/* YACC parser for C syntax and for Objective C. -*-c-*- Copyright (C) 1987, 88, 89, 92, 93, 1994 Free Software Foundation, Inc. This file is part of GNU CC. GNU CC is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. GNU CC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GNU CC; see the file COPYING. If not, write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */ /* This file defines the grammar of C and that of Objective C. ifobjc ... end ifobjc conditionals contain code for Objective C only. ifc ... end ifc conditionals contain code for C only. Sed commands in Makefile.in are used to convert this file into c-parse.y and into objc-parse.y. */ /* To whomever it may concern: I have heard that such a thing was once written by AT&T, but I have never seen it. */ ifobjc %expect 22 end ifobjc ifc %expect 10 /* These are the 10 conflicts you should get in parse.output; the state numbers may vary if minor changes in the grammar are made. State 41 contains 1 shift/reduce conflict. (Two ways to recover from error.) State 97 contains 1 shift/reduce conflict. (Two ways to recover from error.) State 104 contains 1 shift/reduce conflict. (Two ways to recover from error.) State 108 contains 1 shift/reduce conflict. (Two ways to recover from error.) State 124 contains 1 shift/reduce conflict. (See comment at component_decl.) State 191 contains 1 shift/reduce conflict. (Two ways to recover from error.) State 204 contains 1 shift/reduce conflict. (Two ways to recover from error.) State 210 contains 1 shift/reduce conflict. (Two ways to recover from error.) State 449 contains 2 shift/reduce conflicts. (Four ways to parse this.) */ end ifc %{ #include #include #include #include "config.h" #include "tree.h" #include "input.h" #include "c-lex.h" #include "c-tree.h" #include "flags.h" #ifdef MULTIBYTE_CHARS #include #include #endif ifobjc #include "objc-act.h" end ifobjc /* Since parsers are distinct for each language, put the language string definition here. */ ifobjc char *language_string = "GNU Obj-C"; end ifobjc ifc char *language_string = "GNU C"; end ifc #ifndef errno extern int errno; #endif void yyerror (); /* Like YYERROR but do call yyerror. */ #define YYERROR1 { yyerror ("syntax error"); YYERROR; } /* Cause the `yydebug' variable to be defined. */ #define YYDEBUG 1 %} %start program %union {long itype; tree ttype; enum tree_code code; char *filename; int lineno; } /* All identifiers that are not reserved words and are not declared typedefs in the current block */ %token IDENTIFIER /* All identifiers that are declared typedefs in the current block. In some contexts, they are treated just like IDENTIFIER, but they can also serve as typespecs in declarations. */ %token TYPENAME /* Reserved words that specify storage class. yylval contains an IDENTIFIER_NODE which indicates which one. */ %token SCSPEC /* Reserved words that specify type. yylval contains an IDENTIFIER_NODE which indicates which one. */ %token TYPESPEC /* Reserved words that qualify type: "const" or "volatile". yylval contains an IDENTIFIER_NODE which indicates which one. */ %token TYPE_QUAL /* Character or numeric constants. yylval is the node for the constant. */ %token CONSTANT /* String constants in raw form. yylval is a STRING_CST node. */ %token STRING /* "...", used for functions with variable arglists. */ %token ELLIPSIS /* the reserved words */ /* SCO include files test "ASM", so use something else. */ %token SIZEOF ENUM STRUCT UNION IF ELSE WHILE DO FOR SWITCH CASE DEFAULT %token BREAK CONTINUE RETURN GOTO ASM_KEYWORD TYPEOF ALIGNOF ALIGN %token ATTRIBUTE EXTENSION LABEL %token REALPART IMAGPART /* Add precedence rules to solve dangling else s/r conflict */ %nonassoc IF %nonassoc ELSE /* Define the operator tokens and their precedences. The value is an integer because, if used, it is the tree code to use in the expression made from the operator. */ %right ASSIGN '=' %right '?' ':' %left OROR %left ANDAND %left '|' %left '^' %left '&' %left EQCOMPARE %left ARITHCOMPARE %left LSHIFT RSHIFT %left '+' '-' %left '*' '/' '%' %right UNARY PLUSPLUS MINUSMINUS %left HYPERUNARY %left POINTSAT '.' '(' '[' /* The Objective-C keywords. These are included in C and in Objective C, so that the token codes are the same in both. */ %token INTERFACE IMPLEMENTATION END SELECTOR DEFS ENCODE %token CLASSNAME PUBLIC PRIVATE PROTECTED PROTOCOL OBJECTNAME CLASS ALIAS /* Objective-C string constants in raw form. yylval is an OBJC_STRING_CST node. */ %token OBJC_STRING %type unop %type identifier IDENTIFIER TYPENAME CONSTANT expr nonnull_exprlist exprlist %type expr_no_commas cast_expr unary_expr primary string STRING %type typed_declspecs reserved_declspecs %type typed_typespecs reserved_typespecquals %type declmods typespec typespecqual_reserved %type SCSPEC TYPESPEC TYPE_QUAL nonempty_type_quals maybe_type_qual %type initdecls notype_initdecls initdcl notype_initdcl %type init maybeasm %type asm_operands nonnull_asm_operands asm_operand asm_clobbers %type maybe_attribute attributes attribute attribute_list attrib %type any_word %type compstmt %type declarator %type notype_declarator after_type_declarator %type parm_declarator %type structsp component_decl_list component_decl_list2 %type component_decl components component_declarator %type enumlist enumerator %type typename absdcl absdcl1 type_quals %type xexpr parms parm identifiers %type parmlist parmlist_1 parmlist_2 %type parmlist_or_identifiers parmlist_or_identifiers_1 %type identifiers_or_typenames %type setspecs %type save_filename %type save_lineno ifobjc /* the Objective-C nonterminals */ %type ivar_decl_list ivar_decls ivar_decl ivars ivar_declarator %type methoddecl unaryselector keywordselector selector %type keyworddecl receiver objcmessageexpr messageargs %type keywordexpr keywordarglist keywordarg %type myparms myparm optparmlist reservedwords objcselectorexpr %type selectorarg keywordnamelist keywordname objcencodeexpr %type objc_string protocolrefs identifier_list objcprotocolexpr %type CLASSNAME OBJC_STRING OBJECTNAME end ifobjc %{ /* Number of statements (loosely speaking) seen so far. */ static int stmt_count; /* Input file and line number of the end of the body of last simple_if; used by the stmt-rule immediately after simple_if returns. */ static char *if_stmt_file; static int if_stmt_line; /* List of types and structure classes of the current declaration. */ static tree current_declspecs; /* Stack of saved values of current_declspecs. */ static tree declspec_stack; /* 1 if we explained undeclared var errors. */ static int undeclared_variable_notice; ifobjc /* Objective-C specific information */ tree objc_interface_context; tree objc_implementation_context; tree objc_method_context; tree objc_ivar_chain; tree objc_ivar_context; enum tree_code objc_inherit_code; int objc_receiver_context; int objc_public_flag; end ifobjc /* Tell yyparse how to print a token's value, if yydebug is set. */ #define YYPRINT(FILE,YYCHAR,YYLVAL) yyprint(FILE,YYCHAR,YYLVAL) extern void yyprint (); %} %% program: /* empty */ { if (pedantic) pedwarn ("ANSI C forbids an empty source file"); ifobjc objc_finish (); end ifobjc } | extdefs { /* In case there were missing closebraces, get us back to the global binding level. */ while (! global_bindings_p ()) poplevel (0, 0, 0); ifobjc objc_finish (); end ifobjc } ; /* the reason for the strange actions in this rule is so that notype_initdecls when reached via datadef can find a valid list of type and sc specs in $0. */ extdefs: {$$ = NULL_TREE; } extdef | extdefs {$$ = NULL_TREE; } extdef ; extdef: fndef | datadef ifobjc | objcdef end ifobjc | ASM_KEYWORD '(' expr ')' ';' { STRIP_NOPS ($3); if ((TREE_CODE ($3) == ADDR_EXPR && TREE_CODE (TREE_OPERAND ($3, 0)) == STRING_CST) || TREE_CODE ($3) == STRING_CST) assemble_asm ($3); else error ("argument of `asm' is not a constant string"); } ; datadef: setspecs notype_initdecls ';' { if (pedantic) error ("ANSI C forbids data definition with no type or storage class"); else if (!flag_traditional) warning ("data definition has no type or storage class"); } | declmods setspecs notype_initdecls ';' {} | typed_declspecs setspecs initdecls ';' {} | declmods ';' { pedwarn ("empty declaration"); } | typed_declspecs ';' { shadow_tag ($1); } | error ';' | error '}' | ';' { if (pedantic) pedwarn ("ANSI C does not allow extra `;' outside of a function"); } ; fndef: typed_declspecs setspecs declarator { if (! start_function ($1, $3, 0)) YYERROR1; reinit_parse_for_function (); } xdecls { store_parm_decls (); } compstmt_or_error { finish_function (0); } | typed_declspecs setspecs declarator error { } | declmods setspecs notype_declarator { if (! start_function ($1, $3, 0)) YYERROR1; reinit_parse_for_function (); } xdecls { store_parm_decls (); } compstmt_or_error { finish_function (0); } | declmods setspecs notype_declarator error { } | setspecs notype_declarator { if (! start_function (NULL_TREE, $2, 0)) YYERROR1; reinit_parse_for_function (); } xdecls { store_parm_decls (); } compstmt_or_error { finish_function (0); } | setspecs notype_declarator error { } ; identifier: IDENTIFIER | TYPENAME ifobjc | OBJECTNAME | CLASSNAME end ifobjc ; unop: '&' { $$ = ADDR_EXPR; } | '-' { $$ = NEGATE_EXPR; } | '+' { $$ = CONVERT_EXPR; } | PLUSPLUS { $$ = PREINCREMENT_EXPR; } | MINUSMINUS { $$ = PREDECREMENT_EXPR; } | '~' { $$ = BIT_NOT_EXPR; } | '!' { $$ = TRUTH_NOT_EXPR; } ; expr: nonnull_exprlist { $$ = build_compound_expr ($1); } ; exprlist: /* empty */ { $$ = NULL_TREE; } | nonnull_exprlist ; nonnull_exprlist: expr_no_commas { $$ = build_tree_list (NULL_TREE, $1); } | nonnull_exprlist ',' expr_no_commas { chainon ($1, build_tree_list (NULL_TREE, $3)); } ; unary_expr: primary | '*' cast_expr %prec UNARY { $$ = build_indirect_ref ($2, "unary *"); } /* __extension__ turns off -pedantic for following primary. */ | EXTENSION { $1 = pedantic; pedantic = 0; } cast_expr %prec UNARY { $$ = $3; pedantic = $1; } | unop cast_expr %prec UNARY { $$ = build_unary_op ($1, $2, 0); overflow_warning ($$); } /* Refer to the address of a label as a pointer. */ | ANDAND identifier { tree label = lookup_label ($2); if (label == 0) $$ = null_pointer_node; else { TREE_USED (label) = 1; $$ = build1 (ADDR_EXPR, ptr_type_node, label); TREE_CONSTANT ($$) = 1; } } /* This seems to be impossible on some machines, so let's turn it off. You can use __builtin_next_arg to find the anonymous stack args. | '&' ELLIPSIS { tree types = TYPE_ARG_TYPES (TREE_TYPE (current_function_decl)); $$ = error_mark_node; if (TREE_VALUE (tree_last (types)) == void_type_node) error ("`&...' used in function with fixed number of arguments"); else { if (pedantic) pedwarn ("ANSI C forbids `&...'"); $$ = tree_last (DECL_ARGUMENTS (current_function_decl)); $$ = build_unary_op (ADDR_EXPR, $$, 0); } } */ | SIZEOF unary_expr %prec UNARY { if (TREE_CODE ($2) == COMPONENT_REF && DECL_BIT_FIELD (TREE_OPERAND ($2, 1))) error ("`sizeof' applied to a bit-field"); $$ = c_sizeof (TREE_TYPE ($2)); } | SIZEOF '(' typename ')' %prec HYPERUNARY { $$ = c_sizeof (groktypename ($3)); } | ALIGNOF unary_expr %prec UNARY { $$ = c_alignof_expr ($2); } | ALIGNOF '(' typename ')' %prec HYPERUNARY { $$ = c_alignof (groktypename ($3)); } | REALPART cast_expr %prec UNARY { $$ = build_unary_op (REALPART_EXPR, $2, 0); } | IMAGPART cast_expr %prec UNARY { $$ = build_unary_op (IMAGPART_EXPR, $2, 0); } ; cast_expr: unary_expr | '(' typename ')' cast_expr %prec UNARY { tree type = groktypename ($2); $$ = build_c_cast (type, $4); } | '(' typename ')' '{' { start_init (NULL_TREE, NULL, 0); $2 = groktypename ($2); really_start_incremental_init ($2); } initlist_maybe_comma '}' %prec UNARY { char *name; tree result = pop_init_level (0); tree type = $2; finish_init (); if (pedantic) pedwarn ("ANSI C forbids constructor expressions"); if (TYPE_NAME (type) != 0) { if (TREE_CODE (TYPE_NAME (type)) == IDENTIFIER_NODE) name = IDENTIFIER_POINTER (TYPE_NAME (type)); else name = IDENTIFIER_POINTER (DECL_NAME (TYPE_NAME (type))); } else name = ""; $$ = result; if (TREE_CODE (type) == ARRAY_TYPE && TYPE_SIZE (type) == 0) { int failure = complete_array_type (type, $$, 1); if (failure) abort (); } } ; expr_no_commas: cast_expr | expr_no_commas '+' expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas '-' expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas '*' expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas '/' expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas '%' expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas LSHIFT expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas RSHIFT expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas ARITHCOMPARE expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas EQCOMPARE expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas '&' expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas '|' expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas '^' expr_no_commas { $$ = parser_build_binary_op ($2, $1, $3); } | expr_no_commas ANDAND expr_no_commas { $$ = parser_build_binary_op (TRUTH_ANDIF_EXPR, $1, $3); } | expr_no_commas OROR expr_no_commas { $$ = parser_build_binary_op (TRUTH_ORIF_EXPR, $1, $3); } | expr_no_commas '?' xexpr ':' expr_no_commas { $$ = build_conditional_expr ($1, $3, $5); } | expr_no_commas '=' expr_no_commas { $$ = build_modify_expr ($1, NOP_EXPR, $3); C_SET_EXP_ORIGINAL_CODE ($$, MODIFY_EXPR); } | expr_no_commas ASSIGN expr_no_commas { $$ = build_modify_expr ($1, $2, $3); /* This inhibits warnings in truthvalue_conversion. */ C_SET_EXP_ORIGINAL_CODE ($$, ERROR_MARK); } ; primary: IDENTIFIER { $$ = lastiddecl; if (!$$ || $$ == error_mark_node) { if (yychar == YYEMPTY) yychar = YYLEX; if (yychar == '(') { ifobjc tree decl; if (objc_receiver_context && ! (objc_receiver_context && strcmp (IDENTIFIER_POINTER ($1), "super"))) /* we have a message to super */ $$ = get_super_receiver (); else if (objc_method_context && (decl = is_ivar (objc_ivar_chain, $1))) { if (is_private (decl)) $$ = error_mark_node; else $$ = build_ivar_reference ($1); } else end ifobjc { /* Ordinary implicit function declaration. */ $$ = implicitly_declare ($1); assemble_external ($$); TREE_USED ($$) = 1; } } else if (current_function_decl == 0) { error ("`%s' undeclared here (not in a function)", IDENTIFIER_POINTER ($1)); $$ = error_mark_node; } else { ifobjc tree decl; if (objc_receiver_context && ! strcmp (IDENTIFIER_POINTER ($1), "super")) /* we have a message to super */ $$ = get_super_receiver (); else if (objc_method_context && (decl = is_ivar (objc_ivar_chain, $1))) { if (is_private (decl)) $$ = error_mark_node; else $$ = build_ivar_reference ($1); } else end ifobjc { if (IDENTIFIER_GLOBAL_VALUE ($1) != error_mark_node || IDENTIFIER_ERROR_LOCUS ($1) != current_function_decl) { error ("`%s' undeclared (first use this function)", IDENTIFIER_POINTER ($1)); if (! undeclared_variable_notice) { error ("(Each undeclared identifier is reported only once"); error ("for each function it appears in.)"); undeclared_variable_notice = 1; } } $$ = error_mark_node; /* Prevent repeated error messages. */ IDENTIFIER_GLOBAL_VALUE ($1) = error_mark_node; IDENTIFIER_ERROR_LOCUS ($1) = current_function_decl; } } } else if (TREE_TYPE ($$) == error_mark_node) $$ = error_mark_node; else if (C_DECL_ANTICIPATED ($$)) { /* The first time we see a build-in function used, if it has not been declared. */ C_DECL_ANTICIPATED ($$) = 0; if (yychar == YYEMPTY) yychar = YYLEX; if (yychar == '(') { /* Omit the implicit declaration we would ordinarily do, so we don't lose the actual built in type. But print a diagnostic for the mismatch. */ ifobjc if (objc_method_context && is_ivar (objc_ivar_chain, $1)) error ("Instance variable `%s' implicitly declared as function", IDENTIFIER_POINTER (DECL_NAME ($$))); else end ifobjc if (TREE_CODE ($$) != FUNCTION_DECL) error ("`%s' implicitly declared as function", IDENTIFIER_POINTER (DECL_NAME ($$))); else if ((TYPE_MODE (TREE_TYPE (TREE_TYPE ($$))) != TYPE_MODE (integer_type_node)) && (TREE_TYPE (TREE_TYPE ($$)) != void_type_node)) pedwarn ("type mismatch in implicit declaration for built-in function `%s'", IDENTIFIER_POINTER (DECL_NAME ($$))); /* If it really returns void, change that to int. */ if (TREE_TYPE (TREE_TYPE ($$)) == void_type_node) TREE_TYPE ($$) = build_function_type (integer_type_node, TYPE_ARG_TYPES (TREE_TYPE ($$))); } else pedwarn ("built-in function `%s' used without declaration", IDENTIFIER_POINTER (DECL_NAME ($$))); /* Do what we would ordinarily do when a fn is used. */ assemble_external ($$); TREE_USED ($$) = 1; } else { assemble_external ($$); TREE_USED ($$) = 1; ifobjc /* we have a definition - still check if iVariable */ if (!objc_receiver_context || (objc_receiver_context && strcmp (IDENTIFIER_POINTER ($1), "super"))) { tree decl; if (objc_method_context && (decl = is_ivar (objc_ivar_chain, $1))) { if (IDENTIFIER_LOCAL_VALUE ($1)) warning ("local declaration of `%s' hides instance variable", IDENTIFIER_POINTER ($1)); else { if (is_private (decl)) $$ = error_mark_node; else $$ = build_ivar_reference ($1); } } } else /* we have a message to super */ $$ = get_super_receiver (); end ifobjc } if (TREE_CODE ($$) == CONST_DECL) { $$ = DECL_INITIAL ($$); /* This is to prevent an enum whose value is 0 from being considered a null pointer constant. */ $$ = build1 (NOP_EXPR, TREE_TYPE ($$), $$); TREE_CONSTANT ($$) = 1; } } | CONSTANT | string { $$ = combine_strings ($1); } | '(' expr ')' { char class = TREE_CODE_CLASS (TREE_CODE ($2)); if (class == 'e' || class == '1' || class == '2' || class == '<') C_SET_EXP_ORIGINAL_CODE ($2, ERROR_MARK); $$ = $2; } | '(' error ')' { $$ = error_mark_node; } | '(' { if (current_function_decl == 0) { error ("braced-group within expression allowed only inside a function"); YYERROR; } /* We must force a BLOCK for this level so that, if it is not expanded later, there is a way to turn off the entire subtree of blocks that are contained in it. */ keep_next_level (); push_iterator_stack (); push_label_level (); $$ = expand_start_stmt_expr (); } compstmt ')' { tree rtl_exp; if (pedantic) pedwarn ("ANSI C forbids braced-groups within expressions"); pop_iterator_stack (); pop_label_level (); rtl_exp = expand_end_stmt_expr ($2); /* The statements have side effects, so the group does. */ TREE_SIDE_EFFECTS (rtl_exp) = 1; if (TREE_CODE ($3) == BLOCK) { /* Make a BIND_EXPR for the BLOCK already made. */ $$ = build (BIND_EXPR, TREE_TYPE (rtl_exp), NULL_TREE, rtl_exp, $3); /* Remove the block from the tree at this point. It gets put back at the proper place when the BIND_EXPR is expanded. */ delete_block ($3); } else $$ = $3; } | primary '(' exprlist ')' %prec '.' { $$ = build_function_call ($1, $3); } | primary '[' expr ']' %prec '.' { $$ = build_array_ref ($1, $3); } | primary '.' identifier { ifobjc if (doing_objc_thang) { if (is_public ($1, $3)) $$ = build_component_ref ($1, $3); else $$ = error_mark_node; } else end ifobjc $$ = build_component_ref ($1, $3); } | primary POINTSAT identifier { tree expr = build_indirect_ref ($1, "->"); ifobjc if (doing_objc_thang) { if (is_public (expr, $3)) $$ = build_component_ref (expr, $3); else $$ = error_mark_node; } else end ifobjc $$ = build_component_ref (expr, $3); } | primary PLUSPLUS { $$ = build_unary_op (POSTINCREMENT_EXPR, $1, 0); } | primary MINUSMINUS { $$ = build_unary_op (POSTDECREMENT_EXPR, $1, 0); } ifobjc | objcmessageexpr { $$ = build_message_expr ($1); } | objcselectorexpr { $$ = build_selector_expr ($1); } | objcprotocolexpr { $$ = build_protocol_expr ($1); } | objcencodeexpr { $$ = build_encode_expr ($1); } | objc_string { $$ = build_objc_string_object ($1); } end ifobjc ; /* Produces a STRING_CST with perhaps more STRING_CSTs chained onto it. */ string: STRING | string STRING { $$ = chainon ($1, $2); } ; ifobjc /* Produces an OBJC_STRING_CST with prehaps more OBJC_STRING_CSTs chained onto it. */ objc_string: OBJC_STRING | objc_string OBJC_STRING { $$ = chainon ($1, $2); } ; end ifobjc xdecls: /* empty */ | datadecls | datadecls ELLIPSIS /* ... is used here to indicate a varargs function. */ { c_mark_varargs (); if (pedantic) pedwarn ("ANSI C does not permit use of `varargs.h'"); } ; /* The following are analogous to lineno_decl, decls and decl except that they do not allow nested functions. They are used for old-style parm decls. */ lineno_datadecl: save_filename save_lineno datadecl { } ; datadecls: lineno_datadecl | errstmt | datadecls lineno_datadecl | lineno_datadecl errstmt ; datadecl: typed_declspecs setspecs initdecls ';' { current_declspecs = TREE_VALUE (declspec_stack); declspec_stack = TREE_CHAIN (declspec_stack); resume_momentary ($2); } | declmods setspecs notype_initdecls ';' { current_declspecs = TREE_VALUE (declspec_stack); declspec_stack = TREE_CHAIN (declspec_stack); resume_momentary ($2); } | typed_declspecs ';' { shadow_tag_warned ($1, 1); pedwarn ("empty declaration"); } | declmods ';' { pedwarn ("empty declaration"); } ; /* This combination which saves a lineno before a decl is the normal thing to use, rather than decl itself. This is to avoid shift/reduce conflicts in contexts where statement labels are allowed. */ lineno_decl: save_filename save_lineno decl { } ; decls: lineno_decl | errstmt | decls lineno_decl | lineno_decl errstmt ; /* records the type and storage class specs to use for processing the declarators that follow. Maintains a stack of outer-level values of current_declspecs, for the sake of parm declarations nested in function declarators. */ setspecs: /* empty */ { $$ = suspend_momentary (); pending_xref_error (); declspec_stack = tree_cons (NULL_TREE, current_declspecs, declspec_stack); current_declspecs = $0; } ; decl: typed_declspecs setspecs initdecls ';' { current_declspecs = TREE_VALUE (declspec_stack); declspec_stack = TREE_CHAIN (declspec_stack); resume_momentary ($2); } | declmods setspecs notype_initdecls ';' { current_declspecs = TREE_VALUE (declspec_stack); declspec_stack = TREE_CHAIN (declspec_stack); resume_momentary ($2); } | typed_declspecs setspecs nested_function { current_declspecs = TREE_VALUE (declspec_stack); declspec_stack = TREE_CHAIN (declspec_stack); resume_momentary ($2); } | declmods setspecs notype_nested_function { current_declspecs = TREE_VALUE (declspec_stack); declspec_stack = TREE_CHAIN (declspec_stack); resume_momentary ($2); } | typed_declspecs ';' { shadow_tag ($1); } | declmods ';' { pedwarn ("empty declaration"); } ; /* Declspecs which contain at least one type specifier or typedef name. (Just `const' or `volatile' is not enough.) A typedef'd name following these is taken as a name to be declared. */ typed_declspecs: typespec reserved_declspecs { $$ = tree_cons (NULL_TREE, $1, $2); } | declmods typespec reserved_declspecs { $$ = chainon ($3, tree_cons (NULL_TREE, $2, $1)); } ; reserved_declspecs: /* empty */ { $$ = NULL_TREE; } | reserved_declspecs typespecqual_reserved { $$ = tree_cons (NULL_TREE, $2, $1); } | reserved_declspecs SCSPEC { if (extra_warnings) warning ("`%s' is not at beginning of declaration", IDENTIFIER_POINTER ($2)); $$ = tree_cons (NULL_TREE, $2, $1); } ; /* List of just storage classes and type modifiers. A declaration can start with just this, but then it cannot be used to redeclare a typedef-name. */ declmods: TYPE_QUAL { $$ = tree_cons (NULL_TREE, $1, NULL_TREE); TREE_STATIC ($$) = 1; } | SCSPEC { $$ = tree_cons (NULL_TREE, $1, NULL_TREE); } | declmods TYPE_QUAL { $$ = tree_cons (NULL_TREE, $2, $1); TREE_STATIC ($$) = 1; } | declmods SCSPEC { if (extra_warnings && TREE_STATIC ($1)) warning ("`%s' is not at beginning of declaration", IDENTIFIER_POINTER ($2)); $$ = tree_cons (NULL_TREE, $2, $1); TREE_STATIC ($$) = TREE_STATIC ($1); } ; /* Used instead of declspecs where storage classes are not allowed (that is, for typenames and structure components). Don't accept a typedef-name if anything but a modifier precedes it. */ typed_typespecs: typespec reserved_typespecquals { $$ = tree_cons (NULL_TREE, $1, $2); } | nonempty_type_quals typespec reserved_typespecquals { $$ = chainon ($3, tree_cons (NULL_TREE, $2, $1)); } ; reserved_typespecquals: /* empty */ { $$ = NULL_TREE; } | reserved_typespecquals typespecqual_reserved { $$ = tree_cons (NULL_TREE, $2, $1); } ; /* A typespec (but not a type qualifier). Once we have seen one of these in a declaration, if a typedef name appears then it is being redeclared. */ typespec: TYPESPEC | structsp | TYPENAME { /* For a typedef name, record the meaning, not the name. In case of `foo foo, bar;'. */ $$ = lookup_name ($1); } ifobjc | CLASSNAME protocolrefs { $$ = get_static_reference ($1, $2); } | OBJECTNAME protocolrefs { $$ = get_object_reference ($2); } end ifobjc | TYPEOF '(' expr ')' { $$ = TREE_TYPE ($3); } | TYPEOF '(' typename ')' { $$ = groktypename ($3); } ; /* A typespec that is a reserved word, or a type qualifier. */ typespecqual_reserved: TYPESPEC | TYPE_QUAL | structsp ; initdecls: initdcl | initdecls ',' initdcl ; notype_initdecls: notype_initdcl | notype_initdecls ',' initdcl ; maybeasm: /* empty */ { $$ = NULL_TREE; } | ASM_KEYWORD '(' string ')' { if (TREE_CHAIN ($3)) $3 = combine_strings ($3); $$ = $3; } ; initdcl: declarator maybeasm maybe_attribute '=' { $$ = start_decl ($1, current_declspecs, 1); decl_attributes ($$, $3); start_init ($$, $2, global_bindings_p ()); } init /* Note how the declaration of the variable is in effect while its init is parsed! */ { finish_init (); decl_attributes ($5, $3); finish_decl ($5, $6, $2); } | declarator maybeasm maybe_attribute { tree d = start_decl ($1, current_declspecs, 0); decl_attributes (d, $3); finish_decl (d, NULL_TREE, $2); } ; notype_initdcl: notype_declarator maybeasm maybe_attribute '=' { $$ = start_decl ($1, current_declspecs, 1); decl_attributes ($$, $3); start_init ($$, $2, global_bindings_p ()); } init /* Note how the declaration of the variable is in effect while its init is parsed! */ { finish_init (); decl_attributes ($5, $3); finish_decl ($5, $6, $2); } | notype_declarator maybeasm maybe_attribute { tree d = start_decl ($1, current_declspecs, 0); decl_attributes (d, $3); finish_decl (d, NULL_TREE, $2); } ; /* the * rules are dummies to accept the Apollo extended syntax so that the header files compile. */ maybe_attribute: /* empty */ { $$ = NULL_TREE; } | attributes { $$ = $1; } ; attributes: attribute { $$ = $1; } | attributes attribute { $$ = chainon ($1, $2); } ; attribute: ATTRIBUTE '(' '(' attribute_list ')' ')' { $$ = $4; } ; attribute_list: attrib { $$ = build_tree_list (NULL_TREE, $1); } | attribute_list ',' attrib { $$ = chainon ($1, build_tree_list (NULL_TREE, $3)); } ; attrib: /* empty */ { $$ = NULL_TREE; } | any_word { $$ = $1; } | any_word '(' IDENTIFIER ')' { $$ = tree_cons ($1, NULL_TREE, build_tree_list (NULL_TREE, $3)); } | any_word '(' IDENTIFIER ',' nonnull_exprlist ')' { $$ = tree_cons ($1, NULL_TREE, tree_cons (NULL_TREE, $3, $5)); } | any_word '(' nonnull_exprlist ')' { $$ = tree_cons ($1, NULL_TREE, $3); } ; /* This still leaves out most reserved keywords, shouldn't we include them? */ any_word: identifier | SCSPEC | TYPESPEC | TYPE_QUAL ; /* Initializers. `init' is the entry point. */ init: expr_no_commas | '{' { really_start_incremental_init (NULL_TREE); /* Note that the call to clear_momentary is in process_init_element. */ push_momentary (); } initlist_maybe_comma '}' { $$ = pop_init_level (0); if ($$ == error_mark_node && ! (yychar == STRING || yychar == CONSTANT)) pop_momentary (); else pop_momentary_nofree (); } | error { $$ = error_mark_node; } ; /* `initlist_maybe_comma' is the guts of an initializer in braces. */ initlist_maybe_comma: /* empty */ { if (pedantic) pedwarn ("ANSI C forbids empty initializer braces"); } | initlist1 maybecomma ; initlist1: initelt | initlist1 ',' initelt ; /* `initelt' is a single element of an initializer. It may use braces. */ initelt: expr_no_commas { process_init_element ($1); } | '{' { push_init_level (0); } initlist_maybe_comma '}' { process_init_element (pop_init_level (0)); } | error /* These are for labeled elements. The syntax for an array element initializer conflicts with the syntax for an Objective-C message, so don't include these productions in the Objective-C grammer. */ ifc | '[' expr_no_commas ELLIPSIS expr_no_commas ']' '=' { set_init_index ($2, $4); } initelt | '[' expr_no_commas ']' '=' { set_init_index ($2, NULL_TREE); } initelt | '[' expr_no_commas ']' { set_init_index ($2, NULL_TREE); } initelt end ifc | identifier ':' { set_init_label ($1); } initelt | '.' identifier '=' { set_init_label ($2); } initelt ; nested_function: declarator { push_c_function_context (); if (! start_function (current_declspecs, $1, 1)) { pop_c_function_context (); YYERROR1; } reinit_parse_for_function (); store_parm_decls (); } /* This used to use compstmt_or_error. That caused a bug with input `f(g) int g {}', where the use of YYERROR1 above caused an error which then was handled by compstmt_or_error. There followed a repeated execution of that same rule, which called YYERROR1 again, and so on. */ compstmt { finish_function (1); pop_c_function_context (); } ; notype_nested_function: notype_declarator { push_c_function_context (); if (! start_function (current_declspecs, $1, 1)) { pop_c_function_context (); YYERROR1; } reinit_parse_for_function (); store_parm_decls (); } /* This used to use compstmt_or_error. That caused a bug with input `f(g) int g {}', where the use of YYERROR1 above caused an error which then was handled by compstmt_or_error. There followed a repeated execution of that same rule, which called YYERROR1 again, and so on. */ compstmt { finish_function (1); pop_c_function_context (); } ; /* Any kind of declarator (thus, all declarators allowed after an explicit typespec). */ declarator: after_type_declarator | notype_declarator ; /* A declarator that is allowed only after an explicit typespec. */ after_type_declarator: '(' after_type_declarator ')' { $$ = $2; } | after_type_declarator '(' parmlist_or_identifiers %prec '.' { $$ = build_nt (CALL_EXPR, $1, $3, NULL_TREE); } /* | after_type_declarator '(' error ')' %prec '.' { $$ = build_nt (CALL_EXPR, $1, NULL_TREE, NULL_TREE); poplevel (0, 0, 0); } */ | after_type_declarator '[' expr ']' %prec '.' { $$ = build_nt (ARRAY_REF, $1, $3); } | after_type_declarator '[' ']' %prec '.' { $$ = build_nt (ARRAY_REF, $1, NULL_TREE); } | '*' type_quals after_type_declarator %prec UNARY { $$ = make_pointer_declarator ($2, $3); } | TYPENAME ifobjc | OBJECTNAME end ifobjc ; /* Kinds of declarator that can appear in a parameter list in addition to notype_declarator. This is like after_type_declarator but does not allow a typedef name in parentheses as an identifier (because it would conflict with a function with that typedef as arg). */ parm_declarator: parm_declarator '(' parmlist_or_identifiers %prec '.' { $$ = build_nt (CALL_EXPR, $1, $3, NULL_TREE); } /* | parm_declarator '(' error ')' %prec '.' { $$ = build_nt (CALL_EXPR, $1, NULL_TREE, NULL_TREE); poplevel (0, 0, 0); } */ | parm_declarator '[' expr ']' %prec '.' { $$ = build_nt (ARRAY_REF, $1, $3); } | parm_declarator '[' ']' %prec '.' { $$ = build_nt (ARRAY_REF, $1, NULL_TREE); } | '*' type_quals parm_declarator %prec UNARY { $$ = make_pointer_declarator ($2, $3); } | TYPENAME ; /* A declarator allowed whether or not there has been an explicit typespec. These cannot redeclare a typedef-name. */ notype_declarator: notype_declarator '(' parmlist_or_identifiers %prec '.' { $$ = build_nt (CALL_EXPR, $1, $3, NULL_TREE); } /* | notype_declarator '(' error ')' %prec '.' { $$ = build_nt (CALL_EXPR, $1, NULL_TREE, NULL_TREE); poplevel (0, 0, 0); } */ | '(' notype_declarator ')' { $$ = $2; } | '*' type_quals notype_declarator %prec UNARY { $$ = make_pointer_declarator ($2, $3); } | notype_declarator '[' expr ']' %prec '.' { $$ = build_nt (ARRAY_REF, $1, $3); } | notype_declarator '[' ']' %prec '.' { $$ = build_nt (ARRAY_REF, $1, NULL_TREE); } | IDENTIFIER ; structsp: STRUCT identifier '{' { $$ = start_struct (RECORD_TYPE, $2); /* Start scope of tag before parsing components. */ } component_decl_list '}' { $$ = finish_struct ($4, $5); /* Really define the structure. */ } | STRUCT '{' component_decl_list '}' { $$ = finish_struct (start_struct (RECORD_TYPE, NULL_TREE), $3); } | STRUCT identifier { $$ = xref_tag (RECORD_TYPE, $2); } | UNION identifier '{' { $$ = start_struct (UNION_TYPE, $2); } component_decl_list '}' { $$ = finish_struct ($4, $5); } | UNION '{' component_decl_list '}' { $$ = finish_struct (start_struct (UNION_TYPE, NULL_TREE), $3); } | UNION identifier { $$ = xref_tag (UNION_TYPE, $2); } | ENUM identifier '{' { $3 = suspend_momentary (); $$ = start_enum ($2); } enumlist maybecomma_warn '}' { $$ = finish_enum ($4, nreverse ($5)); resume_momentary ($3); } | ENUM '{' { $2 = suspend_momentary (); $$ = start_enum (NULL_TREE); } enumlist maybecomma_warn '}' { $$ = finish_enum ($3, nreverse ($4)); resume_momentary ($2); } | ENUM identifier { $$ = xref_tag (ENUMERAL_TYPE, $2); } ; maybecomma: /* empty */ | ',' ; maybecomma_warn: /* empty */ | ',' { if (pedantic) pedwarn ("comma at end of enumerator list"); } ; component_decl_list: component_decl_list2 { $$ = $1; } | component_decl_list2 component_decl { $$ = chainon ($1, $2); pedwarn ("no semicolon at end of struct or union"); } ; component_decl_list2: /* empty */ { $$ = NULL_TREE; } | component_decl_list2 component_decl ';' { $$ = chainon ($1, $2); } | component_decl_list2 ';' { if (pedantic) pedwarn ("extra semicolon in struct or union specified"); } ifobjc /* foo(sizeof(struct{ @defs(ClassName)})); */ | DEFS '(' CLASSNAME ')' { tree interface = lookup_interface ($3); if (interface) $$ = get_class_ivars (interface); else { error ("Cannot find interface declaration for `%s'", IDENTIFIER_POINTER ($3)); $$ = NULL_TREE; } } end ifobjc ; /* There is a shift-reduce conflict here, because `components' may start with a `typename'. It happens that shifting (the default resolution) does the right thing, because it treats the `typename' as part of a `typed_typespecs'. It is possible that this same technique would allow the distinction between `notype_initdecls' and `initdecls' to be eliminated. But I am being cautious and not trying it. */ component_decl: typed_typespecs setspecs components { $$ = $3; current_declspecs = TREE_VALUE (declspec_stack); declspec_stack = TREE_CHAIN (declspec_stack); resume_momentary ($2); } | typed_typespecs { if (pedantic) pedwarn ("ANSI C forbids member declarations with no members"); shadow_tag($1); $$ = NULL_TREE; } | nonempty_type_quals setspecs components { $$ = $3; current_declspecs = TREE_VALUE (declspec_stack); declspec_stack = TREE_CHAIN (declspec_stack); resume_momentary ($2); } | nonempty_type_quals { if (pedantic) pedwarn ("ANSI C forbids member declarations with no members"); shadow_tag($1); $$ = NULL_TREE; } | error { $$ = NULL_TREE; } ; components: component_declarator | components ',' component_declarator { $$ = chainon ($1, $3); } ; component_declarator: save_filename save_lineno declarator maybe_attribute { $$ = grokfield ($1, $2, $3, current_declspecs, NULL_TREE); decl_attributes ($$, $4); } | save_filename save_lineno declarator ':' expr_no_commas maybe_attribute { $$ = grokfield ($1, $2, $3, current_declspecs, $5); decl_attributes ($$, $6); } | save_filename save_lineno ':' expr_no_commas maybe_attribute { $$ = grokfield ($1, $2, NULL_TREE, current_declspecs, $4); decl_attributes ($$, $5); } ; /* We chain the enumerators in reverse order. They are put in forward order where enumlist is used. (The order used to be significant, but no longer is so. However, we still maintain the order, just to be clean.) */ enumlist: enumerator | enumlist ',' enumerator { $$ = chainon ($3, $1); } | error { $$ = error_mark_node; } ; enumerator: identifier { $$ = build_enumerator ($1, NULL_TREE); } | identifier '=' expr_no_commas { $$ = build_enumerator ($1, $3); } ; typename: typed_typespecs absdcl { $$ = build_tree_list ($1, $2); } | nonempty_type_quals absdcl { $$ = build_tree_list ($1, $2); } ; absdcl: /* an absolute declarator */ /* empty */ { $$ = NULL_TREE; } | absdcl1 ; nonempty_type_quals: TYPE_QUAL { $$ = tree_cons (NULL_TREE, $1, NULL_TREE); } | nonempty_type_quals TYPE_QUAL { $$ = tree_cons (NULL_TREE, $2, $1); } ; type_quals: /* empty */ { $$ = NULL_TREE; } | type_quals TYPE_QUAL { $$ = tree_cons (NULL_TREE, $2, $1); } ; absdcl1: /* a nonempty absolute declarator */ '(' absdcl1 ')' { $$ = $2; } /* `(typedef)1' is `int'. */ | '*' type_quals absdcl1 %prec UNARY { $$ = make_pointer_declarator ($2, $3); } | '*' type_quals %prec UNARY { $$ = make_pointer_declarator ($2, NULL_TREE); } | absdcl1 '(' parmlist %prec '.' { $$ = build_nt (CALL_EXPR, $1, $3, NULL_TREE); } | absdcl1 '[' expr ']' %prec '.' { $$ = build_nt (ARRAY_REF, $1, $3); } | absdcl1 '[' ']' %prec '.' { $$ = build_nt (ARRAY_REF, $1, NULL_TREE); } | '(' parmlist %prec '.' { $$ = build_nt (CALL_EXPR, NULL_TREE, $2, NULL_TREE); } | '[' expr ']' %prec '.' { $$ = build_nt (ARRAY_REF, NULL_TREE, $2); } | '[' ']' %prec '.' { $$ = build_nt (ARRAY_REF, NULL_TREE, NULL_TREE); } ; /* at least one statement, the first of which parses without error. */ /* stmts is used only after decls, so an invalid first statement is actually regarded as an invalid decl and part of the decls. */ stmts: lineno_stmt_or_label | stmts lineno_stmt_or_label | stmts errstmt ; xstmts: /* empty */ | stmts ; errstmt: error ';' ; pushlevel: /* empty */ { emit_line_note (input_filename, lineno); pushlevel (0); clear_last_expr (); push_momentary (); expand_start_bindings (0); ifobjc if (objc_method_context) add_objc_decls (); end ifobjc } ; /* Read zero or more forward-declarations for labels that nested functions can jump to. */ maybe_label_decls: /* empty */ | label_decls { if (pedantic) pedwarn ("ANSI C forbids label declarations"); } ; label_decls: label_decl | label_decls label_decl ; label_decl: LABEL identifiers_or_typenames ';' { tree link; for (link = $2; link; link = TREE_CHAIN (link)) { tree label = shadow_label (TREE_VALUE (link)); C_DECLARED_LABEL_FLAG (label) = 1; declare_nonlocal_label (label); } } ; /* This is the body of a function definition. It causes syntax errors to ignore to the next openbrace. */ compstmt_or_error: compstmt {} | error compstmt ; compstmt: '{' '}' { $$ = convert (void_type_node, integer_zero_node); } | '{' pushlevel maybe_label_decls decls xstmts '}' { emit_line_note (input_filename, lineno); expand_end_bindings (getdecls (), 1, 0); $$ = poplevel (1, 1, 0); if (yychar == CONSTANT || yychar == STRING) pop_momentary_nofree (); else pop_momentary (); } | '{' pushlevel maybe_label_decls error '}' { emit_line_note (input_filename, lineno); expand_end_bindings (getdecls (), kept_level_p (), 0); $$ = poplevel (kept_level_p (), 0, 0); if (yychar == CONSTANT || yychar == STRING) pop_momentary_nofree (); else pop_momentary (); } | '{' pushlevel maybe_label_decls stmts '}' { emit_line_note (input_filename, lineno); expand_end_bindings (getdecls (), kept_level_p (), 0); $$ = poplevel (kept_level_p (), 0, 0); if (yychar == CONSTANT || yychar == STRING) pop_momentary_nofree (); else pop_momentary (); } ; /* Value is number of statements counted as of the closeparen. */ simple_if: if_prefix lineno_labeled_stmt /* Make sure expand_end_cond is run once for each call to expand_start_cond. Otherwise a crash is likely. */ | if_prefix error ; if_prefix: IF '(' expr ')' { emit_line_note ($-1, $0); expand_start_cond (truthvalue_conversion ($3), 0); $$ = stmt_count; if_stmt_file = $-1; if_stmt_line = $0; position_after_white_space (); } ; /* This is a subroutine of stmt. It is used twice, once for valid DO statements and once for catching errors in parsing the end test. */ do_stmt_start: DO { stmt_count++; emit_line_note ($-1, $0); /* See comment in `while' alternative, above. */ emit_nop (); expand_start_loop_continue_elsewhere (1); position_after_white_space (); } lineno_labeled_stmt WHILE { expand_loop_continue_here (); } ; save_filename: { $$ = input_filename; } ; save_lineno: { $$ = lineno; } ; lineno_labeled_stmt: save_filename save_lineno stmt { } /* | save_filename save_lineno error { } */ | save_filename save_lineno label lineno_labeled_stmt { } ; lineno_stmt_or_label: save_filename save_lineno stmt_or_label { } ; stmt_or_label: stmt | label { int next; position_after_white_space (); next = getc (finput); ungetc (next, finput); if (pedantic && next == '}') pedwarn ("ANSI C forbids label at end of compound statement"); } ; /* Parse a single real statement, not including any labels. */ stmt: compstmt { stmt_count++; } | all_iter_stmt | expr ';' { stmt_count++; emit_line_note ($-1, $0); /* It appears that this should not be done--that a non-lvalue array shouldn't get an error if the value isn't used. Section 3.2.2.1 says that an array lvalue gets converted to a pointer if it appears as a top-level expression, but says nothing about non-lvalue arrays. */ #if 0 /* Call default_conversion to get an error on referring to a register array if pedantic. */ if (TREE_CODE (TREE_TYPE ($1)) == ARRAY_TYPE || TREE_CODE (TREE_TYPE ($1)) == FUNCTION_TYPE) $1 = default_conversion ($1); #endif iterator_expand ($1); clear_momentary (); } | simple_if ELSE { expand_start_else (); $1 = stmt_count; position_after_white_space (); } lineno_labeled_stmt { expand_end_cond (); if (extra_warnings && stmt_count == $1) warning ("empty body in an else-statement"); } | simple_if %prec IF { expand_end_cond (); /* This warning is here instead of in simple_if, because we do not want a warning if an empty if is followed by an else statement. Increment stmt_count so we don't give a second error if this is a nested `if'. */ if (extra_warnings && stmt_count++ == $1) warning_with_file_and_line (if_stmt_file, if_stmt_line, "empty body in an if-statement"); } /* Make sure expand_end_cond is run once for each call to expand_start_cond. Otherwise a crash is likely. */ | simple_if ELSE error { expand_end_cond (); } | WHILE { stmt_count++; emit_line_note ($-1, $0); /* The emit_nop used to come before emit_line_note, but that made the nop seem like part of the preceding line. And that was confusing when the preceding line was inside of an if statement and was not really executed. I think it ought to work to put the nop after the line number. We will see. --rms, July 15, 1991. */ emit_nop (); } '(' expr ')' { /* Don't start the loop till we have succeeded in parsing the end test. This is to make sure that we end every loop we start. */ expand_start_loop (1); emit_line_note (input_filename, lineno); expand_exit_loop_if_false (NULL_PTR, truthvalue_conversion ($4)); position_after_white_space (); } lineno_labeled_stmt { expand_end_loop (); } | do_stmt_start '(' expr ')' ';' { emit_line_note (input_filename, lineno); expand_exit_loop_if_false (NULL_PTR, truthvalue_conversion ($3)); expand_end_loop (); clear_momentary (); } /* This rule is needed to make sure we end every loop we start. */ | do_stmt_start error { expand_end_loop (); clear_momentary (); } | FOR '(' xexpr ';' { stmt_count++; emit_line_note ($-1, $0); /* See comment in `while' alternative, above. */ emit_nop (); if ($3) c_expand_expr_stmt ($3); /* Next step is to call expand_start_loop_continue_elsewhere, but wait till after we parse the entire for (...). Otherwise, invalid input might cause us to call that fn without calling expand_end_loop. */ } xexpr ';' /* Can't emit now; wait till after expand_start_loop... */ { $7 = lineno; $$ = input_filename; } xexpr ')' { /* Start the loop. Doing this after parsing all the expressions ensures we will end the loop. */ expand_start_loop_continue_elsewhere (1); /* Emit the end-test, with a line number. */ emit_line_note ($8, $7); if ($6) expand_exit_loop_if_false (NULL_PTR, truthvalue_conversion ($6)); /* Don't let the tree nodes for $9 be discarded by clear_momentary during the parsing of the next stmt. */ push_momentary (); $7 = lineno; $8 = input_filename; position_after_white_space (); } lineno_labeled_stmt { /* Emit the increment expression, with a line number. */ emit_line_note ($8, $7); expand_loop_continue_here (); if ($9) c_expand_expr_stmt ($9); if (yychar == CONSTANT || yychar == STRING) pop_momentary_nofree (); else pop_momentary (); expand_end_loop (); } | SWITCH '(' expr ')' { stmt_count++; emit_line_note ($-1, $0); c_expand_start_case ($3); /* Don't let the tree nodes for $3 be discarded by clear_momentary during the parsing of the next stmt. */ push_momentary (); position_after_white_space (); } lineno_labeled_stmt { expand_end_case ($3); if (yychar == CONSTANT || yychar == STRING) pop_momentary_nofree (); else pop_momentary (); } | BREAK ';' { stmt_count++; emit_line_note ($-1, $0); if ( ! expand_exit_something ()) error ("break statement not within loop or switch"); } | CONTINUE ';' { stmt_count++; emit_line_note ($-1, $0); if (! expand_continue_loop (NULL_PTR)) error ("continue statement not within a loop"); } | RETURN ';' { stmt_count++; emit_line_note ($-1, $0); c_expand_return (NULL_TREE); } | RETURN expr ';' { stmt_count++; emit_line_note ($-1, $0); c_expand_return ($2); } | ASM_KEYWORD maybe_type_qual '(' expr ')' ';' { stmt_count++; emit_line_note ($-1, $0); STRIP_NOPS ($4); if ((TREE_CODE ($4) == ADDR_EXPR && TREE_CODE (TREE_OPERAND ($4, 0)) == STRING_CST) || TREE_CODE ($4) == STRING_CST) expand_asm ($4); else error ("argument of `asm' is not a constant string"); } /* This is the case with just output operands. */ | ASM_KEYWORD maybe_type_qual '(' expr ':' asm_operands ')' ';' { stmt_count++; emit_line_note ($-1, $0); c_expand_asm_operands ($4, $6, NULL_TREE, NULL_TREE, $2 == ridpointers[(int)RID_VOLATILE], input_filename, lineno); } /* This is the case with input operands as well. */ | ASM_KEYWORD maybe_type_qual '(' expr ':' asm_operands ':' asm_operands ')' ';' { stmt_count++; emit_line_note ($-1, $0); c_expand_asm_operands ($4, $6, $8, NULL_TREE, $2 == ridpointers[(int)RID_VOLATILE], input_filename, lineno); } /* This is the case with clobbered registers as well. */ | ASM_KEYWORD maybe_type_qual '(' expr ':' asm_operands ':' asm_operands ':' asm_clobbers ')' ';' { stmt_count++; emit_line_note ($-1, $0); c_expand_asm_operands ($4, $6, $8, $10, $2 == ridpointers[(int)RID_VOLATILE], input_filename, lineno); } | GOTO identifier ';' { tree decl; stmt_count++; emit_line_note ($-1, $0); decl = lookup_label ($2); if (decl != 0) { TREE_USED (decl) = 1; expand_goto (decl); } } | GOTO '*' expr ';' { stmt_count++; emit_line_note ($-1, $0); expand_computed_goto (convert (ptr_type_node, $3)); } | ';' ; all_iter_stmt: all_iter_stmt_simple /* | all_iter_stmt_with_decl */ ; all_iter_stmt_simple: FOR '(' primary ')' { /* The value returned by this action is */ /* 1 if everything is OK */ /* 0 in case of error or already bound iterator */ $$ = 0; if (TREE_CODE ($3) != VAR_DECL) error ("invalid `for (ITERATOR)' syntax"); else if (! ITERATOR_P ($3)) error ("`%s' is not an iterator", IDENTIFIER_POINTER (DECL_NAME ($3))); else if (ITERATOR_BOUND_P ($3)) error ("`for (%s)' inside expansion of same iterator", IDENTIFIER_POINTER (DECL_NAME ($3))); else { $$ = 1; iterator_for_loop_start ($3); } } lineno_labeled_stmt { if ($5) iterator_for_loop_end ($3); } /* This really should allow any kind of declaration, for generality. Fix it before turning it back on. all_iter_stmt_with_decl: FOR '(' ITERATOR pushlevel setspecs iterator_spec ')' { */ /* The value returned by this action is */ /* 1 if everything is OK */ /* 0 in case of error or already bound iterator */ /* iterator_for_loop_start ($6); } lineno_labeled_stmt { iterator_for_loop_end ($6); emit_line_note (input_filename, lineno); expand_end_bindings (getdecls (), 1, 0); $$ = poplevel (1, 1, 0); if (yychar == CONSTANT || yychar == STRING) pop_momentary_nofree (); else pop_momentary (); } */ /* Any kind of label, including jump labels and case labels. ANSI C accepts labels only before statements, but we allow them also at the end of a compound statement. */ label: CASE expr_no_commas ':' { register tree value = check_case_value ($2); register tree label = build_decl (LABEL_DECL, NULL_TREE, NULL_TREE); stmt_count++; if (value != error_mark_node) { tree duplicate; int success = pushcase (value, convert_and_check, label, &duplicate); if (success == 1) error ("case label not within a switch statement"); else if (success == 2) { error ("duplicate case value"); error_with_decl (duplicate, "this is the first entry for that value"); } else if (success == 3) warning ("case value out of range"); else if (success == 5) error ("case label within scope of cleanup or variable array"); } position_after_white_space (); } | CASE expr_no_commas ELLIPSIS expr_no_commas ':' { register tree value1 = check_case_value ($2); register tree value2 = check_case_value ($4); register tree label = build_decl (LABEL_DECL, NULL_TREE, NULL_TREE); stmt_count++; if (value1 != error_mark_node && value2 != error_mark_node) { tree duplicate; int success = pushcase_range (value1, value2, convert_and_check, label, &duplicate); if (success == 1) error ("case label not within a switch statement"); else if (success == 2) { error ("duplicate case value"); error_with_decl (duplicate, "this is the first entry for that value"); } else if (success == 3) warning ("case value out of range"); else if (success == 4) warning ("empty case range"); else if (success == 5) error ("case label within scope of cleanup or variable array"); } position_after_white_space (); } | DEFAULT ':' { tree duplicate; register tree label = build_decl (LABEL_DECL, NULL_TREE, NULL_TREE); int success = pushcase (NULL_TREE, 0, label, &duplicate); stmt_count++; if (success == 1) error ("default label not within a switch statement"); else if (success == 2) { error ("multiple default labels in one switch"); error_with_decl (duplicate, "this is the first default label"); } position_after_white_space (); } | identifier ':' { tree label = define_label (input_filename, lineno, $1); stmt_count++; emit_nop (); if (label) expand_label (label); position_after_white_space (); } ; /* Either a type-qualifier or nothing. First thing in an `asm' statement. */ maybe_type_qual: /* empty */ { emit_line_note (input_filename, lineno); $$ = NULL_TREE; } | TYPE_QUAL { emit_line_note (input_filename, lineno); } ; xexpr: /* empty */ { $$ = NULL_TREE; } | expr ; /* These are the operands other than the first string and colon in asm ("addextend %2,%1": "=dm" (x), "0" (y), "g" (*x)) */ asm_operands: /* empty */ { $$ = NULL_TREE; } | nonnull_asm_operands ; nonnull_asm_operands: asm_operand | nonnull_asm_operands ',' asm_operand { $$ = chainon ($1, $3); } ; asm_operand: STRING '(' expr ')' { $$ = build_tree_list ($1, $3); } ; asm_clobbers: string { $$ = tree_cons (NULL_TREE, combine_strings ($1), NULL_TREE); } | asm_clobbers ',' string { $$ = tree_cons (NULL_TREE, combine_strings ($3), $1); } ; /* This is what appears inside the parens in a function declarator. Its value is a list of ..._TYPE nodes. */ parmlist: { pushlevel (0); clear_parm_order (); declare_parm_level (0); } parmlist_1 { $$ = $2; parmlist_tags_warning (); poplevel (0, 0, 0); } ; parmlist_1: parmlist_2 ')' | parms ';' { tree parm; if (pedantic) pedwarn ("ANSI C forbids forward parameter declarations"); /* Mark the forward decls as such. */ for (parm = getdecls (); parm; parm = TREE_CHAIN (parm)) TREE_ASM_WRITTEN (parm) = 1; clear_parm_order (); } parmlist_1 { $$ = $4; } | error ')' { $$ = tree_cons (NULL_TREE, NULL_TREE, NULL_TREE); } ; /* This is what appears inside the parens in a function declarator. Is value is represented in the format that grokdeclarator expects. */ parmlist_2: /* empty */ { $$ = get_parm_info (0); } | ELLIPSIS { $$ = get_parm_info (0); /* Gcc used to allow this as an extension. However, it does not work for all targets, and thus has been disabled. Also, since func (...) and func () are indistinguishable, it caused problems with the code in expand_builtin which tries to verify that BUILT_IN_NEXT_ARG is being used correctly. */ error ("ANSI C requires a named argument before `...'"); } | parms { $$ = get_parm_info (1); } | parms ',' ELLIPSIS { $$ = get_parm_info (0); } ; parms: parm { push_parm_decl ($1); } | parms ',' parm { push_parm_decl ($3); } ; /* A single parameter declaration or parameter type name, as found in a parmlist. */ parm: typed_declspecs parm_declarator { $$ = build_tree_list ($1, $2) ; } | typed_declspecs notype_declarator { $$ = build_tree_list ($1, $2) ; } | typed_declspecs absdcl { $$ = build_tree_list ($1, $2); } | declmods notype_declarator { $$ = build_tree_list ($1, $2) ; } | declmods absdcl { $$ = build_tree_list ($1, $2); } ; /* This is used in a function definition where either a parmlist or an identifier list is ok. Its value is a list of ..._TYPE nodes or a list of identifiers. */ parmlist_or_identifiers: { pushlevel (0); clear_parm_order (); declare_parm_level (1); } parmlist_or_identifiers_1 { $$ = $2; parmlist_tags_warning (); poplevel (0, 0, 0); } ; parmlist_or_identifiers_1: parmlist_1 | identifiers ')' { tree t; for (t = $1; t; t = TREE_CHAIN (t)) if (TREE_VALUE (t) == NULL_TREE) error ("`...' in old-style identifier list"); $$ = tree_cons (NULL_TREE, NULL_TREE, $1); } ; /* A nonempty list of identifiers. */ identifiers: IDENTIFIER { $$ = build_tree_list (NULL_TREE, $1); } | identifiers ',' IDENTIFIER { $$ = chainon ($1, build_tree_list (NULL_TREE, $3)); } ; /* A nonempty list of identifiers, including typenames. */ identifiers_or_typenames: identifier { $$ = build_tree_list (NULL_TREE, $1); } | identifiers_or_typenames ',' identifier { $$ = chainon ($1, build_tree_list (NULL_TREE, $3)); } ; ifobjc /* Objective-C productions. */ objcdef: classdef | classdecl | aliasdecl | protocoldef | methoddef | END { if (objc_implementation_context) { finish_class (objc_implementation_context); objc_ivar_chain = NULL_TREE; objc_implementation_context = NULL_TREE; } else warning ("`@end' must appear in an implementation context"); } ; /* A nonempty list of identifiers. */ identifier_list: identifier { $$ = build_tree_list (NULL_TREE, $1); } | identifier_list ',' identifier { $$ = chainon ($1, build_tree_list (NULL_TREE, $3)); } ; classdecl: CLASS identifier_list ';' { objc_declare_class ($2); } aliasdecl: ALIAS identifier identifier ';' { objc_declare_alias ($2, $3); } classdef: INTERFACE identifier protocolrefs '{' { objc_interface_context = objc_ivar_context = start_class (CLASS_INTERFACE_TYPE, $2, NULL_TREE, $3); objc_public_flag = 0; } ivar_decl_list '}' { continue_class (objc_interface_context); } methodprotolist END { finish_class (objc_interface_context); objc_interface_context = NULL_TREE; } | INTERFACE identifier protocolrefs { objc_interface_context = start_class (CLASS_INTERFACE_TYPE, $2, NULL_TREE, $3); continue_class (objc_interface_context); } methodprotolist END { finish_class (objc_interface_context); objc_interface_context = NULL_TREE; } | INTERFACE identifier ':' identifier protocolrefs '{' { objc_interface_context = objc_ivar_context = start_class (CLASS_INTERFACE_TYPE, $2, $4, $5); objc_public_flag = 0; } ivar_decl_list '}' { continue_class (objc_interface_context); } methodprotolist END { finish_class (objc_interface_context); objc_interface_context = NULL_TREE; } | INTERFACE identifier ':' identifier protocolrefs { objc_interface_context = start_class (CLASS_INTERFACE_TYPE, $2, $4, $5); continue_class (objc_interface_context); } methodprotolist END { finish_class (objc_interface_context); objc_interface_context = NULL_TREE; } | IMPLEMENTATION identifier '{' { objc_implementation_context = objc_ivar_context = start_class (CLASS_IMPLEMENTATION_TYPE, $2, NULL_TREE, NULL_TREE); objc_public_flag = 0; } ivar_decl_list '}' { objc_ivar_chain = continue_class (objc_implementation_context); } | IMPLEMENTATION identifier { objc_implementation_context = start_class (CLASS_IMPLEMENTATION_TYPE, $2, NULL_TREE, NULL_TREE); objc_ivar_chain = continue_class (objc_implementation_context); } | IMPLEMENTATION identifier ':' identifier '{' { objc_implementation_context = objc_ivar_context = start_class (CLASS_IMPLEMENTATION_TYPE, $2, $4, NULL_TREE); objc_public_flag = 0; } ivar_decl_list '}' { objc_ivar_chain = continue_class (objc_implementation_context); } | IMPLEMENTATION identifier ':' identifier { objc_implementation_context = start_class (CLASS_IMPLEMENTATION_TYPE, $2, $4, NULL_TREE); objc_ivar_chain = continue_class (objc_implementation_context); } | INTERFACE identifier '(' identifier ')' protocolrefs { objc_interface_context = start_class (CATEGORY_INTERFACE_TYPE, $2, $4, $6); continue_class (objc_interface_context); } methodprotolist END { finish_class (objc_interface_context); objc_interface_context = NULL_TREE; } | IMPLEMENTATION identifier '(' identifier ')' { objc_implementation_context = start_class (CATEGORY_IMPLEMENTATION_TYPE, $2, $4, NULL_TREE); objc_ivar_chain = continue_class (objc_implementation_context); } ; protocoldef: PROTOCOL identifier protocolrefs { remember_protocol_qualifiers (); objc_interface_context = start_protocol(PROTOCOL_INTERFACE_TYPE, $2, $3); } methodprotolist END { forget_protocol_qualifiers(); finish_protocol(objc_interface_context); objc_interface_context = NULL_TREE; } ; protocolrefs: /* empty */ { $$ = NULL_TREE; } | ARITHCOMPARE identifier_list ARITHCOMPARE { if ($1 == LT_EXPR && $3 == GT_EXPR) $$ = $2; else YYERROR1; } ; ivar_decl_list: ivar_decl_list visibility_spec ivar_decls | ivar_decls ; visibility_spec: PRIVATE { objc_public_flag = 2; } | PROTECTED { objc_public_flag = 0; } | PUBLIC { objc_public_flag = 1; } ; ivar_decls: /* empty */ { $$ = NULL_TREE; } | ivar_decls ivar_decl ';' | ivar_decls ';' { if (pedantic) pedwarn ("extra semicolon in struct or union specified"); } ; /* There is a shift-reduce conflict here, because `components' may start with a `typename'. It happens that shifting (the default resolution) does the right thing, because it treats the `typename' as part of a `typed_typespecs'. It is possible that this same technique would allow the distinction between `notype_initdecls' and `initdecls' to be eliminated. But I am being cautious and not trying it. */ ivar_decl: typed_typespecs setspecs ivars { $$ = $3; resume_momentary ($2); } | nonempty_type_quals setspecs ivars { $$ = $3; resume_momentary ($2); } | error { $$ = NULL_TREE; } ; ivars: /* empty */ { $$ = NULL_TREE; } | ivar_declarator | ivars ',' ivar_declarator ; ivar_declarator: declarator { $$ = add_instance_variable (objc_ivar_context, objc_public_flag, $1, current_declspecs, NULL_TREE); } | declarator ':' expr_no_commas { $$ = add_instance_variable (objc_ivar_context, objc_public_flag, $1, current_declspecs, $3); } | ':' expr_no_commas { $$ = add_instance_variable (objc_ivar_context, objc_public_flag, NULL_TREE, current_declspecs, $2); } ; methoddef: '+' { remember_protocol_qualifiers (); if (objc_implementation_context) objc_inherit_code = CLASS_METHOD_DECL; else fatal ("method definition not in class context"); } methoddecl { forget_protocol_qualifiers (); add_class_method (objc_implementation_context, $3); start_method_def ($3); objc_method_context = $3; } optarglist { continue_method_def (); } compstmt_or_error { finish_method_def (); objc_method_context = NULL_TREE; } | '-' { remember_protocol_qualifiers (); if (objc_implementation_context) objc_inherit_code = INSTANCE_METHOD_DECL; else fatal ("method definition not in class context"); } methoddecl { forget_protocol_qualifiers (); add_instance_method (objc_implementation_context, $3); start_method_def ($3); objc_method_context = $3; } optarglist { continue_method_def (); } compstmt_or_error { finish_method_def (); objc_method_context = NULL_TREE; } ; /* the reason for the strange actions in this rule is so that notype_initdecls when reached via datadef can find a valid list of type and sc specs in $0. */ methodprotolist: /* empty */ | {$$ = NULL_TREE; } methodprotolist2 ; methodprotolist2: /* eliminates a shift/reduce conflict */ methodproto | datadef | methodprotolist2 methodproto | methodprotolist2 {$$ = NULL_TREE; } datadef ; semi_or_error: ';' | error ; methodproto: '+' { objc_inherit_code = CLASS_METHOD_DECL; } methoddecl { add_class_method (objc_interface_context, $3); } semi_or_error | '-' { objc_inherit_code = INSTANCE_METHOD_DECL; } methoddecl { add_instance_method (objc_interface_context, $3); } semi_or_error ; methoddecl: '(' typename ')' unaryselector { $$ = build_method_decl (objc_inherit_code, $2, $4, NULL_TREE); } | unaryselector { $$ = build_method_decl (objc_inherit_code, NULL_TREE, $1, NULL_TREE); } | '(' typename ')' keywordselector optparmlist { $$ = build_method_decl (objc_inherit_code, $2, $4, $5); } | keywordselector optparmlist { $$ = build_method_decl (objc_inherit_code, NULL_TREE, $1, $2); } ; /* "optarglist" assumes that start_method_def has already been called... if it is not, the "xdecls" will not be placed in the proper scope */ optarglist: /* empty */ | ';' myxdecls ; /* to get around the following situation: "int foo (int a) int b; {}" that is synthesized when parsing "- a:a b:b; id c; id d; { ... }" */ myxdecls: /* empty */ | mydecls ; mydecls: mydecl | errstmt | mydecls mydecl | mydecl errstmt ; mydecl: typed_declspecs setspecs myparms ';' { resume_momentary ($2); } | typed_declspecs ';' { shadow_tag ($1); } | declmods ';' { pedwarn ("empty declaration"); } ; myparms: myparm { push_parm_decl ($1); } | myparms ',' myparm { push_parm_decl ($3); } ; /* A single parameter declaration or parameter type name, as found in a parmlist. DOES NOT ALLOW AN INITIALIZER OR ASMSPEC */ myparm: parm_declarator { $$ = build_tree_list (current_declspecs, $1) ; } | notype_declarator { $$ = build_tree_list (current_declspecs, $1) ; } | absdcl { $$ = build_tree_list (current_declspecs, $1) ; } ; optparmlist: /* empty */ { $$ = NULL_TREE; } | ',' ELLIPSIS { /* oh what a kludge! */ $$ = (tree)1; } | ',' { pushlevel (0); } parmlist_2 { /* returns a tree list node generated by get_parm_info */ $$ = $3; poplevel (0, 0, 0); } ; unaryselector: selector ; keywordselector: keyworddecl | keywordselector keyworddecl { $$ = chainon ($1, $2); } ; selector: IDENTIFIER | TYPENAME | OBJECTNAME | reservedwords ; reservedwords: ENUM { $$ = get_identifier (token_buffer); } | STRUCT { $$ = get_identifier (token_buffer); } | UNION { $$ = get_identifier (token_buffer); } | IF { $$ = get_identifier (token_buffer); } | ELSE { $$ = get_identifier (token_buffer); } | WHILE { $$ = get_identifier (token_buffer); } | DO { $$ = get_identifier (token_buffer); } | FOR { $$ = get_identifier (token_buffer); } | SWITCH { $$ = get_identifier (token_buffer); } | CASE { $$ = get_identifier (token_buffer); } | DEFAULT { $$ = get_identifier (token_buffer); } | BREAK { $$ = get_identifier (token_buffer); } | CONTINUE { $$ = get_identifier (token_buffer); } | RETURN { $$ = get_identifier (token_buffer); } | GOTO { $$ = get_identifier (token_buffer); } | ASM_KEYWORD { $$ = get_identifier (token_buffer); } | SIZEOF { $$ = get_identifier (token_buffer); } | TYPEOF { $$ = get_identifier (token_buffer); } | ALIGNOF { $$ = get_identifier (token_buffer); } | TYPESPEC | TYPE_QUAL ; keyworddecl: selector ':' '(' typename ')' identifier { $$ = build_keyword_decl ($1, $4, $6); } | selector ':' identifier { $$ = build_keyword_decl ($1, NULL_TREE, $3); } | ':' '(' typename ')' identifier { $$ = build_keyword_decl (NULL_TREE, $3, $5); } | ':' identifier { $$ = build_keyword_decl (NULL_TREE, NULL_TREE, $2); } ; messageargs: selector | keywordarglist ; keywordarglist: keywordarg | keywordarglist keywordarg { $$ = chainon ($1, $2); } ; keywordexpr: nonnull_exprlist { if (TREE_CHAIN ($1) == NULL_TREE) /* just return the expr., remove a level of indirection */ $$ = TREE_VALUE ($1); else /* we have a comma expr., we will collapse later */ $$ = $1; } ; keywordarg: selector ':' keywordexpr { $$ = build_tree_list ($1, $3); } | ':' keywordexpr { $$ = build_tree_list (NULL_TREE, $2); } ; receiver: expr | CLASSNAME { $$ = get_class_reference ($1); } ; objcmessageexpr: '[' { objc_receiver_context = 1; } receiver { objc_receiver_context = 0; } messageargs ']' { $$ = build_tree_list ($3, $5); } ; selectorarg: selector | keywordnamelist ; keywordnamelist: keywordname | keywordnamelist keywordname { $$ = chainon ($1, $2); } ; keywordname: selector ':' { $$ = build_tree_list ($1, NULL_TREE); } | ':' { $$ = build_tree_list (NULL_TREE, NULL_TREE); } ; objcselectorexpr: SELECTOR '(' selectorarg ')' { $$ = $3; } ; objcprotocolexpr: PROTOCOL '(' identifier ')' { $$ = $3; } ; /* extension to support C-structures in the archiver */ objcencodeexpr: ENCODE '(' typename ')' { $$ = groktypename ($3); } ; end ifobjc %%