| blob | f6ad3987faa9b77ef0d6d6a0bb479eb00b91284c |
1 /* Process source files and output type information.
2 Copyright (C) 2006-2017 Free Software Foundation, Inc.
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it under
7 the terms of the GNU General Public License as published by the Free
8 Software Foundation; either version 3, or (at your option) any later
9 version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
12 WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 for more details.
16 You should have received a copy of the GNU General Public License
17 along with GCC; see the file COPYING3. If not see
18 <http://www.gnu.org/licenses/>. */
20 #ifdef HOST_GENERATOR_FILE
22 #define GENERATOR_FILE 1
23 #else
25 #endif
29 /* This is a simple recursive-descent parser which understands a subset of
30 the C type grammar.
32 Rule functions are suffixed _seq if they scan a sequence of items;
33 _opt if they may consume zero tokens; _seqopt if both are true. The
34 "consume_" prefix indicates that a sequence of tokens is parsed for
35 syntactic correctness and then thrown away. */
37 /* Simple one-token lookahead mechanism. */
39 struct token
40 {
44 };
47 /* Retrieve the code of the current token; if there is no current token,
48 get the next one from the lexer. */
51 {
53 {
56 }
58 }
60 /* Retrieve the value of the current token (if any) and mark it consumed.
61 The next call to token() will get another token from the lexer. */
64 {
67 }
69 /* Diagnostics. */
71 /* This array is indexed by the token code minus CHAR_TOKEN_OFFSET. */
90 "a C++ keyword to ignore"
91 };
93 /* This array is indexed by token code minus FIRST_TOKEN_WITH_VALUE. */
103 };
105 /* Produce a printable representation for a token defined by CODE and
106 VALUE. This sometimes returns pointers into malloc memory and
107 sometimes not, therefore it is unsafe to free the pointer it
108 returns, so that memory is leaked. This does not matter, as this
109 function is only used for diagnostics, and in a successful run of
110 the program there will be none. */
113 {
120 else
122 value);
123 }
125 /* Convenience wrapper around print_token which produces the printable
126 representation of the current token. */
129 {
131 }
133 /* Report a parse error on the current line, with diagnostic MSG.
134 Behaves as standard printf with respect to additional arguments and
135 format escapes. */
136 static void ATTRIBUTE_PRINTF_1
138 {
151 }
153 /* If the next token does not have code T, report a parse error; otherwise
154 return the token's value. */
157 {
161 {
165 }
167 }
169 /* As per require, but do not advance. */
172 {
176 {
180 }
182 }
184 /* If the next token does not have one of the codes T1 or T2, report a
185 parse error; otherwise return the token's value. */
188 {
192 {
197 }
199 }
201 /* If the next token does not have one of the codes T1, T2, T3 or T4, report a
202 parse error; otherwise return the token's value. */
205 {
209 {
215 }
217 }
219 /* Near-terminals. */
221 /* C-style string constant concatenation: STRING+
222 Bare STRING should appear nowhere else in this file. */
225 {
234 {
243 }
245 }
248 /* The caller has detected a template declaration that starts
249 with TMPL_NAME. Parse up to the closing '>'. This recognizes
250 simple template declarations of the form ID<ID1,ID2,...,IDn>,
251 potentially with a single level of indirection e.g.
252 ID<ID1 *, ID2, ID3 *, ..., IDn>.
253 It does not try to parse anything more sophisticated than that.
255 Returns the template declaration string "ID<ID1,ID2,...,IDn>". */
259 {
263 /* Recognize the opening '<'. */
267 /* Read the comma-separated list of identifiers. */
270 {
272 {
276 }
280 {
283 }
285 {
290 }
292 {
297 }
300 {
302 {
307 }
308 else
310 }
311 else
314 }
316 }
319 /* typedef_name: either an ID, or a template type
320 specification of the form ID<t1,t2,...,tn>. */
324 {
328 else
330 }
332 /* Absorb a sequence of tokens delimited by balanced ()[]{}. */
333 static void
335 {
339 {
366 }
367 }
369 /* Absorb a sequence of tokens, possibly including ()[]{}-delimited
370 expressions, until we encounter an end-of-statement marker (a ';' or
371 a '}') outside any such delimiters; absorb that too. */
373 static void
375 {
378 {
408 }
409 }
411 /* Absorb a sequence of tokens, possibly including ()[]{}-delimited
412 expressions, until we encounter a comma or semicolon outside any
413 such delimiters; absorb that too. Returns true if the loop ended
414 with a comma. */
416 static bool
418 {
421 {
456 }
457 }
458 \f
460 /* GTY(()) option handling. */
463 /* Optional parenthesized string: ('(' string_seq ')')? */
464 static options_p
466 {
470 {
474 }
476 }
478 /* absdecl: type '*'*
479 -- a vague approximation to what the C standard calls an abstract
480 declarator. The only kinds that are actually used are those that
481 are just a bare type and those that have trailing pointer-stars.
482 Further kinds should be implemented if and when they become
483 necessary. Used only within GTY(()) option values, therefore
484 further GTY(()) tags within the type are invalid. Note that the
485 return value has already been run through adjust_field_type. */
486 static type_p
488 {
489 type_p ty;
490 options_p opts;
494 {
497 }
503 }
505 /* Type-option: '(' absdecl ')' */
506 static options_p
508 {
509 type_p ty;
514 }
516 /* Nested pointer data: '(' type '*'* ',' string_seq ',' string_seq ')' */
517 static options_p
519 {
520 type_p ty;
532 }
534 /* One GTY(()) option:
535 ID str_optvalue_opt
536 | PTR_ALIAS type_optvalue
537 | NESTED_PTR nestedptr_optvalue
538 */
539 static options_p
541 {
543 {
563 }
564 }
566 /* One comma-separated list of options. */
567 static options_p
569 {
570 options_p o;
574 {
577 }
579 }
581 /* GTY marker: 'GTY' '(' '(' option_seq? ')' ')' */
582 static options_p
584 {
594 }
596 /* Optional GTY marker. */
597 static options_p
599 {
603 }
606 \f
607 /* Declarators. The logic here is largely lifted from c-parser.c.
608 Note that we do not have to process abstract declarators, which can
609 appear only in parameter type lists or casts (but see absdecl,
610 above). Also, type qualifiers are thrown out in gengtype-lex.l so
611 we don't have to do it. */
613 /* array_and_function_declarators_opt:
614 \epsilon
615 array_and_function_declarators_opt ARRAY
616 array_and_function_declarators_opt '(' ... ')'
618 where '...' indicates stuff we ignore except insofar as grouping
619 symbols ()[]{} must balance.
621 Subroutine of direct_declarator - do not use elsewhere. */
623 static type_p
625 {
627 {
630 }
632 {
633 /* We don't need exact types for functions. */
637 }
638 else
640 }
644 /* direct_declarator:
645 '(' inner_declarator ')'
646 '(' \epsilon ')' <-- C++ ctors/dtors
647 gtymarker_opt ID array_and_function_declarators_opt
649 Subroutine of declarator, mutually recursive with inner_declarator;
650 do not use elsewhere.
652 IN_STRUCT is true if we are called while parsing structures or classes. */
654 static type_p
657 {
658 /* The first token in a direct-declarator must be an ID, a
659 GTY marker, or an open parenthesis. */
661 {
664 /* fall through */
668 /* If the next token is '(', we are parsing a function declaration.
669 Functions are ignored by gengtype, so we return NULL. */
675 /* If the declarator starts with a '(', we have three options. We
676 are either parsing 'TYPE (*ID)' (i.e., a function pointer)
677 or 'TYPE(...)'.
679 The latter will be a constructor iff we are inside a
680 structure or class. Otherwise, it could be a typedef, but
681 since we explicitly reject typedefs inside structures, we can
682 assume that we found a ctor and return NULL. */
685 {
686 /* Found a constructor. Find and consume the closing ')'. */
690 /* Tell the caller to ignore this. */
692 }
698 /* Any C++ keyword like 'operator' means that we are not looking
699 at a regular data declarator. */
705 /* Do _not_ advance if what we have is a close squiggle brace, as
706 we will get much better error recovery that way. */
710 }
712 }
714 /* The difference between inner_declarator and declarator is in the
715 handling of stars. Consider this declaration:
717 char * (*pfc) (void)
719 It declares a pointer to a function that takes no arguments and
720 returns a char*. To construct the correct type for this
721 declaration, the star outside the parentheses must be processed
722 _before_ the function type, the star inside the parentheses must
723 be processed _after_ the function type. To accomplish this,
724 declarator() creates pointers before recursing (it is actually
725 coded as a while loop), whereas inner_declarator() recurses before
726 creating pointers. */
728 /* inner_declarator:
729 '*' inner_declarator
730 direct_declarator
732 Mutually recursive subroutine of direct_declarator; do not use
733 elsewhere.
735 IN_STRUCT is true if we are called while parsing structures or classes. */
737 static type_p
740 {
742 {
743 type_p inner;
748 else
750 }
751 else
753 }
755 /* declarator: '*'+ direct_declarator
757 This is the sole public interface to this part of the grammar.
758 Arguments are the type known so far, a pointer to where the name
759 may be stored, and a pointer to where GTY options may be stored.
761 IN_STRUCT is true when we are called to parse declarators inside
762 a structure or class.
764 Returns the final type. */
766 static type_p
769 {
773 {
776 }
778 }
779 \f
780 /* Types and declarations. */
782 /* Structure field(s) declaration:
783 (
784 type bitfield ';'
785 | type declarator bitfield? ( ',' declarator bitfield? )+ ';'
786 )*
788 Knows that such declarations must end with a close brace (or,
789 erroneously, at EOF).
790 */
791 static pair_p
793 {
801 {
804 /* Ignore access-control keywords ("public:" etc). */
806 {
813 }
816 {
819 }
821 do
822 {
825 /* There could be any number of weird things after the declarator,
826 notably bitfield declarations and __attribute__s. If this
827 function returns true, the last thing was a comma, so we have
828 more than one declarator paired with the current type. */
840 }
842 }
844 }
846 /* Return true if OPTS contain the option named STR. */
848 bool
850 {
855 }
858 /* This is called type(), but what it parses (sort of) is what C calls
859 declaration-specifiers and specifier-qualifier-list:
861 SCALAR
862 | ID // typedef
863 | (STRUCT|UNION) ID? gtymarker? ( '{' gtymarker? struct_field_seq '}' )?
864 | ENUM ID ( '{' ... '}' )?
866 Returns a partial type; under some conditions (notably
867 "struct foo GTY((...)) thing;") it may write an options
868 structure to *OPTSP.
870 NESTED is true when parsing a declaration already known to have a
871 GTY marker. In these cases, typedef and enum declarations are not
872 allowed because gengtype only understands types at the global
873 scope. */
875 static type_p
877 {
881 {
891 /* By returning NULL here, we indicate to the caller that they
892 should ignore everything following this keyword up to the
893 next ';' or '}'. */
898 {
901 /* GTY annotations follow attribute syntax
902 GTY_BEFORE_ID is for union/struct declarations
903 GTY_AFTER_ID is for variable declarations. */
904 enum
905 {
906 NO_GTY,
907 GTY_BEFORE_ID,
908 GTY_AFTER_ID
913 /* Top-level structures that are not explicitly tagged GTY(())
914 are treated as mere forward declarations. This is because
915 there are a lot of structures that we don't need to know
916 about, and some of those have C++ and macro constructs that
917 we cannot handle. */
919 {
922 }
926 else
931 /* Unfortunately above GTY_TOKEN check does not capture the
932 typedef struct_type GTY case. */
934 {
937 }
942 {
944 {
945 /* For GTY-marked types that are not "user", parse some C++
946 inheritance specifications.
947 We require single-inheritance from a non-template type. */
950 /* This may be either an access specifier, or the base name. */
959 }
960 else
961 {
962 /* For types lacking GTY-markings, skip over C++ inheritance
963 specification (and thus avoid having to parse e.g. template
964 types). */
967 }
968 }
971 {
973 {
974 pair_p fields;
980 {
984 }
985 else
986 {
987 /* Do not look inside user defined structures. */
992 }
995 base_class);
996 }
997 }
1003 }
1006 /* In C++, a typedef inside a struct/class/union defines a new
1007 type for that inner scope. We cannot support this in
1008 gengtype because we have no concept of scoping.
1010 We handle typedefs in the global scope separately (see
1011 parse_file), so if we find a 'typedef', we must be inside
1012 a struct. */
1015 "automatic GTY markers. Use GTY((user)) to mark "
1024 else
1032 /* If after parsing the enum we are at the end of the statement,
1033 and we are currently inside a structure, then this was an
1034 enum declaration inside this scope.
1036 We cannot support this for the same reason we cannot support
1037 'typedef' inside structures (see the TYPEDEF handler above).
1038 If this happens, emit an error and return NULL. */
1040 {
1042 "with automatic GTY markers. Use GTY((user)) to mark "
1046 }
1054 }
1055 }
1056 \f
1057 /* Top level constructs. */
1059 /* Dispatch declarations beginning with 'typedef'. */
1061 static void
1063 {
1066 options_p opts;
1077 do
1078 {
1083 /* Yet another place where we could have junk (notably attributes)
1084 after the declarator. */
1088 }
1090 }
1092 /* Structure definition: type() does all the work. */
1094 static void
1096 {
1097 options_p dummy;
1099 /* There may be junk after the type: notably, we cannot currently
1100 distinguish 'struct foo *function(prototype);' from 'struct foo;'
1101 ... we could call declarator(), but it's a waste of time at
1102 present. Instead, just eat whatever token is currently lookahead
1103 and go back to lexical skipping mode. */
1105 }
1107 /* GC root declaration:
1108 (extern|static) gtymarker? type ID array_declarators_opt (';'|'=')
1109 If the gtymarker is not present, we ignore the rest of the declaration. */
1110 static void
1112 {
1119 {
1122 }
1136 {
1139 }
1140 }
1142 /* Parse the file FNAME for GC-relevant declarations and definitions.
1143 This is the only entry point to this file. */
1144 void
1146 {
1149 {
1151 {
1172 }
1174 }
1176 eof:
1179 }