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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- S E M _ W A R N --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 1999-2018, Free Software Foundation, Inc. --
10 -- --
11 -- GNAT is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License --
17 -- for more details. You should have received a copy of the GNU General --
18 -- Public License distributed with GNAT; see file COPYING3. If not, go to --
19 -- http://www.gnu.org/licenses for a complete copy of the license. --
20 -- --
21 -- GNAT was originally developed by the GNAT team at New York University. --
22 -- Extensive contributions were provided by Ada Core Technologies Inc. --
23 -- --
24 ------------------------------------------------------------------------------
26 with Atree; use Atree;
27 with Debug; use Debug;
28 with Einfo; use Einfo;
29 with Errout; use Errout;
30 with Exp_Code; use Exp_Code;
31 with Lib; use Lib;
32 with Lib.Xref; use Lib.Xref;
33 with Namet; use Namet;
34 with Nlists; use Nlists;
35 with Opt; use Opt;
36 with Par_SCO; use Par_SCO;
37 with Rtsfind; use Rtsfind;
38 with Sem; use Sem;
39 with Sem_Ch8; use Sem_Ch8;
40 with Sem_Aux; use Sem_Aux;
41 with Sem_Eval; use Sem_Eval;
42 with Sem_Prag; use Sem_Prag;
43 with Sem_Util; use Sem_Util;
44 with Sinfo; use Sinfo;
45 with Sinput; use Sinput;
46 with Snames; use Snames;
47 with Stand; use Stand;
48 with Stringt; use Stringt;
49 with Tbuild; use Tbuild;
50 with Uintp; use Uintp;
52 package body Sem_Warn is
54 -- The following table collects Id's of entities that are potentially
55 -- unreferenced. See Check_Unset_Reference for further details.
56 -- ??? Check_Unset_Reference has zero information about this table.
58 package Unreferenced_Entities is new Table.Table (
59 Table_Component_Type => Entity_Id,
60 Table_Index_Type => Nat,
61 Table_Low_Bound => 1,
62 Table_Initial => Alloc.Unreferenced_Entities_Initial,
63 Table_Increment => Alloc.Unreferenced_Entities_Increment,
64 Table_Name => "Unreferenced_Entities");
66 -- The following table collects potential warnings for IN OUT parameters
67 -- that are referenced but not modified. These warnings are processed when
68 -- the front end calls the procedure Output_Non_Modified_In_Out_Warnings.
69 -- The reason that we defer output of these messages is that we want to
70 -- detect the case where the relevant procedure is used as a generic actual
71 -- in an instantiation, since we suppress the warnings in this case. The
72 -- flag Used_As_Generic_Actual will be set in this case, but only at the
73 -- point of usage. Similarly, we suppress the message if the address of the
74 -- procedure is taken, where the flag Address_Taken may be set later.
76 package In_Out_Warnings is new Table.Table (
77 Table_Component_Type => Entity_Id,
78 Table_Index_Type => Nat,
79 Table_Low_Bound => 1,
80 Table_Initial => Alloc.In_Out_Warnings_Initial,
81 Table_Increment => Alloc.In_Out_Warnings_Increment,
82 Table_Name => "In_Out_Warnings");
84 --------------------------------------------------------
85 -- Handling of Warnings Off, Unmodified, Unreferenced --
86 --------------------------------------------------------
88 -- The functions Has_Warnings_Off, Has_Unmodified, Has_Unreferenced must
89 -- generally be used instead of Warnings_Off, Has_Pragma_Unmodified and
90 -- Has_Pragma_Unreferenced, as noted in the specs in Einfo.
92 -- In order to avoid losing warnings in -gnatw.w (warn on unnecessary
93 -- warnings off pragma) mode, i.e. to avoid false negatives, the code
94 -- must follow some important rules.
96 -- Call these functions as late as possible, after completing all other
97 -- tests, just before the warnings is given. For example, don't write:
99 -- if not Has_Warnings_Off (E)
100 -- and then some-other-predicate-on-E then ..
102 -- Instead the following is preferred
104 -- if some-other-predicate-on-E
105 -- and then Has_Warnings_Off (E)
107 -- This way if some-other-predicate is false, we avoid a false indication
108 -- that a Warnings (Off, E) pragma was useful in preventing a warning.
110 -- The second rule is that if both Has_Unmodified and Has_Warnings_Off, or
111 -- Has_Unreferenced and Has_Warnings_Off are called, make sure that the
112 -- call to Has_Unmodified/Has_Unreferenced comes first, this way we record
113 -- that the Warnings (Off) could have been Unreferenced or Unmodified. In
114 -- fact Has_Unmodified/Has_Unreferenced includes a test for Warnings Off,
115 -- and so a subsequent test is not needed anyway (though it is harmless).
117 -----------------------
118 -- Local Subprograms --
119 -----------------------
121 function Generic_Package_Spec_Entity (E : Entity_Id) return Boolean;
122 -- This returns true if the entity E is declared within a generic package.
123 -- The point of this is to detect variables which are not assigned within
124 -- the generic, but might be assigned outside the package for any given
125 -- instance. These are cases where we leave the warnings to be posted for
126 -- the instance, when we will know more.
128 function Goto_Spec_Entity (E : Entity_Id) return Entity_Id;
129 -- If E is a parameter entity for a subprogram body, then this function
130 -- returns the corresponding spec entity, if not, E is returned unchanged.
132 function Has_Pragma_Unmodified_Check_Spec (E : Entity_Id) return Boolean;
133 -- Tests Has_Pragma_Unmodified flag for entity E. If E is not a formal,
134 -- this is simply the setting of the flag Has_Pragma_Unmodified. If E is
135 -- a body formal, the setting of the flag in the corresponding spec is
136 -- also checked (and True returned if either flag is True).
138 function Has_Pragma_Unreferenced_Check_Spec (E : Entity_Id) return Boolean;
139 -- Tests Has_Pragma_Unreferenced flag for entity E. If E is not a formal,
140 -- this is simply the setting of the flag Has_Pragma_Unreferenced. If E is
141 -- a body formal, the setting of the flag in the corresponding spec is
142 -- also checked (and True returned if either flag is True).
144 function Is_Attribute_And_Known_Value_Comparison
145 (Op : Node_Id) return Boolean;
146 -- Determine whether operator Op denotes a comparison where the left
147 -- operand is an attribute reference and the value of the right operand is
148 -- known at compile time.
150 function Never_Set_In_Source_Check_Spec (E : Entity_Id) return Boolean;
151 -- Tests Never_Set_In_Source status for entity E. If E is not a formal,
152 -- this is simply the setting of the flag Never_Set_In_Source. If E is
153 -- a body formal, the setting of the flag in the corresponding spec is
154 -- also checked (and False returned if either flag is False).
156 function Operand_Has_Warnings_Suppressed (N : Node_Id) return Boolean;
157 -- This function traverses the expression tree represented by the node N
158 -- and determines if any sub-operand is a reference to an entity for which
159 -- the Warnings_Off flag is set. True is returned if such an entity is
160 -- encountered, and False otherwise.
162 function Referenced_Check_Spec (E : Entity_Id) return Boolean;
163 -- Tests Referenced status for entity E. If E is not a formal, this is
164 -- simply the setting of the flag Referenced. If E is a body formal, the
165 -- setting of the flag in the corresponding spec is also checked (and True
166 -- returned if either flag is True).
168 function Referenced_As_LHS_Check_Spec (E : Entity_Id) return Boolean;
169 -- Tests Referenced_As_LHS status for entity E. If E is not a formal, this
170 -- is simply the setting of the flag Referenced_As_LHS. If E is a body
171 -- formal, the setting of the flag in the corresponding spec is also
172 -- checked (and True returned if either flag is True).
174 function Referenced_As_Out_Parameter_Check_Spec
175 (E : Entity_Id) return Boolean;
176 -- Tests Referenced_As_Out_Parameter status for entity E. If E is not a
177 -- formal, this is simply the setting of Referenced_As_Out_Parameter. If E
178 -- is a body formal, the setting of the flag in the corresponding spec is
179 -- also checked (and True returned if either flag is True).
181 procedure Warn_On_Unreferenced_Entity
182 (Spec_E : Entity_Id;
183 Body_E : Entity_Id := Empty);
184 -- Output warnings for unreferenced entity E. For the case of an entry
185 -- formal, Body_E is the corresponding body entity for a particular
186 -- accept statement, and the message is posted on Body_E. In all other
187 -- cases, Body_E is ignored and must be Empty.
189 function Warnings_Off_Check_Spec (E : Entity_Id) return Boolean;
190 -- Returns True if Warnings_Off is set for the entity E or (in the case
191 -- where there is a Spec_Entity), Warnings_Off is set for the Spec_Entity.
193 --------------------------
194 -- Check_Code_Statement --
195 --------------------------
197 procedure Check_Code_Statement (N : Node_Id) is
198 begin
199 -- If volatile, nothing to worry about
201 if Is_Asm_Volatile (N) then
202 return;
203 end if;
205 -- Warn if no input or no output
207 Setup_Asm_Inputs (N);
209 if No (Asm_Input_Value) then
210 Error_Msg_F
211 ("??code statement with no inputs should usually be Volatile!", N);
212 return;
213 end if;
215 Setup_Asm_Outputs (N);
217 if No (Asm_Output_Variable) then
218 Error_Msg_F
219 ("??code statement with no outputs should usually be Volatile!", N);
220 return;
221 end if;
222 end Check_Code_Statement;
224 ---------------------------------
225 -- Check_Infinite_Loop_Warning --
226 ---------------------------------
228 -- The case we look for is a while loop which tests a local variable, where
229 -- there is no obvious direct or possible indirect update of the variable
230 -- within the body of the loop.
232 procedure Check_Infinite_Loop_Warning (Loop_Statement : Node_Id) is
233 Expression : Node_Id := Empty;
234 -- Set to WHILE or EXIT WHEN condition to be tested
236 Ref : Node_Id := Empty;
237 -- Reference in Expression to variable that might not be modified
238 -- in loop, indicating a possible infinite loop.
240 Var : Entity_Id := Empty;
241 -- Corresponding entity (entity of Ref)
243 Function_Call_Found : Boolean := False;
244 -- True if Find_Var found a function call in the condition
246 procedure Find_Var (N : Node_Id);
247 -- Inspect condition to see if it depends on a single entity reference.
248 -- If so, Ref is set to point to the reference node, and Var is set to
249 -- the referenced Entity.
251 function Has_Condition_Actions (Iter : Node_Id) return Boolean;
252 -- Determine whether iteration scheme Iter has meaningful condition
253 -- actions.
255 function Has_Indirection (T : Entity_Id) return Boolean;
256 -- If the controlling variable is an access type, or is a record type
257 -- with access components, assume that it is changed indirectly and
258 -- suppress the warning. As a concession to low-level programming, in
259 -- particular within Declib, we also suppress warnings on a record
260 -- type that contains components of type Address or Short_Address.
262 function Is_Suspicious_Function_Name (E : Entity_Id) return Boolean;
263 -- Given an entity name, see if the name appears to have something to
264 -- do with I/O or network stuff, and if so, return True. Used to kill
265 -- some false positives on a heuristic basis that such functions will
266 -- likely have some strange side effect dependencies. A rather strange
267 -- test, but warning messages are in the heuristics business.
269 function Test_Ref (N : Node_Id) return Traverse_Result;
270 -- Test for reference to variable in question. Returns Abandon if
271 -- matching reference found. Used in instantiation of No_Ref_Found.
273 function No_Ref_Found is new Traverse_Func (Test_Ref);
274 -- Function to traverse body of procedure. Returns Abandon if matching
275 -- reference found.
277 --------------
278 -- Find_Var --
279 --------------
281 procedure Find_Var (N : Node_Id) is
282 begin
283 -- Condition is a direct variable reference
285 if Is_Entity_Name (N) then
286 Ref := N;
287 Var := Entity (Ref);
289 -- Case of condition is a comparison with compile time known value
291 elsif Nkind (N) in N_Op_Compare then
292 if Compile_Time_Known_Value (Right_Opnd (N)) then
293 Find_Var (Left_Opnd (N));
295 elsif Compile_Time_Known_Value (Left_Opnd (N)) then
296 Find_Var (Right_Opnd (N));
298 -- Ignore any other comparison
300 else
301 return;
302 end if;
304 -- If condition is a negation, check its operand
306 elsif Nkind (N) = N_Op_Not then
307 Find_Var (Right_Opnd (N));
309 -- Case of condition is function call
311 elsif Nkind (N) = N_Function_Call then
313 Function_Call_Found := True;
315 -- Forget it if function name is not entity, who knows what
316 -- we might be calling?
318 if not Is_Entity_Name (Name (N)) then
319 return;
321 -- Forget it if function name is suspicious. A strange test
322 -- but warning generation is in the heuristics business.
324 elsif Is_Suspicious_Function_Name (Entity (Name (N))) then
325 return;
327 -- Forget it if function is marked Volatile_Function
329 elsif Is_Volatile_Function (Entity (Name (N))) then
330 return;
332 -- Forget it if warnings are suppressed on function entity
334 elsif Has_Warnings_Off (Entity (Name (N))) then
335 return;
336 end if;
338 -- OK, see if we have one argument
340 declare
341 PA : constant List_Id := Parameter_Associations (N);
343 begin
344 -- One argument, so check the argument
346 if Present (PA) and then List_Length (PA) = 1 then
347 if Nkind (First (PA)) = N_Parameter_Association then
348 Find_Var (Explicit_Actual_Parameter (First (PA)));
349 else
350 Find_Var (First (PA));
351 end if;
353 -- Not one argument
355 else
356 return;
357 end if;
358 end;
360 -- Any other kind of node is not something we warn for
362 else
363 return;
364 end if;
365 end Find_Var;
367 ---------------------------
368 -- Has_Condition_Actions --
369 ---------------------------
371 function Has_Condition_Actions (Iter : Node_Id) return Boolean is
372 Action : Node_Id;
374 begin
375 -- A call marker is not considered a meaningful action because it
376 -- acts as an annotation and has no runtime semantics.
378 Action := First (Condition_Actions (Iter));
379 while Present (Action) loop
380 if Nkind (Action) /= N_Call_Marker then
381 return True;
382 end if;
384 Next (Action);
385 end loop;
387 return False;
388 end Has_Condition_Actions;
390 ---------------------
391 -- Has_Indirection --
392 ---------------------
394 function Has_Indirection (T : Entity_Id) return Boolean is
395 Comp : Entity_Id;
396 Rec : Entity_Id;
398 begin
399 if Is_Access_Type (T) then
400 return True;
402 elsif Is_Private_Type (T)
403 and then Present (Full_View (T))
404 and then Is_Access_Type (Full_View (T))
405 then
406 return True;
408 elsif Is_Record_Type (T) then
409 Rec := T;
411 elsif Is_Private_Type (T)
412 and then Present (Full_View (T))
413 and then Is_Record_Type (Full_View (T))
414 then
415 Rec := Full_View (T);
416 else
417 return False;
418 end if;
420 Comp := First_Component (Rec);
421 while Present (Comp) loop
422 if Is_Access_Type (Etype (Comp))
423 or else Is_Descendant_Of_Address (Etype (Comp))
424 then
425 return True;
426 end if;
428 Next_Component (Comp);
429 end loop;
431 return False;
432 end Has_Indirection;
434 ---------------------------------
435 -- Is_Suspicious_Function_Name --
436 ---------------------------------
438 function Is_Suspicious_Function_Name (E : Entity_Id) return Boolean is
439 S : Entity_Id;
441 function Substring_Present (S : String) return Boolean;
442 -- Returns True if name buffer has given string delimited by non-
443 -- alphabetic characters or by end of string. S is lower case.
445 -----------------------
446 -- Substring_Present --
447 -----------------------
449 function Substring_Present (S : String) return Boolean is
450 Len : constant Natural := S'Length;
452 begin
453 for J in 1 .. Name_Len - (Len - 1) loop
454 if Name_Buffer (J .. J + (Len - 1)) = S
455 and then (J = 1 or else Name_Buffer (J - 1) not in 'a' .. 'z')
456 and then
457 (J + Len > Name_Len
458 or else Name_Buffer (J + Len) not in 'a' .. 'z')
459 then
460 return True;
461 end if;
462 end loop;
464 return False;
465 end Substring_Present;
467 -- Start of processing for Is_Suspicious_Function_Name
469 begin
470 S := E;
471 while Present (S) and then S /= Standard_Standard loop
472 Get_Name_String (Chars (S));
474 if Substring_Present ("io")
475 or else Substring_Present ("file")
476 or else Substring_Present ("network")
477 then
478 return True;
479 else
480 S := Scope (S);
481 end if;
482 end loop;
484 return False;
485 end Is_Suspicious_Function_Name;
487 --------------
488 -- Test_Ref --
489 --------------
491 function Test_Ref (N : Node_Id) return Traverse_Result is
492 begin
493 -- Waste of time to look at the expression we are testing
495 if N = Expression then
496 return Skip;
498 -- Direct reference to variable in question
500 elsif Is_Entity_Name (N)
501 and then Present (Entity (N))
502 and then Entity (N) = Var
503 then
504 -- If this is an lvalue, then definitely abandon, since
505 -- this could be a direct modification of the variable.
507 if May_Be_Lvalue (N) then
508 return Abandon;
509 end if;
511 -- If the condition contains a function call, we consider it may
512 -- be modified by side effects from a procedure call. Otherwise,
513 -- we consider the condition may not be modified, although that
514 -- might happen if Variable is itself a by-reference parameter,
515 -- and the procedure called modifies the global object referred to
516 -- by Variable, but we actually prefer to issue a warning in this
517 -- odd case. Note that the case where the procedure called has
518 -- visibility over Variable is treated in another case below.
520 if Function_Call_Found then
521 declare
522 P : Node_Id;
524 begin
525 P := N;
526 loop
527 P := Parent (P);
528 exit when P = Loop_Statement;
530 -- Abandon if at procedure call, or something strange is
531 -- going on (perhaps a node with no parent that should
532 -- have one but does not?) As always, for a warning we
533 -- prefer to just abandon the warning than get into the
534 -- business of complaining about the tree structure here.
536 if No (P)
537 or else Nkind (P) = N_Procedure_Call_Statement
538 then
539 return Abandon;
540 end if;
541 end loop;
542 end;
543 end if;
545 -- Reference to variable renaming variable in question
547 elsif Is_Entity_Name (N)
548 and then Present (Entity (N))
549 and then Ekind (Entity (N)) = E_Variable
550 and then Present (Renamed_Object (Entity (N)))
551 and then Is_Entity_Name (Renamed_Object (Entity (N)))
552 and then Entity (Renamed_Object (Entity (N))) = Var
553 and then May_Be_Lvalue (N)
554 then
555 return Abandon;
557 -- Call to subprogram
559 elsif Nkind (N) in N_Subprogram_Call then
561 -- If subprogram is within the scope of the entity we are dealing
562 -- with as the loop variable, then it could modify this parameter,
563 -- so we abandon in this case. In the case of a subprogram that is
564 -- not an entity we also abandon. The check for no entity being
565 -- present is a defense against previous errors.
567 if not Is_Entity_Name (Name (N))
568 or else No (Entity (Name (N)))
569 or else Scope_Within (Entity (Name (N)), Scope (Var))
570 then
571 return Abandon;
572 end if;
574 -- If any of the arguments are of type access to subprogram, then
575 -- we may have funny side effects, so no warning in this case.
577 declare
578 Actual : Node_Id;
579 begin
580 Actual := First_Actual (N);
581 while Present (Actual) loop
582 if Is_Access_Subprogram_Type (Etype (Actual)) then
583 return Abandon;
584 else
585 Next_Actual (Actual);
586 end if;
587 end loop;
588 end;
590 -- Declaration of the variable in question
592 elsif Nkind (N) = N_Object_Declaration
593 and then Defining_Identifier (N) = Var
594 then
595 return Abandon;
596 end if;
598 -- All OK, continue scan
600 return OK;
601 end Test_Ref;
603 -- Start of processing for Check_Infinite_Loop_Warning
605 begin
606 -- Skip processing if debug flag gnatd.w is set
608 if Debug_Flag_Dot_W then
609 return;
610 end if;
612 -- Deal with Iteration scheme present
614 declare
615 Iter : constant Node_Id := Iteration_Scheme (Loop_Statement);
617 begin
618 if Present (Iter) then
620 -- While iteration
622 if Present (Condition (Iter)) then
624 -- Skip processing for while iteration with conditions actions,
625 -- since they make it too complicated to get the warning right.
627 if Has_Condition_Actions (Iter) then
628 return;
629 end if;
631 -- Capture WHILE condition
633 Expression := Condition (Iter);
635 -- For iteration, do not process, since loop will always terminate
637 elsif Present (Loop_Parameter_Specification (Iter)) then
638 return;
639 end if;
640 end if;
641 end;
643 -- Check chain of EXIT statements, we only process loops that have a
644 -- single exit condition (either a single EXIT WHEN statement, or a
645 -- WHILE loop not containing any EXIT WHEN statements).
647 declare
648 Ident : constant Node_Id := Identifier (Loop_Statement);
649 Exit_Stmt : Node_Id;
651 begin
652 -- If we don't have a proper chain set, ignore call entirely. This
653 -- happens because of previous errors.
655 if No (Entity (Ident))
656 or else Ekind (Entity (Ident)) /= E_Loop
657 then
658 Check_Error_Detected;
659 return;
660 end if;
662 -- Otherwise prepare to scan list of EXIT statements
664 Exit_Stmt := First_Exit_Statement (Entity (Ident));
665 while Present (Exit_Stmt) loop
667 -- Check for EXIT WHEN
669 if Present (Condition (Exit_Stmt)) then
671 -- Quit processing if EXIT WHEN in WHILE loop, or more than
672 -- one EXIT WHEN statement present in the loop.
674 if Present (Expression) then
675 return;
677 -- Otherwise capture condition from EXIT WHEN statement
679 else
680 Expression := Condition (Exit_Stmt);
681 end if;
683 -- If an unconditional exit statement is the last statement in the
684 -- loop, assume that no warning is needed, without any attempt at
685 -- checking whether the exit is reachable.
687 elsif Exit_Stmt = Last (Statements (Loop_Statement)) then
688 return;
689 end if;
691 Exit_Stmt := Next_Exit_Statement (Exit_Stmt);
692 end loop;
693 end;
695 -- Return if no condition to test
697 if No (Expression) then
698 return;
699 end if;
701 -- Initial conditions met, see if condition is of right form
703 Find_Var (Expression);
705 -- Nothing to do if local variable from source not found. If it's a
706 -- renaming, it is probably renaming something too complicated to deal
707 -- with here.
709 if No (Var)
710 or else Ekind (Var) /= E_Variable
711 or else Is_Library_Level_Entity (Var)
712 or else not Comes_From_Source (Var)
713 or else Nkind (Parent (Var)) = N_Object_Renaming_Declaration
714 then
715 return;
717 -- Nothing to do if there is some indirection involved (assume that the
718 -- designated variable might be modified in some way we don't see).
719 -- However, if no function call was found, then we don't care about
720 -- indirections, because the condition must be something like "while X
721 -- /= null loop", so we don't care if X.all is modified in the loop.
723 elsif Function_Call_Found and then Has_Indirection (Etype (Var)) then
724 return;
726 -- Same sort of thing for volatile variable, might be modified by
727 -- some other task or by the operating system in some way.
729 elsif Is_Volatile (Var) then
730 return;
731 end if;
733 -- Filter out case of original statement sequence starting with delay.
734 -- We assume this is a multi-tasking program and that the condition
735 -- is affected by other threads (some kind of busy wait).
737 declare
738 Fstm : constant Node_Id :=
739 Original_Node (First (Statements (Loop_Statement)));
740 begin
741 if Nkind (Fstm) = N_Delay_Relative_Statement
742 or else Nkind (Fstm) = N_Delay_Until_Statement
743 then
744 return;
745 end if;
746 end;
748 -- We have a variable reference of the right form, now we scan the loop
749 -- body to see if it looks like it might not be modified
751 if No_Ref_Found (Loop_Statement) = OK then
752 Error_Msg_NE
753 ("??variable& is not modified in loop body!", Ref, Var);
754 Error_Msg_N
755 ("\??possible infinite loop!", Ref);
756 end if;
757 end Check_Infinite_Loop_Warning;
759 ----------------------------
760 -- Check_Low_Bound_Tested --
761 ----------------------------
763 procedure Check_Low_Bound_Tested (Expr : Node_Id) is
764 procedure Check_Low_Bound_Tested_For (Opnd : Node_Id);
765 -- Determine whether operand Opnd denotes attribute 'First whose prefix
766 -- is a formal parameter. If this is the case, mark the entity of the
767 -- prefix as having its low bound tested.
769 --------------------------------
770 -- Check_Low_Bound_Tested_For --
771 --------------------------------
773 procedure Check_Low_Bound_Tested_For (Opnd : Node_Id) is
774 begin
775 if Nkind (Opnd) = N_Attribute_Reference
776 and then Attribute_Name (Opnd) = Name_First
777 and then Is_Entity_Name (Prefix (Opnd))
778 and then Present (Entity (Prefix (Opnd)))
779 and then Is_Formal (Entity (Prefix (Opnd)))
780 then
781 Set_Low_Bound_Tested (Entity (Prefix (Opnd)));
782 end if;
783 end Check_Low_Bound_Tested_For;
785 -- Start of processing for Check_Low_Bound_Tested
787 begin
788 if Comes_From_Source (Expr) then
789 Check_Low_Bound_Tested_For (Left_Opnd (Expr));
790 Check_Low_Bound_Tested_For (Right_Opnd (Expr));
791 end if;
792 end Check_Low_Bound_Tested;
794 ----------------------
795 -- Check_References --
796 ----------------------
798 procedure Check_References (E : Entity_Id; Anod : Node_Id := Empty) is
799 E1 : Entity_Id;
800 E1T : Entity_Id;
801 UR : Node_Id;
803 function Body_Formal
804 (E : Entity_Id;
805 Accept_Statement : Node_Id) return Entity_Id;
806 -- For an entry formal entity from an entry declaration, find the
807 -- corresponding body formal from the given accept statement.
809 procedure May_Need_Initialized_Actual (Ent : Entity_Id);
810 -- If an entity of a generic type has default initialization, then the
811 -- corresponding actual type should be fully initialized, or else there
812 -- will be uninitialized components in the instantiation, that might go
813 -- unreported. This routine marks the type of the uninitialized variable
814 -- appropriately to allow the compiler to emit an appropriate warning
815 -- in the instance. In a sense, the use of a type that requires full
816 -- initialization is a weak part of the generic contract.
818 function Missing_Subunits return Boolean;
819 -- We suppress warnings when there are missing subunits, because this
820 -- may generate too many false positives: entities in a parent may only
821 -- be referenced in one of the subunits. We make an exception for
822 -- subunits that contain no other stubs.
824 procedure Output_Reference_Error (M : String);
825 -- Used to output an error message. Deals with posting the error on the
826 -- body formal in the accept case.
828 function Publicly_Referenceable (Ent : Entity_Id) return Boolean;
829 -- This is true if the entity in question is potentially referenceable
830 -- from another unit. This is true for entities in packages that are at
831 -- the library level.
833 function Warnings_Off_E1 return Boolean;
834 -- Return True if Warnings_Off is set for E1, or for its Etype (E1T),
835 -- or for the base type of E1T.
837 -----------------
838 -- Body_Formal --
839 -----------------
841 function Body_Formal
842 (E : Entity_Id;
843 Accept_Statement : Node_Id) return Entity_Id
845 Body_Param : Node_Id;
846 Body_E : Entity_Id;
848 begin
849 -- Loop to find matching parameter in accept statement
851 Body_Param := First (Parameter_Specifications (Accept_Statement));
852 while Present (Body_Param) loop
853 Body_E := Defining_Identifier (Body_Param);
855 if Chars (Body_E) = Chars (E) then
856 return Body_E;
857 end if;
859 Next (Body_Param);
860 end loop;
862 -- Should never fall through, should always find a match
864 raise Program_Error;
865 end Body_Formal;
867 ---------------------------------
868 -- May_Need_Initialized_Actual --
869 ---------------------------------
871 procedure May_Need_Initialized_Actual (Ent : Entity_Id) is
872 T : constant Entity_Id := Etype (Ent);
873 Par : constant Node_Id := Parent (T);
875 begin
876 if not Is_Generic_Type (T) then
877 null;
879 elsif (Nkind (Par)) = N_Private_Extension_Declaration then
881 -- We only indicate the first such variable in the generic.
883 if No (Uninitialized_Variable (Par)) then
884 Set_Uninitialized_Variable (Par, Ent);
885 end if;
887 elsif (Nkind (Par)) = N_Formal_Type_Declaration
888 and then Nkind (Formal_Type_Definition (Par)) =
889 N_Formal_Private_Type_Definition
890 then
891 if No (Uninitialized_Variable (Formal_Type_Definition (Par))) then
892 Set_Uninitialized_Variable (Formal_Type_Definition (Par), Ent);
893 end if;
894 end if;
895 end May_Need_Initialized_Actual;
897 ----------------------
898 -- Missing_Subunits --
899 ----------------------
901 function Missing_Subunits return Boolean is
902 D : Node_Id;
904 begin
905 if not Unloaded_Subunits then
907 -- Normal compilation, all subunits are present
909 return False;
911 elsif E /= Main_Unit_Entity then
913 -- No warnings on a stub that is not the main unit
915 return True;
917 elsif Nkind (Unit_Declaration_Node (E)) in N_Proper_Body then
918 D := First (Declarations (Unit_Declaration_Node (E)));
919 while Present (D) loop
921 -- No warnings if the proper body contains nested stubs
923 if Nkind (D) in N_Body_Stub then
924 return True;
925 end if;
927 Next (D);
928 end loop;
930 return False;
932 else
933 -- Missing stubs elsewhere
935 return True;
936 end if;
937 end Missing_Subunits;
939 ----------------------------
940 -- Output_Reference_Error --
941 ----------------------------
943 procedure Output_Reference_Error (M : String) is
944 begin
945 -- Never issue messages for internal names or renamings
947 if Is_Internal_Name (Chars (E1))
948 or else Nkind (Parent (E1)) = N_Object_Renaming_Declaration
949 then
950 return;
951 end if;
953 -- Don't output message for IN OUT formal unless we have the warning
954 -- flag specifically set. It is a bit odd to distinguish IN OUT
955 -- formals from other cases. This distinction is historical in
956 -- nature. Warnings for IN OUT formals were added fairly late.
958 if Ekind (E1) = E_In_Out_Parameter
959 and then not Check_Unreferenced_Formals
960 then
961 return;
962 end if;
964 -- Other than accept case, post error on defining identifier
966 if No (Anod) then
967 Error_Msg_N (M, E1);
969 -- Accept case, find body formal to post the message
971 else
972 Error_Msg_NE (M, Body_Formal (E1, Accept_Statement => Anod), E1);
974 end if;
975 end Output_Reference_Error;
977 ----------------------------
978 -- Publicly_Referenceable --
979 ----------------------------
981 function Publicly_Referenceable (Ent : Entity_Id) return Boolean is
982 P : Node_Id;
983 Prev : Node_Id;
985 begin
986 -- A formal parameter is never referenceable outside the body of its
987 -- subprogram or entry.
989 if Is_Formal (Ent) then
990 return False;
991 end if;
993 -- Examine parents to look for a library level package spec. But if
994 -- we find a body or block or other similar construct along the way,
995 -- we cannot be referenced.
997 Prev := Ent;
998 P := Parent (Ent);
999 loop
1000 case Nkind (P) is
1002 -- If we get to top of tree, then publicly referenceable
1004 when N_Empty =>
1005 return True;
1007 -- If we reach a generic package declaration, then always
1008 -- consider this referenceable, since any instantiation will
1009 -- have access to the entities in the generic package. Note
1010 -- that the package itself may not be instantiated, but then
1011 -- we will get a warning for the package entity.
1013 -- Note that generic formal parameters are themselves not
1014 -- publicly referenceable in an instance, and warnings on them
1015 -- are useful.
1017 when N_Generic_Package_Declaration =>
1018 return
1019 not Is_List_Member (Prev)
1020 or else List_Containing (Prev) /=
1021 Generic_Formal_Declarations (P);
1023 -- Similarly, the generic formals of a generic subprogram are
1024 -- not accessible.
1026 when N_Generic_Subprogram_Declaration =>
1027 if Is_List_Member (Prev)
1028 and then List_Containing (Prev) =
1029 Generic_Formal_Declarations (P)
1030 then
1031 return False;
1032 else
1033 P := Parent (P);
1034 end if;
1036 -- If we reach a subprogram body, entity is not referenceable
1037 -- unless it is the defining entity of the body. This will
1038 -- happen, e.g. when a function is an attribute renaming that
1039 -- is rewritten as a body.
1041 when N_Subprogram_Body =>
1042 if Ent /= Defining_Entity (P) then
1043 return False;
1044 else
1045 P := Parent (P);
1046 end if;
1048 -- If we reach any other body, definitely not referenceable
1050 when N_Block_Statement
1051 | N_Entry_Body
1052 | N_Package_Body
1053 | N_Protected_Body
1054 | N_Subunit
1055 | N_Task_Body
1057 return False;
1059 -- For all other cases, keep looking up tree
1061 when others =>
1062 Prev := P;
1063 P := Parent (P);
1064 end case;
1065 end loop;
1066 end Publicly_Referenceable;
1068 ---------------------
1069 -- Warnings_Off_E1 --
1070 ---------------------
1072 function Warnings_Off_E1 return Boolean is
1073 begin
1074 return Has_Warnings_Off (E1T)
1075 or else Has_Warnings_Off (Base_Type (E1T))
1076 or else Warnings_Off_Check_Spec (E1);
1077 end Warnings_Off_E1;
1079 -- Start of processing for Check_References
1081 begin
1082 Process_Deferred_References;
1084 -- No messages if warnings are suppressed, or if we have detected any
1085 -- real errors so far (this last check avoids junk messages resulting
1086 -- from errors, e.g. a subunit that is not loaded).
1088 if Warning_Mode = Suppress or else Serious_Errors_Detected /= 0 then
1089 return;
1090 end if;
1092 -- We also skip the messages if any subunits were not loaded (see
1093 -- comment in Sem_Ch10 to understand how this is set, and why it is
1094 -- necessary to suppress the warnings in this case).
1096 if Missing_Subunits then
1097 return;
1098 end if;
1100 -- Otherwise loop through entities, looking for suspicious stuff
1102 E1 := First_Entity (E);
1103 while Present (E1) loop
1104 E1T := Etype (E1);
1106 -- We are only interested in source entities. We also don't issue
1107 -- warnings within instances, since the proper place for such
1108 -- warnings is on the template when it is compiled, and we don't
1109 -- issue warnings for variables with names like Junk, Discard etc.
1111 if Comes_From_Source (E1)
1112 and then Instantiation_Location (Sloc (E1)) = No_Location
1113 then
1114 -- We are interested in variables and out/in-out parameters, but
1115 -- we exclude protected types, too complicated to worry about.
1117 if Ekind (E1) = E_Variable
1118 or else
1119 (Ekind_In (E1, E_Out_Parameter, E_In_Out_Parameter)
1120 and then not Is_Protected_Type (Current_Scope))
1121 then
1122 -- If the formal has a class-wide type, retrieve its type
1123 -- because checks below depend on its private nature.
1125 if Is_Class_Wide_Type (E1T) then
1126 E1T := Etype (E1T);
1127 end if;
1129 -- Case of an unassigned variable
1131 -- First gather any Unset_Reference indication for E1. In the
1132 -- case of a parameter, it is the Spec_Entity that is relevant.
1134 if Ekind (E1) = E_Out_Parameter
1135 and then Present (Spec_Entity (E1))
1136 then
1137 UR := Unset_Reference (Spec_Entity (E1));
1138 else
1139 UR := Unset_Reference (E1);
1140 end if;
1142 -- Special processing for access types
1144 if Present (UR) and then Is_Access_Type (E1T) then
1146 -- For access types, the only time we made a UR entry was
1147 -- for a dereference, and so we post the appropriate warning
1148 -- here (note that the dereference may not be explicit in
1149 -- the source, for example in the case of a dispatching call
1150 -- with an anonymous access controlling formal, or of an
1151 -- assignment of a pointer involving discriminant check on
1152 -- the designated object).
1154 if not Warnings_Off_E1 then
1155 Error_Msg_NE ("??& may be null!", UR, E1);
1156 end if;
1158 goto Continue;
1160 -- Case of variable that could be a constant. Note that we
1161 -- never signal such messages for generic package entities,
1162 -- since a given instance could have modifications outside
1163 -- the package.
1165 -- Note that we used to check Address_Taken here, but we don't
1166 -- want to do that since it can be set for non-source cases,
1167 -- e.g. the Unrestricted_Access from a valid attribute, and
1168 -- the wanted effect is included in Never_Set_In_Source.
1170 elsif Warn_On_Constant
1171 and then (Ekind (E1) = E_Variable
1172 and then Has_Initial_Value (E1))
1173 and then Never_Set_In_Source_Check_Spec (E1)
1174 and then not Generic_Package_Spec_Entity (E1)
1175 then
1176 -- A special case, if this variable is volatile and not
1177 -- imported, it is not helpful to tell the programmer
1178 -- to mark the variable as constant, since this would be
1179 -- illegal by virtue of RM C.6(13). Instead we suggest
1180 -- using pragma Export (can't be Import because of the
1181 -- initial value).
1183 if (Is_Volatile (E1) or else Has_Volatile_Components (E1))
1184 and then not Is_Imported (E1)
1185 then
1186 Error_Msg_N
1187 ("?k?& is not modified, consider pragma Export for "
1188 & "volatile variable!", E1);
1190 -- Another special case, Exception_Occurrence, this catches
1191 -- the case of exception choice (and a bit more too, but not
1192 -- worth doing more investigation here).
1194 elsif Is_RTE (E1T, RE_Exception_Occurrence) then
1195 null;
1197 -- Here we give the warning if referenced and no pragma
1198 -- Unreferenced or Unmodified is present.
1200 else
1201 -- Variable case
1203 if Ekind (E1) = E_Variable then
1204 if Referenced_Check_Spec (E1)
1205 and then not Has_Pragma_Unreferenced_Check_Spec (E1)
1206 and then not Has_Pragma_Unmodified_Check_Spec (E1)
1207 then
1208 if not Warnings_Off_E1
1209 and then not Has_Junk_Name (E1)
1210 then
1211 Error_Msg_N -- CODEFIX
1212 ("?k?& is not modified, "
1213 & "could be declared constant!",
1214 E1);
1215 end if;
1216 end if;
1217 end if;
1218 end if;
1220 -- Other cases of a variable or parameter never set in source
1222 elsif Never_Set_In_Source_Check_Spec (E1)
1224 -- No warning if warning for this case turned off
1226 and then Warn_On_No_Value_Assigned
1228 -- No warning if address taken somewhere
1230 and then not Address_Taken (E1)
1232 -- No warning if explicit initial value
1234 and then not Has_Initial_Value (E1)
1236 -- No warning for generic package spec entities, since we
1237 -- might set them in a child unit or something like that
1239 and then not Generic_Package_Spec_Entity (E1)
1241 -- No warning if fully initialized type, except that for
1242 -- this purpose we do not consider access types to qualify
1243 -- as fully initialized types (relying on an access type
1244 -- variable being null when it is never set is a bit odd).
1246 -- Also we generate warning for an out parameter that is
1247 -- never referenced, since again it seems odd to rely on
1248 -- default initialization to set an out parameter value.
1250 and then (Is_Access_Type (E1T)
1251 or else Ekind (E1) = E_Out_Parameter
1252 or else not Is_Fully_Initialized_Type (E1T))
1253 then
1254 -- Do not output complaint about never being assigned a
1255 -- value if a pragma Unmodified applies to the variable
1256 -- we are examining, or if it is a parameter, if there is
1257 -- a pragma Unreferenced for the corresponding spec, or
1258 -- if the type is marked as having unreferenced objects.
1259 -- The last is a little peculiar, but better too few than
1260 -- too many warnings in this situation.
1262 if Has_Pragma_Unreferenced_Objects (E1T)
1263 or else Has_Pragma_Unmodified_Check_Spec (E1)
1264 then
1265 null;
1267 -- IN OUT parameter case where parameter is referenced. We
1268 -- separate this out, since this is the case where we delay
1269 -- output of the warning until more information is available
1270 -- (about use in an instantiation or address being taken).
1272 elsif Ekind (E1) = E_In_Out_Parameter
1273 and then Referenced_Check_Spec (E1)
1274 then
1275 -- Suppress warning if private type, and the procedure
1276 -- has a separate declaration in a different unit. This
1277 -- is the case where the client of a package sees only
1278 -- the private type, and it may be quite reasonable
1279 -- for the logical view to be IN OUT, even if the
1280 -- implementation ends up using access types or some
1281 -- other method to achieve the local effect of a
1282 -- modification. On the other hand if the spec and body
1283 -- are in the same unit, we are in the package body and
1284 -- there we have less excuse for a junk IN OUT parameter.
1286 if Has_Private_Declaration (E1T)
1287 and then Present (Spec_Entity (E1))
1288 and then not In_Same_Source_Unit (E1, Spec_Entity (E1))
1289 then
1290 null;
1292 -- Suppress warning for any parameter of a dispatching
1293 -- operation, since it is quite reasonable to have an
1294 -- operation that is overridden, and for some subclasses
1295 -- needs the formal to be IN OUT and for others happens
1296 -- not to assign it.
1298 elsif Is_Dispatching_Operation
1299 (Scope (Goto_Spec_Entity (E1)))
1300 then
1301 null;
1303 -- Suppress warning if composite type contains any access
1304 -- component, since the logical effect of modifying a
1305 -- parameter may be achieved by modifying a referenced
1306 -- object.
1308 elsif Is_Composite_Type (E1T)
1309 and then Has_Access_Values (E1T)
1310 then
1311 null;
1313 -- Suppress warning on formals of an entry body. All
1314 -- references are attached to the formal in the entry
1315 -- declaration, which are marked Is_Entry_Formal.
1317 elsif Ekind (Scope (E1)) = E_Entry
1318 and then not Is_Entry_Formal (E1)
1319 then
1320 null;
1322 -- OK, looks like warning for an IN OUT parameter that
1323 -- could be IN makes sense, but we delay the output of
1324 -- the warning, pending possibly finding out later on
1325 -- that the associated subprogram is used as a generic
1326 -- actual, or its address/access is taken. In these two
1327 -- cases, we suppress the warning because the context may
1328 -- force use of IN OUT, even if in this particular case
1329 -- the formal is not modified.
1331 else
1332 -- Suppress the warnings for a junk name
1334 if not Has_Junk_Name (E1) then
1335 In_Out_Warnings.Append (E1);
1336 end if;
1337 end if;
1339 -- Other cases of formals
1341 elsif Is_Formal (E1) then
1342 if not Is_Trivial_Subprogram (Scope (E1)) then
1343 if Referenced_Check_Spec (E1) then
1344 if not Has_Pragma_Unmodified_Check_Spec (E1)
1345 and then not Warnings_Off_E1
1346 and then not Has_Junk_Name (E1)
1347 then
1348 Output_Reference_Error
1349 ("?f?formal parameter& is read but "
1350 & "never assigned!");
1351 end if;
1353 elsif not Has_Pragma_Unreferenced_Check_Spec (E1)
1354 and then not Warnings_Off_E1
1355 and then not Has_Junk_Name (E1)
1356 then
1357 Output_Reference_Error
1358 ("?f?formal parameter& is not referenced!");
1359 end if;
1360 end if;
1362 -- Case of variable
1364 else
1365 if Referenced (E1) then
1366 if not Has_Unmodified (E1)
1367 and then not Warnings_Off_E1
1368 and then not Has_Junk_Name (E1)
1369 then
1370 Output_Reference_Error
1371 ("?v?variable& is read but never assigned!");
1372 May_Need_Initialized_Actual (E1);
1373 end if;
1375 elsif not Has_Unreferenced (E1)
1376 and then not Warnings_Off_E1
1377 and then not Has_Junk_Name (E1)
1378 then
1379 Output_Reference_Error -- CODEFIX
1380 ("?v?variable& is never read and never assigned!");
1381 end if;
1383 -- Deal with special case where this variable is hidden
1384 -- by a loop variable.
1386 if Ekind (E1) = E_Variable
1387 and then Present (Hiding_Loop_Variable (E1))
1388 and then not Warnings_Off_E1
1389 then
1390 Error_Msg_N
1391 ("?v?for loop implicitly declares loop variable!",
1392 Hiding_Loop_Variable (E1));
1394 Error_Msg_Sloc := Sloc (E1);
1395 Error_Msg_N
1396 ("\?v?declaration hides & declared#!",
1397 Hiding_Loop_Variable (E1));
1398 end if;
1399 end if;
1401 goto Continue;
1402 end if;
1404 -- Check for unset reference
1406 if Warn_On_No_Value_Assigned and then Present (UR) then
1408 -- For other than access type, go back to original node to
1409 -- deal with case where original unset reference has been
1410 -- rewritten during expansion.
1412 -- In some cases, the original node may be a type
1413 -- conversion, a qualification or an attribute reference and
1414 -- in this case we want the object entity inside. Same for
1415 -- an expression with actions.
1417 UR := Original_Node (UR);
1418 loop
1419 if Nkind_In (UR, N_Expression_With_Actions,
1420 N_Qualified_Expression,
1421 N_Type_Conversion)
1422 then
1423 UR := Expression (UR);
1425 elsif Nkind (UR) = N_Attribute_Reference then
1426 UR := Prefix (UR);
1428 else
1429 exit;
1430 end if;
1431 end loop;
1433 -- Don't issue warning if appearing inside Initial_Condition
1434 -- pragma or aspect, since that expression is not evaluated
1435 -- at the point where it occurs in the source.
1437 if In_Pragma_Expression (UR, Name_Initial_Condition) then
1438 goto Continue;
1439 end if;
1441 -- Here we issue the warning, all checks completed
1443 -- If we have a return statement, this was a case of an OUT
1444 -- parameter not being set at the time of the return. (Note:
1445 -- it can't be N_Extended_Return_Statement, because those
1446 -- are only for functions, and functions do not allow OUT
1447 -- parameters.)
1449 if not Is_Trivial_Subprogram (Scope (E1)) then
1450 if Nkind (UR) = N_Simple_Return_Statement
1451 and then not Has_Pragma_Unmodified_Check_Spec (E1)
1452 then
1453 if not Warnings_Off_E1
1454 and then not Has_Junk_Name (E1)
1455 then
1456 Error_Msg_NE
1457 ("?v?OUT parameter& not set before return",
1458 UR, E1);
1459 end if;
1461 -- If the unset reference is a selected component
1462 -- prefix from source, mention the component as well.
1463 -- If the selected component comes from expansion, all
1464 -- we know is that the entity is not fully initialized
1465 -- at the point of the reference. Locate a random
1466 -- uninitialized component to get a better message.
1468 elsif Nkind (Parent (UR)) = N_Selected_Component then
1469 Error_Msg_Node_2 := Selector_Name (Parent (UR));
1471 if not Comes_From_Source (Parent (UR)) then
1472 declare
1473 Comp : Entity_Id;
1475 begin
1476 Comp := First_Entity (E1T);
1477 while Present (Comp) loop
1478 if Ekind (Comp) = E_Component
1479 and then Nkind (Parent (Comp)) =
1480 N_Component_Declaration
1481 and then No (Expression (Parent (Comp)))
1482 then
1483 Error_Msg_Node_2 := Comp;
1484 exit;
1485 end if;
1487 Next_Entity (Comp);
1488 end loop;
1489 end;
1490 end if;
1492 -- Issue proper warning. This is a case of referencing
1493 -- a variable before it has been explicitly assigned.
1494 -- For access types, UR was only set for dereferences,
1495 -- so the issue is that the value may be null.
1497 if not Is_Trivial_Subprogram (Scope (E1)) then
1498 if not Warnings_Off_E1 then
1499 if Is_Access_Type (Etype (Parent (UR))) then
1500 Error_Msg_N ("??`&.&` may be null!", UR);
1501 else
1502 Error_Msg_N
1503 ("??`&.&` may be referenced before "
1504 & "it has a value!", UR);
1505 end if;
1506 end if;
1507 end if;
1509 -- All other cases of unset reference active
1511 elsif not Warnings_Off_E1 then
1512 Error_Msg_N
1513 ("??& may be referenced before it has a value!", UR);
1514 end if;
1515 end if;
1517 goto Continue;
1519 end if;
1520 end if;
1522 -- Then check for unreferenced entities. Note that we are only
1523 -- interested in entities whose Referenced flag is not set.
1525 if not Referenced_Check_Spec (E1)
1527 -- If Referenced_As_LHS is set, then that's still interesting
1528 -- (potential "assigned but never read" case), but not if we
1529 -- have pragma Unreferenced, which cancels this warning.
1531 and then (not Referenced_As_LHS_Check_Spec (E1)
1532 or else not Has_Unreferenced (E1))
1534 -- Check that warnings on unreferenced entities are enabled
1536 and then
1537 ((Check_Unreferenced and then not Is_Formal (E1))
1539 -- Case of warning on unreferenced formal
1541 or else (Check_Unreferenced_Formals and then Is_Formal (E1))
1543 -- Case of warning on unread variables modified by an
1544 -- assignment, or an OUT parameter if it is the only one.
1546 or else (Warn_On_Modified_Unread
1547 and then Referenced_As_LHS_Check_Spec (E1))
1549 -- Case of warning on any unread OUT parameter (note such
1550 -- indications are only set if the appropriate warning
1551 -- options were set, so no need to recheck here.)
1553 or else Referenced_As_Out_Parameter_Check_Spec (E1))
1555 -- All other entities, including local packages that cannot be
1556 -- referenced from elsewhere, including those declared within a
1557 -- package body.
1559 and then (Is_Object (E1)
1560 or else Is_Type (E1)
1561 or else Ekind (E1) = E_Label
1562 or else Ekind_In (E1, E_Exception,
1563 E_Named_Integer,
1564 E_Named_Real)
1565 or else Is_Overloadable (E1)
1567 -- Package case, if the main unit is a package spec
1568 -- or generic package spec, then there may be a
1569 -- corresponding body that references this package
1570 -- in some other file. Otherwise we can be sure
1571 -- that there is no other reference.
1573 or else
1574 (Ekind (E1) = E_Package
1575 and then
1576 not Is_Package_Or_Generic_Package
1577 (Cunit_Entity (Current_Sem_Unit))))
1579 -- Exclude instantiations, since there is no reason why every
1580 -- entity in an instantiation should be referenced.
1582 and then Instantiation_Location (Sloc (E1)) = No_Location
1584 -- Exclude formal parameters from bodies if the corresponding
1585 -- spec entity has been referenced in the case where there is
1586 -- a separate spec.
1588 and then not (Is_Formal (E1)
1589 and then Ekind (Scope (E1)) = E_Subprogram_Body
1590 and then Present (Spec_Entity (E1))
1591 and then Referenced (Spec_Entity (E1)))
1593 -- Consider private type referenced if full view is referenced.
1594 -- If there is not full view, this is a generic type on which
1595 -- warnings are also useful.
1597 and then
1598 not (Is_Private_Type (E1)
1599 and then Present (Full_View (E1))
1600 and then Referenced (Full_View (E1)))
1602 -- Don't worry about full view, only about private type
1604 and then not Has_Private_Declaration (E1)
1606 -- Eliminate dispatching operations from consideration, we
1607 -- cannot tell if these are referenced or not in any easy
1608 -- manner (note this also catches Adjust/Finalize/Initialize).
1610 and then not Is_Dispatching_Operation (E1)
1612 -- Check entity that can be publicly referenced (we do not give
1613 -- messages for such entities, since there could be other
1614 -- units, not involved in this compilation, that contain
1615 -- relevant references.
1617 and then not Publicly_Referenceable (E1)
1619 -- Class wide types are marked as source entities, but they are
1620 -- not really source entities, and are always created, so we do
1621 -- not care if they are not referenced.
1623 and then Ekind (E1) /= E_Class_Wide_Type
1625 -- Objects other than parameters of task types are allowed to
1626 -- be non-referenced, since they start up tasks.
1628 and then ((Ekind (E1) /= E_Variable
1629 and then Ekind (E1) /= E_Constant
1630 and then Ekind (E1) /= E_Component)
1631 or else not Is_Task_Type (E1T))
1633 -- For subunits, only place warnings on the main unit itself,
1634 -- since parent units are not completely compiled.
1636 and then (Nkind (Unit (Cunit (Main_Unit))) /= N_Subunit
1637 or else Get_Source_Unit (E1) = Main_Unit)
1639 -- No warning on a return object, because these are often
1640 -- created with a single expression and an implicit return.
1641 -- If the object is a variable there will be a warning
1642 -- indicating that it could be declared constant.
1644 and then not
1645 (Ekind (E1) = E_Constant and then Is_Return_Object (E1))
1646 then
1647 -- Suppress warnings in internal units if not in -gnatg mode
1648 -- (these would be junk warnings for an applications program,
1649 -- since they refer to problems in internal units).
1651 if GNAT_Mode or else not In_Internal_Unit (E1) then
1652 -- We do not immediately flag the error. This is because we
1653 -- have not expanded generic bodies yet, and they may have
1654 -- the missing reference. So instead we park the entity on a
1655 -- list, for later processing. However for the case of an
1656 -- accept statement we want to output messages now, since
1657 -- we know we already have all information at hand, and we
1658 -- also want to have separate warnings for each accept
1659 -- statement for the same entry.
1661 if Present (Anod) then
1662 pragma Assert (Is_Formal (E1));
1664 -- The unreferenced entity is E1, but post the warning
1665 -- on the body entity for this accept statement.
1667 if not Warnings_Off_E1 then
1668 Warn_On_Unreferenced_Entity
1669 (E1, Body_Formal (E1, Accept_Statement => Anod));
1670 end if;
1672 elsif not Warnings_Off_E1
1673 and then not Has_Junk_Name (E1)
1674 then
1675 Unreferenced_Entities.Append (E1);
1676 end if;
1677 end if;
1679 -- Generic units are referenced in the generic body, but if they
1680 -- are not public and never instantiated we want to force a
1681 -- warning on them. We treat them as redundant constructs to
1682 -- minimize noise.
1684 elsif Is_Generic_Subprogram (E1)
1685 and then not Is_Instantiated (E1)
1686 and then not Publicly_Referenceable (E1)
1687 and then Instantiation_Depth (Sloc (E1)) = 0
1688 and then Warn_On_Redundant_Constructs
1689 then
1690 if not Warnings_Off_E1 and then not Has_Junk_Name (E1) then
1691 Unreferenced_Entities.Append (E1);
1693 -- Force warning on entity
1695 Set_Referenced (E1, False);
1696 end if;
1697 end if;
1698 end if;
1700 -- Recurse into nested package or block. Do not recurse into a formal
1701 -- package, because the corresponding body is not analyzed.
1703 <<Continue>>
1704 if (Is_Package_Or_Generic_Package (E1)
1705 and then Nkind (Parent (E1)) = N_Package_Specification
1706 and then
1707 Nkind (Original_Node (Unit_Declaration_Node (E1))) /=
1708 N_Formal_Package_Declaration)
1710 or else Ekind (E1) = E_Block
1711 then
1712 Check_References (E1);
1713 end if;
1715 Next_Entity (E1);
1716 end loop;
1717 end Check_References;
1719 ---------------------------
1720 -- Check_Unset_Reference --
1721 ---------------------------
1723 procedure Check_Unset_Reference (N : Node_Id) is
1724 Typ : constant Entity_Id := Etype (N);
1726 function Is_OK_Fully_Initialized return Boolean;
1727 -- This function returns true if the given node N is fully initialized
1728 -- so that the reference is safe as far as this routine is concerned.
1729 -- Safe generally means that the type of N is a fully initialized type.
1730 -- The one special case is that for access types, which are always fully
1731 -- initialized, we don't consider a dereference OK since it will surely
1732 -- be dereferencing a null value, which won't do.
1734 function Prefix_Has_Dereference (Pref : Node_Id) return Boolean;
1735 -- Used to test indexed or selected component or slice to see if the
1736 -- evaluation of the prefix depends on a dereference, and if so, returns
1737 -- True, in which case we always check the prefix, even if we know that
1738 -- the referenced component is initialized. Pref is the prefix to test.
1740 -----------------------------
1741 -- Is_OK_Fully_Initialized --
1742 -----------------------------
1744 function Is_OK_Fully_Initialized return Boolean is
1745 begin
1746 if Is_Access_Type (Typ) and then Is_Dereferenced (N) then
1747 return False;
1749 -- A type subject to pragma Default_Initial_Condition may be fully
1750 -- default initialized depending on inheritance and the argument of
1751 -- the pragma (SPARK RM 3.1 and SPARK RM 7.3.3).
1753 elsif Has_Fully_Default_Initializing_DIC_Pragma (Typ) then
1754 return True;
1756 else
1757 return Is_Fully_Initialized_Type (Typ);
1758 end if;
1759 end Is_OK_Fully_Initialized;
1761 ----------------------------
1762 -- Prefix_Has_Dereference --
1763 ----------------------------
1765 function Prefix_Has_Dereference (Pref : Node_Id) return Boolean is
1766 begin
1767 -- If prefix is of an access type, it certainly needs a dereference
1769 if Is_Access_Type (Etype (Pref)) then
1770 return True;
1772 -- If prefix is explicit dereference, that's a dereference for sure
1774 elsif Nkind (Pref) = N_Explicit_Dereference then
1775 return True;
1777 -- If prefix is itself a component reference or slice check prefix
1779 elsif Nkind (Pref) = N_Slice
1780 or else Nkind (Pref) = N_Indexed_Component
1781 or else Nkind (Pref) = N_Selected_Component
1782 then
1783 return Prefix_Has_Dereference (Prefix (Pref));
1785 -- All other cases do not involve a dereference
1787 else
1788 return False;
1789 end if;
1790 end Prefix_Has_Dereference;
1792 -- Start of processing for Check_Unset_Reference
1794 begin
1795 -- Nothing to do if warnings suppressed
1797 if Warning_Mode = Suppress then
1798 return;
1799 end if;
1801 -- Nothing to do for numeric or string literal. Do this test early to
1802 -- save time in a common case (it does not matter that we do not include
1803 -- character literal here, since that will be caught later on in the
1804 -- when others branch of the case statement).
1806 if Nkind (N) in N_Numeric_Or_String_Literal then
1807 return;
1808 end if;
1810 -- Ignore reference unless it comes from source. Almost always if we
1811 -- have a reference from generated code, it is bogus (e.g. calls to init
1812 -- procs to set default discriminant values).
1814 if not Comes_From_Source (N) then
1815 return;
1816 end if;
1818 -- Otherwise see what kind of node we have. If the entity already has an
1819 -- unset reference, it is not necessarily the earliest in the text,
1820 -- because resolution of the prefix of selected components is completed
1821 -- before the resolution of the selected component itself. As a result,
1822 -- given (R /= null and then R.X > 0), the occurrences of R are examined
1823 -- in right-to-left order. If there is already an unset reference, we
1824 -- check whether N is earlier before proceeding.
1826 case Nkind (N) is
1828 -- For identifier or expanded name, examine the entity involved
1830 when N_Expanded_Name
1831 | N_Identifier
1833 declare
1834 E : constant Entity_Id := Entity (N);
1836 begin
1837 if Ekind_In (E, E_Variable, E_Out_Parameter)
1838 and then Never_Set_In_Source_Check_Spec (E)
1839 and then not Has_Initial_Value (E)
1840 and then (No (Unset_Reference (E))
1841 or else
1842 Earlier_In_Extended_Unit
1843 (Sloc (N), Sloc (Unset_Reference (E))))
1844 and then not Has_Pragma_Unmodified_Check_Spec (E)
1845 and then not Warnings_Off_Check_Spec (E)
1846 and then not Has_Junk_Name (E)
1847 then
1848 -- We may have an unset reference. The first test is whether
1849 -- this is an access to a discriminant of a record or a
1850 -- component with default initialization. Both of these
1851 -- cases can be ignored, since the actual object that is
1852 -- referenced is definitely initialized. Note that this
1853 -- covers the case of reading discriminants of an OUT
1854 -- parameter, which is OK even in Ada 83.
1856 -- Note that we are only interested in a direct reference to
1857 -- a record component here. If the reference is through an
1858 -- access type, then the access object is being referenced,
1859 -- not the record, and still deserves an unset reference.
1861 if Nkind (Parent (N)) = N_Selected_Component
1862 and not Is_Access_Type (Typ)
1863 then
1864 declare
1865 ES : constant Entity_Id :=
1866 Entity (Selector_Name (Parent (N)));
1867 begin
1868 if Ekind (ES) = E_Discriminant
1869 or else
1870 (Present (Declaration_Node (ES))
1871 and then
1872 Present (Expression (Declaration_Node (ES))))
1873 then
1874 return;
1875 end if;
1876 end;
1877 end if;
1879 -- Exclude fully initialized types
1881 if Is_OK_Fully_Initialized then
1882 return;
1883 end if;
1885 -- Here we have a potential unset reference. But before we
1886 -- get worried about it, we have to make sure that the
1887 -- entity declaration is in the same procedure as the
1888 -- reference, since if they are in separate procedures, then
1889 -- we have no idea about sequential execution.
1891 -- The tests in the loop below catch all such cases, but do
1892 -- allow the reference to appear in a loop, block, or
1893 -- package spec that is nested within the declaring scope.
1894 -- As always, it is possible to construct cases where the
1895 -- warning is wrong, that is why it is a warning.
1897 Potential_Unset_Reference : declare
1898 SR : Entity_Id;
1899 SE : constant Entity_Id := Scope (E);
1901 function Within_Postcondition return Boolean;
1902 -- Returns True if N is within a Postcondition, a
1903 -- Refined_Post, an Ensures component in a Test_Case,
1904 -- or a Contract_Cases.
1906 --------------------------
1907 -- Within_Postcondition --
1908 --------------------------
1910 function Within_Postcondition return Boolean is
1911 Nod, P : Node_Id;
1913 begin
1914 Nod := Parent (N);
1915 while Present (Nod) loop
1916 if Nkind (Nod) = N_Pragma
1917 and then Nam_In (Pragma_Name_Unmapped (Nod),
1918 Name_Postcondition,
1919 Name_Refined_Post,
1920 Name_Contract_Cases)
1921 then
1922 return True;
1924 elsif Present (Parent (Nod)) then
1925 P := Parent (Nod);
1927 if Nkind (P) = N_Pragma
1928 and then Pragma_Name (P) =
1929 Name_Test_Case
1930 and then Nod = Test_Case_Arg (P, Name_Ensures)
1931 then
1932 return True;
1933 end if;
1934 end if;
1936 Nod := Parent (Nod);
1937 end loop;
1939 return False;
1940 end Within_Postcondition;
1942 -- Start of processing for Potential_Unset_Reference
1944 begin
1945 SR := Current_Scope;
1946 while SR /= SE loop
1947 if SR = Standard_Standard
1948 or else Is_Subprogram (SR)
1949 or else Is_Concurrent_Body (SR)
1950 or else Is_Concurrent_Type (SR)
1951 then
1952 return;
1953 end if;
1955 SR := Scope (SR);
1956 end loop;
1958 -- Case of reference has an access type. This is a
1959 -- special case since access types are always set to null
1960 -- so cannot be truly uninitialized, but we still want to
1961 -- warn about cases of obvious null dereference.
1963 if Is_Access_Type (Typ) then
1964 Access_Type_Case : declare
1965 P : Node_Id;
1967 function Process
1968 (N : Node_Id) return Traverse_Result;
1969 -- Process function for instantiation of Traverse
1970 -- below. Checks if N contains reference to E other
1971 -- than a dereference.
1973 function Ref_In (Nod : Node_Id) return Boolean;
1974 -- Determines whether Nod contains a reference to
1975 -- the entity E that is not a dereference.
1977 -------------
1978 -- Process --
1979 -------------
1981 function Process
1982 (N : Node_Id) return Traverse_Result
1984 begin
1985 if Is_Entity_Name (N)
1986 and then Entity (N) = E
1987 and then not Is_Dereferenced (N)
1988 then
1989 return Abandon;
1990 else
1991 return OK;
1992 end if;
1993 end Process;
1995 ------------
1996 -- Ref_In --
1997 ------------
1999 function Ref_In (Nod : Node_Id) return Boolean is
2000 function Traverse is new Traverse_Func (Process);
2001 begin
2002 return Traverse (Nod) = Abandon;
2003 end Ref_In;
2005 -- Start of processing for Access_Type_Case
2007 begin
2008 -- Don't bother if we are inside an instance, since
2009 -- the compilation of the generic template is where
2010 -- the warning should be issued.
2012 if In_Instance then
2013 return;
2014 end if;
2016 -- Don't bother if this is not the main unit. If we
2017 -- try to give this warning for with'ed units, we
2018 -- get some false positives, since we do not record
2019 -- references in other units.
2021 if not In_Extended_Main_Source_Unit (E)
2022 or else
2023 not In_Extended_Main_Source_Unit (N)
2024 then
2025 return;
2026 end if;
2028 -- We are only interested in dereferences
2030 if not Is_Dereferenced (N) then
2031 return;
2032 end if;
2034 -- One more check, don't bother with references
2035 -- that are inside conditional statements or WHILE
2036 -- loops if the condition references the entity in
2037 -- question. This avoids most false positives.
2039 P := Parent (N);
2040 loop
2041 P := Parent (P);
2042 exit when No (P);
2044 if Nkind_In (P, N_If_Statement, N_Elsif_Part)
2045 and then Ref_In (Condition (P))
2046 then
2047 return;
2049 elsif Nkind (P) = N_Loop_Statement
2050 and then Present (Iteration_Scheme (P))
2051 and then
2052 Ref_In (Condition (Iteration_Scheme (P)))
2053 then
2054 return;
2055 end if;
2056 end loop;
2057 end Access_Type_Case;
2058 end if;
2060 -- One more check, don't bother if we are within a
2061 -- postcondition, since the expression occurs in a
2062 -- place unrelated to the actual test.
2064 if not Within_Postcondition then
2066 -- Here we definitely have a case for giving a warning
2067 -- for a reference to an unset value. But we don't
2068 -- give the warning now. Instead set Unset_Reference
2069 -- in the identifier involved. The reason for this is
2070 -- that if we find the variable is never ever assigned
2071 -- a value then that warning is more important and
2072 -- there is no point in giving the reference warning.
2074 -- If this is an identifier, set the field directly
2076 if Nkind (N) = N_Identifier then
2077 Set_Unset_Reference (E, N);
2079 -- Otherwise it is an expanded name, so set the field
2080 -- of the actual identifier for the reference.
2082 else
2083 Set_Unset_Reference (E, Selector_Name (N));
2084 end if;
2085 end if;
2086 end Potential_Unset_Reference;
2087 end if;
2088 end;
2090 -- Indexed component or slice
2092 when N_Indexed_Component
2093 | N_Slice
2095 -- If prefix does not involve dereferencing an access type, then
2096 -- we know we are OK if the component type is fully initialized,
2097 -- since the component will have been set as part of the default
2098 -- initialization.
2100 if not Prefix_Has_Dereference (Prefix (N))
2101 and then Is_OK_Fully_Initialized
2102 then
2103 return;
2105 -- Look at prefix in access type case, or if the component is not
2106 -- fully initialized.
2108 else
2109 Check_Unset_Reference (Prefix (N));
2110 end if;
2112 -- Record component
2114 when N_Selected_Component =>
2115 declare
2116 Pref : constant Node_Id := Prefix (N);
2117 Ent : constant Entity_Id := Entity (Selector_Name (N));
2119 begin
2120 -- If prefix involves dereferencing an access type, always
2121 -- check the prefix, since the issue then is whether this
2122 -- access value is null.
2124 if Prefix_Has_Dereference (Pref) then
2125 null;
2127 -- Always go to prefix if no selector entity is set. Can this
2128 -- happen in the normal case? Not clear, but it definitely can
2129 -- happen in error cases.
2131 elsif No (Ent) then
2132 null;
2134 -- For a record component, check some cases where we have
2135 -- reasonable cause to consider that the component is known to
2136 -- be or probably is initialized. In this case, we don't care
2137 -- if the prefix itself was explicitly initialized.
2139 -- Discriminants are always considered initialized
2141 elsif Ekind (Ent) = E_Discriminant then
2142 return;
2144 -- An explicitly initialized component is certainly initialized
2146 elsif Nkind (Parent (Ent)) = N_Component_Declaration
2147 and then Present (Expression (Parent (Ent)))
2148 then
2149 return;
2151 -- A fully initialized component is initialized
2153 elsif Is_OK_Fully_Initialized then
2154 return;
2155 end if;
2157 -- If none of those cases apply, check the record type prefix
2159 Check_Unset_Reference (Pref);
2160 end;
2162 -- For type conversions, qualifications, or expressions with actions,
2163 -- examine the expression.
2165 when N_Expression_With_Actions
2166 | N_Qualified_Expression
2167 | N_Type_Conversion
2169 Check_Unset_Reference (Expression (N));
2171 -- For explicit dereference, always check prefix, which will generate
2172 -- an unset reference (since this is a case of dereferencing null).
2174 when N_Explicit_Dereference =>
2175 Check_Unset_Reference (Prefix (N));
2177 -- All other cases are not cases of an unset reference
2179 when others =>
2180 null;
2181 end case;
2182 end Check_Unset_Reference;
2184 ------------------------
2185 -- Check_Unused_Withs --
2186 ------------------------
2188 procedure Check_Unused_Withs (Spec_Unit : Unit_Number_Type := No_Unit) is
2189 Cnode : Node_Id;
2190 Item : Node_Id;
2191 Lunit : Node_Id;
2192 Ent : Entity_Id;
2194 Munite : constant Entity_Id := Cunit_Entity (Main_Unit);
2195 -- This is needed for checking the special renaming case
2197 procedure Check_One_Unit (Unit : Unit_Number_Type);
2198 -- Subsidiary procedure, performs checks for specified unit
2200 --------------------
2201 -- Check_One_Unit --
2202 --------------------
2204 procedure Check_One_Unit (Unit : Unit_Number_Type) is
2205 Is_Visible_Renaming : Boolean := False;
2206 Pack : Entity_Id;
2208 procedure Check_Inner_Package (Pack : Entity_Id);
2209 -- Pack is a package local to a unit in a with_clause. Both the unit
2210 -- and Pack are referenced. If none of the entities in Pack are
2211 -- referenced, then the only occurrence of Pack is in a USE clause
2212 -- or a pragma, and a warning is worthwhile as well.
2214 function Check_System_Aux return Boolean;
2215 -- Before giving a warning on a with_clause for System, check whether
2216 -- a system extension is present.
2218 function Find_Package_Renaming
2219 (P : Entity_Id;
2220 L : Entity_Id) return Entity_Id;
2221 -- The only reference to a context unit may be in a renaming
2222 -- declaration. If this renaming declares a visible entity, do not
2223 -- warn that the context clause could be moved to the body, because
2224 -- the renaming may be intended to re-export the unit.
2226 function Has_Visible_Entities (P : Entity_Id) return Boolean;
2227 -- This function determines if a package has any visible entities.
2228 -- True is returned if there is at least one declared visible entity,
2229 -- otherwise False is returned (e.g. case of only pragmas present).
2231 -------------------------
2232 -- Check_Inner_Package --
2233 -------------------------
2235 procedure Check_Inner_Package (Pack : Entity_Id) is
2236 E : Entity_Id;
2237 Un : constant Node_Id := Sinfo.Unit (Cnode);
2239 function Check_Use_Clause (N : Node_Id) return Traverse_Result;
2240 -- If N is a use_clause for Pack, emit warning
2242 procedure Check_Use_Clauses is new
2243 Traverse_Proc (Check_Use_Clause);
2245 ----------------------
2246 -- Check_Use_Clause --
2247 ----------------------
2249 function Check_Use_Clause (N : Node_Id) return Traverse_Result is
2250 begin
2251 if Nkind (N) = N_Use_Package_Clause
2252 and then Entity (Name (N)) = Pack
2253 then
2254 -- Suppress message if any serious errors detected that turn
2255 -- off expansion, and thus result in false positives for
2256 -- this warning.
2258 if Serious_Errors_Detected = 0 then
2259 Error_Msg_Qual_Level := 1;
2260 Error_Msg_NE -- CODEFIX
2261 ("?u?no entities of package& are referenced!",
2262 Name (N), Pack);
2263 Error_Msg_Qual_Level := 0;
2264 end if;
2265 end if;
2267 return OK;
2268 end Check_Use_Clause;
2270 -- Start of processing for Check_Inner_Package
2272 begin
2273 E := First_Entity (Pack);
2274 while Present (E) loop
2275 if Referenced_Check_Spec (E) then
2276 return;
2277 end if;
2279 Next_Entity (E);
2280 end loop;
2282 -- No entities of the package are referenced. Check whether the
2283 -- reference to the package itself is a use clause, and if so
2284 -- place a warning on it.
2286 Check_Use_Clauses (Un);
2287 end Check_Inner_Package;
2289 ----------------------
2290 -- Check_System_Aux --
2291 ----------------------
2293 function Check_System_Aux return Boolean is
2294 Ent : Entity_Id;
2296 begin
2297 if Chars (Lunit) = Name_System
2298 and then Scope (Lunit) = Standard_Standard
2299 and then Present_System_Aux
2300 then
2301 Ent := First_Entity (System_Aux_Id);
2302 while Present (Ent) loop
2303 if Referenced_Check_Spec (Ent) then
2304 return True;
2305 end if;
2307 Next_Entity (Ent);
2308 end loop;
2309 end if;
2311 return False;
2312 end Check_System_Aux;
2314 ---------------------------
2315 -- Find_Package_Renaming --
2316 ---------------------------
2318 function Find_Package_Renaming
2319 (P : Entity_Id;
2320 L : Entity_Id) return Entity_Id
2322 E1 : Entity_Id;
2323 R : Entity_Id;
2325 begin
2326 Is_Visible_Renaming := False;
2328 E1 := First_Entity (P);
2329 while Present (E1) loop
2330 if Ekind (E1) = E_Package and then Renamed_Object (E1) = L then
2331 Is_Visible_Renaming := not Is_Hidden (E1);
2332 return E1;
2334 elsif Ekind (E1) = E_Package
2335 and then No (Renamed_Object (E1))
2336 and then not Is_Generic_Instance (E1)
2337 then
2338 R := Find_Package_Renaming (E1, L);
2340 if Present (R) then
2341 Is_Visible_Renaming := not Is_Hidden (R);
2342 return R;
2343 end if;
2344 end if;
2346 Next_Entity (E1);
2347 end loop;
2349 return Empty;
2350 end Find_Package_Renaming;
2352 --------------------------
2353 -- Has_Visible_Entities --
2354 --------------------------
2356 function Has_Visible_Entities (P : Entity_Id) return Boolean is
2357 E : Entity_Id;
2359 begin
2360 -- If unit in context is not a package, it is a subprogram that
2361 -- is not called or a generic unit that is not instantiated
2362 -- in the current unit, and warning is appropriate.
2364 if Ekind (P) /= E_Package then
2365 return True;
2366 end if;
2368 -- If unit comes from a limited_with clause, look for declaration
2369 -- of shadow entities.
2371 if Present (Limited_View (P)) then
2372 E := First_Entity (Limited_View (P));
2373 else
2374 E := First_Entity (P);
2375 end if;
2377 while Present (E) and then E /= First_Private_Entity (P) loop
2378 if Comes_From_Source (E) or else Present (Limited_View (P)) then
2379 return True;
2380 end if;
2382 Next_Entity (E);
2383 end loop;
2385 return False;
2386 end Has_Visible_Entities;
2388 -- Start of processing for Check_One_Unit
2390 begin
2391 Cnode := Cunit (Unit);
2393 -- Only do check in units that are part of the extended main unit.
2394 -- This is actually a necessary restriction, because in the case of
2395 -- subprogram acting as its own specification, there can be with's in
2396 -- subunits that we will not see.
2398 if not In_Extended_Main_Source_Unit (Cnode) then
2399 return;
2400 end if;
2402 -- Loop through context items in this unit
2404 Item := First (Context_Items (Cnode));
2405 while Present (Item) loop
2406 if Nkind (Item) = N_With_Clause
2407 and then not Implicit_With (Item)
2408 and then In_Extended_Main_Source_Unit (Item)
2410 -- Guard for no entity present. Not clear under what conditions
2411 -- this happens, but it does occur, and since this is only a
2412 -- warning, we just suppress the warning in this case.
2414 and then Nkind (Name (Item)) in N_Has_Entity
2415 and then Present (Entity (Name (Item)))
2416 then
2417 Lunit := Entity (Name (Item));
2419 -- Check if this unit is referenced (skip the check if this
2420 -- is explicitly marked by a pragma Unreferenced).
2422 if not Referenced (Lunit) and then not Has_Unreferenced (Lunit)
2423 then
2424 -- Suppress warnings in internal units if not in -gnatg mode
2425 -- (these would be junk warnings for an application program,
2426 -- since they refer to problems in internal units).
2428 if GNAT_Mode or else not Is_Internal_Unit (Unit) then
2429 -- Here we definitely have a non-referenced unit. If it
2430 -- is the special call for a spec unit, then just set the
2431 -- flag to be read later.
2433 if Unit = Spec_Unit then
2434 Set_Unreferenced_In_Spec (Item);
2436 -- Otherwise simple unreferenced message, but skip this
2437 -- if no visible entities, because that is most likely a
2438 -- case where warning would be false positive (e.g. a
2439 -- package with only a linker options pragma and nothing
2440 -- else or a pragma elaborate with a body library task).
2442 elsif Has_Visible_Entities (Entity (Name (Item))) then
2443 Error_Msg_N -- CODEFIX
2444 ("?u?unit& is not referenced!", Name (Item));
2445 end if;
2446 end if;
2448 -- If main unit is a renaming of this unit, then we consider
2449 -- the with to be OK (obviously it is needed in this case).
2450 -- This may be transitive: the unit in the with_clause may
2451 -- itself be a renaming, in which case both it and the main
2452 -- unit rename the same ultimate package.
2454 elsif Present (Renamed_Entity (Munite))
2455 and then
2456 (Renamed_Entity (Munite) = Lunit
2457 or else Renamed_Entity (Munite) = Renamed_Entity (Lunit))
2458 then
2459 null;
2461 -- If this unit is referenced, and it is a package, we do
2462 -- another test, to see if any of the entities in the package
2463 -- are referenced. If none of the entities are referenced, we
2464 -- still post a warning. This occurs if the only use of the
2465 -- package is in a use clause, or in a package renaming
2466 -- declaration. This check is skipped for packages that are
2467 -- renamed in a spec, since the entities in such a package are
2468 -- visible to clients via the renaming.
2470 elsif Ekind (Lunit) = E_Package
2471 and then not Renamed_In_Spec (Lunit)
2472 then
2473 -- If Is_Instantiated is set, it means that the package is
2474 -- implicitly instantiated (this is the case of parent
2475 -- instance or an actual for a generic package formal), and
2476 -- this counts as a reference.
2478 if Is_Instantiated (Lunit) then
2479 null;
2481 -- If no entities in package, and there is a pragma
2482 -- Elaborate_Body present, then assume that this with is
2483 -- done for purposes of this elaboration.
2485 elsif No (First_Entity (Lunit))
2486 and then Has_Pragma_Elaborate_Body (Lunit)
2487 then
2488 null;
2490 -- Otherwise see if any entities have been referenced
2492 else
2493 if Limited_Present (Item) then
2494 Ent := First_Entity (Limited_View (Lunit));
2495 else
2496 Ent := First_Entity (Lunit);
2497 end if;
2499 loop
2500 -- No more entities, and we did not find one that was
2501 -- referenced. Means we have a definite case of a with
2502 -- none of whose entities was referenced.
2504 if No (Ent) then
2506 -- If in spec, just set the flag
2508 if Unit = Spec_Unit then
2509 Set_No_Entities_Ref_In_Spec (Item);
2511 elsif Check_System_Aux then
2512 null;
2514 -- Else the warning may be needed
2516 else
2517 declare
2518 Eitem : constant Entity_Id :=
2519 Entity (Name (Item));
2521 begin
2522 -- Warn if we unreferenced flag set and we
2523 -- have not had serious errors. The reason we
2524 -- inhibit the message if there are errors is
2525 -- to prevent false positives from disabling
2526 -- expansion.
2528 if not Has_Unreferenced (Eitem)
2529 and then Serious_Errors_Detected = 0
2530 then
2531 -- Get possible package renaming
2533 Pack :=
2534 Find_Package_Renaming (Munite, Lunit);
2536 -- No warning if either the package or its
2537 -- renaming is used as a generic actual.
2539 if Used_As_Generic_Actual (Eitem)
2540 or else
2541 (Present (Pack)
2542 and then
2543 Used_As_Generic_Actual (Pack))
2544 then
2545 exit;
2546 end if;
2548 -- Here we give the warning
2550 Error_Msg_N -- CODEFIX
2551 ("?u?no entities of & are referenced!",
2552 Name (Item));
2554 -- Flag renaming of package as well. If
2555 -- the original package has warnings off,
2556 -- we suppress the warning on the renaming
2557 -- as well.
2559 if Present (Pack)
2560 and then not Has_Warnings_Off (Lunit)
2561 and then not Has_Unreferenced (Pack)
2562 then
2563 Error_Msg_NE -- CODEFIX
2564 ("?u?no entities of& are referenced!",
2565 Unit_Declaration_Node (Pack), Pack);
2566 end if;
2567 end if;
2568 end;
2569 end if;
2571 exit;
2573 -- Case of entity being referenced. The reference may
2574 -- come from a limited_with_clause, in which case the
2575 -- limited view of the entity carries the flag.
2577 elsif Referenced_Check_Spec (Ent)
2578 or else Referenced_As_LHS_Check_Spec (Ent)
2579 or else Referenced_As_Out_Parameter_Check_Spec (Ent)
2580 or else
2581 (From_Limited_With (Ent)
2582 and then Is_Incomplete_Type (Ent)
2583 and then Present (Non_Limited_View (Ent))
2584 and then Referenced (Non_Limited_View (Ent)))
2585 then
2586 -- This means that the with is indeed fine, in that
2587 -- it is definitely needed somewhere, and we can
2588 -- quit worrying about this one...
2590 -- Except for one little detail: if either of the
2591 -- flags was set during spec processing, this is
2592 -- where we complain that the with could be moved
2593 -- from the spec. If the spec contains a visible
2594 -- renaming of the package, inhibit warning to move
2595 -- with_clause to body.
2597 if Ekind (Munite) = E_Package_Body then
2598 Pack :=
2599 Find_Package_Renaming
2600 (Spec_Entity (Munite), Lunit);
2601 else
2602 Pack := Empty;
2603 end if;
2605 -- If a renaming is present in the spec do not warn
2606 -- because the body or child unit may depend on it.
2608 if Present (Pack)
2609 and then Renamed_Entity (Pack) = Lunit
2610 then
2611 exit;
2613 elsif Unreferenced_In_Spec (Item) then
2614 Error_Msg_N -- CODEFIX
2615 ("?u?unit& is not referenced in spec!",
2616 Name (Item));
2618 elsif No_Entities_Ref_In_Spec (Item) then
2619 Error_Msg_N -- CODEFIX
2620 ("?u?no entities of & are referenced in spec!",
2621 Name (Item));
2623 else
2624 if Ekind (Ent) = E_Package then
2625 Check_Inner_Package (Ent);
2626 end if;
2628 exit;
2629 end if;
2631 if not Is_Visible_Renaming then
2632 Error_Msg_N -- CODEFIX
2633 ("\?u?with clause might be moved to body!",
2634 Name (Item));
2635 end if;
2637 exit;
2639 -- Move to next entity to continue search
2641 else
2642 Next_Entity (Ent);
2643 end if;
2644 end loop;
2645 end if;
2647 -- For a generic package, the only interesting kind of
2648 -- reference is an instantiation, since entities cannot be
2649 -- referenced directly.
2651 elsif Is_Generic_Unit (Lunit) then
2653 -- Unit was never instantiated, set flag for case of spec
2654 -- call, or give warning for normal call.
2656 if not Is_Instantiated (Lunit) then
2657 if Unit = Spec_Unit then
2658 Set_Unreferenced_In_Spec (Item);
2659 else
2660 Error_Msg_N -- CODEFIX
2661 ("?u?unit& is never instantiated!", Name (Item));
2662 end if;
2664 -- If unit was indeed instantiated, make sure that flag is
2665 -- not set showing it was uninstantiated in the spec, and if
2666 -- so, give warning.
2668 elsif Unreferenced_In_Spec (Item) then
2669 Error_Msg_N
2670 ("?u?unit& is not instantiated in spec!", Name (Item));
2671 Error_Msg_N -- CODEFIX
2672 ("\?u?with clause can be moved to body!", Name (Item));
2673 end if;
2674 end if;
2675 end if;
2677 Next (Item);
2678 end loop;
2679 end Check_One_Unit;
2681 -- Start of processing for Check_Unused_Withs
2683 begin
2684 -- Immediate return if no semantics or warning flag not set
2686 if not Opt.Check_Withs or else Operating_Mode = Check_Syntax then
2687 return;
2688 end if;
2690 Process_Deferred_References;
2692 -- Flag any unused with clauses. For a subunit, check only the units
2693 -- in its context, not those of the parent, which may be needed by other
2694 -- subunits. We will get the full warnings when we compile the parent,
2695 -- but the following is helpful when compiling a subunit by itself.
2697 if Nkind (Unit (Cunit (Main_Unit))) = N_Subunit then
2698 if Current_Sem_Unit = Main_Unit then
2699 Check_One_Unit (Main_Unit);
2700 end if;
2702 return;
2703 end if;
2705 -- Process specified units
2707 if Spec_Unit = No_Unit then
2709 -- For main call, check all units
2711 for Unit in Main_Unit .. Last_Unit loop
2712 Check_One_Unit (Unit);
2713 end loop;
2715 else
2716 -- For call for spec, check only the spec
2718 Check_One_Unit (Spec_Unit);
2719 end if;
2720 end Check_Unused_Withs;
2722 ---------------------------------
2723 -- Generic_Package_Spec_Entity --
2724 ---------------------------------
2726 function Generic_Package_Spec_Entity (E : Entity_Id) return Boolean is
2727 S : Entity_Id;
2729 begin
2730 if Is_Package_Body_Entity (E) then
2731 return False;
2733 else
2734 S := Scope (E);
2735 loop
2736 if S = Standard_Standard then
2737 return False;
2739 elsif Ekind (S) = E_Generic_Package then
2740 return True;
2742 elsif Ekind (S) = E_Package then
2743 S := Scope (S);
2745 else
2746 return False;
2747 end if;
2748 end loop;
2749 end if;
2750 end Generic_Package_Spec_Entity;
2752 ----------------------
2753 -- Goto_Spec_Entity --
2754 ----------------------
2756 function Goto_Spec_Entity (E : Entity_Id) return Entity_Id is
2757 begin
2758 if Is_Formal (E) and then Present (Spec_Entity (E)) then
2759 return Spec_Entity (E);
2760 else
2761 return E;
2762 end if;
2763 end Goto_Spec_Entity;
2765 -------------------
2766 -- Has_Junk_Name --
2767 -------------------
2769 function Has_Junk_Name (E : Entity_Id) return Boolean is
2770 function Match (S : String) return Boolean;
2771 -- Return true if substring S is found in Name_Buffer (1 .. Name_Len)
2773 -----------
2774 -- Match --
2775 -----------
2777 function Match (S : String) return Boolean is
2778 Slen1 : constant Integer := S'Length - 1;
2780 begin
2781 for J in 1 .. Name_Len - S'Length + 1 loop
2782 if Name_Buffer (J .. J + Slen1) = S then
2783 return True;
2784 end if;
2785 end loop;
2787 return False;
2788 end Match;
2790 -- Start of processing for Has_Junk_Name
2792 begin
2793 Get_Unqualified_Decoded_Name_String (Chars (E));
2795 return
2796 Match ("discard") or else
2797 Match ("dummy") or else
2798 Match ("ignore") or else
2799 Match ("junk") or else
2800 Match ("unused");
2801 end Has_Junk_Name;
2803 --------------------------------------
2804 -- Has_Pragma_Unmodified_Check_Spec --
2805 --------------------------------------
2807 function Has_Pragma_Unmodified_Check_Spec
2808 (E : Entity_Id) return Boolean
2810 begin
2811 if Is_Formal (E) and then Present (Spec_Entity (E)) then
2813 -- Note: use of OR instead of OR ELSE here is deliberate, we want
2814 -- to mess with Unmodified flags on both body and spec entities.
2815 -- Has_Unmodified has side effects!
2817 return Has_Unmodified (E)
2819 Has_Unmodified (Spec_Entity (E));
2821 else
2822 return Has_Unmodified (E);
2823 end if;
2824 end Has_Pragma_Unmodified_Check_Spec;
2826 ----------------------------------------
2827 -- Has_Pragma_Unreferenced_Check_Spec --
2828 ----------------------------------------
2830 function Has_Pragma_Unreferenced_Check_Spec
2831 (E : Entity_Id) return Boolean
2833 begin
2834 if Is_Formal (E) and then Present (Spec_Entity (E)) then
2836 -- Note: use of OR here instead of OR ELSE is deliberate, we want
2837 -- to mess with flags on both entities.
2839 return Has_Unreferenced (E)
2841 Has_Unreferenced (Spec_Entity (E));
2843 else
2844 return Has_Unreferenced (E);
2845 end if;
2846 end Has_Pragma_Unreferenced_Check_Spec;
2848 ----------------
2849 -- Initialize --
2850 ----------------
2852 procedure Initialize is
2853 begin
2854 Warnings_Off_Pragmas.Init;
2855 Unreferenced_Entities.Init;
2856 In_Out_Warnings.Init;
2857 end Initialize;
2859 ---------------------------------------------
2860 -- Is_Attribute_And_Known_Value_Comparison --
2861 ---------------------------------------------
2863 function Is_Attribute_And_Known_Value_Comparison
2864 (Op : Node_Id) return Boolean
2866 Orig_Op : constant Node_Id := Original_Node (Op);
2868 begin
2869 return
2870 Nkind (Orig_Op) in N_Op_Compare
2871 and then Nkind (Original_Node (Left_Opnd (Orig_Op))) =
2872 N_Attribute_Reference
2873 and then Compile_Time_Known_Value (Right_Opnd (Orig_Op));
2874 end Is_Attribute_And_Known_Value_Comparison;
2876 ------------------------------------
2877 -- Never_Set_In_Source_Check_Spec --
2878 ------------------------------------
2880 function Never_Set_In_Source_Check_Spec (E : Entity_Id) return Boolean is
2881 begin
2882 if Is_Formal (E) and then Present (Spec_Entity (E)) then
2883 return Never_Set_In_Source (E)
2884 and then
2885 Never_Set_In_Source (Spec_Entity (E));
2886 else
2887 return Never_Set_In_Source (E);
2888 end if;
2889 end Never_Set_In_Source_Check_Spec;
2891 -------------------------------------
2892 -- Operand_Has_Warnings_Suppressed --
2893 -------------------------------------
2895 function Operand_Has_Warnings_Suppressed (N : Node_Id) return Boolean is
2897 function Check_For_Warnings (N : Node_Id) return Traverse_Result;
2898 -- Function used to check one node to see if it is or was originally
2899 -- a reference to an entity for which Warnings are off. If so, Abandon
2900 -- is returned, otherwise OK_Orig is returned to continue the traversal
2901 -- of the original expression.
2903 function Traverse is new Traverse_Func (Check_For_Warnings);
2904 -- Function used to traverse tree looking for warnings
2906 ------------------------
2907 -- Check_For_Warnings --
2908 ------------------------
2910 function Check_For_Warnings (N : Node_Id) return Traverse_Result is
2911 R : constant Node_Id := Original_Node (N);
2913 begin
2914 if Nkind (R) in N_Has_Entity
2915 and then Present (Entity (R))
2916 and then Has_Warnings_Off (Entity (R))
2917 then
2918 return Abandon;
2919 else
2920 return OK_Orig;
2921 end if;
2922 end Check_For_Warnings;
2924 -- Start of processing for Operand_Has_Warnings_Suppressed
2926 begin
2927 return Traverse (N) = Abandon;
2929 -- If any exception occurs, then something has gone wrong, and this is
2930 -- only a minor aesthetic issue anyway, so just say we did not find what
2931 -- we are looking for, rather than blow up.
2933 exception
2934 when others =>
2935 return False;
2936 end Operand_Has_Warnings_Suppressed;
2938 -----------------------------------------
2939 -- Output_Non_Modified_In_Out_Warnings --
2940 -----------------------------------------
2942 procedure Output_Non_Modified_In_Out_Warnings is
2944 function No_Warn_On_In_Out (E : Entity_Id) return Boolean;
2945 -- Given a formal parameter entity E, determines if there is a reason to
2946 -- suppress IN OUT warnings (not modified, could be IN) for formals of
2947 -- the subprogram. We suppress these warnings if Warnings Off is set, or
2948 -- if we have seen the address of the subprogram being taken, or if the
2949 -- subprogram is used as a generic actual (in the latter cases the
2950 -- context may force use of IN OUT, even if the parameter is not
2951 -- modifies for this particular case.
2953 -----------------------
2954 -- No_Warn_On_In_Out --
2955 -----------------------
2957 function No_Warn_On_In_Out (E : Entity_Id) return Boolean is
2958 S : constant Entity_Id := Scope (E);
2959 SE : constant Entity_Id := Spec_Entity (E);
2961 begin
2962 -- Do not warn if address is taken, since funny business may be going
2963 -- on in treating the parameter indirectly as IN OUT.
2965 if Address_Taken (S)
2966 or else (Present (SE) and then Address_Taken (Scope (SE)))
2967 then
2968 return True;
2970 -- Do not warn if used as a generic actual, since the generic may be
2971 -- what is forcing the use of an "unnecessary" IN OUT.
2973 elsif Used_As_Generic_Actual (S)
2974 or else (Present (SE) and then Used_As_Generic_Actual (Scope (SE)))
2975 then
2976 return True;
2978 -- Else test warnings off
2980 elsif Warnings_Off_Check_Spec (S) then
2981 return True;
2983 -- All tests for suppressing warning failed
2985 else
2986 return False;
2987 end if;
2988 end No_Warn_On_In_Out;
2990 -- Start of processing for Output_Non_Modified_In_Out_Warnings
2992 begin
2993 -- Loop through entities for which a warning may be needed
2995 for J in In_Out_Warnings.First .. In_Out_Warnings.Last loop
2996 declare
2997 E1 : constant Entity_Id := In_Out_Warnings.Table (J);
2999 begin
3000 -- Suppress warning in specific cases (see details in comments for
3001 -- No_Warn_On_In_Out), or if there is a pragma Unmodified.
3003 if Has_Pragma_Unmodified_Check_Spec (E1)
3004 or else No_Warn_On_In_Out (E1)
3005 then
3006 null;
3008 -- Here we generate the warning
3010 else
3011 -- If -gnatwc is set then output message that we could be IN
3013 if not Is_Trivial_Subprogram (Scope (E1)) then
3014 if Warn_On_Constant then
3015 Error_Msg_N
3016 ("?u?formal parameter & is not modified!", E1);
3017 Error_Msg_N
3018 ("\?u?mode could be IN instead of `IN OUT`!", E1);
3020 -- We do not generate warnings for IN OUT parameters
3021 -- unless we have at least -gnatwu. This is deliberately
3022 -- inconsistent with the treatment of variables, but
3023 -- otherwise we get too many unexpected warnings in
3024 -- default mode.
3026 elsif Check_Unreferenced then
3027 Error_Msg_N
3028 ("?u?formal parameter& is read but "
3029 & "never assigned!", E1);
3030 end if;
3031 end if;
3033 -- Kill any other warnings on this entity, since this is the
3034 -- one that should dominate any other unreferenced warning.
3036 Set_Warnings_Off (E1);
3037 end if;
3038 end;
3039 end loop;
3040 end Output_Non_Modified_In_Out_Warnings;
3042 ----------------------------------------
3043 -- Output_Obsolescent_Entity_Warnings --
3044 ----------------------------------------
3046 procedure Output_Obsolescent_Entity_Warnings (N : Node_Id; E : Entity_Id) is
3047 P : constant Node_Id := Parent (N);
3048 S : Entity_Id;
3050 begin
3051 S := Current_Scope;
3053 -- Do not output message if we are the scope of standard. This means
3054 -- we have a reference from a context clause from when it is originally
3055 -- processed, and that's too early to tell whether it is an obsolescent
3056 -- unit doing the with'ing. In Sem_Ch10.Analyze_Compilation_Unit we make
3057 -- sure that we have a later call when the scope is available. This test
3058 -- also eliminates all messages for use clauses, which is fine (we do
3059 -- not want messages for use clauses, since they are always redundant
3060 -- with respect to the associated with clause).
3062 if S = Standard_Standard then
3063 return;
3064 end if;
3066 -- Do not output message if we are in scope of an obsolescent package
3067 -- or subprogram.
3069 loop
3070 if Is_Obsolescent (S) then
3071 return;
3072 end if;
3074 S := Scope (S);
3075 exit when S = Standard_Standard;
3076 end loop;
3078 -- Here we will output the message
3080 Error_Msg_Sloc := Sloc (E);
3082 -- Case of with clause
3084 if Nkind (P) = N_With_Clause then
3085 if Ekind (E) = E_Package then
3086 Error_Msg_NE
3087 ("?j?with of obsolescent package& declared#", N, E);
3088 elsif Ekind (E) = E_Procedure then
3089 Error_Msg_NE
3090 ("?j?with of obsolescent procedure& declared#", N, E);
3091 else
3092 Error_Msg_NE
3093 ("??with of obsolescent function& declared#", N, E);
3094 end if;
3096 -- If we do not have a with clause, then ignore any reference to an
3097 -- obsolescent package name. We only want to give the one warning of
3098 -- withing the package, not one each time it is used to qualify.
3100 elsif Ekind (E) = E_Package then
3101 return;
3103 -- Procedure call statement
3105 elsif Nkind (P) = N_Procedure_Call_Statement then
3106 Error_Msg_NE
3107 ("??call to obsolescent procedure& declared#", N, E);
3109 -- Function call
3111 elsif Nkind (P) = N_Function_Call then
3112 Error_Msg_NE
3113 ("??call to obsolescent function& declared#", N, E);
3115 -- Reference to obsolescent type
3117 elsif Is_Type (E) then
3118 Error_Msg_NE
3119 ("??reference to obsolescent type& declared#", N, E);
3121 -- Reference to obsolescent component
3123 elsif Ekind_In (E, E_Component, E_Discriminant) then
3124 Error_Msg_NE
3125 ("??reference to obsolescent component& declared#", N, E);
3127 -- Reference to obsolescent variable
3129 elsif Ekind (E) = E_Variable then
3130 Error_Msg_NE
3131 ("??reference to obsolescent variable& declared#", N, E);
3133 -- Reference to obsolescent constant
3135 elsif Ekind (E) = E_Constant or else Ekind (E) in Named_Kind then
3136 Error_Msg_NE
3137 ("??reference to obsolescent constant& declared#", N, E);
3139 -- Reference to obsolescent enumeration literal
3141 elsif Ekind (E) = E_Enumeration_Literal then
3142 Error_Msg_NE
3143 ("??reference to obsolescent enumeration literal& declared#", N, E);
3145 -- Generic message for any other case we missed
3147 else
3148 Error_Msg_NE
3149 ("??reference to obsolescent entity& declared#", N, E);
3150 end if;
3152 -- Output additional warning if present
3154 for J in Obsolescent_Warnings.First .. Obsolescent_Warnings.Last loop
3155 if Obsolescent_Warnings.Table (J).Ent = E then
3156 String_To_Name_Buffer (Obsolescent_Warnings.Table (J).Msg);
3157 Error_Msg_Strlen := Name_Len;
3158 Error_Msg_String (1 .. Name_Len) := Name_Buffer (1 .. Name_Len);
3159 Error_Msg_N ("\\??~", N);
3160 exit;
3161 end if;
3162 end loop;
3163 end Output_Obsolescent_Entity_Warnings;
3165 ----------------------------------
3166 -- Output_Unreferenced_Messages --
3167 ----------------------------------
3169 procedure Output_Unreferenced_Messages is
3170 begin
3171 for J in Unreferenced_Entities.First .. Unreferenced_Entities.Last loop
3172 Warn_On_Unreferenced_Entity (Unreferenced_Entities.Table (J));
3173 end loop;
3174 end Output_Unreferenced_Messages;
3176 -----------------------------------------
3177 -- Output_Unused_Warnings_Off_Warnings --
3178 -----------------------------------------
3180 procedure Output_Unused_Warnings_Off_Warnings is
3181 begin
3182 for J in Warnings_Off_Pragmas.First .. Warnings_Off_Pragmas.Last loop
3183 declare
3184 Wentry : Warnings_Off_Entry renames Warnings_Off_Pragmas.Table (J);
3185 N : Node_Id renames Wentry.N;
3186 E : Node_Id renames Wentry.E;
3188 begin
3189 -- Turn off Warnings_Off, or we won't get the warning
3191 Set_Warnings_Off (E, False);
3193 -- Nothing to do if pragma was used to suppress a general warning
3195 if Warnings_Off_Used (E) then
3196 null;
3198 -- If pragma was used both in unmodified and unreferenced contexts
3199 -- then that's as good as the general case, no warning.
3201 elsif Warnings_Off_Used_Unmodified (E)
3203 Warnings_Off_Used_Unreferenced (E)
3204 then
3205 null;
3207 -- Used only in context where Unmodified would have worked
3209 elsif Warnings_Off_Used_Unmodified (E) then
3210 Error_Msg_NE
3211 ("?W?could use Unmodified instead of "
3212 & "Warnings Off for &", Pragma_Identifier (N), E);
3214 -- Used only in context where Unreferenced would have worked
3216 elsif Warnings_Off_Used_Unreferenced (E) then
3217 Error_Msg_NE
3218 ("?W?could use Unreferenced instead of "
3219 & "Warnings Off for &", Pragma_Identifier (N), E);
3221 -- Not used at all
3223 else
3224 Error_Msg_NE
3225 ("?W?pragma Warnings Off for & unused, "
3226 & "could be omitted", N, E);
3227 end if;
3228 end;
3229 end loop;
3230 end Output_Unused_Warnings_Off_Warnings;
3232 ---------------------------
3233 -- Referenced_Check_Spec --
3234 ---------------------------
3236 function Referenced_Check_Spec (E : Entity_Id) return Boolean is
3237 begin
3238 if Is_Formal (E) and then Present (Spec_Entity (E)) then
3239 return Referenced (E) or else Referenced (Spec_Entity (E));
3240 else
3241 return Referenced (E);
3242 end if;
3243 end Referenced_Check_Spec;
3245 ----------------------------------
3246 -- Referenced_As_LHS_Check_Spec --
3247 ----------------------------------
3249 function Referenced_As_LHS_Check_Spec (E : Entity_Id) return Boolean is
3250 begin
3251 if Is_Formal (E) and then Present (Spec_Entity (E)) then
3252 return Referenced_As_LHS (E)
3253 or else Referenced_As_LHS (Spec_Entity (E));
3254 else
3255 return Referenced_As_LHS (E);
3256 end if;
3257 end Referenced_As_LHS_Check_Spec;
3259 --------------------------------------------
3260 -- Referenced_As_Out_Parameter_Check_Spec --
3261 --------------------------------------------
3263 function Referenced_As_Out_Parameter_Check_Spec
3264 (E : Entity_Id) return Boolean
3266 begin
3267 if Is_Formal (E) and then Present (Spec_Entity (E)) then
3268 return Referenced_As_Out_Parameter (E)
3269 or else Referenced_As_Out_Parameter (Spec_Entity (E));
3270 else
3271 return Referenced_As_Out_Parameter (E);
3272 end if;
3273 end Referenced_As_Out_Parameter_Check_Spec;
3275 --------------------------------------
3276 -- Warn_On_Constant_Valid_Condition --
3277 --------------------------------------
3279 procedure Warn_On_Constant_Valid_Condition (Op : Node_Id) is
3280 Left : constant Node_Id := Left_Opnd (Op);
3281 Right : constant Node_Id := Right_Opnd (Op);
3283 True_Result : Boolean;
3284 False_Result : Boolean;
3286 begin
3287 -- Determine the potential outcome of the comparison assuming that the
3288 -- scalar operands are valid.
3290 if Constant_Condition_Warnings
3291 and then Comes_From_Source (Original_Node (Op))
3292 and then Is_Scalar_Type (Etype (Left))
3293 and then Is_Scalar_Type (Etype (Right))
3295 -- Do not consider instances because the check was already performed
3296 -- in the generic.
3298 and then not In_Instance
3300 -- Do not consider comparisons between two static expressions such as
3301 -- constants or literals because those values cannot be invalidated.
3303 and then not (Is_Static_Expression (Left)
3304 and then Is_Static_Expression (Right))
3306 -- Do not consider comparison between an attribute reference and a
3307 -- compile-time known value since this is most likely a conditional
3308 -- compilation.
3310 and then not Is_Attribute_And_Known_Value_Comparison (Op)
3312 -- Do not consider internal files to allow for various assertions and
3313 -- safeguards within our runtime.
3315 and then not In_Internal_Unit (Op)
3316 then
3317 Test_Comparison
3318 (Op => Op,
3319 Assume_Valid => True,
3320 True_Result => True_Result,
3321 False_Result => False_Result);
3323 -- Warn on a possible evaluation to False / True in the presence of
3324 -- invalid values.
3326 if True_Result then
3327 Error_Msg_N
3328 ("condition can only be False if invalid values present??", Op);
3330 elsif False_Result then
3331 Error_Msg_N
3332 ("condition can only be True if invalid values present??", Op);
3333 end if;
3334 end if;
3335 end Warn_On_Constant_Valid_Condition;
3337 -----------------------------
3338 -- Warn_On_Known_Condition --
3339 -----------------------------
3341 procedure Warn_On_Known_Condition (C : Node_Id) is
3342 Test_Result : Boolean := False;
3343 -- Force initialization to facilitate static analysis
3345 function Is_Known_Branch return Boolean;
3346 -- If the type of the condition is Boolean, the constant value of the
3347 -- condition is a boolean literal. If the type is a derived boolean
3348 -- type, the constant is wrapped in a type conversion of the derived
3349 -- literal. If the value of the condition is not a literal, no warnings
3350 -- can be produced. This function returns True if the result can be
3351 -- determined, and Test_Result is set True/False accordingly. Otherwise
3352 -- False is returned, and Test_Result is unchanged.
3354 procedure Track (N : Node_Id; Loc : Node_Id);
3355 -- Adds continuation warning(s) pointing to reason (assignment or test)
3356 -- for the operand of the conditional having a known value (or at least
3357 -- enough is known about the value to issue the warning). N is the node
3358 -- which is judged to have a known value. Loc is the warning location.
3360 ---------------------
3361 -- Is_Known_Branch --
3362 ---------------------
3364 function Is_Known_Branch return Boolean is
3365 begin
3366 if Etype (C) = Standard_Boolean
3367 and then Is_Entity_Name (C)
3368 and then
3369 (Entity (C) = Standard_False or else Entity (C) = Standard_True)
3370 then
3371 Test_Result := Entity (C) = Standard_True;
3372 return True;
3374 elsif Is_Boolean_Type (Etype (C))
3375 and then Nkind (C) = N_Unchecked_Type_Conversion
3376 and then Is_Entity_Name (Expression (C))
3377 and then Ekind (Entity (Expression (C))) = E_Enumeration_Literal
3378 then
3379 Test_Result :=
3380 Chars (Entity (Expression (C))) = Chars (Standard_True);
3381 return True;
3383 else
3384 return False;
3385 end if;
3386 end Is_Known_Branch;
3388 -----------
3389 -- Track --
3390 -----------
3392 procedure Track (N : Node_Id; Loc : Node_Id) is
3393 Nod : constant Node_Id := Original_Node (N);
3395 begin
3396 if Nkind (Nod) in N_Op_Compare then
3397 Track (Left_Opnd (Nod), Loc);
3398 Track (Right_Opnd (Nod), Loc);
3400 elsif Is_Entity_Name (Nod) and then Is_Object (Entity (Nod)) then
3401 declare
3402 CV : constant Node_Id := Current_Value (Entity (Nod));
3404 begin
3405 if Present (CV) then
3406 Error_Msg_Sloc := Sloc (CV);
3408 if Nkind (CV) not in N_Subexpr then
3409 Error_Msg_N ("\\??(see test #)", Loc);
3411 elsif Nkind (Parent (CV)) =
3412 N_Case_Statement_Alternative
3413 then
3414 Error_Msg_N ("\\??(see case alternative #)", Loc);
3416 else
3417 Error_Msg_N ("\\??(see assignment #)", Loc);
3418 end if;
3419 end if;
3420 end;
3421 end if;
3422 end Track;
3424 -- Local variables
3426 Orig : constant Node_Id := Original_Node (C);
3427 P : Node_Id;
3429 -- Start of processing for Warn_On_Known_Condition
3431 begin
3432 -- Adjust SCO condition if from source
3434 if Generate_SCO
3435 and then Comes_From_Source (Orig)
3436 and then Is_Known_Branch
3437 then
3438 declare
3439 Atrue : Boolean;
3441 begin
3442 Atrue := Test_Result;
3444 if Present (Parent (C)) and then Nkind (Parent (C)) = N_Op_Not then
3445 Atrue := not Atrue;
3446 end if;
3448 Set_SCO_Condition (Orig, Atrue);
3449 end;
3450 end if;
3452 -- Argument replacement in an inlined body can make conditions static.
3453 -- Do not emit warnings in this case.
3455 if In_Inlined_Body then
3456 return;
3457 end if;
3459 if Constant_Condition_Warnings
3460 and then Is_Known_Branch
3461 and then Comes_From_Source (Orig)
3462 and then not In_Instance
3463 then
3464 -- Don't warn if comparison of result of attribute against a constant
3465 -- value, since this is likely legitimate conditional compilation.
3467 if Is_Attribute_And_Known_Value_Comparison (C) then
3468 return;
3469 end if;
3471 -- See if this is in a statement or a declaration
3473 P := Parent (C);
3474 loop
3475 -- If tree is not attached, do not issue warning (this is very
3476 -- peculiar, and probably arises from some other error condition).
3478 if No (P) then
3479 return;
3481 -- If we are in a declaration, then no warning, since in practice
3482 -- conditionals in declarations are used for intended tests which
3483 -- may be known at compile time, e.g. things like
3485 -- x : constant Integer := 2 + (Word'Size = 32);
3487 -- And a warning is annoying in such cases
3489 elsif Nkind (P) in N_Declaration
3490 or else
3491 Nkind (P) in N_Later_Decl_Item
3492 then
3493 return;
3495 -- Don't warn in assert or check pragma, since presumably tests in
3496 -- such a context are very definitely intended, and might well be
3497 -- known at compile time. Note that we have to test the original
3498 -- node, since assert pragmas get rewritten at analysis time.
3500 elsif Nkind (Original_Node (P)) = N_Pragma
3501 and then Nam_In (Pragma_Name_Unmapped (Original_Node (P)),
3502 Name_Assert, Name_Check)
3503 then
3504 return;
3505 end if;
3507 exit when Is_Statement (P);
3508 P := Parent (P);
3509 end loop;
3511 -- Here we issue the warning unless some sub-operand has warnings
3512 -- set off, in which case we suppress the warning for the node. If
3513 -- the original expression is an inequality, it has been expanded
3514 -- into a negation, and the value of the original expression is the
3515 -- negation of the equality. If the expression is an entity that
3516 -- appears within a negation, it is clearer to flag the negation
3517 -- itself, and report on its constant value.
3519 if not Operand_Has_Warnings_Suppressed (C) then
3520 declare
3521 True_Branch : Boolean := Test_Result;
3522 Cond : Node_Id := C;
3524 begin
3525 if Present (Parent (C))
3526 and then Nkind (Parent (C)) = N_Op_Not
3527 then
3528 True_Branch := not True_Branch;
3529 Cond := Parent (C);
3530 end if;
3532 -- Condition always True
3534 if True_Branch then
3535 if Is_Entity_Name (Original_Node (C))
3536 and then Nkind (Cond) /= N_Op_Not
3537 then
3538 Error_Msg_NE
3539 ("object & is always True at this point?c?",
3540 Cond, Original_Node (C));
3541 Track (Original_Node (C), Cond);
3543 else
3544 Error_Msg_N ("condition is always True?c?", Cond);
3545 Track (Cond, Cond);
3546 end if;
3548 -- Condition always False
3550 else
3551 if Is_Entity_Name (Original_Node (C))
3552 and then Nkind (Cond) /= N_Op_Not
3553 then
3554 Error_Msg_NE
3555 ("object & is always False at this point?c?",
3556 Cond, Original_Node (C));
3557 Track (Original_Node (C), Cond);
3559 else
3560 Error_Msg_N ("condition is always False?c?", Cond);
3561 Track (Cond, Cond);
3562 end if;
3563 end if;
3564 end;
3565 end if;
3566 end if;
3567 end Warn_On_Known_Condition;
3569 ---------------------------------------
3570 -- Warn_On_Modified_As_Out_Parameter --
3571 ---------------------------------------
3573 function Warn_On_Modified_As_Out_Parameter (E : Entity_Id) return Boolean is
3574 begin
3575 return
3576 (Warn_On_Modified_Unread and then Is_Only_Out_Parameter (E))
3577 or else Warn_On_All_Unread_Out_Parameters;
3578 end Warn_On_Modified_As_Out_Parameter;
3580 ---------------------------------
3581 -- Warn_On_Overlapping_Actuals --
3582 ---------------------------------
3584 procedure Warn_On_Overlapping_Actuals (Subp : Entity_Id; N : Node_Id) is
3585 function Is_Covered_Formal (Formal : Node_Id) return Boolean;
3586 -- Return True if Formal is covered by the rule
3588 function Refer_Same_Object
3589 (Act1 : Node_Id;
3590 Act2 : Node_Id) return Boolean;
3591 -- Two names are known to refer to the same object if the two names
3592 -- are known to denote the same object; or one of the names is a
3593 -- selected_component, indexed_component, or slice and its prefix is
3594 -- known to refer to the same object as the other name; or one of the
3595 -- two names statically denotes a renaming declaration whose renamed
3596 -- object_name is known to refer to the same object as the other name
3597 -- (RM 6.4.1(6.11/3))
3599 -----------------------
3600 -- Is_Covered_Formal --
3601 -----------------------
3603 function Is_Covered_Formal (Formal : Node_Id) return Boolean is
3604 begin
3605 return
3606 Ekind_In (Formal, E_Out_Parameter, E_In_Out_Parameter)
3607 and then (Is_Elementary_Type (Etype (Formal))
3608 or else Is_Record_Type (Etype (Formal))
3609 or else Is_Array_Type (Etype (Formal)));
3610 end Is_Covered_Formal;
3612 -----------------------
3613 -- Refer_Same_Object --
3614 -----------------------
3616 function Refer_Same_Object
3617 (Act1 : Node_Id;
3618 Act2 : Node_Id) return Boolean
3620 begin
3621 return
3622 Denotes_Same_Object (Act1, Act2)
3623 or else Denotes_Same_Prefix (Act1, Act2);
3624 end Refer_Same_Object;
3626 -- Local variables
3628 Act1 : Node_Id;
3629 Act2 : Node_Id;
3630 Form1 : Entity_Id;
3631 Form2 : Entity_Id;
3632 Warn_Only : Boolean;
3633 -- GNAT warns on overlapping in-out parameters even when there are no
3634 -- two in-out parameters of an elementary type, as stated in
3635 -- RM 6.5.1 (17/2).
3637 -- Start of processing for Warn_On_Overlapping_Actuals
3639 begin
3641 if Ada_Version < Ada_2012 and then not Warn_On_Overlap then
3642 return;
3643 end if;
3645 -- The call is illegal only if there are at least two in-out parameters
3646 -- of the same elementary type.
3648 Warn_Only := True;
3649 Form1 := First_Formal (Subp);
3650 while Present (Form1) loop
3651 Form2 := Next_Formal (Form1);
3652 while Present (Form2) loop
3653 if Is_Elementary_Type (Etype (Form1))
3654 and then Is_Elementary_Type (Etype (Form2))
3655 and then Ekind (Form1) /= E_In_Parameter
3656 and then Ekind (Form2) /= E_In_Parameter
3657 then
3658 Warn_Only := False;
3659 exit;
3660 end if;
3662 Next_Formal (Form2);
3663 end loop;
3665 Next_Formal (Form1);
3666 end loop;
3668 -- Exclude calls rewritten as enumeration literals
3670 if Nkind (N) not in N_Subprogram_Call
3671 and then Nkind (N) /= N_Entry_Call_Statement
3672 then
3673 return;
3674 end if;
3676 -- If a call C has two or more parameters of mode in out or out that are
3677 -- of an elementary type, then the call is legal only if for each name
3678 -- N that is passed as a parameter of mode in out or out to the call C,
3679 -- there is no other name among the other parameters of mode in out or
3680 -- out to C that is known to denote the same object (RM 6.4.1(6.15/3))
3682 -- If appropriate warning switch is set, we also report warnings on
3683 -- overlapping parameters that are record types or array types.
3685 Form1 := First_Formal (Subp);
3686 Act1 := First_Actual (N);
3687 while Present (Form1) and then Present (Act1) loop
3688 if Is_Covered_Formal (Form1) then
3689 Form2 := First_Formal (Subp);
3690 Act2 := First_Actual (N);
3691 while Present (Form2) and then Present (Act2) loop
3692 if Form1 /= Form2
3693 and then Is_Covered_Formal (Form2)
3694 and then Refer_Same_Object (Act1, Act2)
3695 then
3696 -- Guard against previous errors
3698 if Error_Posted (N)
3699 or else No (Etype (Act1))
3700 or else No (Etype (Act2))
3701 then
3702 null;
3704 -- If the actual is a function call in prefix notation,
3705 -- there is no real overlap.
3707 elsif Nkind (Act2) = N_Function_Call then
3708 null;
3710 -- If type is not by-copy, assume that aliasing is intended
3712 elsif
3713 Present (Underlying_Type (Etype (Form1)))
3714 and then
3715 (Is_By_Reference_Type (Underlying_Type (Etype (Form1)))
3716 or else
3717 Convention (Underlying_Type (Etype (Form1))) =
3718 Convention_Ada_Pass_By_Reference)
3719 then
3720 null;
3722 -- Under Ada 2012 we only report warnings on overlapping
3723 -- arrays and record types if switch is set.
3725 elsif Ada_Version >= Ada_2012
3726 and then not Is_Elementary_Type (Etype (Form1))
3727 and then not Warn_On_Overlap
3728 then
3729 null;
3731 -- Here we may need to issue overlap message
3733 else
3734 Error_Msg_Warn :=
3736 -- Overlap checking is an error only in Ada 2012. For
3737 -- earlier versions of Ada, this is a warning.
3739 Ada_Version < Ada_2012
3741 -- Overlap is only illegal in Ada 2012 in the case of
3742 -- elementary types (passed by copy). For other types,
3743 -- we always have a warning in all Ada versions.
3745 or else not Is_Elementary_Type (Etype (Form1))
3747 -- debug flag -gnatd.E changes the error to a warning
3748 -- even in Ada 2012 mode.
3750 or else Error_To_Warning
3751 or else Warn_Only;
3753 declare
3754 Act : Node_Id;
3755 Form : Entity_Id;
3757 begin
3758 -- Find matching actual
3760 Act := First_Actual (N);
3761 Form := First_Formal (Subp);
3762 while Act /= Act2 loop
3763 Next_Formal (Form);
3764 Next_Actual (Act);
3765 end loop;
3767 if Is_Elementary_Type (Etype (Act1))
3768 and then Ekind (Form2) = E_In_Parameter
3769 then
3770 null; -- No real aliasing
3772 elsif Is_Elementary_Type (Etype (Act2))
3773 and then Ekind (Form2) = E_In_Parameter
3774 then
3775 null; -- Ditto
3777 -- If the call was written in prefix notation, and
3778 -- thus its prefix before rewriting was a selected
3779 -- component, count only visible actuals in the call.
3781 elsif Is_Entity_Name (First_Actual (N))
3782 and then Nkind (Original_Node (N)) = Nkind (N)
3783 and then Nkind (Name (Original_Node (N))) =
3784 N_Selected_Component
3785 and then
3786 Is_Entity_Name (Prefix (Name (Original_Node (N))))
3787 and then
3788 Entity (Prefix (Name (Original_Node (N)))) =
3789 Entity (First_Actual (N))
3790 then
3791 if Act1 = First_Actual (N) then
3792 Error_Msg_FE
3793 ("<<`IN OUT` prefix overlaps with "
3794 & "actual for&", Act1, Form);
3796 else
3797 -- For greater clarity, give name of formal
3799 Error_Msg_Node_2 := Form;
3800 Error_Msg_FE
3801 ("<<writable actual for & overlaps with "
3802 & "actual for&", Act1, Form);
3803 end if;
3805 else
3806 -- For greater clarity, give name of formal
3808 Error_Msg_Node_2 := Form;
3810 -- This is one of the messages
3812 Error_Msg_FE
3813 ("<<writable actual for & overlaps with "
3814 & "actual for&", Act1, Form1);
3815 end if;
3816 end;
3817 end if;
3819 return;
3820 end if;
3822 Next_Formal (Form2);
3823 Next_Actual (Act2);
3824 end loop;
3825 end if;
3827 Next_Formal (Form1);
3828 Next_Actual (Act1);
3829 end loop;
3830 end Warn_On_Overlapping_Actuals;
3832 ------------------------------
3833 -- Warn_On_Suspicious_Index --
3834 ------------------------------
3836 procedure Warn_On_Suspicious_Index (Name : Entity_Id; X : Node_Id) is
3838 Low_Bound : Uint;
3839 -- Set to lower bound for a suspicious type
3841 Ent : Entity_Id;
3842 -- Entity for array reference
3844 Typ : Entity_Id;
3845 -- Array type
3847 function Is_Suspicious_Type (Typ : Entity_Id) return Boolean;
3848 -- Tests to see if Typ is a type for which we may have a suspicious
3849 -- index, namely an unconstrained array type, whose lower bound is
3850 -- either zero or one. If so, True is returned, and Low_Bound is set
3851 -- to this lower bound. If not, False is returned, and Low_Bound is
3852 -- undefined on return.
3854 -- For now, we limit this to standard string types, so any other
3855 -- unconstrained types return False. We may change our minds on this
3856 -- later on, but strings seem the most important case.
3858 procedure Test_Suspicious_Index;
3859 -- Test if index is of suspicious type and if so, generate warning
3861 ------------------------
3862 -- Is_Suspicious_Type --
3863 ------------------------
3865 function Is_Suspicious_Type (Typ : Entity_Id) return Boolean is
3866 LB : Node_Id;
3868 begin
3869 if Is_Array_Type (Typ)
3870 and then not Is_Constrained (Typ)
3871 and then Number_Dimensions (Typ) = 1
3872 and then Is_Standard_String_Type (Typ)
3873 and then not Has_Warnings_Off (Typ)
3874 then
3875 LB := Type_Low_Bound (Etype (First_Index (Typ)));
3877 if Compile_Time_Known_Value (LB) then
3878 Low_Bound := Expr_Value (LB);
3879 return Low_Bound = Uint_0 or else Low_Bound = Uint_1;
3880 end if;
3881 end if;
3883 return False;
3884 end Is_Suspicious_Type;
3886 ---------------------------
3887 -- Test_Suspicious_Index --
3888 ---------------------------
3890 procedure Test_Suspicious_Index is
3892 function Length_Reference (N : Node_Id) return Boolean;
3893 -- Check if node N is of the form Name'Length
3895 procedure Warn1;
3896 -- Generate first warning line
3898 procedure Warn_On_Index_Below_Lower_Bound;
3899 -- Generate a warning on indexing the array with a literal value
3900 -- below the lower bound of the index type.
3902 procedure Warn_On_Literal_Index;
3903 -- Generate a warning on indexing the array with a literal value
3905 ----------------------
3906 -- Length_Reference --
3907 ----------------------
3909 function Length_Reference (N : Node_Id) return Boolean is
3910 R : constant Node_Id := Original_Node (N);
3911 begin
3912 return
3913 Nkind (R) = N_Attribute_Reference
3914 and then Attribute_Name (R) = Name_Length
3915 and then Is_Entity_Name (Prefix (R))
3916 and then Entity (Prefix (R)) = Ent;
3917 end Length_Reference;
3919 -----------
3920 -- Warn1 --
3921 -----------
3923 procedure Warn1 is
3924 begin
3925 Error_Msg_Uint_1 := Low_Bound;
3926 Error_Msg_FE -- CODEFIX
3927 ("?w?index for& may assume lower bound of^", X, Ent);
3928 end Warn1;
3930 -------------------------------------
3931 -- Warn_On_Index_Below_Lower_Bound --
3932 -------------------------------------
3934 procedure Warn_On_Index_Below_Lower_Bound is
3935 begin
3936 if Is_Standard_String_Type (Typ) then
3937 Discard_Node
3938 (Compile_Time_Constraint_Error
3939 (N => X,
3940 Msg => "?w?string index should be positive"));
3941 else
3942 Discard_Node
3943 (Compile_Time_Constraint_Error
3944 (N => X,
3945 Msg => "?w?index out of the allowed range"));
3946 end if;
3947 end Warn_On_Index_Below_Lower_Bound;
3949 ---------------------------
3950 -- Warn_On_Literal_Index --
3951 ---------------------------
3953 procedure Warn_On_Literal_Index is
3954 begin
3955 Warn1;
3957 -- Case where original form of subscript is an integer literal
3959 if Nkind (Original_Node (X)) = N_Integer_Literal then
3960 if Intval (X) = Low_Bound then
3961 Error_Msg_FE -- CODEFIX
3962 ("\?w?suggested replacement: `&''First`", X, Ent);
3963 else
3964 Error_Msg_Uint_1 := Intval (X) - Low_Bound;
3965 Error_Msg_FE -- CODEFIX
3966 ("\?w?suggested replacement: `&''First + ^`", X, Ent);
3968 end if;
3970 -- Case where original form of subscript is more complex
3972 else
3973 -- Build string X'First - 1 + expression where the expression
3974 -- is the original subscript. If the expression starts with "1
3975 -- + ", then the "- 1 + 1" is elided.
3977 Error_Msg_String (1 .. 13) := "'First - 1 + ";
3978 Error_Msg_Strlen := 13;
3980 declare
3981 Sref : Source_Ptr := Sloc (First_Node (Original_Node (X)));
3982 Tref : constant Source_Buffer_Ptr :=
3983 Source_Text (Get_Source_File_Index (Sref));
3984 -- Tref (Sref) is used to scan the subscript
3986 Pctr : Natural;
3987 -- Parentheses counter when scanning subscript
3989 begin
3990 -- Tref (Sref) points to start of subscript
3992 -- Elide - 1 if subscript starts with 1 +
3994 if Tref (Sref .. Sref + 2) = "1 +" then
3995 Error_Msg_Strlen := Error_Msg_Strlen - 6;
3996 Sref := Sref + 2;
3998 elsif Tref (Sref .. Sref + 1) = "1+" then
3999 Error_Msg_Strlen := Error_Msg_Strlen - 6;
4000 Sref := Sref + 1;
4001 end if;
4003 -- Now we will copy the subscript to the string buffer
4005 Pctr := 0;
4006 loop
4007 -- Count parens, exit if terminating right paren. Note
4008 -- check to ignore paren appearing as character literal.
4010 if Tref (Sref + 1) = '''
4011 and then
4012 Tref (Sref - 1) = '''
4013 then
4014 null;
4015 else
4016 if Tref (Sref) = '(' then
4017 Pctr := Pctr + 1;
4018 elsif Tref (Sref) = ')' then
4019 exit when Pctr = 0;
4020 Pctr := Pctr - 1;
4021 end if;
4022 end if;
4024 -- Done if terminating double dot (slice case)
4026 exit when Pctr = 0
4027 and then (Tref (Sref .. Sref + 1) = ".."
4028 or else
4029 Tref (Sref .. Sref + 2) = " ..");
4031 -- Quit if we have hit EOF character, something wrong
4033 if Tref (Sref) = EOF then
4034 return;
4035 end if;
4037 -- String literals are too much of a pain to handle
4039 if Tref (Sref) = '"' or else Tref (Sref) = '%' then
4040 return;
4041 end if;
4043 -- If we have a 'Range reference, then this is a case
4044 -- where we cannot easily give a replacement. Don't try.
4046 if Tref (Sref .. Sref + 4) = "range"
4047 and then Tref (Sref - 1) < 'A'
4048 and then Tref (Sref + 5) < 'A'
4049 then
4050 return;
4051 end if;
4053 -- Else store next character
4055 Error_Msg_Strlen := Error_Msg_Strlen + 1;
4056 Error_Msg_String (Error_Msg_Strlen) := Tref (Sref);
4057 Sref := Sref + 1;
4059 -- If we get more than 40 characters then the expression
4060 -- is too long to copy, or something has gone wrong. In
4061 -- either case, just skip the attempt at a suggested fix.
4063 if Error_Msg_Strlen > 40 then
4064 return;
4065 end if;
4066 end loop;
4067 end;
4069 -- Replacement subscript is now in string buffer
4071 Error_Msg_FE -- CODEFIX
4072 ("\?w?suggested replacement: `&~`", Original_Node (X), Ent);
4073 end if;
4074 end Warn_On_Literal_Index;
4076 -- Start of processing for Test_Suspicious_Index
4078 begin
4079 -- Nothing to do if subscript does not come from source (we don't
4080 -- want to give garbage warnings on compiler expanded code, e.g. the
4081 -- loops generated for slice assignments. Such junk warnings would
4082 -- be placed on source constructs with no subscript in sight).
4084 if not Comes_From_Source (Original_Node (X)) then
4085 return;
4086 end if;
4088 -- Case where subscript is a constant integer
4090 if Nkind (X) = N_Integer_Literal then
4092 -- Case where subscript is lower than the lowest possible bound.
4093 -- This might be the case for example when programmers try to
4094 -- access a string at index 0, as they are used to in other
4095 -- programming languages like C.
4097 if Intval (X) < Low_Bound then
4098 Warn_On_Index_Below_Lower_Bound;
4099 else
4100 Warn_On_Literal_Index;
4101 end if;
4103 -- Case where subscript is of the form X'Length
4105 elsif Length_Reference (X) then
4106 Warn1;
4107 Error_Msg_Node_2 := Ent;
4108 Error_Msg_FE
4109 ("\?w?suggest replacement of `&''Length` by `&''Last`",
4110 X, Ent);
4112 -- Case where subscript is of the form X'Length - expression
4114 elsif Nkind (X) = N_Op_Subtract
4115 and then Length_Reference (Left_Opnd (X))
4116 then
4117 Warn1;
4118 Error_Msg_Node_2 := Ent;
4119 Error_Msg_FE
4120 ("\?w?suggest replacement of `&''Length` by `&''Last`",
4121 Left_Opnd (X), Ent);
4122 end if;
4123 end Test_Suspicious_Index;
4125 -- Start of processing for Warn_On_Suspicious_Index
4127 begin
4128 -- Only process if warnings activated
4130 if Warn_On_Assumed_Low_Bound then
4132 -- Test if array is simple entity name
4134 if Is_Entity_Name (Name) then
4136 -- Test if array is parameter of unconstrained string type
4138 Ent := Entity (Name);
4139 Typ := Etype (Ent);
4141 if Is_Formal (Ent)
4142 and then Is_Suspicious_Type (Typ)
4143 and then not Low_Bound_Tested (Ent)
4144 then
4145 Test_Suspicious_Index;
4146 end if;
4147 end if;
4148 end if;
4149 end Warn_On_Suspicious_Index;
4151 -------------------------------
4152 -- Warn_On_Suspicious_Update --
4153 -------------------------------
4155 procedure Warn_On_Suspicious_Update (N : Node_Id) is
4156 Par : constant Node_Id := Parent (N);
4157 Arg : Node_Id;
4159 begin
4160 -- Only process if warnings activated
4162 if Warn_On_Suspicious_Contract then
4163 if Nkind_In (Par, N_Op_Eq, N_Op_Ne) then
4164 if N = Left_Opnd (Par) then
4165 Arg := Right_Opnd (Par);
4166 else
4167 Arg := Left_Opnd (Par);
4168 end if;
4170 if Same_Object (Prefix (N), Arg) then
4171 if Nkind (Par) = N_Op_Eq then
4172 Error_Msg_N
4173 ("suspicious equality test with modified version of "
4174 & "same object?T?", Par);
4175 else
4176 Error_Msg_N
4177 ("suspicious inequality test with modified version of "
4178 & "same object?T?", Par);
4179 end if;
4180 end if;
4181 end if;
4182 end if;
4183 end Warn_On_Suspicious_Update;
4185 --------------------------------------
4186 -- Warn_On_Unassigned_Out_Parameter --
4187 --------------------------------------
4189 procedure Warn_On_Unassigned_Out_Parameter
4190 (Return_Node : Node_Id;
4191 Scope_Id : Entity_Id)
4193 Form : Entity_Id;
4194 Form2 : Entity_Id;
4196 begin
4197 -- Ignore if procedure or return statement does not come from source
4199 if not Comes_From_Source (Scope_Id)
4200 or else not Comes_From_Source (Return_Node)
4201 then
4202 return;
4203 end if;
4205 -- Loop through formals
4207 Form := First_Formal (Scope_Id);
4208 while Present (Form) loop
4210 -- We are only interested in OUT parameters that come from source
4211 -- and are never set in the source, and furthermore only in scalars
4212 -- since non-scalars generate too many false positives.
4214 if Ekind (Form) = E_Out_Parameter
4215 and then Never_Set_In_Source_Check_Spec (Form)
4216 and then Is_Scalar_Type (Etype (Form))
4217 and then not Present (Unset_Reference (Form))
4218 then
4219 -- Before we issue the warning, an add ad hoc defence against the
4220 -- most common case of false positives with this warning which is
4221 -- the case where there is a Boolean OUT parameter that has been
4222 -- set, and whose meaning is "ignore the values of the other
4223 -- parameters". We can't of course reliably tell this case at
4224 -- compile time, but the following test kills a lot of false
4225 -- positives, without generating a significant number of false
4226 -- negatives (missed real warnings).
4228 Form2 := First_Formal (Scope_Id);
4229 while Present (Form2) loop
4230 if Ekind (Form2) = E_Out_Parameter
4231 and then Root_Type (Etype (Form2)) = Standard_Boolean
4232 and then not Never_Set_In_Source_Check_Spec (Form2)
4233 then
4234 return;
4235 end if;
4237 Next_Formal (Form2);
4238 end loop;
4240 -- Here all conditions are met, record possible unset reference
4242 Set_Unset_Reference (Form, Return_Node);
4243 end if;
4245 Next_Formal (Form);
4246 end loop;
4247 end Warn_On_Unassigned_Out_Parameter;
4249 ---------------------------------
4250 -- Warn_On_Unreferenced_Entity --
4251 ---------------------------------
4253 procedure Warn_On_Unreferenced_Entity
4254 (Spec_E : Entity_Id;
4255 Body_E : Entity_Id := Empty)
4257 E : Entity_Id := Spec_E;
4259 begin
4260 if not Referenced_Check_Spec (E)
4261 and then not Has_Pragma_Unreferenced_Check_Spec (E)
4262 and then not Warnings_Off_Check_Spec (E)
4263 and then not Has_Junk_Name (Spec_E)
4264 and then not Is_Exported (Spec_E)
4265 then
4266 case Ekind (E) is
4267 when E_Variable =>
4269 -- Case of variable that is assigned but not read. We suppress
4270 -- the message if the variable is volatile, has an address
4271 -- clause, is aliased, or is a renaming, or is imported.
4273 if Referenced_As_LHS_Check_Spec (E)
4274 and then No (Address_Clause (E))
4275 and then not Is_Volatile (E)
4276 then
4277 if Warn_On_Modified_Unread
4278 and then not Is_Imported (E)
4279 and then not Is_Aliased (E)
4280 and then No (Renamed_Object (E))
4281 then
4282 if not Has_Pragma_Unmodified_Check_Spec (E) then
4283 Error_Msg_N -- CODEFIX
4284 ("?m?variable & is assigned but never read!", E);
4285 end if;
4287 Set_Last_Assignment (E, Empty);
4288 end if;
4290 -- Normal case of neither assigned nor read (exclude variables
4291 -- referenced as out parameters, since we already generated
4292 -- appropriate warnings at the call point in this case).
4294 elsif not Referenced_As_Out_Parameter (E) then
4296 -- We suppress the message for types for which a valid
4297 -- pragma Unreferenced_Objects has been given, otherwise
4298 -- we go ahead and give the message.
4300 if not Has_Pragma_Unreferenced_Objects (Etype (E)) then
4302 -- Distinguish renamed case in message
4304 if Present (Renamed_Object (E))
4305 and then Comes_From_Source (Renamed_Object (E))
4306 then
4307 Error_Msg_N -- CODEFIX
4308 ("?u?renamed variable & is not referenced!", E);
4309 else
4310 Error_Msg_N -- CODEFIX
4311 ("?u?variable & is not referenced!", E);
4312 end if;
4313 end if;
4314 end if;
4316 when E_Constant =>
4317 if not Has_Pragma_Unreferenced_Objects (Etype (E)) then
4318 if Present (Renamed_Object (E))
4319 and then Comes_From_Source (Renamed_Object (E))
4320 then
4321 Error_Msg_N -- CODEFIX
4322 ("?u?renamed constant & is not referenced!", E);
4323 else
4324 Error_Msg_N -- CODEFIX
4325 ("?u?constant & is not referenced!", E);
4326 end if;
4327 end if;
4329 when E_In_Out_Parameter
4330 | E_In_Parameter
4332 -- Do not emit message for formals of a renaming, because they
4333 -- are never referenced explicitly.
4335 if Nkind (Original_Node (Unit_Declaration_Node (Scope (E)))) /=
4336 N_Subprogram_Renaming_Declaration
4337 then
4338 -- Suppress this message for an IN OUT parameter of a
4339 -- non-scalar type, since it is normal to have only an
4340 -- assignment in such a case.
4342 if Ekind (E) = E_In_Parameter
4343 or else not Referenced_As_LHS_Check_Spec (E)
4344 or else Is_Scalar_Type (Etype (E))
4345 then
4346 if Present (Body_E) then
4347 E := Body_E;
4348 end if;
4350 if not Is_Trivial_Subprogram (Scope (E)) then
4351 Error_Msg_NE -- CODEFIX
4352 ("?u?formal parameter & is not referenced!",
4353 E, Spec_E);
4354 end if;
4355 end if;
4356 end if;
4358 when E_Out_Parameter =>
4359 null;
4361 when E_Discriminant =>
4362 Error_Msg_N ("?u?discriminant & is not referenced!", E);
4364 when E_Named_Integer
4365 | E_Named_Real
4367 Error_Msg_N -- CODEFIX
4368 ("?u?named number & is not referenced!", E);
4370 when Formal_Object_Kind =>
4371 Error_Msg_N -- CODEFIX
4372 ("?u?formal object & is not referenced!", E);
4374 when E_Enumeration_Literal =>
4375 Error_Msg_N -- CODEFIX
4376 ("?u?literal & is not referenced!", E);
4378 when E_Function =>
4379 Error_Msg_N -- CODEFIX
4380 ("?u?function & is not referenced!", E);
4382 when E_Procedure =>
4383 Error_Msg_N -- CODEFIX
4384 ("?u?procedure & is not referenced!", E);
4386 when E_Package =>
4387 Error_Msg_N -- CODEFIX
4388 ("?u?package & is not referenced!", E);
4390 when E_Exception =>
4391 Error_Msg_N -- CODEFIX
4392 ("?u?exception & is not referenced!", E);
4394 when E_Label =>
4395 Error_Msg_N -- CODEFIX
4396 ("?u?label & is not referenced!", E);
4398 when E_Generic_Procedure =>
4399 Error_Msg_N -- CODEFIX
4400 ("?u?generic procedure & is never instantiated!", E);
4402 when E_Generic_Function =>
4403 Error_Msg_N -- CODEFIX
4404 ("?u?generic function & is never instantiated!", E);
4406 when Type_Kind =>
4407 Error_Msg_N -- CODEFIX
4408 ("?u?type & is not referenced!", E);
4410 when others =>
4411 Error_Msg_N -- CODEFIX
4412 ("?u?& is not referenced!", E);
4413 end case;
4415 -- Kill warnings on the entity on which the message has been posted
4416 -- (nothing is posted on out parameters because back end might be
4417 -- able to uncover an uninitialized path, and warn accordingly).
4419 if Ekind (E) /= E_Out_Parameter then
4420 Set_Warnings_Off (E);
4421 end if;
4422 end if;
4423 end Warn_On_Unreferenced_Entity;
4425 --------------------------------
4426 -- Warn_On_Useless_Assignment --
4427 --------------------------------
4429 procedure Warn_On_Useless_Assignment
4430 (Ent : Entity_Id;
4431 N : Node_Id := Empty)
4433 P : Node_Id;
4434 X : Node_Id;
4436 function Check_Ref (N : Node_Id) return Traverse_Result;
4437 -- Used to instantiate Traverse_Func. Returns Abandon if a reference to
4438 -- the entity in question is found.
4440 function Test_No_Refs is new Traverse_Func (Check_Ref);
4442 ---------------
4443 -- Check_Ref --
4444 ---------------
4446 function Check_Ref (N : Node_Id) return Traverse_Result is
4447 begin
4448 -- Check reference to our identifier. We use name equality here
4449 -- because the exception handlers have not yet been analyzed. This
4450 -- is not quite right, but it really does not matter that we fail
4451 -- to output the warning in some obscure cases of name clashes.
4453 if Nkind (N) = N_Identifier and then Chars (N) = Chars (Ent) then
4454 return Abandon;
4455 else
4456 return OK;
4457 end if;
4458 end Check_Ref;
4460 -- Start of processing for Warn_On_Useless_Assignment
4462 begin
4463 -- Check if this is a case we want to warn on, a scalar or access
4464 -- variable with the last assignment field set, with warnings enabled,
4465 -- and which is not imported or exported. We also check that it is OK
4466 -- to capture the value. We are not going to capture any value, but
4467 -- the warning message depends on the same kind of conditions.
4469 if Is_Assignable (Ent)
4470 and then not Is_Return_Object (Ent)
4471 and then Present (Last_Assignment (Ent))
4472 and then not Is_Imported (Ent)
4473 and then not Is_Exported (Ent)
4474 and then Safe_To_Capture_Value (N, Ent)
4475 and then not Has_Pragma_Unreferenced_Check_Spec (Ent)
4476 and then not Has_Junk_Name (Ent)
4477 then
4478 -- Before we issue the message, check covering exception handlers.
4479 -- Search up tree for enclosing statement sequences and handlers.
4481 P := Parent (Last_Assignment (Ent));
4482 while Present (P) loop
4484 -- Something is really wrong if we don't find a handled statement
4485 -- sequence, so just suppress the warning.
4487 if No (P) then
4488 Set_Last_Assignment (Ent, Empty);
4489 return;
4491 -- When we hit a package/subprogram body, issue warning and exit
4493 elsif Nkind_In (P, N_Entry_Body,
4494 N_Package_Body,
4495 N_Subprogram_Body,
4496 N_Task_Body)
4497 then
4498 -- Case of assigned value never referenced
4500 if No (N) then
4501 declare
4502 LA : constant Node_Id := Last_Assignment (Ent);
4504 begin
4505 -- Don't give this for OUT and IN OUT formals, since
4506 -- clearly caller may reference the assigned value. Also
4507 -- never give such warnings for internal variables. In
4508 -- either case, word the warning in a conditional way,
4509 -- because in the case of a component of a controlled
4510 -- type, the assigned value might be referenced in the
4511 -- Finalize operation, so we can't make a definitive
4512 -- statement that it's never referenced.
4514 if Ekind (Ent) = E_Variable
4515 and then not Is_Internal_Name (Chars (Ent))
4516 then
4517 -- Give appropriate message, distinguishing between
4518 -- assignment statements and out parameters.
4520 if Nkind_In (Parent (LA), N_Parameter_Association,
4521 N_Procedure_Call_Statement)
4522 then
4523 Error_Msg_NE
4524 ("?m?& modified by call, but value might not be "
4525 & "referenced", LA, Ent);
4527 else
4528 Error_Msg_NE -- CODEFIX
4529 ("?m?possibly useless assignment to&, value "
4530 & "might not be referenced!", LA, Ent);
4531 end if;
4532 end if;
4533 end;
4535 -- Case of assigned value overwritten
4537 else
4538 declare
4539 LA : constant Node_Id := Last_Assignment (Ent);
4541 begin
4542 Error_Msg_Sloc := Sloc (N);
4544 -- Give appropriate message, distinguishing between
4545 -- assignment statements and out parameters.
4547 if Nkind_In (Parent (LA), N_Procedure_Call_Statement,
4548 N_Parameter_Association)
4549 then
4550 Error_Msg_NE
4551 ("?m?& modified by call, but value overwritten #!",
4552 LA, Ent);
4553 else
4554 Error_Msg_NE -- CODEFIX
4555 ("?m?useless assignment to&, value overwritten #!",
4556 LA, Ent);
4557 end if;
4558 end;
4559 end if;
4561 -- Clear last assignment indication and we are done
4563 Set_Last_Assignment (Ent, Empty);
4564 return;
4566 -- Enclosing handled sequence of statements
4568 elsif Nkind (P) = N_Handled_Sequence_Of_Statements then
4570 -- Check exception handlers present
4572 if Present (Exception_Handlers (P)) then
4574 -- If we are not at the top level, we regard an inner
4575 -- exception handler as a decisive indicator that we should
4576 -- not generate the warning, since the variable in question
4577 -- may be accessed after an exception in the outer block.
4579 if not Nkind_In (Parent (P), N_Entry_Body,
4580 N_Package_Body,
4581 N_Subprogram_Body,
4582 N_Task_Body)
4583 then
4584 Set_Last_Assignment (Ent, Empty);
4585 return;
4587 -- Otherwise we are at the outer level. An exception
4588 -- handler is significant only if it references the
4589 -- variable in question, or if the entity in question
4590 -- is an OUT or IN OUT parameter, in which case
4591 -- the caller can reference it after the exception
4592 -- handler completes.
4594 else
4595 if Is_Formal (Ent) then
4596 Set_Last_Assignment (Ent, Empty);
4597 return;
4599 else
4600 X := First (Exception_Handlers (P));
4601 while Present (X) loop
4602 if Test_No_Refs (X) = Abandon then
4603 Set_Last_Assignment (Ent, Empty);
4604 return;
4605 end if;
4607 X := Next (X);
4608 end loop;
4609 end if;
4610 end if;
4611 end if;
4612 end if;
4614 P := Parent (P);
4615 end loop;
4616 end if;
4617 end Warn_On_Useless_Assignment;
4619 ---------------------------------
4620 -- Warn_On_Useless_Assignments --
4621 ---------------------------------
4623 procedure Warn_On_Useless_Assignments (E : Entity_Id) is
4624 Ent : Entity_Id;
4626 begin
4627 Process_Deferred_References;
4629 if Warn_On_Modified_Unread
4630 and then In_Extended_Main_Source_Unit (E)
4631 then
4632 Ent := First_Entity (E);
4633 while Present (Ent) loop
4634 Warn_On_Useless_Assignment (Ent);
4635 Next_Entity (Ent);
4636 end loop;
4637 end if;
4638 end Warn_On_Useless_Assignments;
4640 -----------------------------
4641 -- Warnings_Off_Check_Spec --
4642 -----------------------------
4644 function Warnings_Off_Check_Spec (E : Entity_Id) return Boolean is
4645 begin
4646 if Is_Formal (E) and then Present (Spec_Entity (E)) then
4648 -- Note: use of OR here instead of OR ELSE is deliberate, we want
4649 -- to mess with flags on both entities.
4651 return Has_Warnings_Off (E)
4653 Has_Warnings_Off (Spec_Entity (E));
4655 else
4656 return Has_Warnings_Off (E);
4657 end if;
4658 end Warnings_Off_Check_Spec;
4660 end Sem_Warn;