Id
9733
      is
9734
         New_List : List_Id;
9735
         E        : Node_Id;
9736
 
9737
      begin
9738
         if Old_List = No_List then
9739
            return No_List;
9740
 
9741
         else
9742
            New_List := Empty_List;
9743
 
9744
            E := First (Old_List);
9745
            while Present (E) loop
9746
               Append (Copy_Node_With_Replacement (E), New_List);
9747
               Next (E);
9748
            end loop;
9749
 
9750
            return New_List;
9751
         end if;
9752
      end Copy_List_With_Replacement;
9753
 
9754
      --------------------------------
9755
      -- Copy_Node_With_Replacement --
9756
      --------------------------------
9757
 
9758
      function Copy_Node_With_Replacement
9759
        (Old_Node : Node_Id) return Node_Id
9760
      is
9761
         New_Node : Node_Id;
9762
 
9763
         procedure Adjust_Named_Associations
9764
           (Old_Node : Node_Id;
9765
            New_Node : Node_Id);
9766
         --  If a call node has named associations, these are chained through
9767
         --  the First_Named_Actual, Next_Named_Actual links. These must be
9768
         --  propagated separately to the new parameter list, because these
9769
         --  are not syntactic fields.
9770
 
9771
         function Copy_Field_With_Replacement
9772
           (Field : Union_Id) return Union_Id;
9773
         --  Given Field, which is a field of Old_Node, return a copy of it
9774
         --  if it is a syntactic field (i.e. its parent is Node), setting
9775
         --  the parent of the copy to poit to New_Node. Otherwise returns
9776
         --  the field (possibly mapped if it is an entity).
9777
 
9778
         -------------------------------
9779
         -- Adjust_Named_Associations --
9780
         -------------------------------
9781
 
9782
         procedure Adjust_Named_Associations
9783
           (Old_Node : Node_Id;
9784
            New_Node : Node_Id)
9785
         is
9786
            Old_E : Node_Id;
9787
            New_E : Node_Id;
9788
 
9789
            Old_Next : Node_Id;
9790
            New_Next : Node_Id;
9791
 
9792
         begin
9793
            Old_E := First (Parameter_Associations (Old_Node));
9794
            New_E := First (Parameter_Associations (New_Node));
9795
            while Present (Old_E) loop
9796
               if Nkind (Old_E) = N_Parameter_Association
9797
                 and then Present (Next_Named_Actual (Old_E))
9798
               then
9799
                  if First_Named_Actual (Old_Node)
9800
                    =  Explicit_Actual_Parameter (Old_E)
9801
                  then
9802
                     Set_First_Named_Actual
9803
                       (New_Node, Explicit_Actual_Parameter (New_E));
9804
                  end if;
9805
 
9806
                  --  Now scan parameter list from the beginning,to locate
9807
                  --  next named actual, which can be out of order.
9808
 
9809
                  Old_Next := First (Parameter_Associations (Old_Node));
9810
                  New_Next := First (Parameter_Associations (New_Node));
9811
 
9812
                  while Nkind (Old_Next) /= N_Parameter_Association
9813
                    or else  Explicit_Actual_Parameter (Old_Next)
9814
                      /= Next_Named_Actual (Old_E)
9815
                  loop
9816
                     Next (Old_Next);
9817
                     Next (New_Next);
9818
                  end loop;
9819
 
9820
                  Set_Next_Named_Actual
9821
                    (New_E, Explicit_Actual_Parameter (New_Next));
9822
               end if;
9823
 
9824
               Next (Old_E);
9825
               Next (New_E);
9826
            end loop;
9827
         end Adjust_Named_Associations;
9828
 
9829
         ---------------------------------
9830
         -- Copy_Field_With_Replacement --
9831
         ---------------------------------
9832
 
9833
         function Copy_Field_With_Replacement
9834
           (Field : Union_Id) return Union_Id
9835
         is
9836
         begin
9837
            if Field = Union_Id (Empty) then
9838
               return Field;
9839
 
9840
            elsif Field in Node_Range then
9841
               declare
9842
                  Old_N : constant Node_Id := Node_Id (Field);
9843
                  New_N : Node_Id;
9844
 
9845
               begin
9846
                  --  If syntactic field, as indicated by the parent pointer
9847
                  --  being set, then copy the referenced node recursively.
9848
 
9849
                  if Parent (Old_N) = Old_Node then
9850
                     New_N := Copy_Node_With_Replacement (Old_N);
9851
 
9852
                     if New_N /= Old_N then
9853
                        Set_Parent (New_N, New_Node);
9854
                     end if;
9855
 
9856
                  --  For semantic fields, update possible entity reference
9857
                  --  from the replacement map.
9858
 
9859
                  else
9860
                     New_N := Assoc (Old_N);
9861
                  end if;
9862
 
9863
                  return Union_Id (New_N);
9864
               end;
9865
 
9866
            elsif Field in List_Range then
9867
               declare
9868
                  Old_L : constant List_Id := List_Id (Field);
9869
                  New_L : List_Id;
9870
 
9871
               begin
9872
                  --  If syntactic field, as indicated by the parent pointer,
9873
                  --  then recursively copy the entire referenced list.
9874
 
9875
                  if Parent (Old_L) = Old_Node then
9876
                     New_L := Copy_List_With_Replacement (Old_L);
9877
                     Set_Parent (New_L, New_Node);
9878
 
9879
                  --  For semantic list, just returned unchanged
9880
 
9881
                  else
9882
                     New_L := Old_L;
9883
                  end if;
9884
 
9885
                  return Union_Id (New_L);
9886
               end;
9887
 
9888
            --  Anything other than a list or a node is returned unchanged
9889
 
9890
            else
9891
               return Field;
9892
            end if;
9893
         end Copy_Field_With_Replacement;
9894
 
9895
      --  Start of processing for Copy_Node_With_Replacement
9896
 
9897
      begin
9898
         if Old_Node <= Empty_Or_Error then
9899
            return Old_Node;
9900
 
9901
         elsif Has_Extension (Old_Node) then
9902
            return Assoc (Old_Node);
9903
 
9904
         else
9905
            New_Node := New_Copy (Old_Node);
9906
 
9907
            --  If the node we are copying is the associated node of a
9908
            --  previously copied Itype, then adjust the associated node
9909
            --  of the copy of that Itype accordingly.
9910
 
9911
            if Present (Actual_Map) then
9912
               declare
9913
                  E   : Elmt_Id;
9914
                  Ent : Entity_Id;
9915
 
9916
               begin
9917
                  --  Case of hash table used
9918
 
9919
                  if NCT_Hash_Tables_Used then
9920
                     Ent := NCT_Itype_Assoc.Get (Old_Node);
9921
 
9922
                     if Present (Ent) then
9923
                        Set_Associated_Node_For_Itype (Ent, New_Node);
9924
                     end if;
9925
 
9926
                  --  Case of no hash table used
9927
 
9928
                  else
9929
                     E := First_Elmt (Actual_Map);
9930
                     while Present (E) loop
9931
                        if Is_Itype (Node (E))
9932
                          and then
9933
                            Old_Node = Associated_Node_For_Itype (Node (E))
9934
                        then
9935
                           Set_Associated_Node_For_Itype
9936
                             (Node (Next_Elmt (E)), New_Node);
9937
                        end if;
9938
 
9939
                        E := Next_Elmt (Next_Elmt (E));
9940
                     end loop;
9941
                  end if;
9942
               end;
9943
            end if;
9944
 
9945
            --  Recursively copy descendents
9946
 
9947
            Set_Field1
9948
              (New_Node, Copy_Field_With_Replacement (Field1 (New_Node)));
9949
            Set_Field2
9950
              (New_Node, Copy_Field_With_Replacement (Field2 (New_Node)));
9951
            Set_Field3
9952
              (New_Node, Copy_Field_With_Replacement (Field3 (New_Node)));
9953
            Set_Field4
9954
              (New_Node, Copy_Field_With_Replacement (Field4 (New_Node)));
9955
            Set_Field5
9956
              (New_Node, Copy_Field_With_Replacement (Field5 (New_Node)));
9957
 
9958
            --  Adjust Sloc of new node if necessary
9959
 
9960
            if New_Sloc /= No_Location then
9961
               Set_Sloc (New_Node, New_Sloc);
9962
 
9963
               --  If we adjust the Sloc, then we are essentially making
9964
               --  a completely new node, so the Comes_From_Source flag
9965
               --  should be reset to the proper default value.
9966
 
9967
               Nodes.Table (New_Node).Comes_From_Source :=
9968
                 Default_Node.Comes_From_Source;
9969
            end if;
9970
 
9971
            --  If the node is call and has named associations,
9972
            --  set the corresponding links in the copy.
9973
 
9974
            if (Nkind (Old_Node) = N_Function_Call
9975
                 or else Nkind (Old_Node) = N_Entry_Call_Statement
9976
                 or else
9977
                   Nkind (Old_Node) = N_Procedure_Call_Statement)
9978
              and then Present (First_Named_Actual (Old_Node))
9979
            then
9980
               Adjust_Named_Associations (Old_Node, New_Node);
9981
            end if;
9982
 
9983
            --  Reset First_Real_Statement for Handled_Sequence_Of_Statements.
9984
            --  The replacement mechanism applies to entities, and is not used
9985
            --  here. Eventually we may need a more general graph-copying
9986
            --  routine. For now, do a sequential search to find desired node.
9987
 
9988
            if Nkind (Old_Node) = N_Handled_Sequence_Of_Statements
9989
              and then Present (First_Real_Statement (Old_Node))
9990
            then
9991
               declare
9992
                  Old_F  : constant Node_Id := First_Real_Statement (Old_Node);
9993
                  N1, N2 : Node_Id;
9994
 
9995
               begin
9996
                  N1 := First (Statements (Old_Node));
9997
                  N2 := First (Statements (New_Node));
9998
 
9999
                  while N1 /= Old_F loop
10000
                     Next (N1);
10001
                     Next (N2);
10002
                  end loop;
10003
 
10004
                  Set_First_Real_Statement (New_Node, N2);
10005
               end;
10006
            end if;
10007
         end if;
10008
 
10009
         --  All done, return copied node
10010
 
10011
         return New_Node;
10012
      end Copy_Node_With_Replacement;
10013
 
10014
      -----------------
10015
      -- Visit_Elist --
10016
      -----------------
10017
 
10018
      procedure Visit_Elist (E : Elist_Id) is
10019
         Elmt : Elmt_Id;
10020
      begin
10021
         if Present (E) then
10022
            Elmt := First_Elmt (E);
10023
 
10024
            while Elmt /= No_Elmt loop
10025
               Visit_Node (Node (Elmt));
10026
               Next_Elmt (Elmt);
10027
            end loop;
10028
         end if;
10029
      end Visit_Elist;
10030
 
10031
      -----------------
10032
      -- Visit_Field --
10033
      -----------------
10034
 
10035
      procedure Visit_Field (F : Union_Id; N : Node_Id) is
10036
      begin
10037
         if F = Union_Id (Empty) then
10038
            return;
10039
 
10040
         elsif F in Node_Range then
10041
 
10042
            --  Copy node if it is syntactic, i.e. its parent pointer is
10043
            --  set to point to the field that referenced it (certain
10044
            --  Itypes will also meet this criterion, which is fine, since
10045
            --  these are clearly Itypes that do need to be copied, since
10046
            --  we are copying their parent.)
10047
 
10048
            if Parent (Node_Id (F)) = N then
10049
               Visit_Node (Node_Id (F));
10050
               return;
10051
 
10052
            --  Another case, if we are pointing to an Itype, then we want
10053
            --  to copy it if its associated node is somewhere in the tree
10054
            --  being copied.
10055
 
10056
            --  Note: the exclusion of self-referential copies is just an
10057
            --  optimization, since the search of the already copied list
10058
            --  would catch it, but it is a common case (Etype pointing
10059
            --  to itself for an Itype that is a base type).
10060
 
10061
            elsif Has_Extension (Node_Id (F))
10062
              and then Is_Itype (Entity_Id (F))
10063
              and then Node_Id (F) /= N
10064
            then
10065
               declare
10066
                  P : Node_Id;
10067
 
10068
               begin
10069
                  P := Associated_Node_For_Itype (Node_Id (F));
10070
                  while Present (P) loop
10071
                     if P = Source then
10072
                        Visit_Node (Node_Id (F));
10073
                        return;
10074
                     else
10075
                        P := Parent (P);
10076
                     end if;
10077
                  end loop;
10078
 
10079
                  --  An Itype whose parent is not being copied definitely
10080
                  --  should NOT be copied, since it does not belong in any
10081
                  --  sense to the copied subtree.
10082
 
10083
                  return;
10084
               end;
10085
            end if;
10086
 
10087
         elsif F in List_Range
10088
           and then Parent (List_Id (F)) = N
10089
         then
10090
            Visit_List (List_Id (F));
10091
            return;
10092
         end if;
10093
      end Visit_Field;
10094
 
10095
      -----------------
10096
      -- Visit_Itype --
10097
      -----------------
10098
 
10099
      procedure Visit_Itype (Old_Itype : Entity_Id) is
10100
         New_Itype : Entity_Id;
10101
         E         : Elmt_Id;
10102
         Ent       : Entity_Id;
10103
 
10104
      begin
10105
         --  Itypes that describe the designated type of access to subprograms
10106
         --  have the structure of subprogram declarations, with signatures,
10107
         --  etc. Either we duplicate the signatures completely, or choose to
10108
         --  share such itypes, which is fine because their elaboration will
10109
         --  have no side effects.
10110
 
10111
         if Ekind (Old_Itype) = E_Subprogram_Type then
10112
            return;
10113
         end if;
10114
 
10115
         New_Itype := New_Copy (Old_Itype);
10116
 
10117
         --  The new Itype has all the attributes of the old one, and
10118
         --  we just copy the contents of the entity. However, the back-end
10119
         --  needs different names for debugging purposes, so we create a
10120
         --  new internal name for it in all cases.
10121
 
10122
         Set_Chars (New_Itype, New_Internal_Name ('T'));
10123
 
10124
         --  If our associated node is an entity that has already been copied,
10125
         --  then set the associated node of the copy to point to the right
10126
         --  copy. If we have copied an Itype that is itself the associated
10127
         --  node of some previously copied Itype, then we set the right
10128
         --  pointer in the other direction.
10129
 
10130
         if Present (Actual_Map) then
10131
 
10132
            --  Case of hash tables used
10133
 
10134
            if NCT_Hash_Tables_Used then
10135
 
10136
               Ent := NCT_Assoc.Get (Associated_Node_For_Itype (Old_Itype));
10137
 
10138
               if Present (Ent) then
10139
                  Set_Associated_Node_For_Itype (New_Itype, Ent);
10140
               end if;
10141
 
10142
               Ent := NCT_Itype_Assoc.Get (Old_Itype);
10143
               if Present (Ent) then
10144
                  Set_Associated_Node_For_Itype (Ent, New_Itype);
10145
 
10146
               --  If the hash table has no association for this Itype and
10147
               --  its associated node, enter one now.
10148
 
10149
               else
10150
                  NCT_Itype_Assoc.Set
10151
                    (Associated_Node_For_Itype (Old_Itype), New_Itype);
10152
               end if;
10153
 
10154
            --  Case of hash tables not used
10155
 
10156
            else
10157
               E := First_Elmt (Actual_Map);
10158
               while Present (E) loop
10159
                  if Associated_Node_For_Itype (Old_Itype) = Node (E) then
10160
                     Set_Associated_Node_For_Itype
10161
                       (New_Itype, Node (Next_Elmt (E)));
10162
                  end if;
10163
 
10164
                  if Is_Type (Node (E))
10165
                    and then
10166
                      Old_Itype = Associated_Node_For_Itype (Node (E))
10167
                  then
10168
                     Set_Associated_Node_For_Itype
10169
                       (Node (Next_Elmt (E)), New_Itype);
10170
                  end if;
10171
 
10172
                  E := Next_Elmt (Next_Elmt (E));
10173
               end loop;
10174
            end if;
10175
         end if;
10176
 
10177
         if Present (Freeze_Node (New_Itype)) then
10178
            Set_Is_Frozen (New_Itype, False);
10179
            Set_Freeze_Node (New_Itype, Empty);
10180
         end if;
10181
 
10182
         --  Add new association to map
10183
 
10184
         if No (Actual_Map) then
10185
            Actual_Map := New_Elmt_List;
10186
         end if;
10187
 
10188
         Append_Elmt (Old_Itype, Actual_Map);
10189
         Append_Elmt (New_Itype, Actual_Map);
10190
 
10191
         if NCT_Hash_Tables_Used then
10192
            NCT_Assoc.Set (Old_Itype, New_Itype);
10193
 
10194
         else
10195
            NCT_Table_Entries := NCT_Table_Entries + 1;
10196
 
10197
            if NCT_Table_Entries > NCT_Hash_Threshold then
10198
               Build_NCT_Hash_Tables;
10199
            end if;
10200
         end if;
10201
 
10202
         --  If a record subtype is simply copied, the entity list will be
10203
         --  shared. Thus cloned_Subtype must be set to indicate the sharing.
10204
 
10205
         if Ekind_In (Old_Itype, E_Record_Subtype, E_Class_Wide_Subtype) then
10206
            Set_Cloned_Subtype (New_Itype, Old_Itype);
10207
         end if;
10208
 
10209
         --  Visit descendents that eventually get copied
10210
 
10211
         Visit_Field (Union_Id (Etype (Old_Itype)), Old_Itype);
10212
 
10213
         if Is_Discrete_Type (Old_Itype) then
10214
            Visit_Field (Union_Id (Scalar_Range (Old_Itype)), Old_Itype);
10215
 
10216
         elsif Has_Discriminants (Base_Type (Old_Itype)) then
10217
            --  ??? This should involve call to Visit_Field
10218
            Visit_Elist (Discriminant_Constraint (Old_Itype));
10219
 
10220
         elsif Is_Array_Type (Old_Itype) then
10221
            if Present (First_Index (Old_Itype)) then
10222
               Visit_Field (Union_Id (List_Containing
10223
                                (First_Index (Old_Itype))),
10224
                            Old_Itype);
10225
            end if;
10226
 
10227
            if Is_Packed (Old_Itype) then
10228
               Visit_Field (Union_Id (Packed_Array_Type (Old_Itype)),
10229
                            Old_Itype);
10230
            end if;
10231
         end if;
10232
      end Visit_Itype;
10233
 
10234
      ----------------
10235
      -- Visit_List --
10236
      ----------------
10237
 
10238
      procedure Visit_List (L : List_Id) is
10239
         N : Node_Id;
10240
      begin
10241
         if L /= No_List then
10242
            N := First (L);
10243
 
10244
            while Present (N) loop
10245
               Visit_Node (N);
10246
               Next (N);
10247
            end loop;
10248
         end if;
10249
      end Visit_List;
10250
 
10251
      ----------------
10252
      -- Visit_Node --
10253
      ----------------
10254
 
10255
      procedure Visit_Node (N : Node_Or_Entity_Id) is
10256
 
10257
      --  Start of processing for Visit_Node
10258
 
10259
      begin
10260
         --  Handle case of an Itype, which must be copied
10261
 
10262
         if Has_Extension (N)
10263
           and then Is_Itype (N)
10264
         then
10265
            --  Nothing to do if already in the list. This can happen with an
10266
            --  Itype entity that appears more than once in the tree.
10267
            --  Note that we do not want to visit descendents in this case.
10268
 
10269
            --  Test for already in list when hash table is used
10270
 
10271
            if NCT_Hash_Tables_Used then
10272
               if Present (NCT_Assoc.Get (Entity_Id (N))) then
10273
                  return;
10274
               end if;
10275
 
10276
            --  Test for already in list when hash table not used
10277
 
10278
            else
10279
               declare
10280
                  E : Elmt_Id;
10281
               begin
10282
                  if Present (Actual_Map) then
10283
                     E := First_Elmt (Actual_Map);
10284
                     while Present (E) loop
10285
                        if Node (E) = N then
10286
                           return;
10287
                        else
10288
                           E := Next_Elmt (Next_Elmt (E));
10289
                        end if;
10290
                     end loop;
10291
                  end if;
10292
               end;
10293
            end if;
10294
 
10295
            Visit_Itype (N);
10296
         end if;
10297
 
10298
         --  Visit descendents
10299
 
10300
         Visit_Field (Field1 (N), N);
10301
         Visit_Field (Field2 (N), N);
10302
         Visit_Field (Field3 (N), N);
10303
         Visit_Field (Field4 (N), N);
10304
         Visit_Field (Field5 (N), N);
10305
      end Visit_Node;
10306
 
10307
   --  Start of processing for New_Copy_Tree
10308
 
10309
   begin
10310
      Actual_Map := Map;
10311
 
10312
      --  See if we should use hash table
10313
 
10314
      if No (Actual_Map) then
10315
         NCT_Hash_Tables_Used := False;
10316
 
10317
      else
10318
         declare
10319
            Elmt : Elmt_Id;
10320
 
10321
         begin
10322
            NCT_Table_Entries := 0;
10323
 
10324
            Elmt := First_Elmt (Actual_Map);
10325
            while Present (Elmt) loop
10326
               NCT_Table_Entries := NCT_Table_Entries + 1;
10327
               Next_Elmt (Elmt);
10328
               Next_Elmt (Elmt);
10329
            end loop;
10330
 
10331
            if NCT_Table_Entries > NCT_Hash_Threshold then
10332
               Build_NCT_Hash_Tables;
10333
            else
10334
               NCT_Hash_Tables_Used := False;
10335
            end if;
10336
         end;
10337
      end if;
10338
 
10339
      --  Hash table set up if required, now start phase one by visiting
10340
      --  top node (we will recursively visit the descendents).
10341
 
10342
      Visit_Node (Source);
10343
 
10344
      --  Now the second phase of the copy can start. First we process
10345
      --  all the mapped entities, copying their descendents.
10346
 
10347
      if Present (Actual_Map) then
10348
         declare
10349
            Elmt      : Elmt_Id;
10350
            New_Itype : Entity_Id;
10351
         begin
10352
            Elmt := First_Elmt (Actual_Map);
10353
            while Present (Elmt) loop
10354
               Next_Elmt (Elmt);
10355
               New_Itype := Node (Elmt);
10356
               Copy_Itype_With_Replacement (New_Itype);
10357
               Next_Elmt (Elmt);
10358
            end loop;
10359
         end;
10360
      end if;
10361
 
10362
      --  Now we can copy the actual tree
10363
 
10364
      return Copy_Node_With_Replacement (Source);
10365
   end New_Copy_Tree;
10366
 
10367
   -------------------------
10368
   -- New_External_Entity --
10369
   -------------------------
10370
 
10371
   function New_External_Entity
10372
     (Kind         : Entity_Kind;
10373
      Scope_Id     : Entity_Id;
10374
      Sloc_Value   : Source_Ptr;
10375
      Related_Id   : Entity_Id;
10376
      Suffix       : Character;
10377
      Suffix_Index : Nat := 0;
10378
      Prefix       : Character := ' ') return Entity_Id
10379
   is
10380
      N : constant Entity_Id :=
10381
            Make_Defining_Identifier (Sloc_Value,
10382
              New_External_Name
10383
                (Chars (Related_Id), Suffix, Suffix_Index, Prefix));
10384
 
10385
   begin
10386
      Set_Ekind          (N, Kind);
10387
      Set_Is_Internal    (N, True);
10388
      Append_Entity      (N, Scope_Id);
10389
      Set_Public_Status  (N);
10390
 
10391
      if Kind in Type_Kind then
10392
         Init_Size_Align (N);
10393
      end if;
10394
 
10395
      return N;
10396
   end New_External_Entity;
10397
 
10398
   -------------------------
10399
   -- New_Internal_Entity --
10400
   -------------------------
10401
 
10402
   function New_Internal_Entity
10403
     (Kind       : Entity_Kind;
10404
      Scope_Id   : Entity_Id;
10405
      Sloc_Value : Source_Ptr;
10406
      Id_Char    : Character) return Entity_Id
10407
   is
10408
      N : constant Entity_Id := Make_Temporary (Sloc_Value, Id_Char);
10409
 
10410
   begin
10411
      Set_Ekind          (N, Kind);
10412
      Set_Is_Internal    (N, True);
10413
      Append_Entity      (N, Scope_Id);
10414
 
10415
      if Kind in Type_Kind then
10416
         Init_Size_Align (N);
10417
      end if;
10418
 
10419
      return N;
10420
   end New_Internal_Entity;
10421
 
10422
   -----------------
10423
   -- Next_Actual --
10424
   -----------------
10425
 
10426
   function Next_Actual (Actual_Id : Node_Id) return Node_Id is
10427
      N  : Node_Id;
10428
 
10429
   begin
10430
      --  If we are pointing at a positional parameter, it is a member of a
10431
      --  node list (the list of parameters), and the next parameter is the
10432
      --  next node on the list, unless we hit a parameter association, then
10433
      --  we shift to using the chain whose head is the First_Named_Actual in
10434
      --  the parent, and then is threaded using the Next_Named_Actual of the
10435
      --  Parameter_Association. All this fiddling is because the original node
10436
      --  list is in the textual call order, and what we need is the
10437
      --  declaration order.
10438
 
10439
      if Is_List_Member (Actual_Id) then
10440
         N := Next (Actual_Id);
10441
 
10442
         if Nkind (N) = N_Parameter_Association then
10443
            return First_Named_Actual (Parent (Actual_Id));
10444
         else
10445
            return N;
10446
         end if;
10447
 
10448
      else
10449
         return Next_Named_Actual (Parent (Actual_Id));
10450
      end if;
10451
   end Next_Actual;
10452
 
10453
   procedure Next_Actual (Actual_Id : in out Node_Id) is
10454
   begin
10455
      Actual_Id := Next_Actual (Actual_Id);
10456
   end Next_Actual;
10457
 
10458
   -----------------------
10459
   -- Normalize_Actuals --
10460
   -----------------------
10461
 
10462
   --  Chain actuals according to formals of subprogram. If there are no named
10463
   --  associations, the chain is simply the list of Parameter Associations,
10464
   --  since the order is the same as the declaration order. If there are named
10465
   --  associations, then the First_Named_Actual field in the N_Function_Call
10466
   --  or N_Procedure_Call_Statement node points to the Parameter_Association
10467
   --  node for the parameter that comes first in declaration order. The
10468
   --  remaining named parameters are then chained in declaration order using
10469
   --  Next_Named_Actual.
10470
 
10471
   --  This routine also verifies that the number of actuals is compatible with
10472
   --  the number and default values of formals, but performs no type checking
10473
   --  (type checking is done by the caller).
10474
 
10475
   --  If the matching succeeds, Success is set to True and the caller proceeds
10476
   --  with type-checking. If the match is unsuccessful, then Success is set to
10477
   --  False, and the caller attempts a different interpretation, if there is
10478
   --  one.
10479
 
10480
   --  If the flag Report is on, the call is not overloaded, and a failure to
10481
   --  match can be reported here, rather than in the caller.
10482
 
10483
   procedure Normalize_Actuals
10484
     (N       : Node_Id;
10485
      S       : Entity_Id;
10486
      Report  : Boolean;
10487
      Success : out Boolean)
10488
   is
10489
      Actuals     : constant List_Id := Parameter_Associations (N);
10490
      Actual      : Node_Id := Empty;
10491
      Formal      : Entity_Id;
10492
      Last        : Node_Id := Empty;
10493
      First_Named : Node_Id := Empty;
10494
      Found       : Boolean;
10495
 
10496
      Formals_To_Match : Integer := 0;
10497
      Actuals_To_Match : Integer := 0;
10498
 
10499
      procedure Chain (A : Node_Id);
10500
      --  Add named actual at the proper place in the list, using the
10501
      --  Next_Named_Actual link.
10502
 
10503
      function Reporting return Boolean;
10504
      --  Determines if an error is to be reported. To report an error, we
10505
      --  need Report to be True, and also we do not report errors caused
10506
      --  by calls to init procs that occur within other init procs. Such
10507
      --  errors must always be cascaded errors, since if all the types are
10508
      --  declared correctly, the compiler will certainly build decent calls!
10509
 
10510
      -----------
10511
      -- Chain --
10512
      -----------
10513
 
10514
      procedure Chain (A : Node_Id) is
10515
      begin
10516
         if No (Last) then
10517
 
10518
            --  Call node points to first actual in list
10519
 
10520
            Set_First_Named_Actual (N, Explicit_Actual_Parameter (A));
10521
 
10522
         else
10523
            Set_Next_Named_Actual (Last, Explicit_Actual_Parameter (A));
10524
         end if;
10525
 
10526
         Last := A;
10527
         Set_Next_Named_Actual (Last, Empty);
10528
      end Chain;
10529
 
10530
      ---------------
10531
      -- Reporting --
10532
      ---------------
10533
 
10534
      function Reporting return Boolean is
10535
      begin
10536
         if not Report then
10537
            return False;
10538
 
10539
         elsif not Within_Init_Proc then
10540
            return True;
10541
 
10542
         elsif Is_Init_Proc (Entity (Name (N))) then
10543
            return False;
10544
 
10545
         else
10546
            return True;
10547
         end if;
10548
      end Reporting;
10549
 
10550
   --  Start of processing for Normalize_Actuals
10551
 
10552
   begin
10553
      if Is_Access_Type (S) then
10554
 
10555
         --  The name in the call is a function call that returns an access
10556
         --  to subprogram. The designated type has the list of formals.
10557
 
10558
         Formal := First_Formal (Designated_Type (S));
10559
      else
10560
         Formal := First_Formal (S);
10561
      end if;
10562
 
10563
      while Present (Formal) loop
10564
         Formals_To_Match := Formals_To_Match + 1;
10565
         Next_Formal (Formal);
10566
      end loop;
10567
 
10568
      --  Find if there is a named association, and verify that no positional
10569
      --  associations appear after named ones.
10570
 
10571
      if Present (Actuals) then
10572
         Actual := First (Actuals);
10573
      end if;
10574
 
10575
      while Present (Actual)
10576
        and then Nkind (Actual) /= N_Parameter_Association
10577
      loop
10578
         Actuals_To_Match := Actuals_To_Match + 1;
10579
         Next (Actual);
10580
      end loop;
10581
 
10582
      if No (Actual) and Actuals_To_Match = Formals_To_Match then
10583
 
10584
         --  Most common case: positional notation, no defaults
10585
 
10586
         Success := True;
10587
         return;
10588
 
10589
      elsif Actuals_To_Match > Formals_To_Match then
10590
 
10591
         --  Too many actuals: will not work
10592
 
10593
         if Reporting then
10594
            if Is_Entity_Name (Name (N)) then
10595
               Error_Msg_N ("too many arguments in call to&", Name (N));
10596
            else
10597
               Error_Msg_N ("too many arguments in call", N);
10598
            end if;
10599
         end if;
10600
 
10601
         Success := False;
10602
         return;
10603
      end if;
10604
 
10605
      First_Named := Actual;
10606
 
10607
      while Present (Actual) loop
10608
         if Nkind (Actual) /= N_Parameter_Association then
10609
            Error_Msg_N
10610
              ("positional parameters not allowed after named ones", Actual);
10611
            Success := False;
10612
            return;
10613
 
10614
         else
10615
            Actuals_To_Match := Actuals_To_Match + 1;
10616
         end if;
10617
 
10618
         Next (Actual);
10619
      end loop;
10620
 
10621
      if Present (Actuals) then
10622
         Actual := First (Actuals);
10623
      end if;
10624
 
10625
      Formal := First_Formal (S);
10626
      while Present (Formal) loop
10627
 
10628
         --  Match the formals in order. If the corresponding actual is
10629
         --  positional, nothing to do. Else scan the list of named actuals
10630
         --  to find the one with the right name.
10631
 
10632
         if Present (Actual)
10633
           and then Nkind (Actual) /= N_Parameter_Association
10634
         then
10635
            Next (Actual);
10636
            Actuals_To_Match := Actuals_To_Match - 1;
10637
            Formals_To_Match := Formals_To_Match - 1;
10638
 
10639
         else
10640
            --  For named parameters, search the list of actuals to find
10641
            --  one that matches the next formal name.
10642
 
10643
            Actual := First_Named;
10644
            Found  := False;
10645
            while Present (Actual) loop
10646
               if Chars (Selector_Name (Actual)) = Chars (Formal) then
10647
                  Found := True;
10648
                  Chain (Actual);
10649
                  Actuals_To_Match := Actuals_To_Match - 1;
10650
                  Formals_To_Match := Formals_To_Match - 1;
10651
                  exit;
10652
               end if;
10653
 
10654
               Next (Actual);
10655
            end loop;
10656
 
10657
            if not Found then
10658
               if Ekind (Formal) /= E_In_Parameter
10659
                 or else No (Default_Value (Formal))
10660
               then
10661
                  if Reporting then
10662
                     if (Comes_From_Source (S)
10663
                          or else Sloc (S) = Standard_Location)
10664
                       and then Is_Overloadable (S)
10665
                     then
10666
                        if No (Actuals)
10667
                          and then
10668
                           (Nkind (Parent (N)) = N_Procedure_Call_Statement
10669
                             or else
10670
                           (Nkind (Parent (N)) = N_Function_Call
10671
                             or else
10672
                            Nkind (Parent (N)) = N_Parameter_Association))
10673
                          and then Ekind (S) /= E_Function
10674
                        then
10675
                           Set_Etype (N, Etype (S));
10676
                        else
10677
                           Error_Msg_Name_1 := Chars (S);
10678
                           Error_Msg_Sloc := Sloc (S);
10679
                           Error_Msg_NE
10680
                             ("missing argument for parameter & " &
10681
                                "in call to % declared #", N, Formal);
10682
                        end if;
10683
 
10684
                     elsif Is_Overloadable (S) then
10685
                        Error_Msg_Name_1 := Chars (S);
10686
 
10687
                        --  Point to type derivation that generated the
10688
                        --  operation.
10689
 
10690
                        Error_Msg_Sloc := Sloc (Parent (S));
10691
 
10692
                        Error_Msg_NE
10693
                          ("missing argument for parameter & " &
10694
                             "in call to % (inherited) #", N, Formal);
10695
 
10696
                     else
10697
                        Error_Msg_NE
10698
                          ("missing argument for parameter &", N, Formal);
10699
                     end if;
10700
                  end if;
10701
 
10702
                  Success := False;
10703
                  return;
10704
 
10705
               else
10706
                  Formals_To_Match := Formals_To_Match - 1;
10707
               end if;
10708
            end if;
10709
         end if;
10710
 
10711
         Next_Formal (Formal);
10712
      end loop;
10713
 
10714
      if Formals_To_Match = 0 and then Actuals_To_Match = 0 then
10715
         Success := True;
10716
         return;
10717
 
10718
      else
10719
         if Reporting then
10720
 
10721
            --  Find some superfluous named actual that did not get
10722
            --  attached to the list of associations.
10723
 
10724
            Actual := First (Actuals);
10725
            while Present (Actual) loop
10726
               if Nkind (Actual) = N_Parameter_Association
10727
                 and then Actual /= Last
10728
                 and then No (Next_Named_Actual (Actual))
10729
               then
10730
                  Error_Msg_N ("unmatched actual & in call",
10731
                    Selector_Name (Actual));
10732
                  exit;
10733
               end if;
10734
 
10735
               Next (Actual);
10736
            end loop;
10737
         end if;
10738
 
10739
         Success := False;
10740
         return;
10741
      end if;
10742
   end Normalize_Actuals;
10743
 
10744
   --------------------------------
10745
   -- Note_Possible_Modification --
10746
   --------------------------------
10747
 
10748
   procedure Note_Possible_Modification (N : Node_Id; Sure : Boolean) is
10749
      Modification_Comes_From_Source : constant Boolean :=
10750
                                         Comes_From_Source (Parent (N));
10751
 
10752
      Ent : Entity_Id;
10753
      Exp : Node_Id;
10754
 
10755
   begin
10756
      --  Loop to find referenced entity, if there is one
10757
 
10758
      Exp := N;
10759
      loop
10760
         <<Continue>>
10761
         Ent := Empty;
10762
 
10763
         if Is_Entity_Name (Exp) then
10764
            Ent := Entity (Exp);
10765
 
10766
            --  If the entity is missing, it is an undeclared identifier,
10767
            --  and there is nothing to annotate.
10768
 
10769
            if No (Ent) then
10770
               return;
10771
            end if;
10772
 
10773
         elsif Nkind (Exp) = N_Explicit_Dereference then
10774
            declare
10775
               P : constant Node_Id := Prefix (Exp);
10776
 
10777
            begin
10778
               --  In formal verification mode, keep track of all reads and
10779
               --  writes through explicit dereferences.
10780
 
10781
               if Alfa_Mode then
10782
                  Alfa.Generate_Dereference (N, 'm');
10783
               end if;
10784
 
10785
               if Nkind (P) = N_Selected_Component
10786
                 and then Present (
10787
                   Entry_Formal (Entity (Selector_Name (P))))
10788
               then
10789
                  --  Case of a reference to an entry formal
10790
 
10791
                  Ent := Entry_Formal (Entity (Selector_Name (P)));
10792
 
10793
               elsif Nkind (P) = N_Identifier
10794
                 and then Nkind (Parent (Entity (P))) = N_Object_Declaration
10795
                 and then Present (Expression (Parent (Entity (P))))
10796
                 and then Nkind (Expression (Parent (Entity (P))))
10797
                   = N_Reference
10798
               then
10799
                  --  Case of a reference to a value on which side effects have
10800
                  --  been removed.
10801
 
10802
                  Exp := Prefix (Expression (Parent (Entity (P))));
10803
                  goto Continue;
10804
 
10805
               else
10806
                  return;
10807
 
10808
               end if;
10809
            end;
10810
 
10811
         elsif     Nkind (Exp) = N_Type_Conversion
10812
           or else Nkind (Exp) = N_Unchecked_Type_Conversion
10813
         then
10814
            Exp := Expression (Exp);
10815
            goto Continue;
10816
 
10817
         elsif     Nkind (Exp) = N_Slice
10818
           or else Nkind (Exp) = N_Indexed_Component
10819
           or else Nkind (Exp) = N_Selected_Component
10820
         then
10821
            Exp := Prefix (Exp);
10822
            goto Continue;
10823
 
10824
         else
10825
            return;
10826
         end if;
10827
 
10828
         --  Now look for entity being referenced
10829
 
10830
         if Present (Ent) then
10831
            if Is_Object (Ent) then
10832
               if Comes_From_Source (Exp)
10833
                 or else Modification_Comes_From_Source
10834
               then
10835
                  --  Give warning if pragma unmodified given and we are
10836
                  --  sure this is a modification.
10837
 
10838
                  if Has_Pragma_Unmodified (Ent) and then Sure then
10839
                     Error_Msg_NE ("?pragma Unmodified given for &!", N, Ent);
10840
                  end if;
10841
 
10842
                  Set_Never_Set_In_Source (Ent, False);
10843
               end if;
10844
 
10845
               Set_Is_True_Constant (Ent, False);
10846
               Set_Current_Value    (Ent, Empty);
10847
               Set_Is_Known_Null    (Ent, False);
10848
 
10849
               if not Can_Never_Be_Null (Ent) then
10850
                  Set_Is_Known_Non_Null (Ent, False);
10851
               end if;
10852
 
10853
               --  Follow renaming chain
10854
 
10855
               if (Ekind (Ent) = E_Variable or else Ekind (Ent) = E_Constant)
10856
                 and then Present (Renamed_Object (Ent))
10857
               then
10858
                  Exp := Renamed_Object (Ent);
10859
                  goto Continue;
10860
 
10861
               --  The expression may be the renaming of a subcomponent of an
10862
               --  array or container. The assignment to the subcomponent is
10863
               --  a modification of the container.
10864
 
10865
               elsif Comes_From_Source (Original_Node (Exp))
10866
                 and then Nkind_In (Original_Node (Exp), N_Selected_Component,
10867
                                                         N_Indexed_Component)
10868
               then
10869
                  Exp := Prefix (Original_Node (Exp));
10870
                  goto Continue;
10871
               end if;
10872
 
10873
               --  Generate a reference only if the assignment comes from
10874
               --  source. This excludes, for example, calls to a dispatching
10875
               --  assignment operation when the left-hand side is tagged.
10876
 
10877
               if Modification_Comes_From_Source or else Alfa_Mode then
10878
                  Generate_Reference (Ent, Exp, 'm');
10879
 
10880
                  --  If the target of the assignment is the bound variable
10881
                  --  in an iterator, indicate that the corresponding array
10882
                  --  or container is also modified.
10883
 
10884
                  if Ada_Version >= Ada_2012
10885
                    and then
10886
                      Nkind (Parent (Ent)) = N_Iterator_Specification
10887
                  then
10888
                     declare
10889
                        Domain : constant Node_Id := Name (Parent (Ent));
10890
 
10891
                     begin
10892
                        --  TBD : in the full version of the construct, the
10893
                        --  domain of iteration can be given by an expression.
10894
 
10895
                        if Is_Entity_Name (Domain) then
10896
                           Generate_Reference      (Entity (Domain), Exp, 'm');
10897
                           Set_Is_True_Constant    (Entity (Domain), False);
10898
                           Set_Never_Set_In_Source (Entity (Domain), False);
10899
                        end if;
10900
                     end;
10901
                  end if;
10902
               end if;
10903
 
10904
               Check_Nested_Access (Ent);
10905
            end if;
10906
 
10907
            Kill_Checks (Ent);
10908
 
10909
            --  If we are sure this is a modification from source, and we know
10910
            --  this modifies a constant, then give an appropriate warning.
10911
 
10912
            if Overlays_Constant (Ent)
10913
              and then Modification_Comes_From_Source
10914
              and then Sure
10915
            then
10916
               declare
10917
                  A : constant Node_Id := Address_Clause (Ent);
10918
               begin
10919
                  if Present (A) then
10920
                     declare
10921
                        Exp : constant Node_Id := Expression (A);
10922
                     begin
10923
                        if Nkind (Exp) = N_Attribute_Reference
10924
                          and then Attribute_Name (Exp) = Name_Address
10925
                          and then Is_Entity_Name (Prefix (Exp))
10926
                        then
10927
                           Error_Msg_Sloc := Sloc (A);
10928
                           Error_Msg_NE
10929
                             ("constant& may be modified via address clause#?",
10930
                              N, Entity (Prefix (Exp)));
10931
                        end if;
10932
                     end;
10933
                  end if;
10934
               end;
10935
            end if;
10936
 
10937
            return;
10938
         end if;
10939
      end loop;
10940
   end Note_Possible_Modification;
10941
 
10942
   -------------------------
10943
   -- Object_Access_Level --
10944
   -------------------------
10945
 
10946
   function Object_Access_Level (Obj : Node_Id) return Uint is
10947
      E : Entity_Id;
10948
 
10949
   --  Returns the static accessibility level of the view denoted by Obj. Note
10950
   --  that the value returned is the result of a call to Scope_Depth. Only
10951
   --  scope depths associated with dynamic scopes can actually be returned.
10952
   --  Since only relative levels matter for accessibility checking, the fact
10953
   --  that the distance between successive levels of accessibility is not
10954
   --  always one is immaterial (invariant: if level(E2) is deeper than
10955
   --  level(E1), then Scope_Depth(E1) < Scope_Depth(E2)).
10956
 
10957
      function Reference_To (Obj : Node_Id) return Node_Id;
10958
      --  An explicit dereference is created when removing side-effects from
10959
      --  expressions for constraint checking purposes. In this case a local
10960
      --  access type is created for it. The correct access level is that of
10961
      --  the original source node. We detect this case by noting that the
10962
      --  prefix of the dereference is created by an object declaration whose
10963
      --  initial expression is a reference.
10964
 
10965
      ------------------
10966
      -- Reference_To --
10967
      ------------------
10968
 
10969
      function Reference_To (Obj : Node_Id) return Node_Id is
10970
         Pref : constant Node_Id := Prefix (Obj);
10971
      begin
10972
         if Is_Entity_Name (Pref)
10973
           and then Nkind (Parent (Entity (Pref))) = N_Object_Declaration
10974
           and then Present (Expression (Parent (Entity (Pref))))
10975
           and then Nkind (Expression (Parent (Entity (Pref)))) = N_Reference
10976
         then
10977
            return (Prefix (Expression (Parent (Entity (Pref)))));
10978
         else
10979
            return Empty;
10980
         end if;
10981
      end Reference_To;
10982
 
10983
   --  Start of processing for Object_Access_Level
10984
 
10985
   begin
10986
      if Nkind (Obj) = N_Defining_Identifier
10987
        or else Is_Entity_Name (Obj)
10988
      then
10989
         if Nkind (Obj) = N_Defining_Identifier then
10990
            E := Obj;
10991
         else
10992
            E := Entity (Obj);
10993
         end if;
10994
 
10995
         if Is_Prival (E) then
10996
            E := Prival_Link (E);
10997
         end if;
10998
 
10999
         --  If E is a type then it denotes a current instance. For this case
11000
         --  we add one to the normal accessibility level of the type to ensure
11001
         --  that current instances are treated as always being deeper than
11002
         --  than the level of any visible named access type (see 3.10.2(21)).
11003
 
11004
         if Is_Type (E) then
11005
            return Type_Access_Level (E) +  1;
11006
 
11007
         elsif Present (Renamed_Object (E)) then
11008
            return Object_Access_Level (Renamed_Object (E));
11009
 
11010
         --  Similarly, if E is a component of the current instance of a
11011
         --  protected type, any instance of it is assumed to be at a deeper
11012
         --  level than the type. For a protected object (whose type is an
11013
         --  anonymous protected type) its components are at the same level
11014
         --  as the type itself.
11015
 
11016
         elsif not Is_Overloadable (E)
11017
           and then Ekind (Scope (E)) = E_Protected_Type
11018
           and then Comes_From_Source (Scope (E))
11019
         then
11020
            return Type_Access_Level (Scope (E)) + 1;
11021
 
11022
         else
11023
            return Scope_Depth (Enclosing_Dynamic_Scope (E));
11024
         end if;
11025
 
11026
      elsif Nkind (Obj) = N_Selected_Component then
11027
         if Is_Access_Type (Etype (Prefix (Obj))) then
11028
            return Type_Access_Level (Etype (Prefix (Obj)));
11029
         else
11030
            return Object_Access_Level (Prefix (Obj));
11031
         end if;
11032
 
11033
      elsif Nkind (Obj) = N_Indexed_Component then
11034
         if Is_Access_Type (Etype (Prefix (Obj))) then
11035
            return Type_Access_Level (Etype (Prefix (Obj)));
11036
         else
11037
            return Object_Access_Level (Prefix (Obj));
11038
         end if;
11039
 
11040
      elsif Nkind (Obj) = N_Explicit_Dereference then
11041
 
11042
         --  If the prefix is a selected access discriminant then we make a
11043
         --  recursive call on the prefix, which will in turn check the level
11044
         --  of the prefix object of the selected discriminant.
11045
 
11046
         if Nkind (Prefix (Obj)) = N_Selected_Component
11047
           and then Ekind (Etype (Prefix (Obj))) = E_Anonymous_Access_Type
11048
           and then
11049
             Ekind (Entity (Selector_Name (Prefix (Obj)))) = E_Discriminant
11050
         then
11051
            return Object_Access_Level (Prefix (Obj));
11052
 
11053
         elsif not (Comes_From_Source (Obj)) then
11054
            declare
11055
               Ref : constant Node_Id := Reference_To (Obj);
11056
            begin
11057
               if Present (Ref) then
11058
                  return Object_Access_Level (Ref);
11059
               else
11060
                  return Type_Access_Level (Etype (Prefix (Obj)));
11061
               end if;
11062
            end;
11063
 
11064
         else
11065
            return Type_Access_Level (Etype (Prefix (Obj)));
11066
         end if;
11067
 
11068
      elsif Nkind (Obj) = N_Type_Conversion
11069
        or else Nkind (Obj) = N_Unchecked_Type_Conversion
11070
      then
11071
         return Object_Access_Level (Expression (Obj));
11072
 
11073
      elsif Nkind (Obj) = N_Function_Call then
11074
 
11075
         --  Function results are objects, so we get either the access level of
11076
         --  the function or, in the case of an indirect call, the level of the
11077
         --  access-to-subprogram type. (This code is used for Ada 95, but it
11078
         --  looks wrong, because it seems that we should be checking the level
11079
         --  of the call itself, even for Ada 95. However, using the Ada 2005
11080
         --  version of the code causes regressions in several tests that are
11081
         --  compiled with -gnat95. ???)
11082
 
11083
         if Ada_Version < Ada_2005 then
11084
            if Is_Entity_Name (Name (Obj)) then
11085
               return Subprogram_Access_Level (Entity (Name (Obj)));
11086
            else
11087
               return Type_Access_Level (Etype (Prefix (Name (Obj))));
11088
            end if;
11089
 
11090
         --  For Ada 2005, the level of the result object of a function call is
11091
         --  defined to be the level of the call's innermost enclosing master.
11092
         --  We determine that by querying the depth of the innermost enclosing
11093
         --  dynamic scope.
11094
 
11095
         else
11096
            Return_Master_Scope_Depth_Of_Call : declare
11097
 
11098
               function Innermost_Master_Scope_Depth
11099
                 (N : Node_Id) return Uint;
11100
               --  Returns the scope depth of the given node's innermost
11101
               --  enclosing dynamic scope (effectively the accessibility
11102
               --  level of the innermost enclosing master).
11103
 
11104
               ----------------------------------
11105
               -- Innermost_Master_Scope_Depth --
11106
               ----------------------------------
11107
 
11108
               function Innermost_Master_Scope_Depth
11109
                 (N : Node_Id) return Uint
11110
               is
11111
                  Node_Par : Node_Id := Parent (N);
11112
 
11113
               begin
11114
                  --  Locate the nearest enclosing node (by traversing Parents)
11115
                  --  that Defining_Entity can be applied to, and return the
11116
                  --  depth of that entity's nearest enclosing dynamic scope.
11117
 
11118
                  while Present (Node_Par) loop
11119
                     case Nkind (Node_Par) is
11120
                        when N_Component_Declaration           |
11121
                             N_Entry_Declaration               |
11122
                             N_Formal_Object_Declaration       |
11123
                             N_Formal_Type_Declaration         |
11124
                             N_Full_Type_Declaration           |
11125
                             N_Incomplete_Type_Declaration     |
11126
                             N_Loop_Parameter_Specification    |
11127
                             N_Object_Declaration              |
11128
                             N_Protected_Type_Declaration      |
11129
                             N_Private_Extension_Declaration   |
11130
                             N_Private_Type_Declaration        |
11131
                             N_Subtype_Declaration             |
11132
                             N_Function_Specification          |
11133
                             N_Procedure_Specification         |
11134
                             N_Task_Type_Declaration           |
11135
                             N_Body_Stub                       |
11136
                             N_Generic_Instantiation           |
11137
                             N_Proper_Body                     |
11138
                             N_Implicit_Label_Declaration      |
11139
                             N_Package_Declaration             |
11140
                             N_Single_Task_Declaration         |
11141
                             N_Subprogram_Declaration          |
11142
                             N_Generic_Declaration             |
11143
                             N_Renaming_Declaration            |
11144
                             N_Block_Statement                 |
11145
                             N_Formal_Subprogram_Declaration   |
11146
                             N_Abstract_Subprogram_Declaration |
11147
                             N_Entry_Body                      |
11148
                             N_Exception_Declaration           |
11149
                             N_Formal_Package_Declaration      |
11150
                             N_Number_Declaration              |
11151
                             N_Package_Specification           |
11152
                             N_Parameter_Specification         |
11153
                             N_Single_Protected_Declaration    |
11154
                             N_Subunit                         =>
11155
 
11156
                           return Scope_Depth
11157
                                    (Nearest_Dynamic_Scope
11158
                                       (Defining_Entity (Node_Par)));
11159
 
11160
                        when others =>
11161
                           null;
11162
                     end case;
11163
 
11164
                     Node_Par := Parent (Node_Par);
11165
                  end loop;
11166
 
11167
                  pragma Assert (False);
11168
 
11169
                  --  Should never reach the following return
11170
 
11171
                  return Scope_Depth (Current_Scope) + 1;
11172
               end Innermost_Master_Scope_Depth;
11173
 
11174
            --  Start of processing for Return_Master_Scope_Depth_Of_Call
11175
 
11176
            begin
11177
               return Innermost_Master_Scope_Depth (Obj);
11178
            end Return_Master_Scope_Depth_Of_Call;
11179
         end if;
11180
 
11181
      --  For convenience we handle qualified expressions, even though
11182
      --  they aren't technically object names.
11183
 
11184
      elsif Nkind (Obj) = N_Qualified_Expression then
11185
         return Object_Access_Level (Expression (Obj));
11186
 
11187
      --  Otherwise return the scope level of Standard.
11188
      --  (If there are cases that fall through
11189
      --  to this point they will be treated as
11190
      --  having global accessibility for now. ???)
11191
 
11192
      else
11193
         return Scope_Depth (Standard_Standard);
11194
      end if;
11195
   end Object_Access_Level;
11196
 
11197
   --------------------------------------
11198
   -- Original_Corresponding_Operation --
11199
   --------------------------------------
11200
 
11201
   function Original_Corresponding_Operation (S : Entity_Id) return Entity_Id
11202
   is
11203
      Typ : constant Entity_Id := Find_Dispatching_Type (S);
11204
 
11205
   begin
11206
      --  If S is an inherited primitive S2 the original corresponding
11207
      --  operation of S is the original corresponding operation of S2
11208
 
11209
      if Present (Alias (S))
11210
        and then Find_Dispatching_Type (Alias (S)) /= Typ
11211
      then
11212
         return Original_Corresponding_Operation (Alias (S));
11213
 
11214
      --  If S overrides an inherited subprogram S2 the original corresponding
11215
      --  operation of S is the original corresponding operation of S2
11216
 
11217
      elsif Present (Overridden_Operation (S)) then
11218
         return Original_Corresponding_Operation (Overridden_Operation (S));
11219
 
11220
      --  otherwise it is S itself
11221
 
11222
      else
11223
         return S;
11224
      end if;
11225
   end Original_Corresponding_Operation;
11226
 
11227
   -----------------------
11228
   -- Private_Component --
11229
   -----------------------
11230
 
11231
   function Private_Component (Type_Id : Entity_Id) return Entity_Id is
11232
      Ancestor  : constant Entity_Id := Base_Type (Type_Id);
11233
 
11234
      function Trace_Components
11235
        (T     : Entity_Id;
11236
         Check : Boolean) return Entity_Id;
11237
      --  Recursive function that does the work, and checks against circular
11238
      --  definition for each subcomponent type.
11239
 
11240
      ----------------------
11241
      -- Trace_Components --
11242
      ----------------------
11243
 
11244
      function Trace_Components
11245
         (T     : Entity_Id;
11246
          Check : Boolean) return Entity_Id
11247
       is
11248
         Btype     : constant Entity_Id := Base_Type (T);
11249
         Component : Entity_Id;
11250
         P         : Entity_Id;
11251
         Candidate : Entity_Id := Empty;
11252
 
11253
      begin
11254
         if Check and then Btype = Ancestor then
11255
            Error_Msg_N ("circular type definition", Type_Id);
11256
            return Any_Type;
11257
         end if;
11258
 
11259
         if Is_Private_Type (Btype)
11260
           and then not Is_Generic_Type (Btype)
11261
         then
11262
            if Present (Full_View (Btype))
11263
              and then Is_Record_Type (Full_View (Btype))
11264
              and then not Is_Frozen (Btype)
11265
            then
11266
               --  To indicate that the ancestor depends on a private type, the
11267
               --  current Btype is sufficient. However, to check for circular
11268
               --  definition we must recurse on the full view.
11269
 
11270
               Candidate := Trace_Components (Full_View (Btype), True);
11271
 
11272
               if Candidate = Any_Type then
11273
                  return Any_Type;
11274
               else
11275
                  return Btype;
11276
               end if;
11277
 
11278
            else
11279
               return Btype;
11280
            end if;
11281
 
11282
         elsif Is_Array_Type (Btype) then
11283
            return Trace_Components (Component_Type (Btype), True);
11284
 
11285
         elsif Is_Record_Type (Btype) then
11286
            Component := First_Entity (Btype);
11287
            while Present (Component)
11288
              and then Comes_From_Source (Component)
11289
            loop
11290
               --  Skip anonymous types generated by constrained components
11291
 
11292
               if not Is_Type (Component) then
11293
                  P := Trace_Components (Etype (Component), True);
11294
 
11295
                  if Present (P) then
11296
                     if P = Any_Type then
11297
                        return P;
11298
                     else
11299
                        Candidate := P;
11300
                     end if;
11301
                  end if;
11302
               end if;
11303
 
11304
               Next_Entity (Component);
11305
            end loop;
11306
 
11307
            return Candidate;
11308
 
11309
         else
11310
            return Empty;
11311
         end if;
11312
      end Trace_Components;
11313
 
11314
   --  Start of processing for Private_Component
11315
 
11316
   begin
11317
      return Trace_Components (Type_Id, False);
11318
   end Private_Component;
11319
 
11320
   ---------------------------
11321
   -- Primitive_Names_Match --
11322
   ---------------------------
11323
 
11324
   function Primitive_Names_Match (E1, E2 : Entity_Id) return Boolean is
11325
 
11326
      function Non_Internal_Name (E : Entity_Id) return Name_Id;
11327
      --  Given an internal name, returns the corresponding non-internal name
11328
 
11329
      ------------------------
11330
      --  Non_Internal_Name --
11331
      ------------------------
11332
 
11333
      function Non_Internal_Name (E : Entity_Id) return Name_Id is
11334
      begin
11335
         Get_Name_String (Chars (E));
11336
         Name_Len := Name_Len - 1;
11337
         return Name_Find;
11338
      end Non_Internal_Name;
11339
 
11340
   --  Start of processing for Primitive_Names_Match
11341
 
11342
   begin
11343
      pragma Assert (Present (E1) and then Present (E2));
11344
 
11345
      return Chars (E1) = Chars (E2)
11346
        or else
11347
           (not Is_Internal_Name (Chars (E1))
11348
              and then Is_Internal_Name (Chars (E2))
11349
              and then Non_Internal_Name (E2) = Chars (E1))
11350
        or else
11351
           (not Is_Internal_Name (Chars (E2))
11352
              and then Is_Internal_Name (Chars (E1))
11353
              and then Non_Internal_Name (E1) = Chars (E2))
11354
        or else
11355
           (Is_Predefined_Dispatching_Operation (E1)
11356
              and then Is_Predefined_Dispatching_Operation (E2)
11357
              and then Same_TSS (E1, E2))
11358
        or else
11359
           (Is_Init_Proc (E1) and then Is_Init_Proc (E2));
11360
   end Primitive_Names_Match;
11361
 
11362
   -----------------------
11363
   -- Process_End_Label --
11364
   -----------------------
11365
 
11366
   procedure Process_End_Label
11367
     (N   : Node_Id;
11368
      Typ : Character;
11369
      Ent : Entity_Id)
11370
   is
11371
      Loc  : Source_Ptr;
11372
      Nam  : Node_Id;
11373
      Scop : Entity_Id;
11374
 
11375
      Label_Ref : Boolean;
11376
      --  Set True if reference to end label itself is required
11377
 
11378
      Endl : Node_Id;
11379
      --  Gets set to the operator symbol or identifier that references the
11380
      --  entity Ent. For the child unit case, this is the identifier from the
11381
      --  designator. For other cases, this is simply Endl.
11382
 
11383
      procedure Generate_Parent_Ref (N : Node_Id; E : Entity_Id);
11384
      --  N is an identifier node that appears as a parent unit reference in
11385
      --  the case where Ent is a child unit. This procedure generates an
11386
      --  appropriate cross-reference entry. E is the corresponding entity.
11387
 
11388
      -------------------------
11389
      -- Generate_Parent_Ref --
11390
      -------------------------
11391
 
11392
      procedure Generate_Parent_Ref (N : Node_Id; E : Entity_Id) is
11393
      begin
11394
         --  If names do not match, something weird, skip reference
11395
 
11396
         if Chars (E) = Chars (N) then
11397
 
11398
            --  Generate the reference. We do NOT consider this as a reference
11399
            --  for unreferenced symbol purposes.
11400
 
11401
            Generate_Reference (E, N, 'r', Set_Ref => False, Force => True);
11402
 
11403
            if Style_Check then
11404
               Style.Check_Identifier (N, E);
11405
            end if;
11406
         end if;
11407
      end Generate_Parent_Ref;
11408
 
11409
   --  Start of processing for Process_End_Label
11410
 
11411
   begin
11412
      --  If no node, ignore. This happens in some error situations, and
11413
      --  also for some internally generated structures where no end label
11414
      --  references are required in any case.
11415
 
11416
      if No (N) then
11417
         return;
11418
      end if;
11419
 
11420
      --  Nothing to do if no End_Label, happens for internally generated
11421
      --  constructs where we don't want an end label reference anyway. Also
11422
      --  nothing to do if Endl is a string literal, which means there was
11423
      --  some prior error (bad operator symbol)
11424
 
11425
      Endl := End_Label (N);
11426
 
11427
      if No (Endl) or else Nkind (Endl) = N_String_Literal then
11428
         return;
11429
      end if;
11430
 
11431
      --  Reference node is not in extended main source unit
11432
 
11433
      if not In_Extended_Main_Source_Unit (N) then
11434
 
11435
         --  Generally we do not collect references except for the extended
11436
         --  main source unit. The one exception is the 'e' entry for a
11437
         --  package spec, where it is useful for a client to have the
11438
         --  ending information to define scopes.
11439
 
11440
         if Typ /= 'e' then
11441
            return;
11442
 
11443
         else
11444
            Label_Ref := False;
11445
 
11446
            --  For this case, we can ignore any parent references, but we
11447
            --  need the package name itself for the 'e' entry.
11448
 
11449
            if Nkind (Endl) = N_Designator then
11450
               Endl := Identifier (Endl);
11451
            end if;
11452
         end if;
11453
 
11454
      --  Reference is in extended main source unit
11455
 
11456
      else
11457
         Label_Ref := True;
11458
 
11459
         --  For designator, generate references for the parent entries
11460
 
11461
         if Nkind (Endl) = N_Designator then
11462
 
11463
            --  Generate references for the prefix if the END line comes from
11464
            --  source (otherwise we do not need these references) We climb the
11465
            --  scope stack to find the expected entities.
11466
 
11467
            if Comes_From_Source (Endl) then
11468
               Nam  := Name (Endl);
11469
               Scop := Current_Scope;
11470
               while Nkind (Nam) = N_Selected_Component loop
11471
                  Scop := Scope (Scop);
11472
                  exit when No (Scop);
11473
                  Generate_Parent_Ref (Selector_Name (Nam), Scop);
11474
                  Nam := Prefix (Nam);
11475
               end loop;
11476
 
11477
               if Present (Scop) then
11478
                  Generate_Parent_Ref (Nam, Scope (Scop));
11479
               end if;
11480
            end if;
11481
 
11482
            Endl := Identifier (Endl);
11483
         end if;
11484
      end if;
11485
 
11486
      --  If the end label is not for the given entity, then either we have
11487
      --  some previous error, or this is a generic instantiation for which
11488
      --  we do not need to make a cross-reference in this case anyway. In
11489
      --  either case we simply ignore the call.
11490
 
11491
      if Chars (Ent) /= Chars (Endl) then
11492
         return;
11493
      end if;
11494
 
11495
      --  If label was really there, then generate a normal reference and then
11496
      --  adjust the location in the end label to point past the name (which
11497
      --  should almost always be the semicolon).
11498
 
11499
      Loc := Sloc (Endl);
11500
 
11501
      if Comes_From_Source (Endl) then
11502
 
11503
         --  If a label reference is required, then do the style check and
11504
         --  generate an l-type cross-reference entry for the label
11505
 
11506
         if Label_Ref then
11507
            if Style_Check then
11508
               Style.Check_Identifier (Endl, Ent);
11509
            end if;
11510
 
11511
            Generate_Reference (Ent, Endl, 'l', Set_Ref => False);
11512
         end if;
11513
 
11514
         --  Set the location to point past the label (normally this will
11515
         --  mean the semicolon immediately following the label). This is
11516
         --  done for the sake of the 'e' or 't' entry generated below.
11517
 
11518
         Get_Decoded_Name_String (Chars (Endl));
11519
         Set_Sloc (Endl, Sloc (Endl) + Source_Ptr (Name_Len));
11520
 
11521
      else
11522
         --  In SPARK mode, no missing label is allowed for packages and
11523
         --  subprogram bodies. Detect those cases by testing whether
11524
         --  Process_End_Label was called for a body (Typ = 't') or a package.
11525
 
11526
         if Restriction_Check_Required (SPARK)
11527
           and then (Typ = 't' or else Ekind (Ent) = E_Package)
11528
         then
11529
            Error_Msg_Node_1 := Endl;
11530
            Check_SPARK_Restriction ("`END &` required", Endl, Force => True);
11531
         end if;
11532
      end if;
11533
 
11534
      --  Now generate the e/t reference
11535
 
11536
      Generate_Reference (Ent, Endl, Typ, Set_Ref => False, Force => True);
11537
 
11538
      --  Restore Sloc, in case modified above, since we have an identifier
11539
      --  and the normal Sloc should be left set in the tree.
11540
 
11541
      Set_Sloc (Endl, Loc);
11542
   end Process_End_Label;
11543
 
11544
   ------------------------------------
11545
   -- References_Generic_Formal_Type --
11546
   ------------------------------------
11547
 
11548
   function References_Generic_Formal_Type (N : Node_Id) return Boolean is
11549
 
11550
      function Process (N : Node_Id) return Traverse_Result;
11551
      --  Process one node in search for generic formal type
11552
 
11553
      -------------
11554
      -- Process --
11555
      -------------
11556
 
11557
      function Process (N : Node_Id) return Traverse_Result is
11558
      begin
11559
         if Nkind (N) in N_Has_Entity then
11560
            declare
11561
               E : constant Entity_Id := Entity (N);
11562
            begin
11563
               if Present (E) then
11564
                  if Is_Generic_Type (E) then
11565
                     return Abandon;
11566
                  elsif Present (Etype (E))
11567
                    and then Is_Generic_Type (Etype (E))
11568
                  then
11569
                     return Abandon;
11570
                  end if;
11571
               end if;
11572
            end;
11573
         end if;
11574
 
11575
         return Atree.OK;
11576
      end Process;
11577
 
11578
      function Traverse is new Traverse_Func (Process);
11579
      --  Traverse tree to look for generic type
11580
 
11581
   begin
11582
      if Inside_A_Generic then
11583
         return Traverse (N) = Abandon;
11584
      else
11585
         return False;
11586
      end if;
11587
   end References_Generic_Formal_Type;
11588
 
11589
   --------------------
11590
   -- Remove_Homonym --
11591
   --------------------
11592
 
11593
   procedure Remove_Homonym (E : Entity_Id) is
11594
      Prev  : Entity_Id := Empty;
11595
      H     : Entity_Id;
11596
 
11597
   begin
11598
      if E = Current_Entity (E) then
11599
         if Present (Homonym (E)) then
11600
            Set_Current_Entity (Homonym (E));
11601
         else
11602
            Set_Name_Entity_Id (Chars (E), Empty);
11603
         end if;
11604
      else
11605
         H := Current_Entity (E);
11606
         while Present (H) and then H /= E loop
11607
            Prev := H;
11608
            H    := Homonym (H);
11609
         end loop;
11610
 
11611
         Set_Homonym (Prev, Homonym (E));
11612
      end if;
11613
   end Remove_Homonym;
11614
 
11615
   ---------------------
11616
   -- Rep_To_Pos_Flag --
11617
   ---------------------
11618
 
11619
   function Rep_To_Pos_Flag (E : Entity_Id; Loc : Source_Ptr) return Node_Id is
11620
   begin
11621
      return New_Occurrence_Of
11622
               (Boolean_Literals (not Range_Checks_Suppressed (E)), Loc);
11623
   end Rep_To_Pos_Flag;
11624
 
11625
   --------------------
11626
   -- Require_Entity --
11627
   --------------------
11628
 
11629
   procedure Require_Entity (N : Node_Id) is
11630
   begin
11631
      if Is_Entity_Name (N) and then No (Entity (N)) then
11632
         if Total_Errors_Detected /= 0 then
11633
            Set_Entity (N, Any_Id);
11634
         else
11635
            raise Program_Error;
11636
         end if;
11637
      end if;
11638
   end Require_Entity;
11639
 
11640
   ------------------------------
11641
   -- Requires_Transient_Scope --
11642
   ------------------------------
11643
 
11644
   --  A transient scope is required when variable-sized temporaries are
11645
   --  allocated in the primary or secondary stack, or when finalization
11646
   --  actions must be generated before the next instruction.
11647
 
11648
   function Requires_Transient_Scope (Id : Entity_Id) return Boolean is
11649
      Typ : constant Entity_Id := Underlying_Type (Id);
11650
 
11651
   --  Start of processing for Requires_Transient_Scope
11652
 
11653
   begin
11654
      --  This is a private type which is not completed yet. This can only
11655
      --  happen in a default expression (of a formal parameter or of a
11656
      --  record component). Do not expand transient scope in this case
11657
 
11658
      if No (Typ) then
11659
         return False;
11660
 
11661
      --  Do not expand transient scope for non-existent procedure return
11662
 
11663
      elsif Typ = Standard_Void_Type then
11664
         return False;
11665
 
11666
      --  Elementary types do not require a transient scope
11667
 
11668
      elsif Is_Elementary_Type (Typ) then
11669
         return False;
11670
 
11671
      --  Generally, indefinite subtypes require a transient scope, since the
11672
      --  back end cannot generate temporaries, since this is not a valid type
11673
      --  for declaring an object. It might be possible to relax this in the
11674
      --  future, e.g. by declaring the maximum possible space for the type.
11675
 
11676
      elsif Is_Indefinite_Subtype (Typ) then
11677
         return True;
11678
 
11679
      --  Functions returning tagged types may dispatch on result so their
11680
      --  returned value is allocated on the secondary stack. Controlled
11681
      --  type temporaries need finalization.
11682
 
11683
      elsif Is_Tagged_Type (Typ)
11684
        or else Has_Controlled_Component (Typ)
11685
      then
11686
         return not Is_Value_Type (Typ);
11687
 
11688
      --  Record type
11689
 
11690
      elsif Is_Record_Type (Typ) then
11691
         declare
11692
            Comp : Entity_Id;
11693
         begin
11694
            Comp := First_Entity (Typ);
11695
            while Present (Comp) loop
11696
               if Ekind (Comp) = E_Component
11697
                  and then Requires_Transient_Scope (Etype (Comp))
11698
               then
11699
                  return True;
11700
               else
11701
                  Next_Entity (Comp);
11702
               end if;
11703
            end loop;
11704
         end;
11705
 
11706
         return False;
11707
 
11708
      --  String literal types never require transient scope
11709
 
11710
      elsif Ekind (Typ) = E_String_Literal_Subtype then
11711
         return False;
11712
 
11713
      --  Array type. Note that we already know that this is a constrained
11714
      --  array, since unconstrained arrays will fail the indefinite test.
11715
 
11716
      elsif Is_Array_Type (Typ) then
11717
 
11718
         --  If component type requires a transient scope, the array does too
11719
 
11720
         if Requires_Transient_Scope (Component_Type (Typ)) then
11721
            return True;
11722
 
11723
         --  Otherwise, we only need a transient scope if the size depends on
11724
         --  the value of one or more discriminants.
11725
 
11726
         else
11727
            return Size_Depends_On_Discriminant (Typ);
11728
         end if;
11729
 
11730
      --  All other cases do not require a transient scope
11731
 
11732
      else
11733
         return False;
11734
      end if;
11735
   end Requires_Transient_Scope;
11736
 
11737
   --------------------------
11738
   -- Reset_Analyzed_Flags --
11739
   --------------------------
11740
 
11741
   procedure Reset_Analyzed_Flags (N : Node_Id) is
11742
 
11743
      function Clear_Analyzed (N : Node_Id) return Traverse_Result;
11744
      --  Function used to reset Analyzed flags in tree. Note that we do
11745
      --  not reset Analyzed flags in entities, since there is no need to
11746
      --  reanalyze entities, and indeed, it is wrong to do so, since it
11747
      --  can result in generating auxiliary stuff more than once.
11748
 
11749
      --------------------
11750
      -- Clear_Analyzed --
11751
      --------------------
11752
 
11753
      function Clear_Analyzed (N : Node_Id) return Traverse_Result is
11754
      begin
11755
         if not Has_Extension (N) then
11756
            Set_Analyzed (N, False);
11757
         end if;
11758
 
11759
         return OK;
11760
      end Clear_Analyzed;
11761
 
11762
      procedure Reset_Analyzed is new Traverse_Proc (Clear_Analyzed);
11763
 
11764
   --  Start of processing for Reset_Analyzed_Flags
11765
 
11766
   begin
11767
      Reset_Analyzed (N);
11768
   end Reset_Analyzed_Flags;
11769
 
11770
   ---------------------------
11771
   -- Safe_To_Capture_Value --
11772
   ---------------------------
11773
 
11774
   function Safe_To_Capture_Value
11775
     (N    : Node_Id;
11776
      Ent  : Entity_Id;
11777
      Cond : Boolean := False) return Boolean
11778
   is
11779
   begin
11780
      --  The only entities for which we track constant values are variables
11781
      --  which are not renamings, constants, out parameters, and in out
11782
      --  parameters, so check if we have this case.
11783
 
11784
      --  Note: it may seem odd to track constant values for constants, but in
11785
      --  fact this routine is used for other purposes than simply capturing
11786
      --  the value. In particular, the setting of Known[_Non]_Null.
11787
 
11788
      if (Ekind (Ent) = E_Variable and then No (Renamed_Object (Ent)))
11789
            or else
11790
          Ekind (Ent) = E_Constant
11791
            or else
11792
          Ekind (Ent) = E_Out_Parameter
11793
            or else
11794
          Ekind (Ent) = E_In_Out_Parameter
11795
      then
11796
         null;
11797
 
11798
      --  For conditionals, we also allow loop parameters and all formals,
11799
      --  including in parameters.
11800
 
11801
      elsif Cond
11802
        and then
11803
          (Ekind (Ent) = E_Loop_Parameter
11804
             or else
11805
           Ekind (Ent) = E_In_Parameter)
11806
      then
11807
         null;
11808
 
11809
      --  For all other cases, not just unsafe, but impossible to capture
11810
      --  Current_Value, since the above are the only entities which have
11811
      --  Current_Value fields.
11812
 
11813
      else
11814
         return False;
11815
      end if;
11816
 
11817
      --  Skip if volatile or aliased, since funny things might be going on in
11818
      --  these cases which we cannot necessarily track. Also skip any variable
11819
      --  for which an address clause is given, or whose address is taken. Also
11820
      --  never capture value of library level variables (an attempt to do so
11821
      --  can occur in the case of package elaboration code).
11822
 
11823
      if Treat_As_Volatile (Ent)
11824
        or else Is_Aliased (Ent)
11825
        or else Present (Address_Clause (Ent))
11826
        or else Address_Taken (Ent)
11827
        or else (Is_Library_Level_Entity (Ent)
11828
                   and then Ekind (Ent) = E_Variable)
11829
      then
11830
         return False;
11831
      end if;
11832
 
11833
      --  OK, all above conditions are met. We also require that the scope of
11834
      --  the reference be the same as the scope of the entity, not counting
11835
      --  packages and blocks and loops.
11836
 
11837
      declare
11838
         E_Scope : constant Entity_Id := Scope (Ent);
11839
         R_Scope : Entity_Id;
11840
 
11841
      begin
11842
         R_Scope := Current_Scope;
11843
         while R_Scope /= Standard_Standard loop
11844
            exit when R_Scope = E_Scope;
11845
 
11846
            if not Ekind_In (R_Scope, E_Package, E_Block, E_Loop) then
11847
               return False;
11848
            else
11849
               R_Scope := Scope (R_Scope);
11850
            end if;
11851
         end loop;
11852
      end;
11853
 
11854
      --  We also require that the reference does not appear in a context
11855
      --  where it is not sure to be executed (i.e. a conditional context
11856
      --  or an exception handler). We skip this if Cond is True, since the
11857
      --  capturing of values from conditional tests handles this ok.
11858
 
11859
      if Cond then
11860
         return True;
11861
      end if;
11862
 
11863
      declare
11864
         Desc : Node_Id;
11865
         P    : Node_Id;
11866
 
11867
      begin
11868
         Desc := N;
11869
 
11870
         P := Parent (N);
11871
         while Present (P) loop
11872
            if         Nkind (P) = N_If_Statement
11873
              or else  Nkind (P) = N_Case_Statement
11874
              or else (Nkind (P) in N_Short_Circuit
11875
                         and then Desc = Right_Opnd (P))
11876
              or else (Nkind (P) = N_Conditional_Expression
11877
                         and then Desc /= First (Expressions (P)))
11878
              or else  Nkind (P) = N_Exception_Handler
11879
              or else  Nkind (P) = N_Selective_Accept
11880
              or else  Nkind (P) = N_Conditional_Entry_Call
11881
              or else  Nkind (P) = N_Timed_Entry_Call
11882
              or else  Nkind (P) = N_Asynchronous_Select
11883
            then
11884
               return False;
11885
            else
11886
               Desc := P;
11887
               P    := Parent (P);
11888
            end if;
11889
         end loop;
11890
      end;
11891
 
11892
      --  OK, looks safe to set value
11893
 
11894
      return True;
11895
   end Safe_To_Capture_Value;
11896
 
11897
   ---------------
11898
   -- Same_Name --
11899
   ---------------
11900
 
11901
   function Same_Name (N1, N2 : Node_Id) return Boolean is
11902
      K1 : constant Node_Kind := Nkind (N1);
11903
      K2 : constant Node_Kind := Nkind (N2);
11904
 
11905
   begin
11906
      if (K1 = N_Identifier or else K1 = N_Defining_Identifier)
11907
        and then (K2 = N_Identifier or else K2 = N_Defining_Identifier)
11908
      then
11909
         return Chars (N1) = Chars (N2);
11910
 
11911
      elsif (K1 = N_Selected_Component or else K1 = N_Expanded_Name)
11912
        and then (K2 = N_Selected_Component or else K2 = N_Expanded_Name)
11913
      then
11914
         return Same_Name (Selector_Name (N1), Selector_Name (N2))
11915
           and then Same_Name (Prefix (N1), Prefix (N2));
11916
 
11917
      else
11918
         return False;
11919
      end if;
11920
   end Same_Name;
11921
 
11922
   -----------------
11923
   -- Same_Object --
11924
   -----------------
11925
 
11926
   function Same_Object (Node1, Node2 : Node_Id) return Boolean is
11927
      N1 : constant Node_Id := Original_Node (Node1);
11928
      N2 : constant Node_Id := Original_Node (Node2);
11929
      --  We do the tests on original nodes, since we are most interested
11930
      --  in the original source, not any expansion that got in the way.
11931
 
11932
      K1 : constant Node_Kind := Nkind (N1);
11933
      K2 : constant Node_Kind := Nkind (N2);
11934
 
11935
   begin
11936
      --  First case, both are entities with same entity
11937
 
11938
      if K1 in N_Has_Entity and then K2 in N_Has_Entity then
11939
         declare
11940
            EN1 : constant Entity_Id := Entity (N1);
11941
            EN2 : constant Entity_Id := Entity (N2);
11942
         begin
11943
            if Present (EN1) and then Present (EN2)
11944
              and then (Ekind_In (EN1, E_Variable, E_Constant)
11945
                         or else Is_Formal (EN1))
11946
              and then EN1 = EN2
11947
            then
11948
               return True;
11949
            end if;
11950
         end;
11951
      end if;
11952
 
11953
      --  Second case, selected component with same selector, same record
11954
 
11955
      if K1 = N_Selected_Component
11956
        and then K2 = N_Selected_Component
11957
        and then Chars (Selector_Name (N1)) = Chars (Selector_Name (N2))
11958
      then
11959
         return Same_Object (Prefix (N1), Prefix (N2));
11960
 
11961
      --  Third case, indexed component with same subscripts, same array
11962
 
11963
      elsif K1 = N_Indexed_Component
11964
        and then K2 = N_Indexed_Component
11965
        and then Same_Object (Prefix (N1), Prefix (N2))
11966
      then
11967
         declare
11968
            E1, E2 : Node_Id;
11969
         begin
11970
            E1 := First (Expressions (N1));
11971
            E2 := First (Expressions (N2));
11972
            while Present (E1) loop
11973
               if not Same_Value (E1, E2) then
11974
                  return False;
11975
               else
11976
                  Next (E1);
11977
                  Next (E2);
11978
               end if;
11979
            end loop;
11980
 
11981
            return True;
11982
         end;
11983
 
11984
      --  Fourth case, slice of same array with same bounds
11985
 
11986
      elsif K1 = N_Slice
11987
        and then K2 = N_Slice
11988
        and then Nkind (Discrete_Range (N1)) = N_Range
11989
        and then Nkind (Discrete_Range (N2)) = N_Range
11990
        and then Same_Value (Low_Bound (Discrete_Range (N1)),
11991
                             Low_Bound (Discrete_Range (N2)))
11992
        and then Same_Value (High_Bound (Discrete_Range (N1)),
11993
                             High_Bound (Discrete_Range (N2)))
11994
      then
11995
         return Same_Name (Prefix (N1), Prefix (N2));
11996
 
11997
      --  All other cases, not clearly the same object
11998
 
11999
      else
12000
         return False;
12001
      end if;
12002
   end Same_Object;
12003
 
12004
   ---------------
12005
   -- Same_Type --
12006
   ---------------
12007
 
12008
   function Same_Type (T1, T2 : Entity_Id) return Boolean is
12009
   begin
12010
      if T1 = T2 then
12011
         return True;
12012
 
12013
      elsif not Is_Constrained (T1)
12014
        and then not Is_Constrained (T2)
12015
        and then Base_Type (T1) = Base_Type (T2)
12016
      then
12017
         return True;
12018
 
12019
      --  For now don't bother with case of identical constraints, to be
12020
      --  fiddled with later on perhaps (this is only used for optimization
12021
      --  purposes, so it is not critical to do a best possible job)
12022
 
12023
      else
12024
         return False;
12025
      end if;
12026
   end Same_Type;
12027
 
12028
   ----------------
12029
   -- Same_Value --
12030
   ----------------
12031
 
12032
   function Same_Value (Node1, Node2 : Node_Id) return Boolean is
12033
   begin
12034
      if Compile_Time_Known_Value (Node1)
12035
        and then Compile_Time_Known_Value (Node2)
12036
        and then Expr_Value (Node1) = Expr_Value (Node2)
12037
      then
12038
         return True;
12039
      elsif Same_Object (Node1, Node2) then
12040
         return True;
12041
      else
12042
         return False;
12043
      end if;
12044
   end Same_Value;
12045
 
12046
   -----------------
12047
   -- Save_Actual --
12048
   -----------------
12049
 
12050
   procedure Save_Actual (N : Node_Id;  Writable : Boolean := False) is
12051
   begin
12052
      if Ada_Version < Ada_2012 then
12053
         return;
12054
 
12055
      elsif Is_Entity_Name (N)
12056
        or else
12057
          Nkind_In (N, N_Indexed_Component, N_Selected_Component, N_Slice)
12058
        or else
12059
          (Nkind (N) = N_Attribute_Reference
12060
            and then Attribute_Name (N) = Name_Access)
12061
 
12062
      then
12063
         --  We are only interested in IN OUT parameters of inner calls
12064
 
12065
         if not Writable
12066
           or else Nkind (Parent (N)) = N_Function_Call
12067
           or else Nkind (Parent (N)) in N_Op
12068
         then
12069
            Actuals_In_Call.Increment_Last;
12070
            Actuals_In_Call.Table (Actuals_In_Call.Last) := (N, Writable);
12071
         end if;
12072
      end if;
12073
   end Save_Actual;
12074
 
12075
   ------------------------
12076
   -- Scope_Is_Transient --
12077
   ------------------------
12078
 
12079
   function Scope_Is_Transient return Boolean is
12080
   begin
12081
      return Scope_Stack.Table (Scope_Stack.Last).Is_Transient;
12082
   end Scope_Is_Transient;
12083
 
12084
   ------------------
12085
   -- Scope_Within --
12086
   ------------------
12087
 
12088
   function Scope_Within (Scope1, Scope2 : Entity_Id) return Boolean is
12089
      Scop : Entity_Id;
12090
 
12091
   begin
12092
      Scop := Scope1;
12093
      while Scop /= Standard_Standard loop
12094
         Scop := Scope (Scop);
12095
 
12096
         if Scop = Scope2 then
12097
            return True;
12098
         end if;
12099
      end loop;
12100
 
12101
      return False;
12102
   end Scope_Within;
12103
 
12104
   --------------------------
12105
   -- Scope_Within_Or_Same --
12106
   --------------------------
12107
 
12108
   function Scope_Within_Or_Same (Scope1, Scope2 : Entity_Id) return Boolean is
12109
      Scop : Entity_Id;
12110
 
12111
   begin
12112
      Scop := Scope1;
12113
      while Scop /= Standard_Standard loop
12114
         if Scop = Scope2 then
12115
            return True;
12116
         else
12117
            Scop := Scope (Scop);
12118
         end if;
12119
      end loop;
12120
 
12121
      return False;
12122
   end Scope_Within_Or_Same;
12123
 
12124
   --------------------
12125
   -- Set_Convention --
12126
   --------------------
12127
 
12128
   procedure Set_Convention (E : Entity_Id; Val : Snames.Convention_Id) is
12129
   begin
12130
      Basic_Set_Convention (E, Val);
12131
 
12132
      if Is_Type (E)
12133
        and then Is_Access_Subprogram_Type (Base_Type (E))
12134
        and then Has_Foreign_Convention (E)
12135
      then
12136
         Set_Can_Use_Internal_Rep (E, False);
12137
      end if;
12138
   end Set_Convention;
12139
 
12140
   ------------------------
12141
   -- Set_Current_Entity --
12142
   ------------------------
12143
 
12144
   --  The given entity is to be set as the currently visible definition of its
12145
   --  associated name (i.e. the Node_Id associated with its name). All we have
12146
   --  to do is to get the name from the identifier, and then set the
12147
   --  associated Node_Id to point to the given entity.
12148
 
12149
   procedure Set_Current_Entity (E : Entity_Id) is
12150
   begin
12151
      Set_Name_Entity_Id (Chars (E), E);
12152
   end Set_Current_Entity;
12153
 
12154
   ---------------------------
12155
   -- Set_Debug_Info_Needed --
12156
   ---------------------------
12157
 
12158
   procedure Set_Debug_Info_Needed (T : Entity_Id) is
12159
 
12160
      procedure Set_Debug_Info_Needed_If_Not_Set (E : Entity_Id);
12161
      pragma Inline (Set_Debug_Info_Needed_If_Not_Set);
12162
      --  Used to set debug info in a related node if not set already
12163
 
12164
      --------------------------------------
12165
      -- Set_Debug_Info_Needed_If_Not_Set --
12166
      --------------------------------------
12167
 
12168
      procedure Set_Debug_Info_Needed_If_Not_Set (E : Entity_Id) is
12169
      begin
12170
         if Present (E)
12171
           and then not Needs_Debug_Info (E)
12172
         then
12173
            Set_Debug_Info_Needed (E);
12174
 
12175
            --  For a private type, indicate that the full view also needs
12176
            --  debug information.
12177
 
12178
            if Is_Type (E)
12179
              and then Is_Private_Type (E)
12180
              and then Present (Full_View (E))
12181
            then
12182
               Set_Debug_Info_Needed (Full_View (E));
12183
            end if;
12184
         end if;
12185
      end Set_Debug_Info_Needed_If_Not_Set;
12186
 
12187
   --  Start of processing for Set_Debug_Info_Needed
12188
 
12189
   begin
12190
      --  Nothing to do if argument is Empty or has Debug_Info_Off set, which
12191
      --  indicates that Debug_Info_Needed is never required for the entity.
12192
 
12193
      if No (T)
12194
        or else Debug_Info_Off (T)
12195
      then
12196
         return;
12197
      end if;
12198
 
12199
      --  Set flag in entity itself. Note that we will go through the following
12200
      --  circuitry even if the flag is already set on T. That's intentional,
12201
      --  it makes sure that the flag will be set in subsidiary entities.
12202
 
12203
      Set_Needs_Debug_Info (T);
12204
 
12205
      --  Set flag on subsidiary entities if not set already
12206
 
12207
      if Is_Object (T) then
12208
         Set_Debug_Info_Needed_If_Not_Set (Etype (T));
12209
 
12210
      elsif Is_Type (T) then
12211
         Set_Debug_Info_Needed_If_Not_Set (Etype (T));
12212
 
12213
         if Is_Record_Type (T) then
12214
            declare
12215
               Ent : Entity_Id := First_Entity (T);
12216
            begin
12217
               while Present (Ent) loop
12218
                  Set_Debug_Info_Needed_If_Not_Set (Ent);
12219
                  Next_Entity (Ent);
12220
               end loop;
12221
            end;
12222
 
12223
            --  For a class wide subtype, we also need debug information
12224
            --  for the equivalent type.
12225
 
12226
            if Ekind (T) = E_Class_Wide_Subtype then
12227
               Set_Debug_Info_Needed_If_Not_Set (Equivalent_Type (T));
12228
            end if;
12229
 
12230
         elsif Is_Array_Type (T) then
12231
            Set_Debug_Info_Needed_If_Not_Set (Component_Type (T));
12232
 
12233
            declare
12234
               Indx : Node_Id := First_Index (T);
12235
            begin
12236
               while Present (Indx) loop
12237
                  Set_Debug_Info_Needed_If_Not_Set (Etype (Indx));
12238
                  Indx := Next_Index (Indx);
12239
               end loop;
12240
            end;
12241
 
12242
            --  For a packed array type, we also need debug information for
12243
            --  the type used to represent the packed array. Conversely, we
12244
            --  also need it for the former if we need it for the latter.
12245
 
12246
            if Is_Packed (T) then
12247
               Set_Debug_Info_Needed_If_Not_Set (Packed_Array_Type (T));
12248
            end if;
12249
 
12250
            if Is_Packed_Array_Type (T) then
12251
               Set_Debug_Info_Needed_If_Not_Set (Original_Array_Type (T));
12252
            end if;
12253
 
12254
         elsif Is_Access_Type (T) then
12255
            Set_Debug_Info_Needed_If_Not_Set (Directly_Designated_Type (T));
12256
 
12257
         elsif Is_Private_Type (T) then
12258
            Set_Debug_Info_Needed_If_Not_Set (Full_View (T));
12259
 
12260
         elsif Is_Protected_Type (T) then
12261
            Set_Debug_Info_Needed_If_Not_Set (Corresponding_Record_Type (T));
12262
         end if;
12263
      end if;
12264
   end Set_Debug_Info_Needed;
12265
 
12266
   ---------------------------------
12267
   -- Set_Entity_With_Style_Check --
12268
   ---------------------------------
12269
 
12270
   procedure Set_Entity_With_Style_Check (N : Node_Id; Val : Entity_Id) is
12271
      Val_Actual : Entity_Id;
12272
      Nod        : Node_Id;
12273
 
12274
   begin
12275
      --  Unconditionally set the entity
12276
 
12277
      Set_Entity (N, Val);
12278
 
12279
      --  Check for No_Implementation_Identifiers
12280
 
12281
      if Restriction_Check_Required (No_Implementation_Identifiers) then
12282
 
12283
         --  We have an implementation defined entity if it is marked as
12284
         --  implementation defined, or is defined in a package marked as
12285
         --  implementation defined. However, library packages themselves
12286
         --  are excluded (we don't want to flag Interfaces itself, just
12287
         --  the entities within it).
12288
 
12289
         if (Is_Implementation_Defined (Val)
12290
              and then not (Ekind_In (Val, E_Package, E_Generic_Package)
12291
                              and then Is_Library_Level_Entity (Val)))
12292
           or else Is_Implementation_Defined (Scope (Val))
12293
         then
12294
            Check_Restriction (No_Implementation_Identifiers, N);
12295
         end if;
12296
      end if;
12297
 
12298
      --  Do the style check
12299
 
12300
      if Style_Check
12301
        and then not Suppress_Style_Checks (Val)
12302
        and then not In_Instance
12303
      then
12304
         if Nkind (N) = N_Identifier then
12305
            Nod := N;
12306
         elsif Nkind (N) = N_Expanded_Name then
12307
            Nod := Selector_Name (N);
12308
         else
12309
            return;
12310
         end if;
12311
 
12312
         --  A special situation arises for derived operations, where we want
12313
         --  to do the check against the parent (since the Sloc of the derived
12314
         --  operation points to the derived type declaration itself).
12315
 
12316
         Val_Actual := Val;
12317
         while not Comes_From_Source (Val_Actual)
12318
           and then Nkind (Val_Actual) in N_Entity
12319
           and then (Ekind (Val_Actual) = E_Enumeration_Literal
12320
                      or else Is_Subprogram (Val_Actual)
12321
                      or else Is_Generic_Subprogram (Val_Actual))
12322
           and then Present (Alias (Val_Actual))
12323
         loop
12324
            Val_Actual := Alias (Val_Actual);
12325
         end loop;
12326
 
12327
         --  Renaming declarations for generic actuals do not come from source,
12328
         --  and have a different name from that of the entity they rename, so
12329
         --  there is no style check to perform here.
12330
 
12331
         if Chars (Nod) = Chars (Val_Actual) then
12332
            Style.Check_Identifier (Nod, Val_Actual);
12333
         end if;
12334
      end if;
12335
 
12336
      Set_Entity (N, Val);
12337
   end Set_Entity_With_Style_Check;
12338
 
12339
   ------------------------
12340
   -- Set_Name_Entity_Id --
12341
   ------------------------
12342
 
12343
   procedure Set_Name_Entity_Id (Id : Name_Id; Val : Entity_Id) is
12344
   begin
12345
      Set_Name_Table_Info (Id, Int (Val));
12346
   end Set_Name_Entity_Id;
12347
 
12348
   ---------------------
12349
   -- Set_Next_Actual --
12350
   ---------------------
12351
 
12352
   procedure Set_Next_Actual (Ass1_Id : Node_Id; Ass2_Id : Node_Id) is
12353
   begin
12354
      if Nkind (Parent (Ass1_Id)) = N_Parameter_Association then
12355
         Set_First_Named_Actual (Parent (Ass1_Id), Ass2_Id);
12356
      end if;
12357
   end Set_Next_Actual;
12358
 
12359
   ----------------------------------
12360
   -- Set_Optimize_Alignment_Flags --
12361
   ----------------------------------
12362
 
12363
   procedure Set_Optimize_Alignment_Flags (E : Entity_Id) is
12364
   begin
12365
      if Optimize_Alignment = 'S' then
12366
         Set_Optimize_Alignment_Space (E);
12367
      elsif Optimize_Alignment = 'T' then
12368
         Set_Optimize_Alignment_Time (E);
12369
      end if;
12370
   end Set_Optimize_Alignment_Flags;
12371
 
12372
   -----------------------
12373
   -- Set_Public_Status --
12374
   -----------------------
12375
 
12376
   procedure Set_Public_Status (Id : Entity_Id) is
12377
      S : constant Entity_Id := Current_Scope;
12378
 
12379
      function Within_HSS_Or_If (E : Entity_Id) return Boolean;
12380
      --  Determines if E is defined within handled statement sequence or
12381
      --  an if statement, returns True if so, False otherwise.
12382
 
12383
      ----------------------
12384
      -- Within_HSS_Or_If --
12385
      ----------------------
12386
 
12387
      function Within_HSS_Or_If (E : Entity_Id) return Boolean is
12388
         N : Node_Id;
12389
      begin
12390
         N := Declaration_Node (E);
12391
         loop
12392
            N := Parent (N);
12393
 
12394
            if No (N) then
12395
               return False;
12396
 
12397
            elsif Nkind_In (N, N_Handled_Sequence_Of_Statements,
12398
                               N_If_Statement)
12399
            then
12400
               return True;
12401
            end if;
12402
         end loop;
12403
      end Within_HSS_Or_If;
12404
 
12405
   --  Start of processing for Set_Public_Status
12406
 
12407
   begin
12408
      --  Everything in the scope of Standard is public
12409
 
12410
      if S = Standard_Standard then
12411
         Set_Is_Public (Id);
12412
 
12413
      --  Entity is definitely not public if enclosing scope is not public
12414
 
12415
      elsif not Is_Public (S) then
12416
         return;
12417
 
12418
      --  An object or function declaration that occurs in a handled sequence
12419
      --  of statements or within an if statement is the declaration for a
12420
      --  temporary object or local subprogram generated by the expander. It
12421
      --  never needs to be made public and furthermore, making it public can
12422
      --  cause back end problems.
12423
 
12424
      elsif Nkind_In (Parent (Id), N_Object_Declaration,
12425
                                   N_Function_Specification)
12426
        and then Within_HSS_Or_If (Id)
12427
      then
12428
         return;
12429
 
12430
      --  Entities in public packages or records are public
12431
 
12432
      elsif Ekind (S) = E_Package or Is_Record_Type (S) then
12433
         Set_Is_Public (Id);
12434
 
12435
      --  The bounds of an entry family declaration can generate object
12436
      --  declarations that are visible to the back-end, e.g. in the
12437
      --  the declaration of a composite type that contains tasks.
12438
 
12439
      elsif Is_Concurrent_Type (S)
12440
        and then not Has_Completion (S)
12441
        and then Nkind (Parent (Id)) = N_Object_Declaration
12442
      then
12443
         Set_Is_Public (Id);
12444
      end if;
12445
   end Set_Public_Status;
12446
 
12447
   -----------------------------
12448
   -- Set_Referenced_Modified --
12449
   -----------------------------
12450
 
12451
   procedure Set_Referenced_Modified (N : Node_Id; Out_Param : Boolean) is
12452
      Pref : Node_Id;
12453
 
12454
   begin
12455
      --  Deal with indexed or selected component where prefix is modified
12456
 
12457
      if Nkind_In (N, N_Indexed_Component, N_Selected_Component) then
12458
         Pref := Prefix (N);
12459
 
12460
         --  If prefix is access type, then it is the designated object that is
12461
         --  being modified, which means we have no entity to set the flag on.
12462
 
12463
         if No (Etype (Pref)) or else Is_Access_Type (Etype (Pref)) then
12464
            return;
12465
 
12466
            --  Otherwise chase the prefix
12467
 
12468
         else
12469
            Set_Referenced_Modified (Pref, Out_Param);
12470
         end if;
12471
 
12472
      --  Otherwise see if we have an entity name (only other case to process)
12473
 
12474
      elsif Is_Entity_Name (N) and then Present (Entity (N)) then
12475
         Set_Referenced_As_LHS           (Entity (N), not Out_Param);
12476
         Set_Referenced_As_Out_Parameter (Entity (N), Out_Param);
12477
      end if;
12478
   end Set_Referenced_Modified;
12479
 
12480
   ----------------------------
12481
   -- Set_Scope_Is_Transient --
12482
   ----------------------------
12483
 
12484
   procedure Set_Scope_Is_Transient (V : Boolean := True) is
12485
   begin
12486
      Scope_Stack.Table (Scope_Stack.Last).Is_Transient := V;
12487
   end Set_Scope_Is_Transient;
12488
 
12489
   -------------------
12490
   -- Set_Size_Info --
12491
   -------------------
12492
 
12493
   procedure Set_Size_Info (T1, T2 : Entity_Id) is
12494
   begin
12495
      --  We copy Esize, but not RM_Size, since in general RM_Size is
12496
      --  subtype specific and does not get inherited by all subtypes.
12497
 
12498
      Set_Esize                     (T1, Esize                     (T2));
12499
      Set_Has_Biased_Representation (T1, Has_Biased_Representation (T2));
12500
 
12501
      if Is_Discrete_Or_Fixed_Point_Type (T1)
12502
           and then
12503
         Is_Discrete_Or_Fixed_Point_Type (T2)
12504
      then
12505
         Set_Is_Unsigned_Type       (T1, Is_Unsigned_Type          (T2));
12506
      end if;
12507
 
12508
      Set_Alignment                 (T1, Alignment                 (T2));
12509
   end Set_Size_Info;
12510
 
12511
   --------------------
12512
   -- Static_Boolean --
12513
   --------------------
12514
 
12515
   function Static_Boolean (N : Node_Id) return Uint is
12516
   begin
12517
      Analyze_And_Resolve (N, Standard_Boolean);
12518
 
12519
      if N = Error
12520
        or else Error_Posted (N)
12521
        or else Etype (N) = Any_Type
12522
      then
12523
         return No_Uint;
12524
      end if;
12525
 
12526
      if Is_Static_Expression (N) then
12527
         if not Raises_Constraint_Error (N) then
12528
            return Expr_Value (N);
12529
         else
12530
            return No_Uint;
12531
         end if;
12532
 
12533
      elsif Etype (N) = Any_Type then
12534
         return No_Uint;
12535
 
12536
      else
12537
         Flag_Non_Static_Expr
12538
           ("static boolean expression required here", N);
12539
         return No_Uint;
12540
      end if;
12541
   end Static_Boolean;
12542
 
12543
   --------------------
12544
   -- Static_Integer --
12545
   --------------------
12546
 
12547
   function Static_Integer (N : Node_Id) return Uint is
12548
   begin
12549
      Analyze_And_Resolve (N, Any_Integer);
12550
 
12551
      if N = Error
12552
        or else Error_Posted (N)
12553
        or else Etype (N) = Any_Type
12554
      then
12555
         return No_Uint;
12556
      end if;
12557
 
12558
      if Is_Static_Expression (N) then
12559
         if not Raises_Constraint_Error (N) then
12560
            return Expr_Value (N);
12561
         else
12562
            return No_Uint;
12563
         end if;
12564
 
12565
      elsif Etype (N) = Any_Type then
12566
         return No_Uint;
12567
 
12568
      else
12569
         Flag_Non_Static_Expr
12570
           ("static integer expression required here", N);
12571
         return No_Uint;
12572
      end if;
12573
   end Static_Integer;
12574
 
12575
   --------------------------
12576
   -- Statically_Different --
12577
   --------------------------
12578
 
12579
   function Statically_Different (E1, E2 : Node_Id) return Boolean is
12580
      R1 : constant Node_Id := Get_Referenced_Object (E1);
12581
      R2 : constant Node_Id := Get_Referenced_Object (E2);
12582
   begin
12583
      return     Is_Entity_Name (R1)
12584
        and then Is_Entity_Name (R2)
12585
        and then Entity (R1) /= Entity (R2)
12586
        and then not Is_Formal (Entity (R1))
12587
        and then not Is_Formal (Entity (R2));
12588
   end Statically_Different;
12589
 
12590
   -----------------------------
12591
   -- Subprogram_Access_Level --
12592
   -----------------------------
12593
 
12594
   function Subprogram_Access_Level (Subp : Entity_Id) return Uint is
12595
   begin
12596
      if Present (Alias (Subp)) then
12597
         return Subprogram_Access_Level (Alias (Subp));
12598
      else
12599
         return Scope_Depth (Enclosing_Dynamic_Scope (Subp));
12600
      end if;
12601
   end Subprogram_Access_Level;
12602
 
12603
   -----------------
12604
   -- Trace_Scope --
12605
   -----------------
12606
 
12607
   procedure Trace_Scope (N : Node_Id; E : Entity_Id; Msg : String) is
12608
   begin
12609
      if Debug_Flag_W then
12610
         for J in 0 .. Scope_Stack.Last loop
12611
            Write_Str ("  ");
12612
         end loop;
12613
 
12614
         Write_Str (Msg);
12615
         Write_Name (Chars (E));
12616
         Write_Str (" from ");
12617
         Write_Location (Sloc (N));
12618
         Write_Eol;
12619
      end if;
12620
   end Trace_Scope;
12621
 
12622
   -----------------------
12623
   -- Transfer_Entities --
12624
   -----------------------
12625
 
12626
   procedure Transfer_Entities (From : Entity_Id; To : Entity_Id) is
12627
      Ent : Entity_Id := First_Entity (From);
12628
 
12629
   begin
12630
      if No (Ent) then
12631
         return;
12632
      end if;
12633
 
12634
      if (Last_Entity (To)) = Empty then
12635
         Set_First_Entity (To, Ent);
12636
      else
12637
         Set_Next_Entity (Last_Entity (To), Ent);
12638
      end if;
12639
 
12640
      Set_Last_Entity (To, Last_Entity (From));
12641
 
12642
      while Present (Ent) loop
12643
         Set_Scope (Ent, To);
12644
 
12645
         if not Is_Public (Ent) then
12646
            Set_Public_Status (Ent);
12647
 
12648
            if Is_Public (Ent)
12649
              and then Ekind (Ent) = E_Record_Subtype
12650
 
12651
            then
12652
               --  The components of the propagated Itype must be public
12653
               --  as well.
12654
 
12655
               declare
12656
                  Comp : Entity_Id;
12657
               begin
12658
                  Comp := First_Entity (Ent);
12659
                  while Present (Comp) loop
12660
                     Set_Is_Public (Comp);
12661
                     Next_Entity (Comp);
12662
                  end loop;
12663
               end;
12664
            end if;
12665
         end if;
12666
 
12667
         Next_Entity (Ent);
12668
      end loop;
12669
 
12670
      Set_First_Entity (From, Empty);
12671
      Set_Last_Entity (From, Empty);
12672
   end Transfer_Entities;
12673
 
12674
   -----------------------
12675
   -- Type_Access_Level --
12676
   -----------------------
12677
 
12678
   function Type_Access_Level (Typ : Entity_Id) return Uint is
12679
      Btyp : Entity_Id;
12680
 
12681
   begin
12682
      Btyp := Base_Type (Typ);
12683
 
12684
      --  Ada 2005 (AI-230): For most cases of anonymous access types, we
12685
      --  simply use the level where the type is declared. This is true for
12686
      --  stand-alone object declarations, and for anonymous access types
12687
      --  associated with components the level is the same as that of the
12688
      --  enclosing composite type. However, special treatment is needed for
12689
      --  the cases of access parameters, return objects of an anonymous access
12690
      --  type, and, in Ada 95, access discriminants of limited types.
12691
 
12692
      if Ekind (Btyp) in Access_Kind then
12693
         if Ekind (Btyp) = E_Anonymous_Access_Type then
12694
 
12695
            --  If the type is a nonlocal anonymous access type (such as for
12696
            --  an access parameter) we treat it as being declared at the
12697
            --  library level to ensure that names such as X.all'access don't
12698
            --  fail static accessibility checks.
12699
 
12700
            if not Is_Local_Anonymous_Access (Typ) then
12701
               return Scope_Depth (Standard_Standard);
12702
 
12703
            --  If this is a return object, the accessibility level is that of
12704
            --  the result subtype of the enclosing function. The test here is
12705
            --  little complicated, because we have to account for extended
12706
            --  return statements that have been rewritten as blocks, in which
12707
            --  case we have to find and the Is_Return_Object attribute of the
12708
            --  itype's associated object. It would be nice to find a way to
12709
            --  simplify this test, but it doesn't seem worthwhile to add a new
12710
            --  flag just for purposes of this test. ???
12711
 
12712
            elsif Ekind (Scope (Btyp)) = E_Return_Statement
12713
              or else
12714
                (Is_Itype (Btyp)
12715
                  and then Nkind (Associated_Node_For_Itype (Btyp)) =
12716
                             N_Object_Declaration
12717
                  and then Is_Return_Object
12718
                             (Defining_Identifier
12719
                                (Associated_Node_For_Itype (Btyp))))
12720
            then
12721
               declare
12722
                  Scop : Entity_Id;
12723
 
12724
               begin
12725
                  Scop := Scope (Scope (Btyp));
12726
                  while Present (Scop) loop
12727
                     exit when Ekind (Scop) = E_Function;
12728
                     Scop := Scope (Scop);
12729
                  end loop;
12730
 
12731
                  --  Treat the return object's type as having the level of the
12732
                  --  function's result subtype (as per RM05-6.5(5.3/2)).
12733
 
12734
                  return Type_Access_Level (Etype (Scop));
12735
               end;
12736
            end if;
12737
         end if;
12738
 
12739
         Btyp := Root_Type (Btyp);
12740
 
12741
         --  The accessibility level of anonymous access types associated with
12742
         --  discriminants is that of the current instance of the type, and
12743
         --  that's deeper than the type itself (AARM 3.10.2 (12.3.21)).
12744
 
12745
         --  AI-402: access discriminants have accessibility based on the
12746
         --  object rather than the type in Ada 2005, so the above paragraph
12747
         --  doesn't apply.
12748
 
12749
         --  ??? Needs completion with rules from AI-416
12750
 
12751
         if Ada_Version <= Ada_95
12752
           and then Ekind (Typ) = E_Anonymous_Access_Type
12753
           and then Present (Associated_Node_For_Itype (Typ))
12754
           and then Nkind (Associated_Node_For_Itype (Typ)) =
12755
                                                 N_Discriminant_Specification
12756
         then
12757
            return Scope_Depth (Enclosing_Dynamic_Scope (Btyp)) + 1;
12758
         end if;
12759
      end if;
12760
 
12761
      --  Return library level for a generic formal type. This is done because
12762
      --  RM(10.3.2) says that "The statically deeper relationship does not
12763
      --  apply to ... a descendant of a generic formal type". Rather than
12764
      --  checking at each point where a static accessibility check is
12765
      --  performed to see if we are dealing with a formal type, this rule is
12766
      --  implemented by having Type_Access_Level and Deepest_Type_Access_Level
12767
      --  return extreme values for a formal type; Deepest_Type_Access_Level
12768
      --  returns Int'Last. By calling the appropriate function from among the
12769
      --  two, we ensure that the static accessibility check will pass if we
12770
      --  happen to run into a formal type. More specifically, we should call
12771
      --  Deepest_Type_Access_Level instead of Type_Access_Level whenever the
12772
      --  call occurs as part of a static accessibility check and the error
12773
      --  case is the case where the type's level is too shallow (as opposed
12774
      --  to too deep).
12775
 
12776
      if Is_Generic_Type (Root_Type (Btyp)) then
12777
         return Scope_Depth (Standard_Standard);
12778
      end if;
12779
 
12780
      return Scope_Depth (Enclosing_Dynamic_Scope (Btyp));
12781
   end Type_Access_Level;
12782
 
12783
   ------------------------------------
12784
   -- Type_Without_Stream_Operation  --
12785
   ------------------------------------
12786
 
12787
   function Type_Without_Stream_Operation
12788
     (T  : Entity_Id;
12789
      Op : TSS_Name_Type := TSS_Null) return Entity_Id
12790
   is
12791
      BT         : constant Entity_Id := Base_Type (T);
12792
      Op_Missing : Boolean;
12793
 
12794
   begin
12795
      if not Restriction_Active (No_Default_Stream_Attributes) then
12796
         return Empty;
12797
      end if;
12798
 
12799
      if Is_Elementary_Type (T) then
12800
         if Op = TSS_Null then
12801
            Op_Missing :=
12802
              No (TSS (BT, TSS_Stream_Read))
12803
                or else No (TSS (BT, TSS_Stream_Write));
12804
 
12805
         else
12806
            Op_Missing := No (TSS (BT, Op));
12807
         end if;
12808
 
12809
         if Op_Missing then
12810
            return T;
12811
         else
12812
            return Empty;
12813
         end if;
12814
 
12815
      elsif Is_Array_Type (T) then
12816
         return Type_Without_Stream_Operation (Component_Type (T), Op);
12817
 
12818
      elsif Is_Record_Type (T) then
12819
         declare
12820
            Comp  : Entity_Id;
12821
            C_Typ : Entity_Id;
12822
 
12823
         begin
12824
            Comp := First_Component (T);
12825
            while Present (Comp) loop
12826
               C_Typ := Type_Without_Stream_Operation (Etype (Comp), Op);
12827
 
12828
               if Present (C_Typ) then
12829
                  return C_Typ;
12830
               end if;
12831
 
12832
               Next_Component (Comp);
12833
            end loop;
12834
 
12835
            return Empty;
12836
         end;
12837
 
12838
      elsif Is_Private_Type (T)
12839
        and then Present (Full_View (T))
12840
      then
12841
         return Type_Without_Stream_Operation (Full_View (T), Op);
12842
      else
12843
         return Empty;
12844
      end if;
12845
   end Type_Without_Stream_Operation;
12846
 
12847
   ----------------------------
12848
   -- Unique_Defining_Entity --
12849
   ----------------------------
12850
 
12851
   function Unique_Defining_Entity (N : Node_Id) return Entity_Id is
12852
   begin
12853
      return Unique_Entity (Defining_Entity (N));
12854
   end Unique_Defining_Entity;
12855
 
12856
   -------------------
12857
   -- Unique_Entity --
12858
   -------------------
12859
 
12860
   function Unique_Entity (E : Entity_Id) return Entity_Id is
12861
      U : Entity_Id := E;
12862
      P : Node_Id;
12863
 
12864
   begin
12865
      case Ekind (E) is
12866
         when E_Constant =>
12867
            if Present (Full_View (E)) then
12868
               U := Full_View (E);
12869
            end if;
12870
 
12871
         when Type_Kind =>
12872
            if Present (Full_View (E)) then
12873
               U := Full_View (E);
12874
            end if;
12875
 
12876
         when E_Package_Body =>
12877
            P := Parent (E);
12878
 
12879
            if Nkind (P) = N_Defining_Program_Unit_Name then
12880
               P := Parent (P);
12881
            end if;
12882
 
12883
            U := Corresponding_Spec (P);
12884
 
12885
         when E_Subprogram_Body =>
12886
            P := Parent (E);
12887
 
12888
            if Nkind (P) = N_Defining_Program_Unit_Name then
12889
               P := Parent (P);
12890
            end if;
12891
 
12892
            P := Parent (P);
12893
 
12894
            if Nkind (P) = N_Subprogram_Body_Stub then
12895
               if Present (Library_Unit (P)) then
12896
 
12897
                  --  Get to the function or procedure (generic) entity through
12898
                  --  the body entity.
12899
 
12900
                  U :=
12901
                    Unique_Entity (Defining_Entity (Get_Body_From_Stub (P)));
12902
               end if;
12903
            else
12904
               U := Corresponding_Spec (P);
12905
            end if;
12906
 
12907
         when Formal_Kind =>
12908
            if Present (Spec_Entity (E)) then
12909
               U := Spec_Entity (E);
12910
            end if;
12911
 
12912
         when others =>
12913
            null;
12914
      end case;
12915
 
12916
      return U;
12917
   end Unique_Entity;
12918
 
12919
   -----------------
12920
   -- Unique_Name --
12921
   -----------------
12922
 
12923
   function Unique_Name (E : Entity_Id) return String is
12924
 
12925
      --  Names of E_Subprogram_Body or E_Package_Body entities are not
12926
      --  reliable, as they may not include the overloading suffix. Instead,
12927
      --  when looking for the name of E or one of its enclosing scope, we get
12928
      --  the name of the corresponding Unique_Entity.
12929
 
12930
      function Get_Scoped_Name (E : Entity_Id) return String;
12931
      --  Return the name of E prefixed by all the names of the scopes to which
12932
      --  E belongs, except for Standard.
12933
 
12934
      ---------------------
12935
      -- Get_Scoped_Name --
12936
      ---------------------
12937
 
12938
      function Get_Scoped_Name (E : Entity_Id) return String is
12939
         Name : constant String := Get_Name_String (Chars (E));
12940
      begin
12941
         if Has_Fully_Qualified_Name (E)
12942
           or else Scope (E) = Standard_Standard
12943
         then
12944
            return Name;
12945
         else
12946
            return Get_Scoped_Name (Unique_Entity (Scope (E))) & "__" & Name;
12947
         end if;
12948
      end Get_Scoped_Name;
12949
 
12950
   --  Start of processing for Unique_Name
12951
 
12952
   begin
12953
      if E = Standard_Standard then
12954
         return Get_Name_String (Name_Standard);
12955
 
12956
      elsif Scope (E) = Standard_Standard
12957
        and then not (Ekind (E) = E_Package or else Is_Subprogram (E))
12958
      then
12959
         return Get_Name_String (Name_Standard) & "__" &
12960
           Get_Name_String (Chars (E));
12961
 
12962
      elsif Ekind (E) = E_Enumeration_Literal then
12963
         return Unique_Name (Etype (E)) & "__" & Get_Name_String (Chars (E));
12964
 
12965
      else
12966
         return Get_Scoped_Name (Unique_Entity (E));
12967
      end if;
12968
   end Unique_Name;
12969
 
12970
   ---------------------
12971
   -- Unit_Is_Visible --
12972
   ---------------------
12973
 
12974
   function Unit_Is_Visible (U : Entity_Id) return Boolean is
12975
      Curr        : constant Node_Id   := Cunit (Current_Sem_Unit);
12976
      Curr_Entity : constant Entity_Id := Cunit_Entity (Current_Sem_Unit);
12977
 
12978
      function Unit_In_Parent_Context (Par_Unit : Node_Id) return Boolean;
12979
      --  For a child unit, check whether unit appears in a with_clause
12980
      --  of a parent.
12981
 
12982
      function Unit_In_Context (Comp_Unit : Node_Id) return Boolean;
12983
      --  Scan the context clause of one compilation unit looking for a
12984
      --  with_clause for the unit in question.
12985
 
12986
      ----------------------------
12987
      -- Unit_In_Parent_Context --
12988
      ----------------------------
12989
 
12990
      function Unit_In_Parent_Context (Par_Unit : Node_Id) return Boolean is
12991
      begin
12992
         if Unit_In_Context (Par_Unit) then
12993
            return True;
12994
 
12995
         elsif Is_Child_Unit (Defining_Entity (Unit (Par_Unit))) then
12996
            return Unit_In_Parent_Context (Parent_Spec (Unit (Par_Unit)));
12997
 
12998
         else
12999
            return False;
13000
         end if;
13001
      end Unit_In_Parent_Context;
13002
 
13003
      ---------------------
13004
      -- Unit_In_Context --
13005
      ---------------------
13006
 
13007
      function Unit_In_Context (Comp_Unit : Node_Id) return Boolean is
13008
         Clause : Node_Id;
13009
 
13010
      begin
13011
         Clause := First (Context_Items (Comp_Unit));
13012
         while Present (Clause) loop
13013
            if Nkind (Clause) = N_With_Clause then
13014
               if Library_Unit (Clause) = U then
13015
                  return True;
13016
 
13017
               --  The with_clause may denote a renaming of the unit we are
13018
               --  looking for, eg. Text_IO which renames Ada.Text_IO.
13019
 
13020
               elsif
13021
                 Renamed_Entity (Entity (Name (Clause))) =
13022
                                                Defining_Entity (Unit (U))
13023
               then
13024
                  return True;
13025
               end if;
13026
            end if;
13027
 
13028
            Next (Clause);
13029
         end loop;
13030
 
13031
         return False;
13032
      end Unit_In_Context;
13033
 
13034
   --  Start of processing for Unit_Is_Visible
13035
 
13036
   begin
13037
      --  The currrent unit is directly visible
13038
 
13039
      if Curr = U then
13040
         return True;
13041
 
13042
      elsif Unit_In_Context (Curr) then
13043
         return True;
13044
 
13045
      --  If the current unit is a body, check the context of the spec
13046
 
13047
      elsif Nkind (Unit (Curr)) = N_Package_Body
13048
        or else
13049
          (Nkind (Unit (Curr)) = N_Subprogram_Body
13050
            and then not Acts_As_Spec (Unit (Curr)))
13051
      then
13052
         if Unit_In_Context (Library_Unit (Curr)) then
13053
            return True;
13054
         end if;
13055
      end if;
13056
 
13057
      --  If the spec is a child unit, examine the parents
13058
 
13059
      if Is_Child_Unit (Curr_Entity) then
13060
         if Nkind (Unit (Curr)) in N_Unit_Body then
13061
            return
13062
              Unit_In_Parent_Context
13063
                (Parent_Spec (Unit (Library_Unit (Curr))));
13064
         else
13065
            return Unit_In_Parent_Context (Parent_Spec (Unit (Curr)));
13066
         end if;
13067
 
13068
      else
13069
         return False;
13070
      end if;
13071
   end Unit_Is_Visible;
13072
 
13073
   ------------------------------
13074
   -- Universal_Interpretation --
13075
   ------------------------------
13076
 
13077
   function Universal_Interpretation (Opnd : Node_Id) return Entity_Id is
13078
      Index : Interp_Index;
13079
      It    : Interp;
13080
 
13081
   begin
13082
      --  The argument may be a formal parameter of an operator or subprogram
13083
      --  with multiple interpretations, or else an expression for an actual.
13084
 
13085
      if Nkind (Opnd) = N_Defining_Identifier
13086
        or else not Is_Overloaded (Opnd)
13087
      then
13088
         if Etype (Opnd) = Universal_Integer
13089
           or else Etype (Opnd) = Universal_Real
13090
         then
13091
            return Etype (Opnd);
13092
         else
13093
            return Empty;
13094
         end if;
13095
 
13096
      else
13097
         Get_First_Interp (Opnd, Index, It);
13098
         while Present (It.Typ) loop
13099
            if It.Typ = Universal_Integer
13100
              or else It.Typ = Universal_Real
13101
            then
13102
               return It.Typ;
13103
            end if;
13104
 
13105
            Get_Next_Interp (Index, It);
13106
         end loop;
13107
 
13108
         return Empty;
13109
      end if;
13110
   end Universal_Interpretation;
13111
 
13112
   ---------------
13113
   -- Unqualify --
13114
   ---------------
13115
 
13116
   function Unqualify (Expr : Node_Id) return Node_Id is
13117
   begin
13118
      --  Recurse to handle unlikely case of multiple levels of qualification
13119
 
13120
      if Nkind (Expr) = N_Qualified_Expression then
13121
         return Unqualify (Expression (Expr));
13122
 
13123
      --  Normal case, not a qualified expression
13124
 
13125
      else
13126
         return Expr;
13127
      end if;
13128
   end Unqualify;
13129
 
13130
   -----------------------
13131
   -- Visible_Ancestors --
13132
   -----------------------
13133
 
13134
   function Visible_Ancestors (Typ : Entity_Id) return Elist_Id is
13135
      List_1 : Elist_Id;
13136
      List_2 : Elist_Id;
13137
      Elmt   : Elmt_Id;
13138
 
13139
   begin
13140
      pragma Assert (Is_Record_Type (Typ)
13141
        and then Is_Tagged_Type (Typ));
13142
 
13143
      --  Collect all the parents and progenitors of Typ. If the full-view of
13144
      --  private parents and progenitors is available then it is used to
13145
      --  generate the list of visible ancestors; otherwise their partial
13146
      --  view is added to the resulting list.
13147
 
13148
      Collect_Parents
13149
        (T               => Typ,
13150
         List            => List_1,
13151
         Use_Full_View   => True);
13152
 
13153
      Collect_Interfaces
13154
        (T               => Typ,
13155
         Ifaces_List     => List_2,
13156
         Exclude_Parents => True,
13157
         Use_Full_View   => True);
13158
 
13159
      --  Join the two lists. Avoid duplications because an interface may
13160
      --  simultaneously be parent and progenitor of a type.
13161
 
13162
      Elmt := First_Elmt (List_2);
13163
      while Present (Elmt) loop
13164
         Append_Unique_Elmt (Node (Elmt), List_1);
13165
         Next_Elmt (Elmt);
13166
      end loop;
13167
 
13168
      return List_1;
13169
   end Visible_Ancestors;
13170
 
13171
   ----------------------
13172
   -- Within_Init_Proc --
13173
   ----------------------
13174
 
13175
   function Within_Init_Proc return Boolean is
13176
      S : Entity_Id;
13177
 
13178
   begin
13179
      S := Current_Scope;
13180
      while not Is_Overloadable (S) loop
13181
         if S = Standard_Standard then
13182
            return False;
13183
         else
13184
            S := Scope (S);
13185
         end if;
13186
      end loop;
13187
 
13188
      return Is_Init_Proc (S);
13189
   end Within_Init_Proc;
13190
 
13191
   ----------------
13192
   -- Wrong_Type --
13193
   ----------------
13194
 
13195
   procedure Wrong_Type (Expr : Node_Id; Expected_Type : Entity_Id) is
13196
      Found_Type : constant Entity_Id := First_Subtype (Etype (Expr));
13197
      Expec_Type : constant Entity_Id := First_Subtype (Expected_Type);
13198
 
13199
      Matching_Field : Entity_Id;
13200
      --  Entity to give a more precise suggestion on how to write a one-
13201
      --  element positional aggregate.
13202
 
13203
      function Has_One_Matching_Field return Boolean;
13204
      --  Determines if Expec_Type is a record type with a single component or
13205
      --  discriminant whose type matches the found type or is one dimensional
13206
      --  array whose component type matches the found type.
13207
 
13208
      ----------------------------
13209
      -- Has_One_Matching_Field --
13210
      ----------------------------
13211
 
13212
      function Has_One_Matching_Field return Boolean is
13213
         E : Entity_Id;
13214
 
13215
      begin
13216
         Matching_Field := Empty;
13217
 
13218
         if Is_Array_Type (Expec_Type)
13219
           and then Number_Dimensions (Expec_Type) = 1
13220
           and then
13221
             Covers (Etype (Component_Type (Expec_Type)), Found_Type)
13222
         then
13223
            --  Use type name if available. This excludes multidimensional
13224
            --  arrays and anonymous arrays.
13225
 
13226
            if Comes_From_Source (Expec_Type) then
13227
               Matching_Field := Expec_Type;
13228
 
13229
            --  For an assignment, use name of target
13230
 
13231
            elsif Nkind (Parent (Expr)) = N_Assignment_Statement
13232
              and then Is_Entity_Name (Name (Parent (Expr)))
13233
            then
13234
               Matching_Field := Entity (Name (Parent (Expr)));
13235
            end if;
13236
 
13237
            return True;
13238
 
13239
         elsif not Is_Record_Type (Expec_Type) then
13240
            return False;
13241
 
13242
         else
13243
            E := First_Entity (Expec_Type);
13244
            loop
13245
               if No (E) then
13246
                  return False;
13247
 
13248
               elsif (Ekind (E) /= E_Discriminant
13249
                       and then Ekind (E) /= E_Component)
13250
                 or else (Chars (E) = Name_uTag
13251
                           or else Chars (E) = Name_uParent)
13252
               then
13253
                  Next_Entity (E);
13254
 
13255
               else
13256
                  exit;
13257
               end if;
13258
            end loop;
13259
 
13260
            if not Covers (Etype (E), Found_Type) then
13261
               return False;
13262
 
13263
            elsif Present (Next_Entity (E)) then
13264
               return False;
13265
 
13266
            else
13267
               Matching_Field := E;
13268
               return True;
13269
            end if;
13270
         end if;
13271
      end Has_One_Matching_Field;
13272
 
13273
   --  Start of processing for Wrong_Type
13274
 
13275
   begin
13276
      --  Don't output message if either type is Any_Type, or if a message
13277
      --  has already been posted for this node. We need to do the latter
13278
      --  check explicitly (it is ordinarily done in Errout), because we
13279
      --  are using ! to force the output of the error messages.
13280
 
13281
      if Expec_Type = Any_Type
13282
        or else Found_Type = Any_Type
13283
        or else Error_Posted (Expr)
13284
      then
13285
         return;
13286
 
13287
      --  If one of the types is a Taft-Amendment type and the other it its
13288
      --  completion, it must be an illegal use of a TAT in the spec, for
13289
      --  which an error was already emitted. Avoid cascaded errors.
13290
 
13291
      elsif Is_Incomplete_Type (Expec_Type)
13292
        and then Has_Completion_In_Body (Expec_Type)
13293
        and then Full_View (Expec_Type) = Etype (Expr)
13294
      then
13295
         return;
13296
 
13297
      elsif Is_Incomplete_Type (Etype (Expr))
13298
        and then Has_Completion_In_Body (Etype (Expr))
13299
        and then Full_View (Etype (Expr)) = Expec_Type
13300
      then
13301
         return;
13302
 
13303
      --  In  an instance, there is an ongoing problem with completion of
13304
      --  type derived from private types. Their structure is what Gigi
13305
      --  expects, but the  Etype is the parent type rather than the
13306
      --  derived private type itself. Do not flag error in this case. The
13307
      --  private completion is an entity without a parent, like an Itype.
13308
      --  Similarly, full and partial views may be incorrect in the instance.
13309
      --  There is no simple way to insure that it is consistent ???
13310
 
13311
      elsif In_Instance then
13312
         if Etype (Etype (Expr)) = Etype (Expected_Type)
13313
           and then
13314
             (Has_Private_Declaration (Expected_Type)
13315
               or else Has_Private_Declaration (Etype (Expr)))
13316
           and then No (Parent (Expected_Type))
13317
         then
13318
            return;
13319
         end if;
13320
      end if;
13321
 
13322
      --  An interesting special check. If the expression is parenthesized
13323
      --  and its type corresponds to the type of the sole component of the
13324
      --  expected record type, or to the component type of the expected one
13325
      --  dimensional array type, then assume we have a bad aggregate attempt.
13326
 
13327
      if Nkind (Expr) in N_Subexpr
13328
        and then Paren_Count (Expr) /= 0
13329
        and then Has_One_Matching_Field
13330
      then
13331
         Error_Msg_N ("positional aggregate cannot have one component", Expr);
13332
         if Present (Matching_Field) then
13333
            if Is_Array_Type (Expec_Type) then
13334
               Error_Msg_NE
13335
                 ("\write instead `&''First ='> ...`", Expr, Matching_Field);
13336
 
13337
            else
13338
               Error_Msg_NE
13339
                 ("\write instead `& ='> ...`", Expr, Matching_Field);
13340
            end if;
13341
         end if;
13342
 
13343
      --  Another special check, if we are looking for a pool-specific access
13344
      --  type and we found an E_Access_Attribute_Type, then we have the case
13345
      --  of an Access attribute being used in a context which needs a pool-
13346
      --  specific type, which is never allowed. The one extra check we make
13347
      --  is that the expected designated type covers the Found_Type.
13348
 
13349
      elsif Is_Access_Type (Expec_Type)
13350
        and then Ekind (Found_Type) = E_Access_Attribute_Type
13351
        and then Ekind (Base_Type (Expec_Type)) /= E_General_Access_Type
13352
        and then Ekind (Base_Type (Expec_Type)) /= E_Anonymous_Access_Type
13353
        and then Covers
13354
          (Designated_Type (Expec_Type), Designated_Type (Found_Type))
13355
      then
13356
         Error_Msg_N -- CODEFIX
13357
           ("result must be general access type!", Expr);
13358
         Error_Msg_NE -- CODEFIX
13359
           ("add ALL to }!", Expr, Expec_Type);
13360
 
13361
      --  Another special check, if the expected type is an integer type,
13362
      --  but the expression is of type System.Address, and the parent is
13363
      --  an addition or subtraction operation whose left operand is the
13364
      --  expression in question and whose right operand is of an integral
13365
      --  type, then this is an attempt at address arithmetic, so give
13366
      --  appropriate message.
13367
 
13368
      elsif Is_Integer_Type (Expec_Type)
13369
        and then Is_RTE (Found_Type, RE_Address)
13370
        and then (Nkind (Parent (Expr)) = N_Op_Add
13371
                    or else
13372
                  Nkind (Parent (Expr)) = N_Op_Subtract)
13373
        and then Expr = Left_Opnd (Parent (Expr))
13374
        and then Is_Integer_Type (Etype (Right_Opnd (Parent (Expr))))
13375
      then
13376
         Error_Msg_N
13377
           ("address arithmetic not predefined in package System",
13378
            Parent (Expr));
13379
         Error_Msg_N
13380
           ("\possible missing with/use of System.Storage_Elements",
13381
            Parent (Expr));
13382
         return;
13383
 
13384
      --  If the expected type is an anonymous access type, as for access
13385
      --  parameters and discriminants, the error is on the designated types.
13386
 
13387
      elsif Ekind (Expec_Type) = E_Anonymous_Access_Type then
13388
         if Comes_From_Source (Expec_Type) then
13389
            Error_Msg_NE ("expected}!", Expr, Expec_Type);
13390
         else
13391
            Error_Msg_NE
13392
              ("expected an access type with designated}",
13393
                 Expr, Designated_Type (Expec_Type));
13394
         end if;
13395
 
13396
         if Is_Access_Type (Found_Type)
13397
           and then not Comes_From_Source (Found_Type)
13398
         then
13399
            Error_Msg_NE
13400
              ("\\found an access type with designated}!",
13401
                Expr, Designated_Type (Found_Type));
13402
         else
13403
            if From_With_Type (Found_Type) then
13404
               Error_Msg_NE ("\\found incomplete}!", Expr, Found_Type);
13405
               Error_Msg_Qual_Level := 99;
13406
               Error_Msg_NE -- CODEFIX
13407
                 ("\\missing `WITH &;", Expr, Scope (Found_Type));
13408
               Error_Msg_Qual_Level := 0;
13409
            else
13410
               Error_Msg_NE ("found}!", Expr, Found_Type);
13411
            end if;
13412
         end if;
13413
 
13414
      --  Normal case of one type found, some other type expected
13415
 
13416
      else
13417
         --  If the names of the two types are the same, see if some number
13418
         --  of levels of qualification will help. Don't try more than three
13419
         --  levels, and if we get to standard, it's no use (and probably
13420
         --  represents an error in the compiler) Also do not bother with
13421
         --  internal scope names.
13422
 
13423
         declare
13424
            Expec_Scope : Entity_Id;
13425
            Found_Scope : Entity_Id;
13426
 
13427
         begin
13428
            Expec_Scope := Expec_Type;
13429
            Found_Scope := Found_Type;
13430
 
13431
            for Levels in Int range 0 .. 3 loop
13432
               if Chars (Expec_Scope) /= Chars (Found_Scope) then
13433
                  Error_Msg_Qual_Level := Levels;
13434
                  exit;
13435
               end if;
13436
 
13437
               Expec_Scope := Scope (Expec_Scope);
13438
               Found_Scope := Scope (Found_Scope);
13439
 
13440
               exit when Expec_Scope = Standard_Standard
13441
                 or else Found_Scope = Standard_Standard
13442
                 or else not Comes_From_Source (Expec_Scope)
13443
                 or else not Comes_From_Source (Found_Scope);
13444
            end loop;
13445
         end;
13446
 
13447
         if Is_Record_Type (Expec_Type)
13448
           and then Present (Corresponding_Remote_Type (Expec_Type))
13449
         then
13450
            Error_Msg_NE ("expected}!", Expr,
13451
                          Corresponding_Remote_Type (Expec_Type));
13452
         else
13453
            Error_Msg_NE ("expected}!", Expr, Expec_Type);
13454
         end if;
13455
 
13456
         if Is_Entity_Name (Expr)
13457
           and then Is_Package_Or_Generic_Package (Entity (Expr))
13458
         then
13459
            Error_Msg_N ("\\found package name!", Expr);
13460
 
13461
         elsif Is_Entity_Name (Expr)
13462
           and then
13463
             (Ekind (Entity (Expr)) = E_Procedure
13464
                or else
13465
              Ekind (Entity (Expr)) = E_Generic_Procedure)
13466
         then
13467
            if Ekind (Expec_Type) = E_Access_Subprogram_Type then
13468
               Error_Msg_N
13469
                 ("found procedure name, possibly missing Access attribute!",
13470
                   Expr);
13471
            else
13472
               Error_Msg_N
13473
                 ("\\found procedure name instead of function!", Expr);
13474
            end if;
13475
 
13476
         elsif Nkind (Expr) = N_Function_Call
13477
           and then Ekind (Expec_Type) = E_Access_Subprogram_Type
13478
           and then Etype (Designated_Type (Expec_Type)) = Etype (Expr)
13479
           and then No (Parameter_Associations (Expr))
13480
         then
13481
            Error_Msg_N
13482
              ("found function name, possibly missing Access attribute!",
13483
               Expr);
13484
 
13485
         --  Catch common error: a prefix or infix operator which is not
13486
         --  directly visible because the type isn't.
13487
 
13488
         elsif Nkind (Expr) in N_Op
13489
            and then Is_Overloaded (Expr)
13490
            and then not Is_Immediately_Visible (Expec_Type)
13491
            and then not Is_Potentially_Use_Visible (Expec_Type)
13492
            and then not In_Use (Expec_Type)
13493
            and then Has_Compatible_Type (Right_Opnd (Expr), Expec_Type)
13494
         then
13495
            Error_Msg_N
13496
              ("operator of the type is not directly visible!", Expr);
13497
 
13498
         elsif Ekind (Found_Type) = E_Void
13499
           and then Present (Parent (Found_Type))
13500
           and then Nkind (Parent (Found_Type)) = N_Full_Type_Declaration
13501
         then
13502
            Error_Msg_NE ("\\found premature usage of}!", Expr, Found_Type);
13503
 
13504
         else
13505
            Error_Msg_NE ("\\found}!", Expr, Found_Type);
13506
         end if;
13507
 
13508
         --  A special check for cases like M1 and M2 = 0 where M1 and M2 are
13509
         --  of the same modular type, and (M1 and M2) = 0 was intended.
13510
 
13511
         if Expec_Type = Standard_Boolean
13512
           and then Is_Modular_Integer_Type (Found_Type)
13513
           and then Nkind_In (Parent (Expr), N_Op_And, N_Op_Or, N_Op_Xor)
13514
           and then Nkind (Right_Opnd (Parent (Expr))) in N_Op_Compare
13515
         then
13516
            declare
13517
               Op : constant Node_Id := Right_Opnd (Parent (Expr));
13518
               L  : constant Node_Id := Left_Opnd (Op);
13519
               R  : constant Node_Id := Right_Opnd (Op);
13520
            begin
13521
               --  The case for the message is when the left operand of the
13522
               --  comparison is the same modular type, or when it is an
13523
               --  integer literal (or other universal integer expression),
13524
               --  which would have been typed as the modular type if the
13525
               --  parens had been there.
13526
 
13527
               if (Etype (L) = Found_Type
13528
                     or else
13529
                   Etype (L) = Universal_Integer)
13530
                 and then Is_Integer_Type (Etype (R))
13531
               then
13532
                  Error_Msg_N
13533
                    ("\\possible missing parens for modular operation", Expr);
13534
               end if;
13535
            end;
13536
         end if;
13537
 
13538
         --  Reset error message qualification indication
13539
 
13540
         Error_Msg_Qual_Level := 0;
13541
      end if;
13542
   end Wrong_Type;
13543
 
13544
end Sem_Util;

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