* loop-invariant.c (invariant_for_use, check_dependencies): Fail for
[official-gcc.git] / gcc / ada / sem.adb
blob8c73ae952421dec85671f7c935b06ca5966549b6
1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- S E M --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 1992-2005, 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 2, 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 COPYING. If not, write --
19 -- to the Free Software Foundation, 51 Franklin Street, Fifth Floor, --
20 -- Boston, MA 02110-1301, USA. --
21 -- --
22 -- GNAT was originally developed by the GNAT team at New York University. --
23 -- Extensive contributions were provided by Ada Core Technologies Inc. --
24 -- --
25 ------------------------------------------------------------------------------
27 with Atree; use Atree;
28 with Debug; use Debug;
29 with Debug_A; use Debug_A;
30 with Errout; use Errout;
31 with Expander; use Expander;
32 with Fname; use Fname;
33 with HLO; use HLO;
34 with Lib; use Lib;
35 with Lib.Load; use Lib.Load;
36 with Nlists; use Nlists;
37 with Sem_Attr; use Sem_Attr;
38 with Sem_Ch2; use Sem_Ch2;
39 with Sem_Ch3; use Sem_Ch3;
40 with Sem_Ch4; use Sem_Ch4;
41 with Sem_Ch5; use Sem_Ch5;
42 with Sem_Ch6; use Sem_Ch6;
43 with Sem_Ch7; use Sem_Ch7;
44 with Sem_Ch8; use Sem_Ch8;
45 with Sem_Ch9; use Sem_Ch9;
46 with Sem_Ch10; use Sem_Ch10;
47 with Sem_Ch11; use Sem_Ch11;
48 with Sem_Ch12; use Sem_Ch12;
49 with Sem_Ch13; use Sem_Ch13;
50 with Sem_Prag; use Sem_Prag;
51 with Sem_Util; use Sem_Util;
52 with Sinfo; use Sinfo;
53 with Stand; use Stand;
54 with Uintp; use Uintp;
56 pragma Warnings (Off, Sem_Util);
57 -- Suppress warnings of unused with for Sem_Util (used only in asserts)
59 package body Sem is
61 Outer_Generic_Scope : Entity_Id := Empty;
62 -- Global reference to the outer scope that is generic. In a non
63 -- generic context, it is empty. At the moment, it is only used
64 -- for avoiding freezing of external references in generics.
66 -------------
67 -- Analyze --
68 -------------
70 procedure Analyze (N : Node_Id) is
71 begin
72 Debug_A_Entry ("analyzing ", N);
74 -- Immediate return if already analyzed
76 if Analyzed (N) then
77 Debug_A_Exit ("analyzing ", N, " (done, analyzed already)");
78 return;
79 end if;
81 -- Otherwise processing depends on the node kind
83 case Nkind (N) is
85 when N_Abort_Statement =>
86 Analyze_Abort_Statement (N);
88 when N_Abstract_Subprogram_Declaration =>
89 Analyze_Abstract_Subprogram_Declaration (N);
91 when N_Accept_Alternative =>
92 Analyze_Accept_Alternative (N);
94 when N_Accept_Statement =>
95 Analyze_Accept_Statement (N);
97 when N_Aggregate =>
98 Analyze_Aggregate (N);
100 when N_Allocator =>
101 Analyze_Allocator (N);
103 when N_And_Then =>
104 Analyze_Short_Circuit (N);
106 when N_Assignment_Statement =>
107 Analyze_Assignment (N);
109 when N_Asynchronous_Select =>
110 Analyze_Asynchronous_Select (N);
112 when N_At_Clause =>
113 Analyze_At_Clause (N);
115 when N_Attribute_Reference =>
116 Analyze_Attribute (N);
118 when N_Attribute_Definition_Clause =>
119 Analyze_Attribute_Definition_Clause (N);
121 when N_Block_Statement =>
122 Analyze_Block_Statement (N);
124 when N_Case_Statement =>
125 Analyze_Case_Statement (N);
127 when N_Character_Literal =>
128 Analyze_Character_Literal (N);
130 when N_Code_Statement =>
131 Analyze_Code_Statement (N);
133 when N_Compilation_Unit =>
134 Analyze_Compilation_Unit (N);
136 when N_Component_Declaration =>
137 Analyze_Component_Declaration (N);
139 when N_Conditional_Expression =>
140 Analyze_Conditional_Expression (N);
142 when N_Conditional_Entry_Call =>
143 Analyze_Conditional_Entry_Call (N);
145 when N_Delay_Alternative =>
146 Analyze_Delay_Alternative (N);
148 when N_Delay_Relative_Statement =>
149 Analyze_Delay_Relative (N);
151 when N_Delay_Until_Statement =>
152 Analyze_Delay_Until (N);
154 when N_Entry_Body =>
155 Analyze_Entry_Body (N);
157 when N_Entry_Body_Formal_Part =>
158 Analyze_Entry_Body_Formal_Part (N);
160 when N_Entry_Call_Alternative =>
161 Analyze_Entry_Call_Alternative (N);
163 when N_Entry_Declaration =>
164 Analyze_Entry_Declaration (N);
166 when N_Entry_Index_Specification =>
167 Analyze_Entry_Index_Specification (N);
169 when N_Enumeration_Representation_Clause =>
170 Analyze_Enumeration_Representation_Clause (N);
172 when N_Exception_Declaration =>
173 Analyze_Exception_Declaration (N);
175 when N_Exception_Renaming_Declaration =>
176 Analyze_Exception_Renaming (N);
178 when N_Exit_Statement =>
179 Analyze_Exit_Statement (N);
181 when N_Expanded_Name =>
182 Analyze_Expanded_Name (N);
184 when N_Explicit_Dereference =>
185 Analyze_Explicit_Dereference (N);
187 when N_Extension_Aggregate =>
188 Analyze_Aggregate (N);
190 when N_Formal_Object_Declaration =>
191 Analyze_Formal_Object_Declaration (N);
193 when N_Formal_Package_Declaration =>
194 Analyze_Formal_Package (N);
196 when N_Formal_Subprogram_Declaration =>
197 Analyze_Formal_Subprogram (N);
199 when N_Formal_Type_Declaration =>
200 Analyze_Formal_Type_Declaration (N);
202 when N_Free_Statement =>
203 Analyze_Free_Statement (N);
205 when N_Freeze_Entity =>
206 null; -- no semantic processing required
208 when N_Full_Type_Declaration =>
209 Analyze_Type_Declaration (N);
211 when N_Function_Call =>
212 Analyze_Function_Call (N);
214 when N_Function_Instantiation =>
215 Analyze_Function_Instantiation (N);
217 when N_Generic_Function_Renaming_Declaration =>
218 Analyze_Generic_Function_Renaming (N);
220 when N_Generic_Package_Declaration =>
221 Analyze_Generic_Package_Declaration (N);
223 when N_Generic_Package_Renaming_Declaration =>
224 Analyze_Generic_Package_Renaming (N);
226 when N_Generic_Procedure_Renaming_Declaration =>
227 Analyze_Generic_Procedure_Renaming (N);
229 when N_Generic_Subprogram_Declaration =>
230 Analyze_Generic_Subprogram_Declaration (N);
232 when N_Goto_Statement =>
233 Analyze_Goto_Statement (N);
235 when N_Handled_Sequence_Of_Statements =>
236 Analyze_Handled_Statements (N);
238 when N_Identifier =>
239 Analyze_Identifier (N);
241 when N_If_Statement =>
242 Analyze_If_Statement (N);
244 when N_Implicit_Label_Declaration =>
245 Analyze_Implicit_Label_Declaration (N);
247 when N_In =>
248 Analyze_Membership_Op (N);
250 when N_Incomplete_Type_Declaration =>
251 Analyze_Incomplete_Type_Decl (N);
253 when N_Indexed_Component =>
254 Analyze_Indexed_Component_Form (N);
256 when N_Integer_Literal =>
257 Analyze_Integer_Literal (N);
259 when N_Itype_Reference =>
260 Analyze_Itype_Reference (N);
262 when N_Label =>
263 Analyze_Label (N);
265 when N_Loop_Statement =>
266 Analyze_Loop_Statement (N);
268 when N_Not_In =>
269 Analyze_Membership_Op (N);
271 when N_Null =>
272 Analyze_Null (N);
274 when N_Null_Statement =>
275 Analyze_Null_Statement (N);
277 when N_Number_Declaration =>
278 Analyze_Number_Declaration (N);
280 when N_Object_Declaration =>
281 Analyze_Object_Declaration (N);
283 when N_Object_Renaming_Declaration =>
284 Analyze_Object_Renaming (N);
286 when N_Operator_Symbol =>
287 Analyze_Operator_Symbol (N);
289 when N_Op_Abs =>
290 Analyze_Unary_Op (N);
292 when N_Op_Add =>
293 Analyze_Arithmetic_Op (N);
295 when N_Op_And =>
296 Analyze_Logical_Op (N);
298 when N_Op_Concat =>
299 Analyze_Concatenation (N);
301 when N_Op_Divide =>
302 Analyze_Arithmetic_Op (N);
304 when N_Op_Eq =>
305 Analyze_Equality_Op (N);
307 when N_Op_Expon =>
308 Analyze_Arithmetic_Op (N);
310 when N_Op_Ge =>
311 Analyze_Comparison_Op (N);
313 when N_Op_Gt =>
314 Analyze_Comparison_Op (N);
316 when N_Op_Le =>
317 Analyze_Comparison_Op (N);
319 when N_Op_Lt =>
320 Analyze_Comparison_Op (N);
322 when N_Op_Minus =>
323 Analyze_Unary_Op (N);
325 when N_Op_Mod =>
326 Analyze_Arithmetic_Op (N);
328 when N_Op_Multiply =>
329 Analyze_Arithmetic_Op (N);
331 when N_Op_Ne =>
332 Analyze_Equality_Op (N);
334 when N_Op_Not =>
335 Analyze_Negation (N);
337 when N_Op_Or =>
338 Analyze_Logical_Op (N);
340 when N_Op_Plus =>
341 Analyze_Unary_Op (N);
343 when N_Op_Rem =>
344 Analyze_Arithmetic_Op (N);
346 when N_Op_Rotate_Left =>
347 Analyze_Arithmetic_Op (N);
349 when N_Op_Rotate_Right =>
350 Analyze_Arithmetic_Op (N);
352 when N_Op_Shift_Left =>
353 Analyze_Arithmetic_Op (N);
355 when N_Op_Shift_Right =>
356 Analyze_Arithmetic_Op (N);
358 when N_Op_Shift_Right_Arithmetic =>
359 Analyze_Arithmetic_Op (N);
361 when N_Op_Subtract =>
362 Analyze_Arithmetic_Op (N);
364 when N_Op_Xor =>
365 Analyze_Logical_Op (N);
367 when N_Or_Else =>
368 Analyze_Short_Circuit (N);
370 when N_Others_Choice =>
371 Analyze_Others_Choice (N);
373 when N_Package_Body =>
374 Analyze_Package_Body (N);
376 when N_Package_Body_Stub =>
377 Analyze_Package_Body_Stub (N);
379 when N_Package_Declaration =>
380 Analyze_Package_Declaration (N);
382 when N_Package_Instantiation =>
383 Analyze_Package_Instantiation (N);
385 when N_Package_Renaming_Declaration =>
386 Analyze_Package_Renaming (N);
388 when N_Package_Specification =>
389 Analyze_Package_Specification (N);
391 when N_Parameter_Association =>
392 Analyze_Parameter_Association (N);
394 when N_Pragma =>
395 Analyze_Pragma (N);
397 when N_Private_Extension_Declaration =>
398 Analyze_Private_Extension_Declaration (N);
400 when N_Private_Type_Declaration =>
401 Analyze_Private_Type_Declaration (N);
403 when N_Procedure_Call_Statement =>
404 Analyze_Procedure_Call (N);
406 when N_Procedure_Instantiation =>
407 Analyze_Procedure_Instantiation (N);
409 when N_Protected_Body =>
410 Analyze_Protected_Body (N);
412 when N_Protected_Body_Stub =>
413 Analyze_Protected_Body_Stub (N);
415 when N_Protected_Definition =>
416 Analyze_Protected_Definition (N);
418 when N_Protected_Type_Declaration =>
419 Analyze_Protected_Type (N);
421 when N_Qualified_Expression =>
422 Analyze_Qualified_Expression (N);
424 when N_Raise_Statement =>
425 Analyze_Raise_Statement (N);
427 when N_Raise_xxx_Error =>
428 Analyze_Raise_xxx_Error (N);
430 when N_Range =>
431 Analyze_Range (N);
433 when N_Range_Constraint =>
434 Analyze_Range (Range_Expression (N));
436 when N_Real_Literal =>
437 Analyze_Real_Literal (N);
439 when N_Record_Representation_Clause =>
440 Analyze_Record_Representation_Clause (N);
442 when N_Reference =>
443 Analyze_Reference (N);
445 when N_Requeue_Statement =>
446 Analyze_Requeue (N);
448 when N_Return_Statement =>
449 Analyze_Return_Statement (N);
451 when N_Selected_Component =>
452 Find_Selected_Component (N);
453 -- ??? why not Analyze_Selected_Component, needs comments
455 when N_Selective_Accept =>
456 Analyze_Selective_Accept (N);
458 when N_Single_Protected_Declaration =>
459 Analyze_Single_Protected (N);
461 when N_Single_Task_Declaration =>
462 Analyze_Single_Task (N);
464 when N_Slice =>
465 Analyze_Slice (N);
467 when N_String_Literal =>
468 Analyze_String_Literal (N);
470 when N_Subprogram_Body =>
471 Analyze_Subprogram_Body (N);
473 when N_Subprogram_Body_Stub =>
474 Analyze_Subprogram_Body_Stub (N);
476 when N_Subprogram_Declaration =>
477 Analyze_Subprogram_Declaration (N);
479 when N_Subprogram_Info =>
480 Analyze_Subprogram_Info (N);
482 when N_Subprogram_Renaming_Declaration =>
483 Analyze_Subprogram_Renaming (N);
485 when N_Subtype_Declaration =>
486 Analyze_Subtype_Declaration (N);
488 when N_Subtype_Indication =>
489 Analyze_Subtype_Indication (N);
491 when N_Subunit =>
492 Analyze_Subunit (N);
494 when N_Task_Body =>
495 Analyze_Task_Body (N);
497 when N_Task_Body_Stub =>
498 Analyze_Task_Body_Stub (N);
500 when N_Task_Definition =>
501 Analyze_Task_Definition (N);
503 when N_Task_Type_Declaration =>
504 Analyze_Task_Type (N);
506 when N_Terminate_Alternative =>
507 Analyze_Terminate_Alternative (N);
509 when N_Timed_Entry_Call =>
510 Analyze_Timed_Entry_Call (N);
512 when N_Triggering_Alternative =>
513 Analyze_Triggering_Alternative (N);
515 when N_Type_Conversion =>
516 Analyze_Type_Conversion (N);
518 when N_Unchecked_Expression =>
519 Analyze_Unchecked_Expression (N);
521 when N_Unchecked_Type_Conversion =>
522 Analyze_Unchecked_Type_Conversion (N);
524 when N_Use_Package_Clause =>
525 Analyze_Use_Package (N);
527 when N_Use_Type_Clause =>
528 Analyze_Use_Type (N);
530 when N_Validate_Unchecked_Conversion =>
531 null;
533 when N_Variant_Part =>
534 Analyze_Variant_Part (N);
536 when N_With_Clause =>
537 Analyze_With_Clause (N);
539 when N_With_Type_Clause =>
540 Analyze_With_Type_Clause (N);
542 -- A call to analyze the Empty node is an error, but most likely
543 -- it is an error caused by an attempt to analyze a malformed
544 -- piece of tree caused by some other error, so if there have
545 -- been any other errors, we just ignore it, otherwise it is
546 -- a real internal error which we complain about.
548 when N_Empty =>
549 pragma Assert (Serious_Errors_Detected /= 0);
550 null;
552 -- A call to analyze the error node is simply ignored, to avoid
553 -- causing cascaded errors (happens of course only in error cases)
555 when N_Error =>
556 null;
558 -- For the remaining node types, we generate compiler abort, because
559 -- these nodes are always analyzed within the Sem_Chn routines and
560 -- there should never be a case of making a call to the main Analyze
561 -- routine for these node kinds. For example, an N_Access_Definition
562 -- node appears only in the context of a type declaration, and is
563 -- processed by the analyze routine for type declarations.
565 when
566 N_Abortable_Part |
567 N_Access_Definition |
568 N_Access_Function_Definition |
569 N_Access_Procedure_Definition |
570 N_Access_To_Object_Definition |
571 N_Case_Statement_Alternative |
572 N_Compilation_Unit_Aux |
573 N_Component_Association |
574 N_Component_Clause |
575 N_Component_Definition |
576 N_Component_List |
577 N_Constrained_Array_Definition |
578 N_Decimal_Fixed_Point_Definition |
579 N_Defining_Character_Literal |
580 N_Defining_Identifier |
581 N_Defining_Operator_Symbol |
582 N_Defining_Program_Unit_Name |
583 N_Delta_Constraint |
584 N_Derived_Type_Definition |
585 N_Designator |
586 N_Digits_Constraint |
587 N_Discriminant_Association |
588 N_Discriminant_Specification |
589 N_Elsif_Part |
590 N_Entry_Call_Statement |
591 N_Enumeration_Type_Definition |
592 N_Exception_Handler |
593 N_Floating_Point_Definition |
594 N_Formal_Decimal_Fixed_Point_Definition |
595 N_Formal_Derived_Type_Definition |
596 N_Formal_Discrete_Type_Definition |
597 N_Formal_Floating_Point_Definition |
598 N_Formal_Modular_Type_Definition |
599 N_Formal_Ordinary_Fixed_Point_Definition |
600 N_Formal_Private_Type_Definition |
601 N_Formal_Signed_Integer_Type_Definition |
602 N_Function_Specification |
603 N_Generic_Association |
604 N_Index_Or_Discriminant_Constraint |
605 N_Iteration_Scheme |
606 N_Loop_Parameter_Specification |
607 N_Mod_Clause |
608 N_Modular_Type_Definition |
609 N_Ordinary_Fixed_Point_Definition |
610 N_Parameter_Specification |
611 N_Pragma_Argument_Association |
612 N_Procedure_Specification |
613 N_Real_Range_Specification |
614 N_Record_Definition |
615 N_Signed_Integer_Type_Definition |
616 N_Unconstrained_Array_Definition |
617 N_Unused_At_Start |
618 N_Unused_At_End |
619 N_Variant =>
621 raise Program_Error;
622 end case;
624 Debug_A_Exit ("analyzing ", N, " (done)");
626 -- Now that we have analyzed the node, we call the expander to
627 -- perform possible expansion. This is done only for nodes that
628 -- are not subexpressions, because in the case of subexpressions,
629 -- we don't have the type yet, and the expander will need to know
630 -- the type before it can do its job. For subexpression nodes, the
631 -- call to the expander happens in the Sem_Res.Resolve.
633 -- The Analyzed flag is also set at this point for non-subexpression
634 -- nodes (in the case of subexpression nodes, we can't set the flag
635 -- yet, since resolution and expansion have not yet been completed)
637 if Nkind (N) not in N_Subexpr then
638 Expand (N);
639 end if;
640 end Analyze;
642 -- Version with check(s) suppressed
644 procedure Analyze (N : Node_Id; Suppress : Check_Id) is
645 begin
646 if Suppress = All_Checks then
647 declare
648 Svg : constant Suppress_Array := Scope_Suppress;
649 begin
650 Scope_Suppress := (others => True);
651 Analyze (N);
652 Scope_Suppress := Svg;
653 end;
655 else
656 declare
657 Svg : constant Boolean := Scope_Suppress (Suppress);
658 begin
659 Scope_Suppress (Suppress) := True;
660 Analyze (N);
661 Scope_Suppress (Suppress) := Svg;
662 end;
663 end if;
664 end Analyze;
666 ------------------
667 -- Analyze_List --
668 ------------------
670 procedure Analyze_List (L : List_Id) is
671 Node : Node_Id;
673 begin
674 Node := First (L);
675 while Present (Node) loop
676 Analyze (Node);
677 Next (Node);
678 end loop;
679 end Analyze_List;
681 -- Version with check(s) suppressed
683 procedure Analyze_List (L : List_Id; Suppress : Check_Id) is
684 begin
685 if Suppress = All_Checks then
686 declare
687 Svg : constant Suppress_Array := Scope_Suppress;
688 begin
689 Scope_Suppress := (others => True);
690 Analyze_List (L);
691 Scope_Suppress := Svg;
692 end;
694 else
695 declare
696 Svg : constant Boolean := Scope_Suppress (Suppress);
697 begin
698 Scope_Suppress (Suppress) := True;
699 Analyze_List (L);
700 Scope_Suppress (Suppress) := Svg;
701 end;
702 end if;
703 end Analyze_List;
705 --------------------------
706 -- Copy_Suppress_Status --
707 --------------------------
709 procedure Copy_Suppress_Status
710 (C : Check_Id;
711 From : Entity_Id;
712 To : Entity_Id)
714 begin
715 if not Checks_May_Be_Suppressed (From) then
716 return;
717 end if;
719 -- First search the local entity suppress table, we search this in
720 -- reverse order so that we get the innermost entry that applies to
721 -- this case if there are nested entries. Note that for the purpose
722 -- of this procedure we are ONLY looking for entries corresponding
723 -- to a two-argument Suppress, where the second argument matches From.
725 for J in
726 reverse Local_Entity_Suppress.First .. Local_Entity_Suppress.Last
727 loop
728 declare
729 R : Entity_Check_Suppress_Record
730 renames Local_Entity_Suppress.Table (J);
732 begin
733 if R.Entity = From
734 and then (R.Check = All_Checks or else R.Check = C)
735 then
736 if R.Suppress then
737 Set_Checks_May_Be_Suppressed (To, True);
738 Local_Entity_Suppress.Append
739 ((Entity => To,
740 Check => C,
741 Suppress => True));
742 return;
743 end if;
744 end if;
745 end;
746 end loop;
748 -- Now search the global entity suppress table for a matching entry
749 -- We also search this in reverse order so that if there are multiple
750 -- pragmas for the same entity, the last one applies.
752 for J in
753 reverse Global_Entity_Suppress.First .. Global_Entity_Suppress.Last
754 loop
755 declare
756 R : Entity_Check_Suppress_Record
757 renames Global_Entity_Suppress.Table (J);
759 begin
760 if R.Entity = From
761 and then (R.Check = All_Checks or else R.Check = C)
762 then
763 if R.Suppress then
764 Set_Checks_May_Be_Suppressed (To, True);
765 Local_Entity_Suppress.Append
766 ((Entity => To,
767 Check => C,
768 Suppress => True));
769 end if;
770 end if;
771 end;
772 end loop;
773 end Copy_Suppress_Status;
775 -------------------------
776 -- Enter_Generic_Scope --
777 -------------------------
779 procedure Enter_Generic_Scope (S : Entity_Id) is
780 begin
781 if No (Outer_Generic_Scope) then
782 Outer_Generic_Scope := S;
783 end if;
784 end Enter_Generic_Scope;
786 ------------------------
787 -- Exit_Generic_Scope --
788 ------------------------
790 procedure Exit_Generic_Scope (S : Entity_Id) is
791 begin
792 if S = Outer_Generic_Scope then
793 Outer_Generic_Scope := Empty;
794 end if;
795 end Exit_Generic_Scope;
797 -----------------------
798 -- Explicit_Suppress --
799 -----------------------
801 function Explicit_Suppress (E : Entity_Id; C : Check_Id) return Boolean is
802 begin
803 if not Checks_May_Be_Suppressed (E) then
804 return False;
806 else
807 for J in
808 reverse Global_Entity_Suppress.First .. Global_Entity_Suppress.Last
809 loop
810 declare
811 R : Entity_Check_Suppress_Record
812 renames Global_Entity_Suppress.Table (J);
814 begin
815 if R.Entity = E
816 and then (R.Check = All_Checks or else R.Check = C)
817 then
818 return R.Suppress;
819 end if;
820 end;
821 end loop;
823 return False;
824 end if;
825 end Explicit_Suppress;
827 -----------------------------
828 -- External_Ref_In_Generic --
829 -----------------------------
831 function External_Ref_In_Generic (E : Entity_Id) return Boolean is
832 Scop : Entity_Id;
834 begin
835 -- Entity is global if defined outside of current outer_generic_scope:
836 -- Either the entity has a smaller depth that the outer generic, or it
837 -- is in a different compilation unit, or it is defined within a unit
838 -- in the same compilation, that is not within the outer_generic.
840 if No (Outer_Generic_Scope) then
841 return False;
843 elsif Scope_Depth (Scope (E)) < Scope_Depth (Outer_Generic_Scope)
844 or else not In_Same_Source_Unit (E, Outer_Generic_Scope)
845 then
846 return True;
848 else
849 Scop := Scope (E);
851 while Present (Scop) loop
852 if Scop = Outer_Generic_Scope then
853 return False;
854 elsif Scope_Depth (Scop) < Scope_Depth (Outer_Generic_Scope) then
855 return True;
856 else
857 Scop := Scope (Scop);
858 end if;
859 end loop;
861 return True;
862 end if;
863 end External_Ref_In_Generic;
865 ----------------
866 -- Initialize --
867 ----------------
869 procedure Initialize is
870 begin
871 Local_Entity_Suppress.Init;
872 Global_Entity_Suppress.Init;
873 Scope_Stack.Init;
874 Unloaded_Subunits := False;
875 end Initialize;
877 ------------------------------
878 -- Insert_After_And_Analyze --
879 ------------------------------
881 procedure Insert_After_And_Analyze (N : Node_Id; M : Node_Id) is
882 Node : Node_Id;
884 begin
885 if Present (M) then
887 -- If we are not at the end of the list, then the easiest
888 -- coding is simply to insert before our successor
890 if Present (Next (N)) then
891 Insert_Before_And_Analyze (Next (N), M);
893 -- Case of inserting at the end of the list
895 else
896 -- Capture the Node_Id of the node to be inserted. This Node_Id
897 -- will still be the same after the insert operation.
899 Node := M;
900 Insert_After (N, M);
902 -- Now just analyze from the inserted node to the end of
903 -- the new list (note that this properly handles the case
904 -- where any of the analyze calls result in the insertion of
905 -- nodes after the analyzed node, expecting analysis).
907 while Present (Node) loop
908 Analyze (Node);
909 Mark_Rewrite_Insertion (Node);
910 Next (Node);
911 end loop;
912 end if;
913 end if;
914 end Insert_After_And_Analyze;
916 -- Version with check(s) suppressed
918 procedure Insert_After_And_Analyze
919 (N : Node_Id;
920 M : Node_Id;
921 Suppress : Check_Id)
923 begin
924 if Suppress = All_Checks then
925 declare
926 Svg : constant Suppress_Array := Scope_Suppress;
927 begin
928 Scope_Suppress := (others => True);
929 Insert_After_And_Analyze (N, M);
930 Scope_Suppress := Svg;
931 end;
933 else
934 declare
935 Svg : constant Boolean := Scope_Suppress (Suppress);
936 begin
937 Scope_Suppress (Suppress) := True;
938 Insert_After_And_Analyze (N, M);
939 Scope_Suppress (Suppress) := Svg;
940 end;
941 end if;
942 end Insert_After_And_Analyze;
944 -------------------------------
945 -- Insert_Before_And_Analyze --
946 -------------------------------
948 procedure Insert_Before_And_Analyze (N : Node_Id; M : Node_Id) is
949 Node : Node_Id;
951 begin
952 if Present (M) then
954 -- Capture the Node_Id of the first list node to be inserted.
955 -- This will still be the first node after the insert operation,
956 -- since Insert_List_After does not modify the Node_Id values.
958 Node := M;
959 Insert_Before (N, M);
961 -- The insertion does not change the Id's of any of the nodes in
962 -- the list, and they are still linked, so we can simply loop from
963 -- the original first node until we meet the node before which the
964 -- insertion is occurring. Note that this properly handles the case
965 -- where any of the analyzed nodes insert nodes after themselves,
966 -- expecting them to get analyzed.
968 while Node /= N loop
969 Analyze (Node);
970 Mark_Rewrite_Insertion (Node);
971 Next (Node);
972 end loop;
973 end if;
974 end Insert_Before_And_Analyze;
976 -- Version with check(s) suppressed
978 procedure Insert_Before_And_Analyze
979 (N : Node_Id;
980 M : Node_Id;
981 Suppress : Check_Id)
983 begin
984 if Suppress = All_Checks then
985 declare
986 Svg : constant Suppress_Array := Scope_Suppress;
987 begin
988 Scope_Suppress := (others => True);
989 Insert_Before_And_Analyze (N, M);
990 Scope_Suppress := Svg;
991 end;
993 else
994 declare
995 Svg : constant Boolean := Scope_Suppress (Suppress);
996 begin
997 Scope_Suppress (Suppress) := True;
998 Insert_Before_And_Analyze (N, M);
999 Scope_Suppress (Suppress) := Svg;
1000 end;
1001 end if;
1002 end Insert_Before_And_Analyze;
1004 -----------------------------------
1005 -- Insert_List_After_And_Analyze --
1006 -----------------------------------
1008 procedure Insert_List_After_And_Analyze (N : Node_Id; L : List_Id) is
1009 After : constant Node_Id := Next (N);
1010 Node : Node_Id;
1012 begin
1013 if Is_Non_Empty_List (L) then
1015 -- Capture the Node_Id of the first list node to be inserted.
1016 -- This will still be the first node after the insert operation,
1017 -- since Insert_List_After does not modify the Node_Id values.
1019 Node := First (L);
1020 Insert_List_After (N, L);
1022 -- Now just analyze from the original first node until we get to
1023 -- the successor of the original insertion point (which may be
1024 -- Empty if the insertion point was at the end of the list). Note
1025 -- that this properly handles the case where any of the analyze
1026 -- calls result in the insertion of nodes after the analyzed
1027 -- node (possibly calling this routine recursively).
1029 while Node /= After loop
1030 Analyze (Node);
1031 Mark_Rewrite_Insertion (Node);
1032 Next (Node);
1033 end loop;
1034 end if;
1035 end Insert_List_After_And_Analyze;
1037 -- Version with check(s) suppressed
1039 procedure Insert_List_After_And_Analyze
1040 (N : Node_Id; L : List_Id; Suppress : Check_Id)
1042 begin
1043 if Suppress = All_Checks then
1044 declare
1045 Svg : constant Suppress_Array := Scope_Suppress;
1046 begin
1047 Scope_Suppress := (others => True);
1048 Insert_List_After_And_Analyze (N, L);
1049 Scope_Suppress := Svg;
1050 end;
1052 else
1053 declare
1054 Svg : constant Boolean := Scope_Suppress (Suppress);
1055 begin
1056 Scope_Suppress (Suppress) := True;
1057 Insert_List_After_And_Analyze (N, L);
1058 Scope_Suppress (Suppress) := Svg;
1059 end;
1060 end if;
1061 end Insert_List_After_And_Analyze;
1063 ------------------------------------
1064 -- Insert_List_Before_And_Analyze --
1065 ------------------------------------
1067 procedure Insert_List_Before_And_Analyze (N : Node_Id; L : List_Id) is
1068 Node : Node_Id;
1070 begin
1071 if Is_Non_Empty_List (L) then
1073 -- Capture the Node_Id of the first list node to be inserted.
1074 -- This will still be the first node after the insert operation,
1075 -- since Insert_List_After does not modify the Node_Id values.
1077 Node := First (L);
1078 Insert_List_Before (N, L);
1080 -- The insertion does not change the Id's of any of the nodes in
1081 -- the list, and they are still linked, so we can simply loop from
1082 -- the original first node until we meet the node before which the
1083 -- insertion is occurring. Note that this properly handles the case
1084 -- where any of the analyzed nodes insert nodes after themselves,
1085 -- expecting them to get analyzed.
1087 while Node /= N loop
1088 Analyze (Node);
1089 Mark_Rewrite_Insertion (Node);
1090 Next (Node);
1091 end loop;
1092 end if;
1093 end Insert_List_Before_And_Analyze;
1095 -- Version with check(s) suppressed
1097 procedure Insert_List_Before_And_Analyze
1098 (N : Node_Id; L : List_Id; Suppress : Check_Id)
1100 begin
1101 if Suppress = All_Checks then
1102 declare
1103 Svg : constant Suppress_Array := Scope_Suppress;
1104 begin
1105 Scope_Suppress := (others => True);
1106 Insert_List_Before_And_Analyze (N, L);
1107 Scope_Suppress := Svg;
1108 end;
1110 else
1111 declare
1112 Svg : constant Boolean := Scope_Suppress (Suppress);
1113 begin
1114 Scope_Suppress (Suppress) := True;
1115 Insert_List_Before_And_Analyze (N, L);
1116 Scope_Suppress (Suppress) := Svg;
1117 end;
1118 end if;
1119 end Insert_List_Before_And_Analyze;
1121 -------------------------
1122 -- Is_Check_Suppressed --
1123 -------------------------
1125 function Is_Check_Suppressed (E : Entity_Id; C : Check_Id) return Boolean is
1126 begin
1127 -- First search the local entity suppress table, we search this in
1128 -- reverse order so that we get the innermost entry that applies to
1129 -- this case if there are nested entries.
1131 for J in
1132 reverse Local_Entity_Suppress.First .. Local_Entity_Suppress.Last
1133 loop
1134 declare
1135 R : Entity_Check_Suppress_Record
1136 renames Local_Entity_Suppress.Table (J);
1138 begin
1139 if (R.Entity = Empty or else R.Entity = E)
1140 and then (R.Check = All_Checks or else R.Check = C)
1141 then
1142 return R.Suppress;
1143 end if;
1144 end;
1145 end loop;
1147 -- Now search the global entity suppress table for a matching entry
1148 -- We also search this in reverse order so that if there are multiple
1149 -- pragmas for the same entity, the last one applies (not clear what
1150 -- or whether the RM specifies this handling, but it seems reasonable).
1152 for J in
1153 reverse Global_Entity_Suppress.First .. Global_Entity_Suppress.Last
1154 loop
1155 declare
1156 R : Entity_Check_Suppress_Record
1157 renames Global_Entity_Suppress.Table (J);
1159 begin
1160 if R.Entity = E
1161 and then (R.Check = All_Checks or else R.Check = C)
1162 then
1163 return R.Suppress;
1164 end if;
1165 end;
1166 end loop;
1168 -- If we did not find a matching entry, then use the normal scope
1169 -- suppress value after all (actually this will be the global setting
1170 -- since it clearly was not overridden at any point)
1172 return Scope_Suppress (C);
1173 end Is_Check_Suppressed;
1175 ----------
1176 -- Lock --
1177 ----------
1179 procedure Lock is
1180 begin
1181 Local_Entity_Suppress.Locked := True;
1182 Global_Entity_Suppress.Locked := True;
1183 Scope_Stack.Locked := True;
1184 Local_Entity_Suppress.Release;
1185 Global_Entity_Suppress.Release;
1186 Scope_Stack.Release;
1187 end Lock;
1189 ---------------
1190 -- Semantics --
1191 ---------------
1193 procedure Semantics (Comp_Unit : Node_Id) is
1195 -- The following locations save the corresponding global flags and
1196 -- variables so that they can be restored on completion. This is
1197 -- needed so that calls to Rtsfind start with the proper default
1198 -- values for these variables, and also that such calls do not
1199 -- disturb the settings for units being analyzed at a higher level.
1201 S_Full_Analysis : constant Boolean := Full_Analysis;
1202 S_In_Default_Expr : constant Boolean := In_Default_Expression;
1203 S_Inside_A_Generic : constant Boolean := Inside_A_Generic;
1204 S_New_Nodes_OK : constant Int := New_Nodes_OK;
1205 S_Outer_Gen_Scope : constant Entity_Id := Outer_Generic_Scope;
1206 S_Sem_Unit : constant Unit_Number_Type := Current_Sem_Unit;
1207 S_GNAT_Mode : constant Boolean := GNAT_Mode;
1208 Generic_Main : constant Boolean :=
1209 Nkind (Unit (Cunit (Main_Unit)))
1210 in N_Generic_Declaration;
1212 -- If the main unit is generic, every compiled unit, including its
1213 -- context, is compiled with expansion disabled.
1215 Save_Config_Switches : Config_Switches_Type;
1216 -- Variable used to save values of config switches while we analyze
1217 -- the new unit, to be restored on exit for proper recursive behavior.
1219 procedure Do_Analyze;
1220 -- Procedure to analyze the compilation unit. This is called more
1221 -- than once when the high level optimizer is activated.
1223 ----------------
1224 -- Do_Analyze --
1225 ----------------
1227 procedure Do_Analyze is
1228 begin
1229 Save_Scope_Stack;
1230 New_Scope (Standard_Standard);
1231 Scope_Suppress := Suppress_Options;
1232 Scope_Stack.Table
1233 (Scope_Stack.Last).Component_Alignment_Default := Calign_Default;
1234 Scope_Stack.Table
1235 (Scope_Stack.Last).Is_Active_Stack_Base := True;
1236 Outer_Generic_Scope := Empty;
1238 -- Now analyze the top level compilation unit node
1240 Analyze (Comp_Unit);
1242 -- Check for scope mismatch on exit from compilation
1244 pragma Assert (Current_Scope = Standard_Standard
1245 or else Comp_Unit = Cunit (Main_Unit));
1247 -- Then pop entry for Standard, and pop implicit types
1249 Pop_Scope;
1250 Restore_Scope_Stack;
1251 end Do_Analyze;
1253 -- Start of processing for Semantics
1255 begin
1256 Compiler_State := Analyzing;
1257 Current_Sem_Unit := Get_Cunit_Unit_Number (Comp_Unit);
1259 -- Compile predefined units with GNAT_Mode set to True, to properly
1260 -- process the categorization stuff. However, do not set set GNAT_Mode
1261 -- to True for the renamings units (Text_IO, IO_Exceptions, Direct_IO,
1262 -- Sequential_IO) as this would prevent pragma System_Extend to be
1263 -- taken into account, for example when Text_IO is renaming DEC.Text_IO.
1265 -- Cleaner might be to do the kludge at the point of excluding the
1266 -- pragma (do not exclude for renamings ???)
1268 GNAT_Mode :=
1269 GNAT_Mode
1270 or else Is_Predefined_File_Name
1271 (Unit_File_Name (Current_Sem_Unit),
1272 Renamings_Included => False);
1274 if Generic_Main then
1275 Expander_Mode_Save_And_Set (False);
1276 else
1277 Expander_Mode_Save_And_Set
1278 (Operating_Mode = Generate_Code or Debug_Flag_X);
1279 end if;
1281 Full_Analysis := True;
1282 Inside_A_Generic := False;
1283 In_Default_Expression := False;
1285 Set_Comes_From_Source_Default (False);
1286 Save_Opt_Config_Switches (Save_Config_Switches);
1287 Set_Opt_Config_Switches
1288 (Is_Internal_File_Name (Unit_File_Name (Current_Sem_Unit)),
1289 Current_Sem_Unit = Main_Unit);
1291 -- Only do analysis of unit that has not already been analyzed
1293 if not Analyzed (Comp_Unit) then
1294 Initialize_Version (Current_Sem_Unit);
1295 if HLO_Active then
1296 Expander_Mode_Save_And_Set (False);
1297 New_Nodes_OK := 1;
1298 Do_Analyze;
1299 Reset_Analyzed_Flags (Comp_Unit);
1300 Expander_Mode_Restore;
1301 High_Level_Optimize (Comp_Unit);
1302 New_Nodes_OK := 0;
1303 end if;
1305 Do_Analyze;
1306 end if;
1308 -- Save indication of dynamic elaboration checks for ALI file
1310 Set_Dynamic_Elab (Current_Sem_Unit, Dynamic_Elaboration_Checks);
1312 -- Restore settings of saved switches to entry values
1314 Current_Sem_Unit := S_Sem_Unit;
1315 Full_Analysis := S_Full_Analysis;
1316 In_Default_Expression := S_In_Default_Expr;
1317 Inside_A_Generic := S_Inside_A_Generic;
1318 New_Nodes_OK := S_New_Nodes_OK;
1319 Outer_Generic_Scope := S_Outer_Gen_Scope;
1320 GNAT_Mode := S_GNAT_Mode;
1322 Restore_Opt_Config_Switches (Save_Config_Switches);
1323 Expander_Mode_Restore;
1325 end Semantics;
1326 end Sem;