PR c++/60417
[official-gcc.git] / gcc / ada / par-ch5.adb
blob7b1bc44f39d97da6d2c602538f1c135d30e7a45f
1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- P A R . C H 5 --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 1992-2014, 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 pragma Style_Checks (All_Checks);
27 -- Turn off subprogram body ordering check. Subprograms are in order by RM
28 -- section rather than alphabetical.
30 with Sinfo.CN; use Sinfo.CN;
32 separate (Par)
33 package body Ch5 is
35 -- Local functions, used only in this chapter
37 function P_Case_Statement return Node_Id;
38 function P_Case_Statement_Alternative return Node_Id;
39 function P_Exit_Statement return Node_Id;
40 function P_Goto_Statement return Node_Id;
41 function P_If_Statement return Node_Id;
42 function P_Label return Node_Id;
43 function P_Null_Statement return Node_Id;
45 function P_Assignment_Statement (LHS : Node_Id) return Node_Id;
46 -- Parse assignment statement. On entry, the caller has scanned the left
47 -- hand side (passed in as Lhs), and the colon-equal (or some symbol
48 -- taken to be an error equivalent such as equal).
50 function P_Begin_Statement (Block_Name : Node_Id := Empty) return Node_Id;
51 -- Parse begin-end statement. If Block_Name is non-Empty on entry, it is
52 -- the N_Identifier node for the label on the block. If Block_Name is
53 -- Empty on entry (the default), then the block statement is unlabeled.
55 function P_Declare_Statement (Block_Name : Node_Id := Empty) return Node_Id;
56 -- Parse declare block. If Block_Name is non-Empty on entry, it is
57 -- the N_Identifier node for the label on the block. If Block_Name is
58 -- Empty on entry (the default), then the block statement is unlabeled.
60 function P_For_Statement (Loop_Name : Node_Id := Empty) return Node_Id;
61 -- Parse for statement. If Loop_Name is non-Empty on entry, it is
62 -- the N_Identifier node for the label on the loop. If Loop_Name is
63 -- Empty on entry (the default), then the for statement is unlabeled.
65 function P_Iterator_Specification (Def_Id : Node_Id) return Node_Id;
66 -- Parse an iterator specification. The defining identifier has already
67 -- been scanned, as it is the common prefix between loop and iterator
68 -- specification.
70 function P_Loop_Statement (Loop_Name : Node_Id := Empty) return Node_Id;
71 -- Parse loop statement. If Loop_Name is non-Empty on entry, it is
72 -- the N_Identifier node for the label on the loop. If Loop_Name is
73 -- Empty on entry (the default), then the loop statement is unlabeled.
75 function P_While_Statement (Loop_Name : Node_Id := Empty) return Node_Id;
76 -- Parse while statement. If Loop_Name is non-Empty on entry, it is
77 -- the N_Identifier node for the label on the loop. If Loop_Name is
78 -- Empty on entry (the default), then the while statement is unlabeled.
80 function Set_Loop_Block_Name (L : Character) return Name_Id;
81 -- Given a letter 'L' for a loop or 'B' for a block, returns a name
82 -- of the form L_nn or B_nn where nn is a serial number obtained by
83 -- incrementing the variable Loop_Block_Count.
85 procedure Then_Scan;
86 -- Scan past THEN token, testing for illegal junk after it
88 ---------------------------------
89 -- 5.1 Sequence of Statements --
90 ---------------------------------
92 -- SEQUENCE_OF_STATEMENTS ::= STATEMENT {STATEMENT} {LABEL}
93 -- Note: the final label is an Ada 2012 addition.
95 -- STATEMENT ::=
96 -- {LABEL} SIMPLE_STATEMENT | {LABEL} COMPOUND_STATEMENT
98 -- SIMPLE_STATEMENT ::= NULL_STATEMENT
99 -- | ASSIGNMENT_STATEMENT | EXIT_STATEMENT
100 -- | GOTO_STATEMENT | PROCEDURE_CALL_STATEMENT
101 -- | RETURN_STATEMENT | ENTRY_CALL_STATEMENT
102 -- | REQUEUE_STATEMENT | DELAY_STATEMENT
103 -- | ABORT_STATEMENT | RAISE_STATEMENT
104 -- | CODE_STATEMENT
106 -- COMPOUND_STATEMENT ::=
107 -- IF_STATEMENT | CASE_STATEMENT
108 -- | LOOP_STATEMENT | BLOCK_STATEMENT
109 -- | ACCEPT_STATEMENT | SELECT_STATEMENT
111 -- This procedure scans a sequence of statements. The caller sets SS_Flags
112 -- to indicate acceptable termination conditions for the sequence:
114 -- SS_Flags.Eftm Terminate on ELSIF
115 -- SS_Flags.Eltm Terminate on ELSE
116 -- SS_Flags.Extm Terminate on EXCEPTION
117 -- SS_Flags.Ortm Terminate on OR
118 -- SS_Flags.Tatm Terminate on THEN ABORT (Token = ABORT on return)
119 -- SS_Flags.Whtm Terminate on WHEN
120 -- SS_Flags.Unco Unconditional terminate after scanning one statement
122 -- In addition, the scan is always terminated by encountering END or the
123 -- end of file (EOF) condition. If one of the six above terminators is
124 -- encountered with the corresponding SS_Flags flag not set, then the
125 -- action taken is as follows:
127 -- If the keyword occurs to the left of the expected column of the end
128 -- for the current sequence (as recorded in the current end context),
129 -- then it is assumed to belong to an outer context, and is considered
130 -- to terminate the sequence of statements.
132 -- If the keyword occurs to the right of, or in the expected column of
133 -- the end for the current sequence, then an error message is output,
134 -- the keyword together with its associated context is skipped, and
135 -- the statement scan continues until another terminator is found.
137 -- Note that the first action means that control can return to the caller
138 -- with Token set to a terminator other than one of those specified by the
139 -- SS parameter. The caller should treat such a case as equivalent to END.
141 -- In addition, the flag SS_Flags.Sreq is set to True to indicate that at
142 -- least one real statement (other than a pragma) is required in the
143 -- statement sequence. During the processing of the sequence, this
144 -- flag is manipulated to indicate the current status of the requirement
145 -- for a statement. For example, it is turned off by the occurrence of a
146 -- statement, and back on by a label (which requires a following statement)
148 -- Error recovery: cannot raise Error_Resync. If an error occurs during
149 -- parsing a statement, then the scan pointer is advanced past the next
150 -- semicolon and the parse continues.
152 function P_Sequence_Of_Statements (SS_Flags : SS_Rec) return List_Id is
154 Statement_Required : Boolean;
155 -- This flag indicates if a subsequent statement (other than a pragma)
156 -- is required. It is initialized from the Sreq flag, and modified as
157 -- statements are scanned (a statement turns it off, and a label turns
158 -- it back on again since a statement must follow a label).
159 -- Note : this final requirement is lifted in Ada 2012.
161 Statement_Seen : Boolean;
162 -- In Ada 2012, a label can end a sequence of statements, but the
163 -- sequence cannot contain only labels. This flag is set whenever a
164 -- label is encountered, to enforce this rule at the end of a sequence.
166 Declaration_Found : Boolean := False;
167 -- This flag is set True if a declaration is encountered, so that the
168 -- error message about declarations in the statement part is only
169 -- given once for a given sequence of statements.
171 Scan_State_Label : Saved_Scan_State;
172 Scan_State : Saved_Scan_State;
174 Statement_List : List_Id;
175 Block_Label : Name_Id;
176 Id_Node : Node_Id;
177 Name_Node : Node_Id;
179 procedure Junk_Declaration;
180 -- Procedure called to handle error of declaration encountered in
181 -- statement sequence.
183 procedure Test_Statement_Required;
184 -- Flag error if Statement_Required flag set
186 ----------------------
187 -- Junk_Declaration --
188 ----------------------
190 procedure Junk_Declaration is
191 begin
192 if (not Declaration_Found) or All_Errors_Mode then
193 Error_Msg_SC -- CODEFIX
194 ("declarations must come before BEGIN");
195 Declaration_Found := True;
196 end if;
198 Skip_Declaration (Statement_List);
199 end Junk_Declaration;
201 -----------------------------
202 -- Test_Statement_Required --
203 -----------------------------
205 procedure Test_Statement_Required is
206 function All_Pragmas return Boolean;
207 -- Return True if statement list is all pragmas
209 -----------------
210 -- All_Pragmas --
211 -----------------
213 function All_Pragmas return Boolean is
214 S : Node_Id;
215 begin
216 S := First (Statement_List);
217 while Present (S) loop
218 if Nkind (S) /= N_Pragma then
219 return False;
220 else
221 Next (S);
222 end if;
223 end loop;
225 return True;
226 end All_Pragmas;
228 -- Start of processing for Test_Statement_Required
230 begin
231 if Statement_Required then
233 -- Check no statement required after label in Ada 2012, and that
234 -- it is OK to have nothing but pragmas in a statement sequence.
236 if Ada_Version >= Ada_2012
237 and then not Is_Empty_List (Statement_List)
238 and then
239 ((Nkind (Last (Statement_List)) = N_Label
240 and then Statement_Seen)
241 or else All_Pragmas)
242 then
243 -- This Ada 2012 construct not allowed in a compiler unit
245 Check_Compiler_Unit ("null statement list", Token_Ptr);
247 declare
248 Null_Stm : constant Node_Id :=
249 Make_Null_Statement (Token_Ptr);
250 begin
251 Set_Comes_From_Source (Null_Stm, False);
252 Append_To (Statement_List, Null_Stm);
253 end;
255 -- If not Ada 2012, or not special case above, give error message
257 else
258 Error_Msg_BC -- CODEFIX
259 ("statement expected");
260 end if;
261 end if;
262 end Test_Statement_Required;
264 -- Start of processing for P_Sequence_Of_Statements
266 begin
267 Statement_List := New_List;
268 Statement_Required := SS_Flags.Sreq;
269 Statement_Seen := False;
271 loop
272 Ignore (Tok_Semicolon);
274 begin
275 if Style_Check then
276 Style.Check_Indentation;
277 end if;
279 -- Deal with reserved identifier (in assignment or call)
281 if Is_Reserved_Identifier then
282 Save_Scan_State (Scan_State); -- at possible bad identifier
283 Scan; -- and scan past it
285 -- We have an reserved word which is spelled in identifier
286 -- style, so the question is whether it really is intended
287 -- to be an identifier.
290 -- If followed by a semicolon, then it is an identifier,
291 -- with the exception of the cases tested for below.
293 (Token = Tok_Semicolon
294 and then Prev_Token /= Tok_Return
295 and then Prev_Token /= Tok_Null
296 and then Prev_Token /= Tok_Raise
297 and then Prev_Token /= Tok_End
298 and then Prev_Token /= Tok_Exit)
300 -- If followed by colon, colon-equal, or dot, then we
301 -- definitely have an identifier (could not be reserved)
303 or else Token = Tok_Colon
304 or else Token = Tok_Colon_Equal
305 or else Token = Tok_Dot
307 -- Left paren means we have an identifier except for those
308 -- reserved words that can legitimately be followed by a
309 -- left paren.
311 or else
312 (Token = Tok_Left_Paren
313 and then Prev_Token /= Tok_Case
314 and then Prev_Token /= Tok_Delay
315 and then Prev_Token /= Tok_If
316 and then Prev_Token /= Tok_Elsif
317 and then Prev_Token /= Tok_Return
318 and then Prev_Token /= Tok_When
319 and then Prev_Token /= Tok_While
320 and then Prev_Token /= Tok_Separate)
321 then
322 -- Here we have an apparent reserved identifier and the
323 -- token past it is appropriate to this usage (and would
324 -- be a definite error if this is not an identifier). What
325 -- we do is to use P_Identifier to fix up the identifier,
326 -- and then fall into the normal processing.
328 Restore_Scan_State (Scan_State); -- back to the ID
329 Scan_Reserved_Identifier (Force_Msg => False);
331 -- Not a reserved identifier after all (or at least we can't
332 -- be sure that it is), so reset the scan and continue.
334 else
335 Restore_Scan_State (Scan_State); -- back to the reserved word
336 end if;
337 end if;
339 -- Now look to see what kind of statement we have
341 case Token is
343 -- Case of end or EOF
345 when Tok_End | Tok_EOF =>
347 -- These tokens always terminate the statement sequence
349 Test_Statement_Required;
350 exit;
352 -- Case of ELSIF
354 when Tok_Elsif =>
356 -- Terminate if Eftm set or if the ELSIF is to the left
357 -- of the expected column of the end for this sequence
359 if SS_Flags.Eftm
360 or else Start_Column < Scope.Table (Scope.Last).Ecol
361 then
362 Test_Statement_Required;
363 exit;
365 -- Otherwise complain and skip past ELSIF Condition then
367 else
368 Error_Msg_SC ("ELSIF not allowed here");
369 Scan; -- past ELSIF
370 Discard_Junk_Node (P_Expression_No_Right_Paren);
371 Then_Scan;
372 Statement_Required := False;
373 end if;
375 -- Case of ELSE
377 when Tok_Else =>
379 -- Terminate if Eltm set or if the else is to the left
380 -- of the expected column of the end for this sequence
382 if SS_Flags.Eltm
383 or else Start_Column < Scope.Table (Scope.Last).Ecol
384 then
385 Test_Statement_Required;
386 exit;
388 -- Otherwise complain and skip past else
390 else
391 Error_Msg_SC ("ELSE not allowed here");
392 Scan; -- past ELSE
393 Statement_Required := False;
394 end if;
396 -- Case of exception
398 when Tok_Exception =>
399 Test_Statement_Required;
401 -- If Extm not set and the exception is not to the left of
402 -- the expected column of the end for this sequence, then we
403 -- assume it belongs to the current sequence, even though it
404 -- is not permitted.
406 if not SS_Flags.Extm and then
407 Start_Column >= Scope.Table (Scope.Last).Ecol
409 then
410 Error_Msg_SC ("exception handler not permitted here");
411 Scan; -- past EXCEPTION
412 Discard_Junk_List (Parse_Exception_Handlers);
413 end if;
415 -- Always return, in the case where we scanned out handlers
416 -- that we did not expect, Parse_Exception_Handlers returned
417 -- with Token being either end or EOF, so we are OK.
419 exit;
421 -- Case of OR
423 when Tok_Or =>
425 -- Terminate if Ortm set or if the or is to the left of the
426 -- expected column of the end for this sequence.
428 if SS_Flags.Ortm
429 or else Start_Column < Scope.Table (Scope.Last).Ecol
430 then
431 Test_Statement_Required;
432 exit;
434 -- Otherwise complain and skip past or
436 else
437 Error_Msg_SC ("OR not allowed here");
438 Scan; -- past or
439 Statement_Required := False;
440 end if;
442 -- Case of THEN (deal also with THEN ABORT)
444 when Tok_Then =>
445 Save_Scan_State (Scan_State); -- at THEN
446 Scan; -- past THEN
448 -- Terminate if THEN ABORT allowed (ATC case)
450 exit when SS_Flags.Tatm and then Token = Tok_Abort;
452 -- Otherwise we treat THEN as some kind of mess where we did
453 -- not see the associated IF, but we pick up assuming it had
454 -- been there.
456 Restore_Scan_State (Scan_State); -- to THEN
457 Append_To (Statement_List, P_If_Statement);
458 Statement_Required := False;
460 -- Case of WHEN (error because we are not in a case)
462 when Tok_When | Tok_Others =>
464 -- Terminate if Whtm set or if the WHEN is to the left of
465 -- the expected column of the end for this sequence.
467 if SS_Flags.Whtm
468 or else Start_Column < Scope.Table (Scope.Last).Ecol
469 then
470 Test_Statement_Required;
471 exit;
473 -- Otherwise complain and skip when Choice {| Choice} =>
475 else
476 Error_Msg_SC ("WHEN not allowed here");
477 Scan; -- past when
478 Discard_Junk_List (P_Discrete_Choice_List);
479 TF_Arrow;
480 Statement_Required := False;
481 end if;
483 -- Cases of statements starting with an identifier
485 when Tok_Identifier =>
486 Check_Bad_Layout;
488 -- Save scan pointers and line number in case block label
490 Id_Node := Token_Node;
491 Block_Label := Token_Name;
492 Save_Scan_State (Scan_State_Label); -- at possible label
493 Scan; -- past Id
495 -- Check for common case of assignment, since it occurs
496 -- frequently, and we want to process it efficiently.
498 if Token = Tok_Colon_Equal then
499 Scan; -- past the colon-equal
500 Append_To (Statement_List,
501 P_Assignment_Statement (Id_Node));
502 Statement_Required := False;
504 -- Check common case of procedure call, another case that
505 -- we want to speed up as much as possible.
507 elsif Token = Tok_Semicolon then
508 Change_Name_To_Procedure_Call_Statement (Id_Node);
509 Append_To (Statement_List, Id_Node);
510 Scan; -- past semicolon
511 Statement_Required := False;
513 -- Here is the special test for a suspicious label, more
514 -- accurately a suspicious name, which we think perhaps
515 -- should have been a label. If next token is one of
516 -- LOOP, FOR, WHILE, DECLARE, BEGIN, then make an entry
517 -- in the suspicious label table.
519 if Token = Tok_Loop or else
520 Token = Tok_For or else
521 Token = Tok_While or else
522 Token = Tok_Declare or else
523 Token = Tok_Begin
524 then
525 Suspicious_Labels.Append
526 ((Proc_Call => Id_Node,
527 Semicolon_Loc => Prev_Token_Ptr,
528 Start_Token => Token_Ptr));
529 end if;
531 -- Check for case of "go to" in place of "goto"
533 elsif Token = Tok_Identifier
534 and then Block_Label = Name_Go
535 and then Token_Name = Name_To
536 then
537 Error_Msg_SP -- CODEFIX
538 ("goto is one word");
539 Append_To (Statement_List, P_Goto_Statement);
540 Statement_Required := False;
542 -- Check common case of = used instead of :=, just so we
543 -- give a better error message for this special misuse.
545 elsif Token = Tok_Equal then
546 T_Colon_Equal; -- give := expected message
547 Append_To (Statement_List,
548 P_Assignment_Statement (Id_Node));
549 Statement_Required := False;
551 -- Check case of loop label or block label
553 elsif Token = Tok_Colon
554 or else (Token in Token_Class_Labeled_Stmt
555 and then not Token_Is_At_Start_Of_Line)
556 then
557 T_Colon; -- past colon (if there, or msg for missing one)
559 -- Test for more than one label
561 loop
562 exit when Token /= Tok_Identifier;
563 Save_Scan_State (Scan_State); -- at second Id
564 Scan; -- past Id
566 if Token = Tok_Colon then
567 Error_Msg_SP
568 ("only one label allowed on block or loop");
569 Scan; -- past colon on extra label
571 -- Use the second label as the "real" label
573 Scan_State_Label := Scan_State;
575 -- We will set Error_name as the Block_Label since
576 -- we really don't know which of the labels might
577 -- be used at the end of the loop or block.
579 Block_Label := Error_Name;
581 -- If Id with no colon, then backup to point to the
582 -- Id and we will issue the message below when we try
583 -- to scan out the statement as some other form.
585 else
586 Restore_Scan_State (Scan_State); -- to second Id
587 exit;
588 end if;
589 end loop;
591 -- Loop_Statement (labeled Loop_Statement)
593 if Token = Tok_Loop then
594 Append_To (Statement_List,
595 P_Loop_Statement (Id_Node));
597 -- While statement (labeled loop statement with WHILE)
599 elsif Token = Tok_While then
600 Append_To (Statement_List,
601 P_While_Statement (Id_Node));
603 -- Declare statement (labeled block statement with
604 -- DECLARE part)
606 elsif Token = Tok_Declare then
607 Append_To (Statement_List,
608 P_Declare_Statement (Id_Node));
610 -- Begin statement (labeled block statement with no
611 -- DECLARE part)
613 elsif Token = Tok_Begin then
614 Append_To (Statement_List,
615 P_Begin_Statement (Id_Node));
617 -- For statement (labeled loop statement with FOR)
619 elsif Token = Tok_For then
620 Append_To (Statement_List,
621 P_For_Statement (Id_Node));
623 -- Improper statement follows label. If we have an
624 -- expression token, then assume the colon was part
625 -- of a misplaced declaration.
627 elsif Token not in Token_Class_Eterm then
628 Restore_Scan_State (Scan_State_Label);
629 Junk_Declaration;
631 -- Otherwise complain we have inappropriate statement
633 else
634 Error_Msg_AP
635 ("loop or block statement must follow label");
636 end if;
638 Statement_Required := False;
640 -- Here we have an identifier followed by something
641 -- other than a colon, semicolon or assignment symbol.
642 -- The only valid possibility is a name extension symbol
644 elsif Token in Token_Class_Namext then
645 Restore_Scan_State (Scan_State_Label); -- to Id
646 Name_Node := P_Name;
648 -- Skip junk right parens in this context
650 Ignore (Tok_Right_Paren);
652 -- Check context following call
654 if Token = Tok_Colon_Equal then
655 Scan; -- past colon equal
656 Append_To (Statement_List,
657 P_Assignment_Statement (Name_Node));
658 Statement_Required := False;
660 -- Check common case of = used instead of :=
662 elsif Token = Tok_Equal then
663 T_Colon_Equal; -- give := expected message
664 Append_To (Statement_List,
665 P_Assignment_Statement (Name_Node));
666 Statement_Required := False;
668 -- Check apostrophe cases
670 elsif Token = Tok_Apostrophe then
671 Append_To (Statement_List,
672 P_Code_Statement (Name_Node));
673 Statement_Required := False;
675 -- The only other valid item after a name is ; which
676 -- means that the item we just scanned was a call.
678 elsif Token = Tok_Semicolon then
679 Change_Name_To_Procedure_Call_Statement (Name_Node);
680 Append_To (Statement_List, Name_Node);
681 Scan; -- past semicolon
682 Statement_Required := False;
684 -- A slash following an identifier or a selected
685 -- component in this situation is most likely a period
686 -- (see location of keys on keyboard).
688 elsif Token = Tok_Slash
689 and then (Nkind (Name_Node) = N_Identifier
690 or else
691 Nkind (Name_Node) = N_Selected_Component)
692 then
693 Error_Msg_SC -- CODEFIX
694 ("""/"" should be "".""");
695 Statement_Required := False;
696 raise Error_Resync;
698 -- Else we have a missing semicolon
700 else
701 TF_Semicolon;
703 -- Normal processing as though semicolon were present
705 Change_Name_To_Procedure_Call_Statement (Name_Node);
706 Append_To (Statement_List, Name_Node);
707 Statement_Required := False;
708 end if;
710 -- If junk after identifier, check if identifier is an
711 -- instance of an incorrectly spelled keyword. If so, we
712 -- do nothing. The Bad_Spelling_Of will have reset Token
713 -- to the appropriate keyword, so the next time round the
714 -- loop we will process the modified token. Note that we
715 -- check for ELSIF before ELSE here. That's not accidental.
716 -- We don't want to identify a misspelling of ELSE as
717 -- ELSIF, and in particular we do not want to treat ELSEIF
718 -- as ELSE IF.
720 else
721 Restore_Scan_State (Scan_State_Label); -- to identifier
723 if Bad_Spelling_Of (Tok_Abort)
724 or else Bad_Spelling_Of (Tok_Accept)
725 or else Bad_Spelling_Of (Tok_Case)
726 or else Bad_Spelling_Of (Tok_Declare)
727 or else Bad_Spelling_Of (Tok_Delay)
728 or else Bad_Spelling_Of (Tok_Elsif)
729 or else Bad_Spelling_Of (Tok_Else)
730 or else Bad_Spelling_Of (Tok_End)
731 or else Bad_Spelling_Of (Tok_Exception)
732 or else Bad_Spelling_Of (Tok_Exit)
733 or else Bad_Spelling_Of (Tok_For)
734 or else Bad_Spelling_Of (Tok_Goto)
735 or else Bad_Spelling_Of (Tok_If)
736 or else Bad_Spelling_Of (Tok_Loop)
737 or else Bad_Spelling_Of (Tok_Or)
738 or else Bad_Spelling_Of (Tok_Pragma)
739 or else Bad_Spelling_Of (Tok_Raise)
740 or else Bad_Spelling_Of (Tok_Requeue)
741 or else Bad_Spelling_Of (Tok_Return)
742 or else Bad_Spelling_Of (Tok_Select)
743 or else Bad_Spelling_Of (Tok_When)
744 or else Bad_Spelling_Of (Tok_While)
745 then
746 null;
748 -- If not a bad spelling, then we really have junk
750 else
751 Scan; -- past identifier again
753 -- If next token is first token on line, then we
754 -- consider that we were missing a semicolon after
755 -- the identifier, and process it as a procedure
756 -- call with no parameters.
758 if Token_Is_At_Start_Of_Line then
759 Change_Name_To_Procedure_Call_Statement (Id_Node);
760 Append_To (Statement_List, Id_Node);
761 T_Semicolon; -- to give error message
762 Statement_Required := False;
764 -- Otherwise we give a missing := message and
765 -- simply abandon the junk that is there now.
767 else
768 T_Colon_Equal; -- give := expected message
769 raise Error_Resync;
770 end if;
772 end if;
773 end if;
775 -- Statement starting with operator symbol. This could be
776 -- a call, a name starting an assignment, or a qualified
777 -- expression.
779 when Tok_Operator_Symbol =>
780 Check_Bad_Layout;
781 Name_Node := P_Name;
783 -- An attempt at a range attribute or a qualified expression
784 -- must be illegal here (a code statement cannot possibly
785 -- allow qualification by a function name).
787 if Token = Tok_Apostrophe then
788 Error_Msg_SC ("apostrophe illegal here");
789 raise Error_Resync;
790 end if;
792 -- Scan possible assignment if we have a name
794 if Expr_Form = EF_Name
795 and then Token = Tok_Colon_Equal
796 then
797 Scan; -- past colon equal
798 Append_To (Statement_List,
799 P_Assignment_Statement (Name_Node));
800 else
801 Change_Name_To_Procedure_Call_Statement (Name_Node);
802 Append_To (Statement_List, Name_Node);
803 end if;
805 TF_Semicolon;
806 Statement_Required := False;
808 -- Label starting with << which must precede real statement
809 -- Note: in Ada 2012, the label may end the sequence.
811 when Tok_Less_Less =>
812 if Present (Last (Statement_List))
813 and then Nkind (Last (Statement_List)) /= N_Label
814 then
815 Statement_Seen := True;
816 end if;
818 Append_To (Statement_List, P_Label);
819 Statement_Required := True;
821 -- Pragma appearing as a statement in a statement sequence
823 when Tok_Pragma =>
824 Check_Bad_Layout;
825 Append_To (Statement_List, P_Pragma);
827 -- Abort_Statement
829 when Tok_Abort =>
830 Check_Bad_Layout;
831 Append_To (Statement_List, P_Abort_Statement);
832 Statement_Required := False;
834 -- Accept_Statement
836 when Tok_Accept =>
837 Check_Bad_Layout;
838 Append_To (Statement_List, P_Accept_Statement);
839 Statement_Required := False;
841 -- Begin_Statement (Block_Statement with no declare, no label)
843 when Tok_Begin =>
844 Check_Bad_Layout;
845 Append_To (Statement_List, P_Begin_Statement);
846 Statement_Required := False;
848 -- Case_Statement
850 when Tok_Case =>
851 Check_Bad_Layout;
852 Append_To (Statement_List, P_Case_Statement);
853 Statement_Required := False;
855 -- Block_Statement with DECLARE and no label
857 when Tok_Declare =>
858 Check_Bad_Layout;
859 Append_To (Statement_List, P_Declare_Statement);
860 Statement_Required := False;
862 -- Delay_Statement
864 when Tok_Delay =>
865 Check_Bad_Layout;
866 Append_To (Statement_List, P_Delay_Statement);
867 Statement_Required := False;
869 -- Exit_Statement
871 when Tok_Exit =>
872 Check_Bad_Layout;
873 Append_To (Statement_List, P_Exit_Statement);
874 Statement_Required := False;
876 -- Loop_Statement with FOR and no label
878 when Tok_For =>
879 Check_Bad_Layout;
880 Append_To (Statement_List, P_For_Statement);
881 Statement_Required := False;
883 -- Goto_Statement
885 when Tok_Goto =>
886 Check_Bad_Layout;
887 Append_To (Statement_List, P_Goto_Statement);
888 Statement_Required := False;
890 -- If_Statement
892 when Tok_If =>
893 Check_Bad_Layout;
894 Append_To (Statement_List, P_If_Statement);
895 Statement_Required := False;
897 -- Loop_Statement
899 when Tok_Loop =>
900 Check_Bad_Layout;
901 Append_To (Statement_List, P_Loop_Statement);
902 Statement_Required := False;
904 -- Null_Statement
906 when Tok_Null =>
907 Check_Bad_Layout;
908 Append_To (Statement_List, P_Null_Statement);
909 Statement_Required := False;
911 -- Raise_Statement
913 when Tok_Raise =>
914 Check_Bad_Layout;
915 Append_To (Statement_List, P_Raise_Statement);
916 Statement_Required := False;
918 -- Requeue_Statement
920 when Tok_Requeue =>
921 Check_Bad_Layout;
922 Append_To (Statement_List, P_Requeue_Statement);
923 Statement_Required := False;
925 -- Return_Statement
927 when Tok_Return =>
928 Check_Bad_Layout;
929 Append_To (Statement_List, P_Return_Statement);
930 Statement_Required := False;
932 -- Select_Statement
934 when Tok_Select =>
935 Check_Bad_Layout;
936 Append_To (Statement_List, P_Select_Statement);
937 Statement_Required := False;
939 -- While_Statement (Block_Statement with while and no loop)
941 when Tok_While =>
942 Check_Bad_Layout;
943 Append_To (Statement_List, P_While_Statement);
944 Statement_Required := False;
946 -- Anything else is some kind of junk, signal an error message
947 -- and then raise Error_Resync, to merge with the normal
948 -- handling of a bad statement.
950 when others =>
952 if Token in Token_Class_Declk then
953 Junk_Declaration;
955 else
956 Error_Msg_BC -- CODEFIX
957 ("statement expected");
958 raise Error_Resync;
959 end if;
960 end case;
962 -- On error resynchronization, skip past next semicolon, and, since
963 -- we are still in the statement loop, look for next statement. We
964 -- set Statement_Required False to avoid an unnecessary error message
965 -- complaining that no statement was found (i.e. we consider the
966 -- junk to satisfy the requirement for a statement being present).
968 exception
969 when Error_Resync =>
970 Resync_Past_Semicolon_Or_To_Loop_Or_Then;
971 Statement_Required := False;
972 end;
974 exit when SS_Flags.Unco;
976 end loop;
978 return Statement_List;
980 end P_Sequence_Of_Statements;
982 --------------------
983 -- 5.1 Statement --
984 --------------------
986 ---------------------------
987 -- 5.1 Simple Statement --
988 ---------------------------
990 -- Parsed by P_Sequence_Of_Statements (5.1)
992 -----------------------------
993 -- 5.1 Compound Statement --
994 -----------------------------
996 -- Parsed by P_Sequence_Of_Statements (5.1)
998 -------------------------
999 -- 5.1 Null Statement --
1000 -------------------------
1002 -- NULL_STATEMENT ::= null;
1004 -- The caller has already checked that the current token is null
1006 -- Error recovery: cannot raise Error_Resync
1008 function P_Null_Statement return Node_Id is
1009 Null_Stmt_Node : Node_Id;
1011 begin
1012 Null_Stmt_Node := New_Node (N_Null_Statement, Token_Ptr);
1013 Scan; -- past NULL
1014 TF_Semicolon;
1015 return Null_Stmt_Node;
1016 end P_Null_Statement;
1018 ----------------
1019 -- 5.1 Label --
1020 ----------------
1022 -- LABEL ::= <<label_STATEMENT_IDENTIFIER>>
1024 -- STATEMENT_IDENTIFIER ::= DIRECT_NAME
1026 -- The IDENTIFIER of a STATEMENT_IDENTIFIER shall be an identifier
1027 -- (not an OPERATOR_SYMBOL)
1029 -- The caller has already checked that the current token is <<
1031 -- Error recovery: can raise Error_Resync
1033 function P_Label return Node_Id is
1034 Label_Node : Node_Id;
1036 begin
1037 Label_Node := New_Node (N_Label, Token_Ptr);
1038 Scan; -- past <<
1039 Set_Identifier (Label_Node, P_Identifier (C_Greater_Greater));
1040 T_Greater_Greater;
1041 Append_Elmt (Label_Node, Label_List);
1042 return Label_Node;
1043 end P_Label;
1045 -------------------------------
1046 -- 5.1 Statement Identifier --
1047 -------------------------------
1049 -- Statement label is parsed by P_Label (5.1)
1051 -- Loop label is parsed by P_Loop_Statement (5.5), P_For_Statement (5.5)
1052 -- or P_While_Statement (5.5)
1054 -- Block label is parsed by P_Begin_Statement (5.6) or
1055 -- P_Declare_Statement (5.6)
1057 -------------------------------
1058 -- 5.2 Assignment Statement --
1059 -------------------------------
1061 -- ASSIGNMENT_STATEMENT ::=
1062 -- variable_NAME := EXPRESSION;
1064 -- Error recovery: can raise Error_Resync
1066 function P_Assignment_Statement (LHS : Node_Id) return Node_Id is
1067 Assign_Node : Node_Id;
1069 begin
1070 Assign_Node := New_Node (N_Assignment_Statement, Prev_Token_Ptr);
1071 Set_Name (Assign_Node, LHS);
1072 Set_Expression (Assign_Node, P_Expression_No_Right_Paren);
1073 TF_Semicolon;
1074 return Assign_Node;
1075 end P_Assignment_Statement;
1077 -----------------------
1078 -- 5.3 If Statement --
1079 -----------------------
1081 -- IF_STATEMENT ::=
1082 -- if CONDITION then
1083 -- SEQUENCE_OF_STATEMENTS
1084 -- {elsif CONDITION then
1085 -- SEQUENCE_OF_STATEMENTS}
1086 -- [else
1087 -- SEQUENCE_OF_STATEMENTS]
1088 -- end if;
1090 -- The caller has checked that the initial token is IF (or in the error
1091 -- case of a mysterious THEN, the initial token may simply be THEN, in
1092 -- which case, no condition (or IF) was scanned).
1094 -- Error recovery: can raise Error_Resync
1096 function P_If_Statement return Node_Id is
1097 If_Node : Node_Id;
1098 Elsif_Node : Node_Id;
1099 Loc : Source_Ptr;
1101 procedure Add_Elsif_Part;
1102 -- An internal procedure used to scan out a single ELSIF part. On entry
1103 -- the ELSIF (or an ELSE which has been determined should be ELSIF) is
1104 -- scanned out and is in Prev_Token.
1106 procedure Check_If_Column;
1107 -- An internal procedure used to check that THEN, ELSE, or ELSIF
1108 -- appear in the right place if column checking is enabled (i.e. if
1109 -- they are the first token on the line, then they must appear in
1110 -- the same column as the opening IF).
1112 procedure Check_Then_Column;
1113 -- This procedure carries out the style checks for a THEN token
1114 -- Note that the caller has set Loc to the Source_Ptr value for
1115 -- the previous IF or ELSIF token.
1117 function Else_Should_Be_Elsif return Boolean;
1118 -- An internal routine used to do a special error recovery check when
1119 -- an ELSE is encountered. It determines if the ELSE should be treated
1120 -- as an ELSIF. A positive decision (TRUE returned, is made if the ELSE
1121 -- is followed by a sequence of tokens, starting on the same line as
1122 -- the ELSE, which are not expression terminators, followed by a THEN.
1123 -- On entry, the ELSE has been scanned out.
1125 procedure Add_Elsif_Part is
1126 begin
1127 if No (Elsif_Parts (If_Node)) then
1128 Set_Elsif_Parts (If_Node, New_List);
1129 end if;
1131 Elsif_Node := New_Node (N_Elsif_Part, Prev_Token_Ptr);
1132 Loc := Prev_Token_Ptr;
1133 Set_Condition (Elsif_Node, P_Condition);
1134 Check_Then_Column;
1135 Then_Scan;
1136 Set_Then_Statements
1137 (Elsif_Node, P_Sequence_Of_Statements (SS_Eftm_Eltm_Sreq));
1138 Append (Elsif_Node, Elsif_Parts (If_Node));
1139 end Add_Elsif_Part;
1141 procedure Check_If_Column is
1142 begin
1143 if RM_Column_Check and then Token_Is_At_Start_Of_Line
1144 and then Start_Column /= Scope.Table (Scope.Last).Ecol
1145 then
1146 Error_Msg_Col := Scope.Table (Scope.Last).Ecol;
1147 Error_Msg_SC ("(style) this token should be@");
1148 end if;
1149 end Check_If_Column;
1151 procedure Check_Then_Column is
1152 begin
1153 if Token = Tok_Then then
1154 Check_If_Column;
1156 if Style_Check then
1157 Style.Check_Then (Loc);
1158 end if;
1159 end if;
1160 end Check_Then_Column;
1162 function Else_Should_Be_Elsif return Boolean is
1163 Scan_State : Saved_Scan_State;
1165 begin
1166 if Token_Is_At_Start_Of_Line then
1167 return False;
1169 else
1170 Save_Scan_State (Scan_State);
1172 loop
1173 if Token in Token_Class_Eterm then
1174 Restore_Scan_State (Scan_State);
1175 return False;
1176 else
1177 Scan; -- past non-expression terminating token
1179 if Token = Tok_Then then
1180 Restore_Scan_State (Scan_State);
1181 return True;
1182 end if;
1183 end if;
1184 end loop;
1185 end if;
1186 end Else_Should_Be_Elsif;
1188 -- Start of processing for P_If_Statement
1190 begin
1191 If_Node := New_Node (N_If_Statement, Token_Ptr);
1193 Push_Scope_Stack;
1194 Scope.Table (Scope.Last).Etyp := E_If;
1195 Scope.Table (Scope.Last).Ecol := Start_Column;
1196 Scope.Table (Scope.Last).Sloc := Token_Ptr;
1197 Scope.Table (Scope.Last).Labl := Error;
1198 Scope.Table (Scope.Last).Node := If_Node;
1200 if Token = Tok_If then
1201 Loc := Token_Ptr;
1202 Scan; -- past IF
1203 Set_Condition (If_Node, P_Condition);
1205 -- Deal with misuse of IF expression => used instead
1206 -- of WHEN expression =>
1208 if Token = Tok_Arrow then
1209 Error_Msg_SC -- CODEFIX
1210 ("THEN expected");
1211 Scan; -- past the arrow
1212 Pop_Scope_Stack; -- remove unneeded entry
1213 raise Error_Resync;
1214 end if;
1216 Check_Then_Column;
1218 else
1219 Error_Msg_SC ("no IF for this THEN");
1220 Set_Condition (If_Node, Error);
1221 end if;
1223 Then_Scan;
1225 Set_Then_Statements
1226 (If_Node, P_Sequence_Of_Statements (SS_Eftm_Eltm_Sreq));
1228 -- This loop scans out else and elsif parts
1230 loop
1231 if Token = Tok_Elsif then
1232 Check_If_Column;
1234 if Present (Else_Statements (If_Node)) then
1235 Error_Msg_SP ("ELSIF cannot appear after ELSE");
1236 end if;
1238 Scan; -- past ELSIF
1239 Add_Elsif_Part;
1241 elsif Token = Tok_Else then
1242 Check_If_Column;
1243 Scan; -- past ELSE
1245 if Else_Should_Be_Elsif then
1246 Error_Msg_SP -- CODEFIX
1247 ("ELSE should be ELSIF");
1248 Add_Elsif_Part;
1250 else
1251 -- Here we have an else that really is an else
1253 if Present (Else_Statements (If_Node)) then
1254 Error_Msg_SP ("only one ELSE part allowed");
1255 Append_List
1256 (P_Sequence_Of_Statements (SS_Eftm_Eltm_Sreq),
1257 Else_Statements (If_Node));
1258 else
1259 Set_Else_Statements
1260 (If_Node, P_Sequence_Of_Statements (SS_Eftm_Eltm_Sreq));
1261 end if;
1262 end if;
1264 -- If anything other than ELSE or ELSIF, exit the loop. The token
1265 -- had better be END (and in fact it had better be END IF), but
1266 -- we will let End_Statements take care of checking that.
1268 else
1269 exit;
1270 end if;
1271 end loop;
1273 End_Statements;
1274 return If_Node;
1276 end P_If_Statement;
1278 --------------------
1279 -- 5.3 Condition --
1280 --------------------
1282 -- CONDITION ::= boolean_EXPRESSION
1284 function P_Condition return Node_Id is
1285 begin
1286 return P_Condition (P_Expression_No_Right_Paren);
1287 end P_Condition;
1289 function P_Condition (Cond : Node_Id) return Node_Id is
1290 begin
1291 -- It is never possible for := to follow a condition, so if we get
1292 -- a := we assume it is a mistyped equality. Note that we do not try
1293 -- to reconstruct the tree correctly in this case, but we do at least
1294 -- give an accurate error message.
1296 if Token = Tok_Colon_Equal then
1297 while Token = Tok_Colon_Equal loop
1298 Error_Msg_SC -- CODEFIX
1299 (""":="" should be ""=""");
1300 Scan; -- past junk :=
1301 Discard_Junk_Node (P_Expression_No_Right_Paren);
1302 end loop;
1304 return Cond;
1306 -- Otherwise check for redundant parentheses
1308 -- If the condition is a conditional or a quantified expression, it is
1309 -- parenthesized in the context of a condition, because of a separate
1310 -- syntax rule.
1312 else
1313 if Style_Check and then Paren_Count (Cond) > 0 then
1314 if not Nkind_In (Cond, N_If_Expression,
1315 N_Case_Expression,
1316 N_Quantified_Expression)
1317 or else Paren_Count (Cond) > 1
1318 then
1319 Style.Check_Xtra_Parens (First_Sloc (Cond));
1320 end if;
1321 end if;
1323 -- And return the result
1325 return Cond;
1326 end if;
1327 end P_Condition;
1329 -------------------------
1330 -- 5.4 Case Statement --
1331 -------------------------
1333 -- CASE_STATEMENT ::=
1334 -- case EXPRESSION is
1335 -- CASE_STATEMENT_ALTERNATIVE
1336 -- {CASE_STATEMENT_ALTERNATIVE}
1337 -- end case;
1339 -- The caller has checked that the first token is CASE
1341 -- Can raise Error_Resync
1343 function P_Case_Statement return Node_Id is
1344 Case_Node : Node_Id;
1345 Alternatives_List : List_Id;
1346 First_When_Loc : Source_Ptr;
1348 begin
1349 Case_Node := New_Node (N_Case_Statement, Token_Ptr);
1351 Push_Scope_Stack;
1352 Scope.Table (Scope.Last).Etyp := E_Case;
1353 Scope.Table (Scope.Last).Ecol := Start_Column;
1354 Scope.Table (Scope.Last).Sloc := Token_Ptr;
1355 Scope.Table (Scope.Last).Labl := Error;
1356 Scope.Table (Scope.Last).Node := Case_Node;
1358 Scan; -- past CASE
1359 Set_Expression (Case_Node, P_Expression_No_Right_Paren);
1360 TF_Is;
1362 -- Prepare to parse case statement alternatives
1364 Alternatives_List := New_List;
1365 P_Pragmas_Opt (Alternatives_List);
1366 First_When_Loc := Token_Ptr;
1368 -- Loop through case statement alternatives
1370 loop
1371 -- If we have a WHEN or OTHERS, then that's fine keep going. Note
1372 -- that it is a semantic check to ensure the proper use of OTHERS
1374 if Token = Tok_When or else Token = Tok_Others then
1375 Append (P_Case_Statement_Alternative, Alternatives_List);
1377 -- If we have an END, then probably we are at the end of the case
1378 -- but we only exit if Check_End thinks the END was reasonable.
1380 elsif Token = Tok_End then
1381 exit when Check_End;
1383 -- Here if token is other than WHEN, OTHERS or END. We definitely
1384 -- have an error, but the question is whether or not to get out of
1385 -- the case statement. We don't want to get out early, or we will
1386 -- get a slew of junk error messages for subsequent when tokens.
1388 -- If the token is not at the start of the line, or if it is indented
1389 -- with respect to the current case statement, then the best guess is
1390 -- that we are still supposed to be inside the case statement. We
1391 -- complain about the missing WHEN, and discard the junk statements.
1393 elsif not Token_Is_At_Start_Of_Line
1394 or else Start_Column > Scope.Table (Scope.Last).Ecol
1395 then
1396 Error_Msg_BC ("WHEN (case statement alternative) expected");
1398 -- Here is a possibility for infinite looping if we don't make
1399 -- progress. So try to process statements, otherwise exit
1401 declare
1402 Error_Ptr : constant Source_Ptr := Scan_Ptr;
1403 begin
1404 Discard_Junk_List (P_Sequence_Of_Statements (SS_Whtm));
1405 exit when Scan_Ptr = Error_Ptr and then Check_End;
1406 end;
1408 -- Here we have a junk token at the start of the line and it is
1409 -- not indented. If Check_End thinks there is a missing END, then
1410 -- we will get out of the case, otherwise we keep going.
1412 else
1413 exit when Check_End;
1414 end if;
1415 end loop;
1417 -- Make sure we have at least one alternative
1419 if No (First_Non_Pragma (Alternatives_List)) then
1420 Error_Msg
1421 ("WHEN expected, must have at least one alternative in case",
1422 First_When_Loc);
1423 return Error;
1425 else
1426 Set_Alternatives (Case_Node, Alternatives_List);
1427 return Case_Node;
1428 end if;
1429 end P_Case_Statement;
1431 -------------------------------------
1432 -- 5.4 Case Statement Alternative --
1433 -------------------------------------
1435 -- CASE_STATEMENT_ALTERNATIVE ::=
1436 -- when DISCRETE_CHOICE_LIST =>
1437 -- SEQUENCE_OF_STATEMENTS
1439 -- The caller has checked that the initial token is WHEN or OTHERS
1440 -- Error recovery: can raise Error_Resync
1442 function P_Case_Statement_Alternative return Node_Id is
1443 Case_Alt_Node : Node_Id;
1445 begin
1446 if Style_Check then
1447 Style.Check_Indentation;
1448 end if;
1450 Case_Alt_Node := New_Node (N_Case_Statement_Alternative, Token_Ptr);
1451 T_When; -- past WHEN (or give error in OTHERS case)
1452 Set_Discrete_Choices (Case_Alt_Node, P_Discrete_Choice_List);
1453 TF_Arrow;
1454 Set_Statements (Case_Alt_Node, P_Sequence_Of_Statements (SS_Sreq_Whtm));
1455 return Case_Alt_Node;
1456 end P_Case_Statement_Alternative;
1458 -------------------------
1459 -- 5.5 Loop Statement --
1460 -------------------------
1462 -- LOOP_STATEMENT ::=
1463 -- [LOOP_STATEMENT_IDENTIFIER:]
1464 -- [ITERATION_SCHEME] loop
1465 -- SEQUENCE_OF_STATEMENTS
1466 -- end loop [loop_IDENTIFIER];
1468 -- ITERATION_SCHEME ::=
1469 -- while CONDITION
1470 -- | for LOOP_PARAMETER_SPECIFICATION
1472 -- The parsing of loop statements is handled by one of three functions
1473 -- P_Loop_Statement, P_For_Statement or P_While_Statement depending
1474 -- on the initial keyword in the construct (excluding the identifier)
1476 -- P_Loop_Statement
1478 -- This function parses the case where no iteration scheme is present
1480 -- The caller has checked that the initial token is LOOP. The parameter
1481 -- is the node identifiers for the loop label if any (or is set to Empty
1482 -- if there is no loop label).
1484 -- Error recovery : cannot raise Error_Resync
1486 function P_Loop_Statement (Loop_Name : Node_Id := Empty) return Node_Id is
1487 Loop_Node : Node_Id;
1488 Created_Name : Node_Id;
1490 begin
1491 Push_Scope_Stack;
1492 Scope.Table (Scope.Last).Labl := Loop_Name;
1493 Scope.Table (Scope.Last).Ecol := Start_Column;
1494 Scope.Table (Scope.Last).Sloc := Token_Ptr;
1495 Scope.Table (Scope.Last).Etyp := E_Loop;
1497 Loop_Node := New_Node (N_Loop_Statement, Token_Ptr);
1498 TF_Loop;
1500 if No (Loop_Name) then
1501 Created_Name :=
1502 Make_Identifier (Sloc (Loop_Node), Set_Loop_Block_Name ('L'));
1503 Set_Comes_From_Source (Created_Name, False);
1504 Set_Has_Created_Identifier (Loop_Node, True);
1505 Set_Identifier (Loop_Node, Created_Name);
1506 Scope.Table (Scope.Last).Labl := Created_Name;
1507 else
1508 Set_Identifier (Loop_Node, Loop_Name);
1509 end if;
1511 Append_Elmt (Loop_Node, Label_List);
1512 Set_Statements (Loop_Node, P_Sequence_Of_Statements (SS_Sreq));
1513 End_Statements (Loop_Node);
1514 return Loop_Node;
1515 end P_Loop_Statement;
1517 -- P_For_Statement
1519 -- This function parses a loop statement with a FOR iteration scheme
1521 -- The caller has checked that the initial token is FOR. The parameter
1522 -- is the node identifier for the block label if any (or is set to Empty
1523 -- if there is no block label).
1525 -- Note: the caller fills in the Identifier field if a label was present
1527 -- Error recovery: can raise Error_Resync
1529 function P_For_Statement (Loop_Name : Node_Id := Empty) return Node_Id is
1530 Loop_Node : Node_Id;
1531 Iter_Scheme_Node : Node_Id;
1532 Loop_For_Flag : Boolean;
1533 Created_Name : Node_Id;
1534 Spec : Node_Id;
1536 begin
1537 Push_Scope_Stack;
1538 Scope.Table (Scope.Last).Labl := Loop_Name;
1539 Scope.Table (Scope.Last).Ecol := Start_Column;
1540 Scope.Table (Scope.Last).Sloc := Token_Ptr;
1541 Scope.Table (Scope.Last).Etyp := E_Loop;
1543 Loop_For_Flag := (Prev_Token = Tok_Loop);
1544 Scan; -- past FOR
1545 Iter_Scheme_Node := New_Node (N_Iteration_Scheme, Token_Ptr);
1546 Spec := P_Loop_Parameter_Specification;
1548 if Nkind (Spec) = N_Loop_Parameter_Specification then
1549 Set_Loop_Parameter_Specification (Iter_Scheme_Node, Spec);
1550 else
1551 Set_Iterator_Specification (Iter_Scheme_Node, Spec);
1552 end if;
1554 -- The following is a special test so that a miswritten for loop such
1555 -- as "loop for I in 1..10;" is handled nicely, without making an extra
1556 -- entry in the scope stack. We don't bother to actually fix up the
1557 -- tree in this case since it's not worth the effort. Instead we just
1558 -- eat up the loop junk, leaving the entry for what now looks like an
1559 -- unmodified loop intact.
1561 if Loop_For_Flag and then Token = Tok_Semicolon then
1562 Error_Msg_SC ("LOOP belongs here, not before FOR");
1563 Pop_Scope_Stack;
1564 return Error;
1566 -- Normal case
1568 else
1569 Loop_Node := New_Node (N_Loop_Statement, Token_Ptr);
1571 if No (Loop_Name) then
1572 Created_Name :=
1573 Make_Identifier (Sloc (Loop_Node), Set_Loop_Block_Name ('L'));
1574 Set_Comes_From_Source (Created_Name, False);
1575 Set_Has_Created_Identifier (Loop_Node, True);
1576 Set_Identifier (Loop_Node, Created_Name);
1577 Scope.Table (Scope.Last).Labl := Created_Name;
1578 else
1579 Set_Identifier (Loop_Node, Loop_Name);
1580 end if;
1582 TF_Loop;
1583 Set_Statements (Loop_Node, P_Sequence_Of_Statements (SS_Sreq));
1584 End_Statements (Loop_Node);
1585 Set_Iteration_Scheme (Loop_Node, Iter_Scheme_Node);
1586 Append_Elmt (Loop_Node, Label_List);
1587 return Loop_Node;
1588 end if;
1589 end P_For_Statement;
1591 -- P_While_Statement
1593 -- This procedure scans a loop statement with a WHILE iteration scheme
1595 -- The caller has checked that the initial token is WHILE. The parameter
1596 -- is the node identifier for the block label if any (or is set to Empty
1597 -- if there is no block label).
1599 -- Error recovery: cannot raise Error_Resync
1601 function P_While_Statement (Loop_Name : Node_Id := Empty) return Node_Id is
1602 Loop_Node : Node_Id;
1603 Iter_Scheme_Node : Node_Id;
1604 Loop_While_Flag : Boolean;
1605 Created_Name : Node_Id;
1607 begin
1608 Push_Scope_Stack;
1609 Scope.Table (Scope.Last).Labl := Loop_Name;
1610 Scope.Table (Scope.Last).Ecol := Start_Column;
1611 Scope.Table (Scope.Last).Sloc := Token_Ptr;
1612 Scope.Table (Scope.Last).Etyp := E_Loop;
1614 Loop_While_Flag := (Prev_Token = Tok_Loop);
1615 Iter_Scheme_Node := New_Node (N_Iteration_Scheme, Token_Ptr);
1616 Scan; -- past WHILE
1617 Set_Condition (Iter_Scheme_Node, P_Condition);
1619 -- The following is a special test so that a miswritten for loop such
1620 -- as "loop while I > 10;" is handled nicely, without making an extra
1621 -- entry in the scope stack. We don't bother to actually fix up the
1622 -- tree in this case since it's not worth the effort. Instead we just
1623 -- eat up the loop junk, leaving the entry for what now looks like an
1624 -- unmodified loop intact.
1626 if Loop_While_Flag and then Token = Tok_Semicolon then
1627 Error_Msg_SC ("LOOP belongs here, not before WHILE");
1628 Pop_Scope_Stack;
1629 return Error;
1631 -- Normal case
1633 else
1634 Loop_Node := New_Node (N_Loop_Statement, Token_Ptr);
1635 TF_Loop;
1637 if No (Loop_Name) then
1638 Created_Name :=
1639 Make_Identifier (Sloc (Loop_Node), Set_Loop_Block_Name ('L'));
1640 Set_Comes_From_Source (Created_Name, False);
1641 Set_Has_Created_Identifier (Loop_Node, True);
1642 Set_Identifier (Loop_Node, Created_Name);
1643 Scope.Table (Scope.Last).Labl := Created_Name;
1644 else
1645 Set_Identifier (Loop_Node, Loop_Name);
1646 end if;
1648 Set_Statements (Loop_Node, P_Sequence_Of_Statements (SS_Sreq));
1649 End_Statements (Loop_Node);
1650 Set_Iteration_Scheme (Loop_Node, Iter_Scheme_Node);
1651 Append_Elmt (Loop_Node, Label_List);
1652 return Loop_Node;
1653 end if;
1654 end P_While_Statement;
1656 ---------------------------------------
1657 -- 5.5 Loop Parameter Specification --
1658 ---------------------------------------
1660 -- LOOP_PARAMETER_SPECIFICATION ::=
1661 -- DEFINING_IDENTIFIER in [reverse] DISCRETE_SUBTYPE_DEFINITION
1663 -- Error recovery: cannot raise Error_Resync
1665 function P_Loop_Parameter_Specification return Node_Id is
1666 Loop_Param_Specification_Node : Node_Id;
1668 ID_Node : Node_Id;
1669 Scan_State : Saved_Scan_State;
1671 begin
1673 Save_Scan_State (Scan_State);
1674 ID_Node := P_Defining_Identifier (C_In);
1676 -- If the next token is OF, it indicates an Ada 2012 iterator. If the
1677 -- next token is a colon, this is also an Ada 2012 iterator, including
1678 -- a subtype indication for the loop parameter. Otherwise we parse the
1679 -- construct as a loop parameter specification. Note that the form
1680 -- "for A in B" is ambiguous, and must be resolved semantically: if B
1681 -- is a discrete subtype this is a loop specification, but if it is an
1682 -- expression it is an iterator specification. Ambiguity is resolved
1683 -- during analysis of the loop parameter specification.
1685 if Token = Tok_Of or else Token = Tok_Colon then
1686 Error_Msg_Ada_2012_Feature ("iterator", Token_Ptr);
1687 return P_Iterator_Specification (ID_Node);
1688 end if;
1690 -- The span of the Loop_Parameter_Specification starts at the
1691 -- defining identifier.
1693 Loop_Param_Specification_Node :=
1694 New_Node (N_Loop_Parameter_Specification, Sloc (ID_Node));
1695 Set_Defining_Identifier (Loop_Param_Specification_Node, ID_Node);
1697 if Token = Tok_Left_Paren then
1698 Error_Msg_SC ("subscripted loop parameter not allowed");
1699 Restore_Scan_State (Scan_State);
1700 Discard_Junk_Node (P_Name);
1702 elsif Token = Tok_Dot then
1703 Error_Msg_SC ("selected loop parameter not allowed");
1704 Restore_Scan_State (Scan_State);
1705 Discard_Junk_Node (P_Name);
1706 end if;
1708 T_In;
1710 if Token = Tok_Reverse then
1711 Scan; -- past REVERSE
1712 Set_Reverse_Present (Loop_Param_Specification_Node, True);
1713 end if;
1715 Set_Discrete_Subtype_Definition
1716 (Loop_Param_Specification_Node, P_Discrete_Subtype_Definition);
1717 return Loop_Param_Specification_Node;
1719 exception
1720 when Error_Resync =>
1721 return Error;
1722 end P_Loop_Parameter_Specification;
1724 ----------------------------------
1725 -- 5.5.1 Iterator_Specification --
1726 ----------------------------------
1728 function P_Iterator_Specification (Def_Id : Node_Id) return Node_Id is
1729 Node1 : Node_Id;
1731 begin
1732 Node1 := New_Node (N_Iterator_Specification, Sloc (Def_Id));
1733 Set_Defining_Identifier (Node1, Def_Id);
1735 if Token = Tok_Colon then
1736 Scan; -- past :
1737 Set_Subtype_Indication (Node1, P_Subtype_Indication);
1738 end if;
1740 if Token = Tok_Of then
1741 Set_Of_Present (Node1);
1742 Scan; -- past OF
1744 elsif Token = Tok_In then
1745 Scan; -- past IN
1747 elsif Prev_Token = Tok_In
1748 and then Present (Subtype_Indication (Node1))
1749 then
1750 -- Simplest recovery is to transform it into an element iterator.
1751 -- Error message on 'in" has already been emitted when parsing the
1752 -- optional constraint.
1754 Set_Of_Present (Node1);
1755 Error_Msg_N
1756 ("subtype indication is only legal on an element iterator",
1757 Subtype_Indication (Node1));
1759 else
1760 return Error;
1761 end if;
1763 if Token = Tok_Reverse then
1764 Scan; -- past REVERSE
1765 Set_Reverse_Present (Node1, True);
1766 end if;
1768 Set_Name (Node1, P_Name);
1769 return Node1;
1770 end P_Iterator_Specification;
1772 --------------------------
1773 -- 5.6 Block Statement --
1774 --------------------------
1776 -- BLOCK_STATEMENT ::=
1777 -- [block_STATEMENT_IDENTIFIER:]
1778 -- [declare
1779 -- DECLARATIVE_PART]
1780 -- begin
1781 -- HANDLED_SEQUENCE_OF_STATEMENTS
1782 -- end [block_IDENTIFIER];
1784 -- The parsing of block statements is handled by one of the two functions
1785 -- P_Declare_Statement or P_Begin_Statement depending on whether or not
1786 -- a declare section is present
1788 -- P_Declare_Statement
1790 -- This function parses a block statement with DECLARE present
1792 -- The caller has checked that the initial token is DECLARE
1794 -- Error recovery: cannot raise Error_Resync
1796 function P_Declare_Statement
1797 (Block_Name : Node_Id := Empty)
1798 return Node_Id
1800 Block_Node : Node_Id;
1801 Created_Name : Node_Id;
1803 begin
1804 Block_Node := New_Node (N_Block_Statement, Token_Ptr);
1806 Push_Scope_Stack;
1807 Scope.Table (Scope.Last).Etyp := E_Name;
1808 Scope.Table (Scope.Last).Lreq := Present (Block_Name);
1809 Scope.Table (Scope.Last).Ecol := Start_Column;
1810 Scope.Table (Scope.Last).Labl := Block_Name;
1811 Scope.Table (Scope.Last).Sloc := Token_Ptr;
1813 Scan; -- past DECLARE
1815 if No (Block_Name) then
1816 Created_Name :=
1817 Make_Identifier (Sloc (Block_Node), Set_Loop_Block_Name ('B'));
1818 Set_Comes_From_Source (Created_Name, False);
1819 Set_Has_Created_Identifier (Block_Node, True);
1820 Set_Identifier (Block_Node, Created_Name);
1821 Scope.Table (Scope.Last).Labl := Created_Name;
1822 else
1823 Set_Identifier (Block_Node, Block_Name);
1824 end if;
1826 Append_Elmt (Block_Node, Label_List);
1827 Parse_Decls_Begin_End (Block_Node);
1828 return Block_Node;
1829 end P_Declare_Statement;
1831 -- P_Begin_Statement
1833 -- This function parses a block statement with no DECLARE present
1835 -- The caller has checked that the initial token is BEGIN
1837 -- Error recovery: cannot raise Error_Resync
1839 function P_Begin_Statement
1840 (Block_Name : Node_Id := Empty)
1841 return Node_Id
1843 Block_Node : Node_Id;
1844 Created_Name : Node_Id;
1846 begin
1847 Block_Node := New_Node (N_Block_Statement, Token_Ptr);
1849 Push_Scope_Stack;
1850 Scope.Table (Scope.Last).Etyp := E_Name;
1851 Scope.Table (Scope.Last).Lreq := Present (Block_Name);
1852 Scope.Table (Scope.Last).Ecol := Start_Column;
1853 Scope.Table (Scope.Last).Labl := Block_Name;
1854 Scope.Table (Scope.Last).Sloc := Token_Ptr;
1856 if No (Block_Name) then
1857 Created_Name :=
1858 Make_Identifier (Sloc (Block_Node), Set_Loop_Block_Name ('B'));
1859 Set_Comes_From_Source (Created_Name, False);
1860 Set_Has_Created_Identifier (Block_Node, True);
1861 Set_Identifier (Block_Node, Created_Name);
1862 Scope.Table (Scope.Last).Labl := Created_Name;
1863 else
1864 Set_Identifier (Block_Node, Block_Name);
1865 end if;
1867 Append_Elmt (Block_Node, Label_List);
1869 Scope.Table (Scope.Last).Ecol := Start_Column;
1870 Scope.Table (Scope.Last).Sloc := Token_Ptr;
1871 Scan; -- past BEGIN
1872 Set_Handled_Statement_Sequence
1873 (Block_Node, P_Handled_Sequence_Of_Statements);
1874 End_Statements (Handled_Statement_Sequence (Block_Node));
1875 return Block_Node;
1876 end P_Begin_Statement;
1878 -------------------------
1879 -- 5.7 Exit Statement --
1880 -------------------------
1882 -- EXIT_STATEMENT ::=
1883 -- exit [loop_NAME] [when CONDITION];
1885 -- The caller has checked that the initial token is EXIT
1887 -- Error recovery: can raise Error_Resync
1889 function P_Exit_Statement return Node_Id is
1890 Exit_Node : Node_Id;
1892 function Missing_Semicolon_On_Exit return Boolean;
1893 -- This function deals with the following specialized situation
1895 -- when 'x' =>
1896 -- exit [identifier]
1897 -- when 'y' =>
1899 -- This looks like a messed up EXIT WHEN, when in fact the problem
1900 -- is a missing semicolon. It is called with Token pointing to the
1901 -- WHEN token, and returns True if a semicolon is missing before
1902 -- the WHEN as in the above example.
1904 -------------------------------
1905 -- Missing_Semicolon_On_Exit --
1906 -------------------------------
1908 function Missing_Semicolon_On_Exit return Boolean is
1909 State : Saved_Scan_State;
1911 begin
1912 if not Token_Is_At_Start_Of_Line then
1913 return False;
1915 elsif Scope.Table (Scope.Last).Etyp /= E_Case then
1916 return False;
1918 else
1919 Save_Scan_State (State);
1920 Scan; -- past WHEN
1921 Scan; -- past token after WHEN
1923 if Token = Tok_Arrow then
1924 Restore_Scan_State (State);
1925 return True;
1926 else
1927 Restore_Scan_State (State);
1928 return False;
1929 end if;
1930 end if;
1931 end Missing_Semicolon_On_Exit;
1933 -- Start of processing for P_Exit_Statement
1935 begin
1936 Exit_Node := New_Node (N_Exit_Statement, Token_Ptr);
1937 Scan; -- past EXIT
1939 if Token = Tok_Identifier then
1940 Set_Name (Exit_Node, P_Qualified_Simple_Name);
1942 elsif Style_Check then
1943 -- This EXIT has no name, so check that
1944 -- the innermost loop is unnamed too.
1946 Check_No_Exit_Name :
1947 for J in reverse 1 .. Scope.Last loop
1948 if Scope.Table (J).Etyp = E_Loop then
1949 if Present (Scope.Table (J).Labl)
1950 and then Comes_From_Source (Scope.Table (J).Labl)
1951 then
1952 -- Innermost loop in fact had a name, style check fails
1954 Style.No_Exit_Name (Scope.Table (J).Labl);
1955 end if;
1957 exit Check_No_Exit_Name;
1958 end if;
1959 end loop Check_No_Exit_Name;
1960 end if;
1962 if Token = Tok_When and then not Missing_Semicolon_On_Exit then
1963 Scan; -- past WHEN
1964 Set_Condition (Exit_Node, P_Condition);
1966 -- Allow IF instead of WHEN, giving error message
1968 elsif Token = Tok_If then
1969 T_When;
1970 Scan; -- past IF used in place of WHEN
1971 Set_Condition (Exit_Node, P_Expression_No_Right_Paren);
1972 end if;
1974 TF_Semicolon;
1975 return Exit_Node;
1976 end P_Exit_Statement;
1978 -------------------------
1979 -- 5.8 Goto Statement --
1980 -------------------------
1982 -- GOTO_STATEMENT ::= goto label_NAME;
1984 -- The caller has checked that the initial token is GOTO (or TO in the
1985 -- error case where GO and TO were incorrectly separated).
1987 -- Error recovery: can raise Error_Resync
1989 function P_Goto_Statement return Node_Id is
1990 Goto_Node : Node_Id;
1992 begin
1993 Goto_Node := New_Node (N_Goto_Statement, Token_Ptr);
1994 Scan; -- past GOTO (or TO)
1995 Set_Name (Goto_Node, P_Qualified_Simple_Name_Resync);
1996 Append_Elmt (Goto_Node, Goto_List);
1997 No_Constraint;
1998 TF_Semicolon;
1999 return Goto_Node;
2000 end P_Goto_Statement;
2002 ---------------------------
2003 -- Parse_Decls_Begin_End --
2004 ---------------------------
2006 -- This function parses the construct:
2008 -- DECLARATIVE_PART
2009 -- begin
2010 -- HANDLED_SEQUENCE_OF_STATEMENTS
2011 -- end [NAME];
2013 -- The caller has built the scope stack entry, and created the node to
2014 -- whose Declarations and Handled_Statement_Sequence fields are to be
2015 -- set. On return these fields are filled in (except in the case of a
2016 -- task body, where the handled statement sequence is optional, and may
2017 -- thus be Empty), and the scan is positioned past the End sequence.
2019 -- If the BEGIN is missing, then the parent node is used to help construct
2020 -- an appropriate missing BEGIN message. Possibilities for the parent are:
2022 -- N_Block_Statement declare block
2023 -- N_Entry_Body entry body
2024 -- N_Package_Body package body (begin part optional)
2025 -- N_Subprogram_Body procedure or function body
2026 -- N_Task_Body task body
2028 -- Note: in the case of a block statement, there is definitely a DECLARE
2029 -- present (because a Begin statement without a DECLARE is handled by the
2030 -- P_Begin_Statement procedure, which does not call Parse_Decls_Begin_End.
2032 -- Error recovery: cannot raise Error_Resync
2034 procedure Parse_Decls_Begin_End (Parent : Node_Id) is
2035 Body_Decl : Node_Id;
2036 Decls : List_Id;
2037 Parent_Nkind : Node_Kind;
2038 Spec_Node : Node_Id;
2039 HSS : Node_Id;
2041 procedure Missing_Begin (Msg : String);
2042 -- Called to post a missing begin message. In the normal case this is
2043 -- posted at the start of the current token. A special case arises when
2044 -- P_Declarative_Items has previously found a missing begin, in which
2045 -- case we replace the original error message.
2047 procedure Set_Null_HSS (Parent : Node_Id);
2048 -- Construct an empty handled statement sequence and install in Parent
2049 -- Leaves HSS set to reference the newly constructed statement sequence.
2051 -------------------
2052 -- Missing_Begin --
2053 -------------------
2055 procedure Missing_Begin (Msg : String) is
2056 begin
2057 if Missing_Begin_Msg = No_Error_Msg then
2058 Error_Msg_BC (Msg);
2059 else
2060 Change_Error_Text (Missing_Begin_Msg, Msg);
2062 -- Purge any messages issued after than, since a missing begin
2063 -- can cause a lot of havoc, and it is better not to dump these
2064 -- cascaded messages on the user.
2066 Purge_Messages (Get_Location (Missing_Begin_Msg), Prev_Token_Ptr);
2067 end if;
2068 end Missing_Begin;
2070 ------------------
2071 -- Set_Null_HSS --
2072 ------------------
2074 procedure Set_Null_HSS (Parent : Node_Id) is
2075 Null_Stm : Node_Id;
2077 begin
2078 Null_Stm :=
2079 Make_Null_Statement (Token_Ptr);
2080 Set_Comes_From_Source (Null_Stm, False);
2082 HSS :=
2083 Make_Handled_Sequence_Of_Statements (Token_Ptr,
2084 Statements => New_List (Null_Stm));
2085 Set_Comes_From_Source (HSS, False);
2087 Set_Handled_Statement_Sequence (Parent, HSS);
2088 end Set_Null_HSS;
2090 -- Start of processing for Parse_Decls_Begin_End
2092 begin
2093 Decls := P_Declarative_Part;
2095 if Ada_Version = Ada_83 then
2096 Check_Later_Vs_Basic_Declarations (Decls, During_Parsing => True);
2097 end if;
2099 -- Here is where we deal with the case of IS used instead of semicolon.
2100 -- Specifically, if the last declaration in the declarative part is a
2101 -- subprogram body still marked as having a bad IS, then this is where
2102 -- we decide that the IS should really have been a semicolon and that
2103 -- the body should have been a declaration. Note that if the bad IS
2104 -- had turned out to be OK (i.e. a decent begin/end was found for it),
2105 -- then the Bad_Is_Detected flag would have been reset by now.
2107 Body_Decl := Last (Decls);
2109 if Present (Body_Decl)
2110 and then Nkind (Body_Decl) = N_Subprogram_Body
2111 and then Bad_Is_Detected (Body_Decl)
2112 then
2113 -- OK, we have the case of a bad IS, so we need to fix up the tree.
2114 -- What we have now is a subprogram body with attached declarations
2115 -- and a possible statement sequence.
2117 -- First step is to take the declarations that were part of the bogus
2118 -- subprogram body and append them to the outer declaration chain.
2119 -- In other words we append them past the body (which we will later
2120 -- convert into a declaration).
2122 Append_List (Declarations (Body_Decl), Decls);
2124 -- Now take the handled statement sequence of the bogus body and
2125 -- set it as the statement sequence for the outer construct. Note
2126 -- that it may be empty (we specially allowed a missing BEGIN for
2127 -- a subprogram body marked as having a bad IS -- see below).
2129 Set_Handled_Statement_Sequence (Parent,
2130 Handled_Statement_Sequence (Body_Decl));
2132 -- Next step is to convert the old body node to a declaration node
2134 Spec_Node := Specification (Body_Decl);
2135 Change_Node (Body_Decl, N_Subprogram_Declaration);
2136 Set_Specification (Body_Decl, Spec_Node);
2138 -- Final step is to put the declarations for the parent where
2139 -- they belong, and then fall through the IF to scan out the
2140 -- END statements.
2142 Set_Declarations (Parent, Decls);
2144 -- This is the normal case (i.e. any case except the bad IS case)
2145 -- If we have a BEGIN, then scan out the sequence of statements, and
2146 -- also reset the expected column for the END to match the BEGIN.
2148 else
2149 Set_Declarations (Parent, Decls);
2151 if Token = Tok_Begin then
2152 if Style_Check then
2153 Style.Check_Indentation;
2154 end if;
2156 Error_Msg_Col := Scope.Table (Scope.Last).Ecol;
2158 if RM_Column_Check
2159 and then Token_Is_At_Start_Of_Line
2160 and then Start_Column /= Error_Msg_Col
2161 then
2162 Error_Msg_SC ("(style) BEGIN in wrong column, should be@");
2164 else
2165 Scope.Table (Scope.Last).Ecol := Start_Column;
2166 end if;
2168 Scope.Table (Scope.Last).Sloc := Token_Ptr;
2169 Scan; -- past BEGIN
2170 Set_Handled_Statement_Sequence (Parent,
2171 P_Handled_Sequence_Of_Statements);
2173 -- No BEGIN present
2175 else
2176 Parent_Nkind := Nkind (Parent);
2178 -- A special check for the missing IS case. If we have a
2179 -- subprogram body that was marked as having a suspicious
2180 -- IS, and the current token is END, then we simply confirm
2181 -- the suspicion, and do not require a BEGIN to be present
2183 if Parent_Nkind = N_Subprogram_Body
2184 and then Token = Tok_End
2185 and then Scope.Table (Scope.Last).Etyp = E_Suspicious_Is
2186 then
2187 Scope.Table (Scope.Last).Etyp := E_Bad_Is;
2189 -- Otherwise BEGIN is not required for a package body, so we
2190 -- don't mind if it is missing, but we do construct a dummy
2191 -- one (so that we have somewhere to set End_Label).
2193 -- However if we have something other than a BEGIN which
2194 -- looks like it might be statements, then we signal a missing
2195 -- BEGIN for these cases as well. We define "something which
2196 -- looks like it might be statements" as a token other than
2197 -- END, EOF, or a token which starts declarations.
2199 elsif Parent_Nkind = N_Package_Body
2200 and then (Token = Tok_End
2201 or else Token = Tok_EOF
2202 or else Token in Token_Class_Declk)
2203 then
2204 Set_Null_HSS (Parent);
2206 -- These are cases in which a BEGIN is required and not present
2208 else
2209 Set_Null_HSS (Parent);
2211 -- Prepare to issue error message
2213 Error_Msg_Sloc := Scope.Table (Scope.Last).Sloc;
2214 Error_Msg_Node_1 := Scope.Table (Scope.Last).Labl;
2216 -- Now issue appropriate message
2218 if Parent_Nkind = N_Block_Statement then
2219 Missing_Begin ("missing BEGIN for DECLARE#!");
2221 elsif Parent_Nkind = N_Entry_Body then
2222 Missing_Begin ("missing BEGIN for ENTRY#!");
2224 elsif Parent_Nkind = N_Subprogram_Body then
2225 if Nkind (Specification (Parent))
2226 = N_Function_Specification
2227 then
2228 Missing_Begin ("missing BEGIN for function&#!");
2229 else
2230 Missing_Begin ("missing BEGIN for procedure&#!");
2231 end if;
2233 -- The case for package body arises only when
2234 -- we have possible statement junk present.
2236 elsif Parent_Nkind = N_Package_Body then
2237 Missing_Begin ("missing BEGIN for package body&#!");
2239 else
2240 pragma Assert (Parent_Nkind = N_Task_Body);
2241 Missing_Begin ("missing BEGIN for task body&#!");
2242 end if;
2244 -- Here we pick up the statements after the BEGIN that
2245 -- should have been present but was not. We don't insist
2246 -- on statements being present if P_Declarative_Part had
2247 -- already found a missing BEGIN, since it might have
2248 -- swallowed a lone statement into the declarative part.
2250 if Missing_Begin_Msg /= No_Error_Msg
2251 and then Token = Tok_End
2252 then
2253 null;
2254 else
2255 Set_Handled_Statement_Sequence (Parent,
2256 P_Handled_Sequence_Of_Statements);
2257 end if;
2258 end if;
2259 end if;
2260 end if;
2262 -- Here with declarations and handled statement sequence scanned
2264 if Present (Handled_Statement_Sequence (Parent)) then
2265 End_Statements (Handled_Statement_Sequence (Parent));
2266 else
2267 End_Statements;
2268 end if;
2270 -- We know that End_Statements removed an entry from the scope stack
2271 -- (because it is required to do so under all circumstances). We can
2272 -- therefore reference the entry it removed one past the stack top.
2273 -- What we are interested in is whether it was a case of a bad IS.
2275 if Scope.Table (Scope.Last + 1).Etyp = E_Bad_Is then
2276 Error_Msg -- CODEFIX
2277 ("|IS should be "";""", Scope.Table (Scope.Last + 1).S_Is);
2278 Set_Bad_Is_Detected (Parent, True);
2279 end if;
2281 end Parse_Decls_Begin_End;
2283 -------------------------
2284 -- Set_Loop_Block_Name --
2285 -------------------------
2287 function Set_Loop_Block_Name (L : Character) return Name_Id is
2288 begin
2289 Name_Buffer (1) := L;
2290 Name_Buffer (2) := '_';
2291 Name_Len := 2;
2292 Loop_Block_Count := Loop_Block_Count + 1;
2293 Add_Nat_To_Name_Buffer (Loop_Block_Count);
2294 return Name_Find;
2295 end Set_Loop_Block_Name;
2297 ---------------
2298 -- Then_Scan --
2299 ---------------
2301 procedure Then_Scan is
2302 begin
2303 TF_Then;
2305 while Token = Tok_Then loop
2306 Error_Msg_SC -- CODEFIX
2307 ("redundant THEN");
2308 TF_Then;
2309 end loop;
2311 if Token = Tok_And or else Token = Tok_Or then
2312 Error_Msg_SC ("unexpected logical operator");
2313 Scan; -- past logical operator
2315 if (Prev_Token = Tok_And and then Token = Tok_Then)
2316 or else
2317 (Prev_Token = Tok_Or and then Token = Tok_Else)
2318 then
2319 Scan;
2320 end if;
2322 Discard_Junk_Node (P_Expression);
2323 end if;
2325 if Token = Tok_Then then
2326 Scan;
2327 end if;
2328 end Then_Scan;
2330 end Ch5;