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1 706 jeremybenn
------------------------------------------------------------------------------
2
--                                                                          --
3
--                         GNAT COMPILER COMPONENTS                         --
4
--                                                                          --
5
--                               I N L I N E                                --
6
--                                                                          --
7
--                                 B o d y                                  --
8
--                                                                          --
9
--          Copyright (C) 1992-2011, Free Software Foundation, Inc.         --
10
--                                                                          --
11
-- GNAT is free software;  you can  redistribute it  and/or modify it under --
12
-- terms of the  GNU General Public License as published  by the Free Soft- --
13
-- ware  Foundation;  either version 3,  or (at your option) any later ver- --
14
-- sion.  GNAT is distributed in the hope that it will be useful, but WITH- --
15
-- OUT ANY WARRANTY;  without even the  implied warranty of MERCHANTABILITY --
16
-- or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License --
17
-- for  more details.  You should have  received  a copy of the GNU General --
18
-- Public License  distributed with GNAT; see file COPYING3.  If not, go to --
19
-- http://www.gnu.org/licenses for a complete copy of the license.          --
20
--                                                                          --
21
-- GNAT was originally developed  by the GNAT team at  New York University. --
22
-- Extensive contributions were provided by Ada Core Technologies Inc.      --
23
--                                                                          --
24
------------------------------------------------------------------------------
25
 
26
with Atree;    use Atree;
27
with Einfo;    use Einfo;
28
with Elists;   use Elists;
29
with Errout;   use Errout;
30
with Exp_Ch7;  use Exp_Ch7;
31
with Exp_Tss;  use Exp_Tss;
32
with Fname;    use Fname;
33
with Fname.UF; use Fname.UF;
34
with Lib;      use Lib;
35
with Namet;    use Namet;
36
with Nlists;   use Nlists;
37
with Sem_Aux;  use Sem_Aux;
38
with Sem_Ch8;  use Sem_Ch8;
39
with Sem_Ch10; use Sem_Ch10;
40
with Sem_Ch12; use Sem_Ch12;
41
with Sem_Util; use Sem_Util;
42
with Sinfo;    use Sinfo;
43
with Snames;   use Snames;
44
with Stand;    use Stand;
45
with Uname;    use Uname;
46
 
47
package body Inline is
48
 
49
   --------------------
50
   -- Inlined Bodies --
51
   --------------------
52
 
53
   --  Inlined functions are actually placed in line by the backend if the
54
   --  corresponding bodies are available (i.e. compiled). Whenever we find
55
   --  a call to an inlined subprogram, we add the name of the enclosing
56
   --  compilation unit to a worklist. After all compilation, and after
57
   --  expansion of generic bodies, we traverse the list of pending bodies
58
   --  and compile them as well.
59
 
60
   package Inlined_Bodies is new Table.Table (
61
     Table_Component_Type => Entity_Id,
62
     Table_Index_Type     => Int,
63
     Table_Low_Bound      => 0,
64
     Table_Initial        => Alloc.Inlined_Bodies_Initial,
65
     Table_Increment      => Alloc.Inlined_Bodies_Increment,
66
     Table_Name           => "Inlined_Bodies");
67
 
68
   -----------------------
69
   -- Inline Processing --
70
   -----------------------
71
 
72
   --  For each call to an inlined subprogram, we make entries in a table
73
   --  that stores caller and callee, and indicates a prerequisite from
74
   --  one to the other. We also record the compilation unit that contains
75
   --  the callee. After analyzing the bodies of all such compilation units,
76
   --  we produce a list of subprograms in  topological order, for use by the
77
   --  back-end. If P2 is a prerequisite of P1, then P1 calls P2, and for
78
   --  proper inlining the back-end must analyze the body of P2 before that of
79
   --  P1. The code below guarantees that the transitive closure of inlined
80
   --  subprograms called from the main compilation unit is made available to
81
   --  the code generator.
82
 
83
   Last_Inlined : Entity_Id := Empty;
84
 
85
   --  For each entry in the table we keep a list of successors in topological
86
   --  order, i.e. callers of the current subprogram.
87
 
88
   type Subp_Index is new Nat;
89
   No_Subp : constant Subp_Index := 0;
90
 
91
   --  The subprogram entities are hashed into the Inlined table
92
 
93
   Num_Hash_Headers : constant := 512;
94
 
95
   Hash_Headers : array (Subp_Index range 0 .. Num_Hash_Headers - 1)
96
                                                          of Subp_Index;
97
 
98
   type Succ_Index is new Nat;
99
   No_Succ : constant Succ_Index := 0;
100
 
101
   type Succ_Info is record
102
      Subp : Subp_Index;
103
      Next : Succ_Index;
104
   end record;
105
 
106
   --  The following table stores list elements for the successor lists.
107
   --  These lists cannot be chained directly through entries in the Inlined
108
   --  table, because a given subprogram can appear in several such lists.
109
 
110
   package Successors is new Table.Table (
111
      Table_Component_Type => Succ_Info,
112
      Table_Index_Type     => Succ_Index,
113
      Table_Low_Bound      => 1,
114
      Table_Initial        => Alloc.Successors_Initial,
115
      Table_Increment      => Alloc.Successors_Increment,
116
      Table_Name           => "Successors");
117
 
118
   type Subp_Info is record
119
      Name        : Entity_Id  := Empty;
120
      First_Succ  : Succ_Index := No_Succ;
121
      Count       : Integer    := 0;
122
      Listed      : Boolean    := False;
123
      Main_Call   : Boolean    := False;
124
      Next        : Subp_Index := No_Subp;
125
      Next_Nopred : Subp_Index := No_Subp;
126
   end record;
127
 
128
   package Inlined is new Table.Table (
129
      Table_Component_Type => Subp_Info,
130
      Table_Index_Type     => Subp_Index,
131
      Table_Low_Bound      => 1,
132
      Table_Initial        => Alloc.Inlined_Initial,
133
      Table_Increment      => Alloc.Inlined_Increment,
134
      Table_Name           => "Inlined");
135
 
136
   -----------------------
137
   -- Local Subprograms --
138
   -----------------------
139
 
140
   function Get_Code_Unit_Entity (E : Entity_Id) return Entity_Id;
141
   pragma Inline (Get_Code_Unit_Entity);
142
   --  Return the entity node for the unit containing E
143
 
144
   function Scope_In_Main_Unit (Scop : Entity_Id) return Boolean;
145
   --  Return True if Scop is in the main unit or its spec
146
 
147
   procedure Add_Call (Called : Entity_Id; Caller : Entity_Id := Empty);
148
   --  Make two entries in Inlined table, for an inlined subprogram being
149
   --  called, and for the inlined subprogram that contains the call. If
150
   --  the call is in the main compilation unit, Caller is Empty.
151
 
152
   function Add_Subp (E : Entity_Id) return Subp_Index;
153
   --  Make entry in Inlined table for subprogram E, or return table index
154
   --  that already holds E.
155
 
156
   function Has_Initialized_Type (E : Entity_Id) return Boolean;
157
   --  If a candidate for inlining contains type declarations for types with
158
   --  non-trivial initialization procedures, they are not worth inlining.
159
 
160
   function Is_Nested (E : Entity_Id) return Boolean;
161
   --  If the function is nested inside some other function, it will
162
   --  always be compiled if that function is, so don't add it to the
163
   --  inline list. We cannot compile a nested function outside the
164
   --  scope of the containing function anyway. This is also the case if
165
   --  the function is defined in a task body or within an entry (for
166
   --  example, an initialization procedure).
167
 
168
   procedure Add_Inlined_Subprogram (Index : Subp_Index);
169
   --  Add subprogram to Inlined List once all of its predecessors have been
170
   --  placed on the list. Decrement the count of all its successors, and
171
   --  add them to list (recursively) if count drops to zero.
172
 
173
   ------------------------------
174
   -- Deferred Cleanup Actions --
175
   ------------------------------
176
 
177
   --  The cleanup actions for scopes that contain instantiations is delayed
178
   --  until after expansion of those instantiations, because they may
179
   --  contain finalizable objects or tasks that affect the cleanup code.
180
   --  A scope that contains instantiations only needs to be finalized once,
181
   --  even if it contains more than one instance. We keep a list of scopes
182
   --  that must still be finalized, and call cleanup_actions after all the
183
   --  instantiations have been completed.
184
 
185
   To_Clean : Elist_Id;
186
 
187
   procedure Add_Scope_To_Clean (Inst : Entity_Id);
188
   --  Build set of scopes on which cleanup actions must be performed
189
 
190
   procedure Cleanup_Scopes;
191
   --  Complete cleanup actions on scopes that need it
192
 
193
   --------------
194
   -- Add_Call --
195
   --------------
196
 
197
   procedure Add_Call (Called : Entity_Id; Caller : Entity_Id := Empty) is
198
      P1 : constant Subp_Index := Add_Subp (Called);
199
      P2 : Subp_Index;
200
      J  : Succ_Index;
201
 
202
   begin
203
      if Present (Caller) then
204
         P2 := Add_Subp (Caller);
205
 
206
         --  Add P2 to the list of successors of P1, if not already there.
207
         --  Note that P2 may contain more than one call to P1, and only
208
         --  one needs to be recorded.
209
 
210
         J := Inlined.Table (P1).First_Succ;
211
         while J /= No_Succ loop
212
            if Successors.Table (J).Subp = P2 then
213
               return;
214
            end if;
215
 
216
            J := Successors.Table (J).Next;
217
         end loop;
218
 
219
         --  On exit, make a successor entry for P2
220
 
221
         Successors.Increment_Last;
222
         Successors.Table (Successors.Last).Subp := P2;
223
         Successors.Table (Successors.Last).Next :=
224
                             Inlined.Table (P1).First_Succ;
225
         Inlined.Table (P1).First_Succ := Successors.Last;
226
 
227
         Inlined.Table (P2).Count := Inlined.Table (P2).Count + 1;
228
 
229
      else
230
         Inlined.Table (P1).Main_Call := True;
231
      end if;
232
   end Add_Call;
233
 
234
   ----------------------
235
   -- Add_Inlined_Body --
236
   ----------------------
237
 
238
   procedure Add_Inlined_Body (E : Entity_Id) is
239
 
240
      function Must_Inline return Boolean;
241
      --  Inlining is only done if the call statement N is in the main unit,
242
      --  or within the body of another inlined subprogram.
243
 
244
      -----------------
245
      -- Must_Inline --
246
      -----------------
247
 
248
      function Must_Inline return Boolean is
249
         Scop : Entity_Id;
250
         Comp : Node_Id;
251
 
252
      begin
253
         --  Check if call is in main unit
254
 
255
         Scop := Current_Scope;
256
 
257
         --  Do not try to inline if scope is standard. This could happen, for
258
         --  example, for a call to Add_Global_Declaration, and it causes
259
         --  trouble to try to inline at this level.
260
 
261
         if Scop = Standard_Standard then
262
            return False;
263
         end if;
264
 
265
         --  Otherwise lookup scope stack to outer scope
266
 
267
         while Scope (Scop) /= Standard_Standard
268
           and then not Is_Child_Unit (Scop)
269
         loop
270
            Scop := Scope (Scop);
271
         end loop;
272
 
273
         Comp := Parent (Scop);
274
         while Nkind (Comp) /= N_Compilation_Unit loop
275
            Comp := Parent (Comp);
276
         end loop;
277
 
278
         if Comp = Cunit (Main_Unit)
279
           or else Comp = Library_Unit (Cunit (Main_Unit))
280
         then
281
            Add_Call (E);
282
            return True;
283
         end if;
284
 
285
         --  Call is not in main unit. See if it's in some inlined subprogram
286
 
287
         Scop := Current_Scope;
288
         while Scope (Scop) /= Standard_Standard
289
           and then not Is_Child_Unit (Scop)
290
         loop
291
            if Is_Overloadable (Scop)
292
              and then Is_Inlined (Scop)
293
            then
294
               Add_Call (E, Scop);
295
               return True;
296
            end if;
297
 
298
            Scop := Scope (Scop);
299
         end loop;
300
 
301
         return False;
302
      end Must_Inline;
303
 
304
   --  Start of processing for Add_Inlined_Body
305
 
306
   begin
307
      --  Find unit containing E, and add to list of inlined bodies if needed.
308
      --  If the body is already present, no need to load any other unit. This
309
      --  is the case for an initialization procedure, which appears in the
310
      --  package declaration that contains the type. It is also the case if
311
      --  the body has already been analyzed. Finally, if the unit enclosing
312
      --  E is an instance, the instance body will be analyzed in any case,
313
      --  and there is no need to add the enclosing unit (whose body might not
314
      --  be available).
315
 
316
      --  Library-level functions must be handled specially, because there is
317
      --  no enclosing package to retrieve. In this case, it is the body of
318
      --  the function that will have to be loaded.
319
 
320
      if not Is_Abstract_Subprogram (E)
321
        and then not Is_Nested (E)
322
        and then Convention (E) /= Convention_Protected
323
        and then Must_Inline
324
      then
325
         declare
326
            Pack : constant Entity_Id := Get_Code_Unit_Entity (E);
327
 
328
         begin
329
            if Pack = E then
330
 
331
               --  Library-level inlined function. Add function itself to
332
               --  list of needed units.
333
 
334
               Set_Is_Called (E);
335
               Inlined_Bodies.Increment_Last;
336
               Inlined_Bodies.Table (Inlined_Bodies.Last) := E;
337
 
338
            elsif Ekind (Pack) = E_Package then
339
               Set_Is_Called (E);
340
 
341
               if Is_Generic_Instance (Pack) then
342
                  null;
343
 
344
               --  Do not inline the package if the subprogram is an init proc
345
               --  or other internally generated subprogram, because in that
346
               --  case the subprogram body appears in the same unit that
347
               --  declares the type, and that body is visible to the back end.
348
 
349
               elsif not Is_Inlined (Pack)
350
                 and then Comes_From_Source (E)
351
               then
352
                  Set_Is_Inlined (Pack);
353
                  Inlined_Bodies.Increment_Last;
354
                  Inlined_Bodies.Table (Inlined_Bodies.Last) := Pack;
355
               end if;
356
            end if;
357
         end;
358
      end if;
359
   end Add_Inlined_Body;
360
 
361
   ----------------------------
362
   -- Add_Inlined_Subprogram --
363
   ----------------------------
364
 
365
   procedure Add_Inlined_Subprogram (Index : Subp_Index) is
366
      E    : constant Entity_Id := Inlined.Table (Index).Name;
367
      Pack : constant Entity_Id := Get_Code_Unit_Entity (E);
368
      Succ : Succ_Index;
369
      Subp : Subp_Index;
370
 
371
      function Back_End_Cannot_Inline (Subp : Entity_Id) return Boolean;
372
      --  There are various conditions under which back-end inlining cannot
373
      --  be done reliably:
374
      --
375
      --    a) If a body has handlers, it must not be inlined, because this
376
      --    may violate program semantics, and because in zero-cost exception
377
      --    mode it will lead to undefined symbols at link time.
378
      --
379
      --    b) If a body contains inlined function instances, it cannot be
380
      --    inlined under ZCX because the numeric suffix generated by gigi
381
      --    will be different in the body and the place of the inlined call.
382
      --
383
      --  This procedure must be carefully coordinated with the back end.
384
 
385
      ----------------------------
386
      -- Back_End_Cannot_Inline --
387
      ----------------------------
388
 
389
      function Back_End_Cannot_Inline (Subp : Entity_Id) return Boolean is
390
         Decl     : constant Node_Id := Unit_Declaration_Node (Subp);
391
         Body_Ent : Entity_Id;
392
         Ent      : Entity_Id;
393
 
394
      begin
395
         if Nkind (Decl) = N_Subprogram_Declaration
396
           and then Present (Corresponding_Body (Decl))
397
         then
398
            Body_Ent := Corresponding_Body (Decl);
399
         else
400
            return False;
401
         end if;
402
 
403
         --  If subprogram is marked Inline_Always, inlining is mandatory
404
 
405
         if Has_Pragma_Inline_Always (Subp) then
406
            return False;
407
         end if;
408
 
409
         if Present
410
          (Exception_Handlers
411
            (Handled_Statement_Sequence
412
              (Unit_Declaration_Node (Corresponding_Body (Decl)))))
413
         then
414
            return True;
415
         end if;
416
 
417
         Ent := First_Entity (Body_Ent);
418
         while Present (Ent) loop
419
            if Is_Subprogram (Ent)
420
              and then Is_Generic_Instance (Ent)
421
            then
422
               return True;
423
            end if;
424
 
425
            Next_Entity (Ent);
426
         end loop;
427
 
428
         return False;
429
      end Back_End_Cannot_Inline;
430
 
431
   --  Start of processing for Add_Inlined_Subprogram
432
 
433
   begin
434
      --  If the subprogram is to be inlined, and if its unit is known to be
435
      --  inlined or is an instance whose body will be analyzed anyway or the
436
      --  subprogram has been generated by the compiler, and if it is declared
437
      --  at the library level not in the main unit, and if it can be inlined
438
      --  by the back-end, then insert it in the list of inlined subprograms.
439
 
440
      if Is_Inlined (E)
441
        and then (Is_Inlined (Pack)
442
                    or else Is_Generic_Instance (Pack)
443
                    or else Is_Internal (E))
444
        and then not Scope_In_Main_Unit (E)
445
        and then not Is_Nested (E)
446
        and then not Has_Initialized_Type (E)
447
      then
448
         if Back_End_Cannot_Inline (E) then
449
            Set_Is_Inlined (E, False);
450
 
451
         else
452
            if No (Last_Inlined) then
453
               Set_First_Inlined_Subprogram (Cunit (Main_Unit), E);
454
            else
455
               Set_Next_Inlined_Subprogram (Last_Inlined, E);
456
            end if;
457
 
458
            Last_Inlined := E;
459
         end if;
460
      end if;
461
 
462
      Inlined.Table (Index).Listed := True;
463
 
464
      --  Now add to the list those callers of the current subprogram that
465
      --  are themselves called. They may appear on the graph as callers
466
      --  of the current one, even if they are themselves not called, and
467
      --  there is no point in including them in the list for the backend.
468
      --  Furthermore, they might not even be public, in which case the
469
      --  back-end cannot handle them at all.
470
 
471
      Succ := Inlined.Table (Index).First_Succ;
472
      while Succ /= No_Succ loop
473
         Subp := Successors.Table (Succ).Subp;
474
         Inlined.Table (Subp).Count := Inlined.Table (Subp).Count - 1;
475
 
476
         if Inlined.Table (Subp).Count = 0
477
           and then Is_Called (Inlined.Table (Subp).Name)
478
         then
479
            Add_Inlined_Subprogram (Subp);
480
         end if;
481
 
482
         Succ := Successors.Table (Succ).Next;
483
      end loop;
484
   end Add_Inlined_Subprogram;
485
 
486
   ------------------------
487
   -- Add_Scope_To_Clean --
488
   ------------------------
489
 
490
   procedure Add_Scope_To_Clean (Inst : Entity_Id) is
491
      Scop : constant Entity_Id := Enclosing_Dynamic_Scope (Inst);
492
      Elmt : Elmt_Id;
493
 
494
   begin
495
      --  If the instance appears in a library-level package declaration,
496
      --  all finalization is global, and nothing needs doing here.
497
 
498
      if Scop = Standard_Standard then
499
         return;
500
      end if;
501
 
502
      --  If the instance is within a generic unit, no finalization code
503
      --  can be generated. Note that at this point all bodies have been
504
      --  analyzed, and the scope stack itself is not present, and the flag
505
      --  Inside_A_Generic is not set.
506
 
507
      declare
508
         S : Entity_Id;
509
 
510
      begin
511
         S := Scope (Inst);
512
         while Present (S) and then S /= Standard_Standard loop
513
            if Is_Generic_Unit (S) then
514
               return;
515
            end if;
516
 
517
            S := Scope (S);
518
         end loop;
519
      end;
520
 
521
      Elmt := First_Elmt (To_Clean);
522
      while Present (Elmt) loop
523
         if Node (Elmt) = Scop then
524
            return;
525
         end if;
526
 
527
         Elmt := Next_Elmt (Elmt);
528
      end loop;
529
 
530
      Append_Elmt (Scop, To_Clean);
531
   end Add_Scope_To_Clean;
532
 
533
   --------------
534
   -- Add_Subp --
535
   --------------
536
 
537
   function Add_Subp (E : Entity_Id) return Subp_Index is
538
      Index : Subp_Index := Subp_Index (E) mod Num_Hash_Headers;
539
      J     : Subp_Index;
540
 
541
      procedure New_Entry;
542
      --  Initialize entry in Inlined table
543
 
544
      procedure New_Entry is
545
      begin
546
         Inlined.Increment_Last;
547
         Inlined.Table (Inlined.Last).Name        := E;
548
         Inlined.Table (Inlined.Last).First_Succ  := No_Succ;
549
         Inlined.Table (Inlined.Last).Count       := 0;
550
         Inlined.Table (Inlined.Last).Listed      := False;
551
         Inlined.Table (Inlined.Last).Main_Call   := False;
552
         Inlined.Table (Inlined.Last).Next        := No_Subp;
553
         Inlined.Table (Inlined.Last).Next_Nopred := No_Subp;
554
      end New_Entry;
555
 
556
   --  Start of processing for Add_Subp
557
 
558
   begin
559
      if Hash_Headers (Index) = No_Subp then
560
         New_Entry;
561
         Hash_Headers (Index) := Inlined.Last;
562
         return Inlined.Last;
563
 
564
      else
565
         J := Hash_Headers (Index);
566
         while J /= No_Subp loop
567
            if Inlined.Table (J).Name = E then
568
               return J;
569
            else
570
               Index := J;
571
               J := Inlined.Table (J).Next;
572
            end if;
573
         end loop;
574
 
575
         --  On exit, subprogram was not found. Enter in table. Index is
576
         --  the current last entry on the hash chain.
577
 
578
         New_Entry;
579
         Inlined.Table (Index).Next := Inlined.Last;
580
         return Inlined.Last;
581
      end if;
582
   end Add_Subp;
583
 
584
   ----------------------------
585
   -- Analyze_Inlined_Bodies --
586
   ----------------------------
587
 
588
   procedure Analyze_Inlined_Bodies is
589
      Comp_Unit : Node_Id;
590
      J         : Int;
591
      Pack      : Entity_Id;
592
      S         : Succ_Index;
593
 
594
      function Is_Ancestor_Of_Main
595
        (U_Name : Entity_Id;
596
         Nam    : Node_Id) return Boolean;
597
      --  Determine whether the unit whose body is loaded is an ancestor of
598
      --  the main unit, and has a with_clause on it. The body is not
599
      --  analyzed yet, so the check is purely lexical: the name of the with
600
      --  clause is a selected component, and names of ancestors must match.
601
 
602
      -------------------------
603
      -- Is_Ancestor_Of_Main --
604
      -------------------------
605
 
606
      function Is_Ancestor_Of_Main
607
        (U_Name : Entity_Id;
608
         Nam    : Node_Id) return Boolean
609
      is
610
         Pref : Node_Id;
611
 
612
      begin
613
         if Nkind (Nam) /= N_Selected_Component then
614
            return False;
615
 
616
         else
617
            if Chars (Selector_Name (Nam)) /=
618
               Chars (Cunit_Entity (Main_Unit))
619
            then
620
               return False;
621
            end if;
622
 
623
            Pref := Prefix (Nam);
624
            if Nkind (Pref) = N_Identifier then
625
 
626
               --  Par is an ancestor of Par.Child.
627
 
628
               return Chars (Pref) = Chars (U_Name);
629
 
630
            elsif Nkind (Pref) = N_Selected_Component
631
              and then Chars (Selector_Name (Pref)) = Chars (U_Name)
632
            then
633
               --  Par.Child is an ancestor of Par.Child.Grand.
634
 
635
               return True;   --  should check that ancestor match
636
 
637
            else
638
               --  A is an ancestor of A.B.C if it is an ancestor of A.B
639
 
640
               return Is_Ancestor_Of_Main (U_Name, Pref);
641
            end if;
642
         end if;
643
      end Is_Ancestor_Of_Main;
644
 
645
   --  Start of processing for  Analyze_Inlined_Bodies
646
 
647
   begin
648
      Analyzing_Inlined_Bodies := False;
649
 
650
      if Serious_Errors_Detected = 0 then
651
         Push_Scope (Standard_Standard);
652
 
653
         J := 0;
654
         while J <= Inlined_Bodies.Last
655
           and then Serious_Errors_Detected = 0
656
         loop
657
            Pack := Inlined_Bodies.Table (J);
658
            while Present (Pack)
659
              and then Scope (Pack) /= Standard_Standard
660
              and then not Is_Child_Unit (Pack)
661
            loop
662
               Pack := Scope (Pack);
663
            end loop;
664
 
665
            Comp_Unit := Parent (Pack);
666
            while Present (Comp_Unit)
667
              and then Nkind (Comp_Unit) /= N_Compilation_Unit
668
            loop
669
               Comp_Unit := Parent (Comp_Unit);
670
            end loop;
671
 
672
            --  Load the body, unless it the main unit, or is an instance whose
673
            --  body has already been analyzed.
674
 
675
            if Present (Comp_Unit)
676
              and then Comp_Unit /= Cunit (Main_Unit)
677
              and then Body_Required (Comp_Unit)
678
              and then (Nkind (Unit (Comp_Unit)) /= N_Package_Declaration
679
                         or else No (Corresponding_Body (Unit (Comp_Unit))))
680
            then
681
               declare
682
                  Bname : constant Unit_Name_Type :=
683
                            Get_Body_Name (Get_Unit_Name (Unit (Comp_Unit)));
684
 
685
                  OK : Boolean;
686
 
687
               begin
688
                  if not Is_Loaded (Bname) then
689
                     Style_Check := False;
690
                     Load_Needed_Body (Comp_Unit, OK, Do_Analyze => False);
691
 
692
                     if not OK then
693
 
694
                        --  Warn that a body was not available for inlining
695
                        --  by the back-end.
696
 
697
                        Error_Msg_Unit_1 := Bname;
698
                        Error_Msg_N
699
                          ("one or more inlined subprograms accessed in $!?",
700
                           Comp_Unit);
701
                        Error_Msg_File_1 :=
702
                          Get_File_Name (Bname, Subunit => False);
703
                        Error_Msg_N ("\but file{ was not found!?", Comp_Unit);
704
 
705
                     else
706
                        --  If the package to be inlined is an ancestor unit of
707
                        --  the main unit, and it has a semantic dependence on
708
                        --  it, the inlining cannot take place to prevent an
709
                        --  elaboration circularity. The desired body is not
710
                        --  analyzed yet, to prevent the completion of Taft
711
                        --  amendment types that would lead to elaboration
712
                        --  circularities in gigi.
713
 
714
                        declare
715
                           U_Id      : constant Entity_Id :=
716
                                         Defining_Entity (Unit (Comp_Unit));
717
                           Body_Unit : constant Node_Id :=
718
                                         Library_Unit (Comp_Unit);
719
                           Item      : Node_Id;
720
 
721
                        begin
722
                           Item := First (Context_Items (Body_Unit));
723
                           while Present (Item) loop
724
                              if Nkind (Item) = N_With_Clause
725
                                and then
726
                                  Is_Ancestor_Of_Main (U_Id, Name (Item))
727
                              then
728
                                 Set_Is_Inlined (U_Id, False);
729
                                 exit;
730
                              end if;
731
 
732
                              Next (Item);
733
                           end loop;
734
 
735
                           --  If no suspicious with_clauses, analyze the body.
736
 
737
                           if Is_Inlined (U_Id) then
738
                              Semantics (Body_Unit);
739
                           end if;
740
                        end;
741
                     end if;
742
                  end if;
743
               end;
744
            end if;
745
 
746
            J := J + 1;
747
         end loop;
748
 
749
         --  The analysis of required bodies may have produced additional
750
         --  generic instantiations. To obtain further inlining, we perform
751
         --  another round of generic body instantiations. Establishing a
752
         --  fully recursive loop between inlining and generic instantiations
753
         --  is unlikely to yield more than this one additional pass.
754
 
755
         Instantiate_Bodies;
756
 
757
         --  The list of inlined subprograms is an overestimate, because it
758
         --  includes inlined functions called from functions that are compiled
759
         --  as part of an inlined package, but are not themselves called. An
760
         --  accurate computation of just those subprograms that are needed
761
         --  requires that we perform a transitive closure over the call graph,
762
         --  starting from calls in the main program. Here we do one step of
763
         --  the inverse transitive closure, and reset the Is_Called flag on
764
         --  subprograms all of whose callers are not.
765
 
766
         for Index in Inlined.First .. Inlined.Last loop
767
            S := Inlined.Table (Index).First_Succ;
768
 
769
            if S /= No_Succ
770
              and then not Inlined.Table (Index).Main_Call
771
            then
772
               Set_Is_Called (Inlined.Table (Index).Name, False);
773
 
774
               while S /= No_Succ loop
775
                  if Is_Called
776
                    (Inlined.Table (Successors.Table (S).Subp).Name)
777
                   or else Inlined.Table (Successors.Table (S).Subp).Main_Call
778
                  then
779
                     Set_Is_Called (Inlined.Table (Index).Name);
780
                     exit;
781
                  end if;
782
 
783
                  S := Successors.Table (S).Next;
784
               end loop;
785
            end if;
786
         end loop;
787
 
788
         --  Now that the units are compiled, chain the subprograms within
789
         --  that are called and inlined. Produce list of inlined subprograms
790
         --  sorted in  topological order. Start with all subprograms that
791
         --  have no prerequisites, i.e. inlined subprograms that do not call
792
         --  other inlined subprograms.
793
 
794
         for Index in Inlined.First .. Inlined.Last loop
795
 
796
            if Is_Called (Inlined.Table (Index).Name)
797
              and then Inlined.Table (Index).Count = 0
798
              and then not Inlined.Table (Index).Listed
799
            then
800
               Add_Inlined_Subprogram (Index);
801
            end if;
802
         end loop;
803
 
804
         --  Because Add_Inlined_Subprogram treats recursively nodes that have
805
         --  no prerequisites left, at the end of the loop all subprograms
806
         --  must have been listed. If there are any unlisted subprograms
807
         --  left, there must be some recursive chains that cannot be inlined.
808
 
809
         for Index in Inlined.First .. Inlined.Last loop
810
            if Is_Called (Inlined.Table (Index).Name)
811
              and then Inlined.Table (Index).Count /= 0
812
              and then not Is_Predefined_File_Name
813
                (Unit_File_Name
814
                  (Get_Source_Unit (Inlined.Table (Index).Name)))
815
            then
816
               Error_Msg_N
817
                 ("& cannot be inlined?", Inlined.Table (Index).Name);
818
 
819
               --  A warning on the first one might be sufficient ???
820
            end if;
821
         end loop;
822
 
823
         Pop_Scope;
824
      end if;
825
   end Analyze_Inlined_Bodies;
826
 
827
   -----------------------------
828
   -- Check_Body_For_Inlining --
829
   -----------------------------
830
 
831
   procedure Check_Body_For_Inlining (N : Node_Id; P : Entity_Id) is
832
      Bname : Unit_Name_Type;
833
      E     : Entity_Id;
834
      OK    : Boolean;
835
 
836
   begin
837
      if Is_Compilation_Unit (P)
838
        and then not Is_Generic_Instance (P)
839
      then
840
         Bname := Get_Body_Name (Get_Unit_Name (Unit (N)));
841
 
842
         E := First_Entity (P);
843
         while Present (E) loop
844
            if Has_Pragma_Inline_Always (E)
845
              or else (Front_End_Inlining and then Has_Pragma_Inline (E))
846
            then
847
               if not Is_Loaded (Bname) then
848
                  Load_Needed_Body (N, OK);
849
 
850
                  if OK then
851
 
852
                     --  Check we are not trying to inline a parent whose body
853
                     --  depends on a child, when we are compiling the body of
854
                     --  the child. Otherwise we have a potential elaboration
855
                     --  circularity with inlined subprograms and with
856
                     --  Taft-Amendment types.
857
 
858
                     declare
859
                        Comp        : Node_Id;      --  Body just compiled
860
                        Child_Spec  : Entity_Id;    --  Spec of main unit
861
                        Ent         : Entity_Id;    --  For iteration
862
                        With_Clause : Node_Id;      --  Context of body.
863
 
864
                     begin
865
                        if Nkind (Unit (Cunit (Main_Unit))) = N_Package_Body
866
                          and then Present (Body_Entity (P))
867
                        then
868
                           Child_Spec :=
869
                             Defining_Entity
870
                               ((Unit (Library_Unit (Cunit (Main_Unit)))));
871
 
872
                           Comp :=
873
                             Parent (Unit_Declaration_Node (Body_Entity (P)));
874
 
875
                           --  Check whether the context of the body just
876
                           --  compiled includes a child of itself, and that
877
                           --  child is the spec of the main compilation.
878
 
879
                           With_Clause := First (Context_Items (Comp));
880
                           while Present (With_Clause) loop
881
                              if Nkind (With_Clause) = N_With_Clause
882
                                and then
883
                                  Scope (Entity (Name (With_Clause))) = P
884
                                and then
885
                                  Entity (Name (With_Clause)) = Child_Spec
886
                              then
887
                                 Error_Msg_Node_2 := Child_Spec;
888
                                 Error_Msg_NE
889
                                   ("body of & depends on child unit&?",
890
                                      With_Clause, P);
891
                                 Error_Msg_N
892
                                   ("\subprograms in body cannot be inlined?",
893
                                      With_Clause);
894
 
895
                                 --  Disable further inlining from this unit,
896
                                 --  and keep Taft-amendment types incomplete.
897
 
898
                                 Ent := First_Entity (P);
899
                                 while Present (Ent) loop
900
                                    if Is_Type (Ent)
901
                                       and then Has_Completion_In_Body (Ent)
902
                                    then
903
                                       Set_Full_View (Ent, Empty);
904
 
905
                                    elsif Is_Subprogram (Ent) then
906
                                       Set_Is_Inlined (Ent, False);
907
                                    end if;
908
 
909
                                    Next_Entity (Ent);
910
                                 end loop;
911
 
912
                                 return;
913
                              end if;
914
 
915
                              Next (With_Clause);
916
                           end loop;
917
                        end if;
918
                     end;
919
 
920
                  elsif Ineffective_Inline_Warnings then
921
                     Error_Msg_Unit_1 := Bname;
922
                     Error_Msg_N
923
                       ("unable to inline subprograms defined in $?", P);
924
                     Error_Msg_N ("\body not found?", P);
925
                     return;
926
                  end if;
927
               end if;
928
 
929
               return;
930
            end if;
931
 
932
            Next_Entity (E);
933
         end loop;
934
      end if;
935
   end Check_Body_For_Inlining;
936
 
937
   --------------------
938
   -- Cleanup_Scopes --
939
   --------------------
940
 
941
   procedure Cleanup_Scopes is
942
      Elmt : Elmt_Id;
943
      Decl : Node_Id;
944
      Scop : Entity_Id;
945
 
946
   begin
947
      Elmt := First_Elmt (To_Clean);
948
      while Present (Elmt) loop
949
         Scop := Node (Elmt);
950
 
951
         if Ekind (Scop) = E_Entry then
952
            Scop := Protected_Body_Subprogram (Scop);
953
 
954
         elsif Is_Subprogram (Scop)
955
           and then Is_Protected_Type (Scope (Scop))
956
           and then Present (Protected_Body_Subprogram (Scop))
957
         then
958
            --  If a protected operation contains an instance, its
959
            --  cleanup operations have been delayed, and the subprogram
960
            --  has been rewritten in the expansion of the enclosing
961
            --  protected body. It is the corresponding subprogram that
962
            --  may require the cleanup operations, so propagate the
963
            --  information that triggers cleanup activity.
964
 
965
            Set_Uses_Sec_Stack
966
              (Protected_Body_Subprogram (Scop),
967
                Uses_Sec_Stack (Scop));
968
 
969
            Scop := Protected_Body_Subprogram (Scop);
970
         end if;
971
 
972
         if Ekind (Scop) = E_Block then
973
            Decl := Parent (Block_Node (Scop));
974
 
975
         else
976
            Decl := Unit_Declaration_Node (Scop);
977
 
978
            if Nkind (Decl) = N_Subprogram_Declaration
979
              or else Nkind (Decl) = N_Task_Type_Declaration
980
              or else Nkind (Decl) = N_Subprogram_Body_Stub
981
            then
982
               Decl := Unit_Declaration_Node (Corresponding_Body (Decl));
983
            end if;
984
         end if;
985
 
986
         Push_Scope (Scop);
987
         Expand_Cleanup_Actions (Decl);
988
         End_Scope;
989
 
990
         Elmt := Next_Elmt (Elmt);
991
      end loop;
992
   end Cleanup_Scopes;
993
 
994
   --------------------------
995
   -- Get_Code_Unit_Entity --
996
   --------------------------
997
 
998
   function Get_Code_Unit_Entity (E : Entity_Id) return Entity_Id is
999
   begin
1000
      return Cunit_Entity (Get_Code_Unit (E));
1001
   end Get_Code_Unit_Entity;
1002
 
1003
   --------------------------
1004
   -- Has_Initialized_Type --
1005
   --------------------------
1006
 
1007
   function Has_Initialized_Type (E : Entity_Id) return Boolean is
1008
      E_Body : constant Node_Id := Get_Subprogram_Body (E);
1009
      Decl   : Node_Id;
1010
 
1011
   begin
1012
      if No (E_Body) then        --  imported subprogram
1013
         return False;
1014
 
1015
      else
1016
         Decl := First (Declarations (E_Body));
1017
         while Present (Decl) loop
1018
 
1019
            if Nkind (Decl) = N_Full_Type_Declaration
1020
              and then Present (Init_Proc (Defining_Identifier (Decl)))
1021
            then
1022
               return True;
1023
            end if;
1024
 
1025
            Next (Decl);
1026
         end loop;
1027
      end if;
1028
 
1029
      return False;
1030
   end Has_Initialized_Type;
1031
 
1032
   ----------------
1033
   -- Initialize --
1034
   ----------------
1035
 
1036
   procedure Initialize is
1037
   begin
1038
      Analyzing_Inlined_Bodies := False;
1039
      Pending_Descriptor.Init;
1040
      Pending_Instantiations.Init;
1041
      Inlined_Bodies.Init;
1042
      Successors.Init;
1043
      Inlined.Init;
1044
 
1045
      for J in Hash_Headers'Range loop
1046
         Hash_Headers (J) := No_Subp;
1047
      end loop;
1048
   end Initialize;
1049
 
1050
   ------------------------
1051
   -- Instantiate_Bodies --
1052
   ------------------------
1053
 
1054
   --  Generic bodies contain all the non-local references, so an
1055
   --  instantiation does not need any more context than Standard
1056
   --  itself, even if the instantiation appears in an inner scope.
1057
   --  Generic associations have verified that the contract model is
1058
   --  satisfied, so that any error that may occur in the analysis of
1059
   --  the body is an internal error.
1060
 
1061
   procedure Instantiate_Bodies is
1062
      J    : Int;
1063
      Info : Pending_Body_Info;
1064
 
1065
   begin
1066
      if Serious_Errors_Detected = 0 then
1067
 
1068
         Expander_Active := (Operating_Mode = Opt.Generate_Code);
1069
         Push_Scope (Standard_Standard);
1070
         To_Clean := New_Elmt_List;
1071
 
1072
         if Is_Generic_Unit (Cunit_Entity (Main_Unit)) then
1073
            Start_Generic;
1074
         end if;
1075
 
1076
         --  A body instantiation may generate additional instantiations, so
1077
         --  the following loop must scan to the end of a possibly expanding
1078
         --  set (that's why we can't simply use a FOR loop here).
1079
 
1080
         J := 0;
1081
         while J <= Pending_Instantiations.Last
1082
           and then Serious_Errors_Detected = 0
1083
         loop
1084
            Info := Pending_Instantiations.Table (J);
1085
 
1086
            --  If the instantiation node is absent, it has been removed
1087
            --  as part of unreachable code.
1088
 
1089
            if No (Info.Inst_Node) then
1090
               null;
1091
 
1092
            elsif Nkind (Info.Act_Decl) = N_Package_Declaration then
1093
               Instantiate_Package_Body (Info);
1094
               Add_Scope_To_Clean (Defining_Entity (Info.Act_Decl));
1095
 
1096
            else
1097
               Instantiate_Subprogram_Body (Info);
1098
            end if;
1099
 
1100
            J := J + 1;
1101
         end loop;
1102
 
1103
         --  Reset the table of instantiations. Additional instantiations
1104
         --  may be added through inlining, when additional bodies are
1105
         --  analyzed.
1106
 
1107
         Pending_Instantiations.Init;
1108
 
1109
         --  We can now complete the cleanup actions of scopes that contain
1110
         --  pending instantiations (skipped for generic units, since we
1111
         --  never need any cleanups in generic units).
1112
         --  pending instantiations.
1113
 
1114
         if Expander_Active
1115
           and then not Is_Generic_Unit (Main_Unit_Entity)
1116
         then
1117
            Cleanup_Scopes;
1118
         elsif Is_Generic_Unit (Cunit_Entity (Main_Unit)) then
1119
            End_Generic;
1120
         end if;
1121
 
1122
         Pop_Scope;
1123
      end if;
1124
   end Instantiate_Bodies;
1125
 
1126
   ---------------
1127
   -- Is_Nested --
1128
   ---------------
1129
 
1130
   function Is_Nested (E : Entity_Id) return Boolean is
1131
      Scop : Entity_Id;
1132
 
1133
   begin
1134
      Scop := Scope (E);
1135
      while Scop /= Standard_Standard loop
1136
         if Ekind (Scop) in Subprogram_Kind then
1137
            return True;
1138
 
1139
         elsif Ekind (Scop) = E_Task_Type
1140
           or else Ekind (Scop) = E_Entry
1141
           or else Ekind (Scop) = E_Entry_Family then
1142
            return True;
1143
         end if;
1144
 
1145
         Scop := Scope (Scop);
1146
      end loop;
1147
 
1148
      return False;
1149
   end Is_Nested;
1150
 
1151
   ----------
1152
   -- Lock --
1153
   ----------
1154
 
1155
   procedure Lock is
1156
   begin
1157
      Pending_Instantiations.Locked := True;
1158
      Inlined_Bodies.Locked := True;
1159
      Successors.Locked := True;
1160
      Inlined.Locked := True;
1161
      Pending_Instantiations.Release;
1162
      Inlined_Bodies.Release;
1163
      Successors.Release;
1164
      Inlined.Release;
1165
   end Lock;
1166
 
1167
   --------------------------
1168
   -- Remove_Dead_Instance --
1169
   --------------------------
1170
 
1171
   procedure Remove_Dead_Instance (N : Node_Id) is
1172
      J : Int;
1173
 
1174
   begin
1175
      J := 0;
1176
      while J <= Pending_Instantiations.Last loop
1177
         if Pending_Instantiations.Table (J).Inst_Node = N then
1178
            Pending_Instantiations.Table (J).Inst_Node := Empty;
1179
            return;
1180
         end if;
1181
 
1182
         J := J + 1;
1183
      end loop;
1184
   end Remove_Dead_Instance;
1185
 
1186
   ------------------------
1187
   -- Scope_In_Main_Unit --
1188
   ------------------------
1189
 
1190
   function Scope_In_Main_Unit (Scop : Entity_Id) return Boolean is
1191
      Comp : constant Node_Id := Cunit (Get_Code_Unit (Scop));
1192
 
1193
   begin
1194
      --  Check whether the scope of the subprogram to inline is within the
1195
      --  main unit or within its spec. In either case there are no additional
1196
      --  bodies to process. If the subprogram appears in a parent of the
1197
      --  current unit, the check on whether inlining is possible is done in
1198
      --  Analyze_Inlined_Bodies.
1199
 
1200
      return
1201
        Comp = Cunit (Main_Unit)
1202
          or else Comp = Library_Unit (Cunit (Main_Unit));
1203
   end Scope_In_Main_Unit;
1204
 
1205
end Inline;

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