/* Separate lexical analyzer for GNU C++. Copyright (C) 1987, 1989, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000 Free Software Foundation, Inc. Hacked by Michael Tiemann (tiemann@cygnus.com) 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, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* This file is the lexical analyzer for GNU C++. */ /* Cause the `yydebug' variable to be defined. */ #define YYDEBUG 1 #include "config.h" #include "system.h" #include "input.h" #include "tree.h" #include "lex.h" #include "cp-tree.h" #include "parse.h" #include "flags.h" #include "obstack.h" #include "c-pragma.h" #include "toplev.h" #include "output.h" #include "ggc.h" #include "tm_p.h" #ifdef MULTIBYTE_CHARS #include "mbchar.h" #include #endif #define obstack_chunk_alloc xmalloc #define obstack_chunk_free free extern void yyprint PARAMS ((FILE *, int, YYSTYPE)); static tree get_time_identifier PARAMS ((const char *)); static int check_newline PARAMS ((void)); static int whitespace_cr PARAMS ((int)); static int skip_white_space PARAMS ((int)); static void finish_defarg PARAMS ((void)); static int my_get_run_time PARAMS ((void)); static int interface_strcmp PARAMS ((const char *)); static int readescape PARAMS ((int *)); static char *extend_token_buffer PARAMS ((const char *)); static void consume_string PARAMS ((struct obstack *, int)); static void feed_defarg PARAMS ((tree, tree)); static void store_pending_inline PARAMS ((tree, struct pending_inline *)); static void reinit_parse_for_expr PARAMS ((struct obstack *)); static int *init_cpp_parse PARAMS ((void)); static void cp_pragma_interface PARAMS ((char *)); static void cp_pragma_implementation PARAMS ((char *)); static int handle_cp_pragma PARAMS ((const char *)); #ifdef HANDLE_GENERIC_PRAGMAS static int handle_generic_pragma PARAMS ((int)); #endif #ifdef GATHER_STATISTICS #ifdef REDUCE_LENGTH static int reduce_cmp PARAMS ((int *, int *)); static int token_cmp PARAMS ((int *, int *)); #endif #endif static void begin_definition_of_inclass_inline PARAMS ((struct pending_inline*)); static void parse_float PARAMS ((PTR)); static int is_global PARAMS ((tree)); static void init_filename_times PARAMS ((void)); static void extend_token_buffer_to PARAMS ((int)); #ifdef HANDLE_PRAGMA static int pragma_getc PARAMS ((void)); static void pragma_ungetc PARAMS ((int)); #endif static int read_line_number PARAMS ((int *)); static int token_getch PARAMS ((void)); static void token_put_back PARAMS ((int)); static void mark_impl_file_chain PARAMS ((void *)); /* Given a file name X, return the nondirectory portion. Keep in mind that X can be computed more than once. */ char * file_name_nondirectory (x) const char *x; { char *tmp = (char *) rindex (x, '/'); if (DIR_SEPARATOR != '/' && ! tmp) tmp = (char *) rindex (x, DIR_SEPARATOR); if (tmp) return (char *) (tmp + 1); else return (char *) x; } /* This obstack is needed to hold text. It is not safe to use TOKEN_BUFFER because `check_newline' calls `yylex'. */ struct obstack inline_text_obstack; char *inline_text_firstobj; /* Nonzero if parse output is being saved to an obstack for later parsing. */ static int saving_parse_to_obstack = 0; #if USE_CPPLIB #include "cpplib.h" extern cpp_reader parse_in; extern cpp_options parse_options; extern unsigned char *yy_cur, *yy_lim; extern enum cpp_token cpp_token; #else FILE *finput; #endif int end_of_file; int linemode; /* Pending language change. Positive is push count, negative is pop count. */ int pending_lang_change = 0; /* Wrap the current header file in extern "C". */ static int c_header_level = 0; extern int first_token; extern struct obstack token_obstack; /* ??? Don't really know where this goes yet. */ #include "input.c" /* Holds translations from TREE_CODEs to operator name strings, i.e., opname_tab[PLUS_EXPR] == "+". */ const char **opname_tab; const char **assignop_tab; extern int yychar; /* the lookahead symbol */ extern YYSTYPE yylval; /* the semantic value of the */ /* lookahead symbol */ #if 0 YYLTYPE yylloc; /* location data for the lookahead */ /* symbol */ #endif /* the declaration found for the last IDENTIFIER token read in. yylex must look this up to detect typedefs, which get token type TYPENAME, so it is left around in case the identifier is not a typedef but is used in a context which makes it a reference to a variable. */ tree lastiddecl; /* The elements of `ridpointers' are identifier nodes for the reserved type names and storage classes. It is indexed by a RID_... value. */ tree ridpointers[(int) RID_MAX]; /* We may keep statistics about how long which files took to compile. */ static int header_time, body_time; static tree filename_times; static tree this_filename_time; /* Array for holding counts of the numbers of tokens seen. */ extern int *token_count; /* When we see a default argument in a method declaration, we snarf it as text using snarf_defarg. When we get up to namespace scope, we then go through and parse all of them using do_pending_defargs. Since yacc parsers are not reentrant, we retain defargs state in these two variables so that subsequent calls to do_pending_defargs can resume where the previous call left off. */ static tree defarg_fns; static tree defarg_parm; /* Functions and data structures for #pragma interface. `#pragma implementation' means that the main file being compiled is considered to implement (provide) the classes that appear in its main body. I.e., if this is file "foo.cc", and class `bar' is defined in "foo.cc", then we say that "foo.cc implements bar". All main input files "implement" themselves automagically. `#pragma interface' means that unless this file (of the form "foo.h" is not presently being included by file "foo.cc", the CLASSTYPE_INTERFACE_ONLY bit gets set. The effect is that none of the vtables nor any of the inline functions defined in foo.h will ever be output. There are cases when we want to link files such as "defs.h" and "main.cc". In this case, we give "defs.h" a `#pragma interface', and "main.cc" has `#pragma implementation "defs.h"'. */ struct impl_files { char *filename; struct impl_files *next; }; static struct impl_files *impl_file_chain; /* The string used to represent the filename of internally generated tree nodes. The variable, which is dynamically allocated, should be used; the macro is only used to initialize it. */ static char *internal_filename; #define INTERNAL_FILENAME ("") /* Return something to represent absolute declarators containing a *. TARGET is the absolute declarator that the * contains. CV_QUALIFIERS is a list of modifiers such as const or volatile to apply to the pointer type, represented as identifiers. We return an INDIRECT_REF whose "contents" are TARGET and whose type is the modifier list. */ tree make_pointer_declarator (cv_qualifiers, target) tree cv_qualifiers, target; { if (target && TREE_CODE (target) == IDENTIFIER_NODE && ANON_AGGRNAME_P (target)) error ("type name expected before `*'"); target = build_parse_node (INDIRECT_REF, target); TREE_TYPE (target) = cv_qualifiers; return target; } /* Return something to represent absolute declarators containing a &. TARGET is the absolute declarator that the & contains. CV_QUALIFIERS is a list of modifiers such as const or volatile to apply to the reference type, represented as identifiers. We return an ADDR_EXPR whose "contents" are TARGET and whose type is the modifier list. */ tree make_reference_declarator (cv_qualifiers, target) tree cv_qualifiers, target; { if (target) { if (TREE_CODE (target) == ADDR_EXPR) { error ("cannot declare references to references"); return target; } if (TREE_CODE (target) == INDIRECT_REF) { error ("cannot declare pointers to references"); return target; } if (TREE_CODE (target) == IDENTIFIER_NODE && ANON_AGGRNAME_P (target)) error ("type name expected before `&'"); } target = build_parse_node (ADDR_EXPR, target); TREE_TYPE (target) = cv_qualifiers; return target; } tree make_call_declarator (target, parms, cv_qualifiers, exception_specification) tree target, parms, cv_qualifiers, exception_specification; { target = build_parse_node (CALL_EXPR, target, /* Both build_parse_node and decl_tree_cons build on the temp_decl_obstack. */ decl_tree_cons (parms, cv_qualifiers, NULL_TREE), /* The third operand is really RTL. We shouldn't put anything there. */ NULL_TREE); CALL_DECLARATOR_EXCEPTION_SPEC (target) = exception_specification; return target; } void set_quals_and_spec (call_declarator, cv_qualifiers, exception_specification) tree call_declarator, cv_qualifiers, exception_specification; { CALL_DECLARATOR_QUALS (call_declarator) = cv_qualifiers; CALL_DECLARATOR_EXCEPTION_SPEC (call_declarator) = exception_specification; } /* Build names and nodes for overloaded operators. */ tree ansi_opname[LAST_CPLUS_TREE_CODE]; tree ansi_assopname[LAST_CPLUS_TREE_CODE]; const char * operator_name_string (name) tree name; { char *opname = IDENTIFIER_POINTER (name) + 2; tree *opname_table; int i, assign; /* Works for builtin and user defined types. */ if (IDENTIFIER_GLOBAL_VALUE (name) && TREE_CODE (IDENTIFIER_GLOBAL_VALUE (name)) == TYPE_DECL) return IDENTIFIER_POINTER (name); if (opname[0] == 'a' && opname[2] != '\0' && opname[2] != '_') { opname += 1; assign = 1; opname_table = ansi_assopname; } else { assign = 0; opname_table = ansi_opname; } for (i = 0; i < (int) LAST_CPLUS_TREE_CODE; i++) { if (opname[0] == IDENTIFIER_POINTER (opname_table[i])[2+assign] && opname[1] == IDENTIFIER_POINTER (opname_table[i])[3+assign]) break; } if (i == LAST_CPLUS_TREE_CODE) return ""; if (assign) return assignop_tab[i]; else return opname_tab[i]; } int interface_only; /* whether or not current file is only for interface definitions. */ int interface_unknown; /* whether or not we know this class to behave according to #pragma interface. */ /* lexical analyzer */ #undef WCHAR_TYPE_SIZE #define WCHAR_TYPE_SIZE TYPE_PRECISION (wchar_type_node) /* Number of bytes in a wide character. */ #define WCHAR_BYTES (WCHAR_TYPE_SIZE / BITS_PER_UNIT) static int maxtoken; /* Current nominal length of token buffer. */ char *token_buffer; /* Pointer to token buffer. Actual allocated length is maxtoken + 2. */ static int indent_level; /* Number of { minus number of }. */ #include "hash.h" /* Nonzero tells yylex to ignore \ in string constants. */ static int ignore_escape_flag; static tree get_time_identifier (name) const char *name; { tree time_identifier; int len = strlen (name); char *buf = (char *) alloca (len + 6); strcpy (buf, "file "); bcopy (name, buf+5, len); buf[len+5] = '\0'; time_identifier = get_identifier (buf); if (TIME_IDENTIFIER_TIME (time_identifier) == NULL_TREE) { TIME_IDENTIFIER_TIME (time_identifier) = build_int_2 (0, 0); TIME_IDENTIFIER_FILEINFO (time_identifier) = build_int_2 (0, 1); SET_IDENTIFIER_GLOBAL_VALUE (time_identifier, filename_times); filename_times = time_identifier; } return time_identifier; } static inline int my_get_run_time () { int old_quiet_flag = quiet_flag; int this_time; quiet_flag = 0; this_time = get_run_time (); quiet_flag = old_quiet_flag; return this_time; } /* Table indexed by tree code giving a string containing a character classifying the tree code. Possibilities are t, d, s, c, r, <, 1 and 2. See cp/cp-tree.def for details. */ #define DEFTREECODE(SYM, NAME, TYPE, LENGTH) TYPE, static char cplus_tree_code_type[] = { 'x', #include "cp-tree.def" }; #undef DEFTREECODE /* Table indexed by tree code giving number of expression operands beyond the fixed part of the node structure. Not used for types or decls. */ #define DEFTREECODE(SYM, NAME, TYPE, LENGTH) LENGTH, static int cplus_tree_code_length[] = { 0, #include "cp-tree.def" }; #undef DEFTREECODE /* Names of tree components. Used for printing out the tree and error messages. */ #define DEFTREECODE(SYM, NAME, TYPE, LEN) NAME, static const char *cplus_tree_code_name[] = { "@@dummy", #include "cp-tree.def" }; #undef DEFTREECODE /* toplev.c needs to call these. */ void lang_init_options () { #if USE_CPPLIB cpp_reader_init (&parse_in); parse_in.opts = &parse_options; cpp_options_init (&parse_options); parse_options.cplusplus = 1; #endif /* Default exceptions on. */ flag_exceptions = 1; /* Mark as "unspecified". */ flag_bounds_check = -1; /* By default wrap lines at 72 characters. */ set_message_length (72); } void lang_init () { /* If still "unspecified", make it match -fbounded-pointers. */ if (flag_bounds_check < 0) flag_bounds_check = flag_bounded_pointers; /* the beginning of the file is a new line; check for # */ /* With luck, we discover the real source file's name from that and put it in input_filename. */ put_back (check_newline ()); if (flag_gnu_xref) GNU_xref_begin (input_filename); init_repo (input_filename); } void lang_finish () { if (flag_gnu_xref) GNU_xref_end (errorcount+sorrycount); } const char * lang_identify () { return "cplusplus"; } static void init_filename_times () { this_filename_time = get_time_identifier (""); if (flag_detailed_statistics) { header_time = 0; body_time = my_get_run_time (); TREE_INT_CST_LOW (TIME_IDENTIFIER_TIME (this_filename_time)) = body_time; } } /* Change by Bryan Boreham, Kewill, Thu Jul 27 09:46:05 1989. Stuck this hack in to get the files open correctly; this is called in place of init_parse if we are an unexec'd binary. */ #if 0 void reinit_lang_specific () { init_filename_times (); reinit_search_statistics (); } #endif static int * init_cpp_parse () { #ifdef GATHER_STATISTICS #ifdef REDUCE_LENGTH reduce_count = (int *) xcalloc (sizeof (int), (REDUCE_LENGTH + 1)); reduce_count += 1; token_count = (int *) xcalloc (sizeof (int), (TOKEN_LENGTH + 1)); token_count += 1; #endif #endif return token_count; } char * init_parse (filename) char *filename; { extern int flag_no_gnu_keywords; extern int flag_operator_names; int i; #ifdef MULTIBYTE_CHARS /* Change to the native locale for multibyte conversions. */ setlocale (LC_CTYPE, ""); literal_codeset = getenv ("LANG"); #endif #if !USE_CPPLIB /* Open input file. */ if (filename == 0 || !strcmp (filename, "-")) { finput = stdin; filename = "stdin"; } else finput = fopen (filename, "r"); if (finput == 0) pfatal_with_name (filename); #ifdef IO_BUFFER_SIZE setvbuf (finput, (char *) xmalloc (IO_BUFFER_SIZE), _IOFBF, IO_BUFFER_SIZE); #endif #else /* !USE_CPPLIB */ parse_in.show_column = 1; if (! cpp_start_read (&parse_in, filename)) abort (); if (filename == 0 || !strcmp (filename, "-")) filename = "stdin"; /* cpp_start_read always puts at least one line directive into the token buffer. We must arrange to read it out here. */ yy_cur = parse_in.token_buffer; yy_lim = CPP_PWRITTEN (&parse_in); cpp_token = CPP_DIRECTIVE; #endif /* !USE_CPPLIB */ /* Initialize the lookahead machinery. */ init_spew (); /* Make identifier nodes long enough for the language-specific slots. */ set_identifier_size (sizeof (struct lang_identifier)); decl_printable_name = lang_printable_name; init_tree (); init_cplus_expand (); memcpy (tree_code_type + (int) LAST_AND_UNUSED_TREE_CODE, cplus_tree_code_type, (int)LAST_CPLUS_TREE_CODE - (int)LAST_AND_UNUSED_TREE_CODE); memcpy (tree_code_length + (int) LAST_AND_UNUSED_TREE_CODE, cplus_tree_code_length, (LAST_CPLUS_TREE_CODE - (int)LAST_AND_UNUSED_TREE_CODE) * sizeof (int)); memcpy (tree_code_name + (int) LAST_AND_UNUSED_TREE_CODE, cplus_tree_code_name, (LAST_CPLUS_TREE_CODE - (int)LAST_AND_UNUSED_TREE_CODE) * sizeof (char *)); opname_tab = (const char **)oballoc ((int)LAST_CPLUS_TREE_CODE * sizeof (char *)); memset (opname_tab, 0, (int)LAST_CPLUS_TREE_CODE * sizeof (char *)); assignop_tab = (const char **)oballoc ((int)LAST_CPLUS_TREE_CODE * sizeof (char *)); memset (assignop_tab, 0, (int)LAST_CPLUS_TREE_CODE * sizeof (char *)); ansi_opname[0] = get_identifier (""); for (i = 0; i < (int) LAST_CPLUS_TREE_CODE; i++) { ansi_opname[i] = ansi_opname[0]; ansi_assopname[i] = ansi_opname[0]; } ansi_opname[(int) MULT_EXPR] = get_identifier ("__ml"); IDENTIFIER_OPNAME_P (ansi_opname[(int) MULT_EXPR]) = 1; ansi_opname[(int) INDIRECT_REF] = ansi_opname[(int) MULT_EXPR]; ansi_assopname[(int) MULT_EXPR] = get_identifier ("__aml"); IDENTIFIER_OPNAME_P (ansi_assopname[(int) MULT_EXPR]) = 1; ansi_assopname[(int) INDIRECT_REF] = ansi_assopname[(int) MULT_EXPR]; ansi_opname[(int) TRUNC_MOD_EXPR] = get_identifier ("__md"); IDENTIFIER_OPNAME_P (ansi_opname[(int) TRUNC_MOD_EXPR]) = 1; ansi_assopname[(int) TRUNC_MOD_EXPR] = get_identifier ("__amd"); IDENTIFIER_OPNAME_P (ansi_assopname[(int) TRUNC_MOD_EXPR]) = 1; ansi_opname[(int) CEIL_MOD_EXPR] = ansi_opname[(int) TRUNC_MOD_EXPR]; ansi_opname[(int) FLOOR_MOD_EXPR] = ansi_opname[(int) TRUNC_MOD_EXPR]; ansi_opname[(int) ROUND_MOD_EXPR] = ansi_opname[(int) TRUNC_MOD_EXPR]; ansi_opname[(int) MINUS_EXPR] = get_identifier ("__mi"); IDENTIFIER_OPNAME_P (ansi_opname[(int) MINUS_EXPR]) = 1; ansi_opname[(int) NEGATE_EXPR] = ansi_opname[(int) MINUS_EXPR]; ansi_assopname[(int) MINUS_EXPR] = get_identifier ("__ami"); IDENTIFIER_OPNAME_P (ansi_assopname[(int) MINUS_EXPR]) = 1; ansi_assopname[(int) NEGATE_EXPR] = ansi_assopname[(int) MINUS_EXPR]; ansi_opname[(int) RSHIFT_EXPR] = get_identifier ("__rs"); IDENTIFIER_OPNAME_P (ansi_opname[(int) RSHIFT_EXPR]) = 1; ansi_assopname[(int) RSHIFT_EXPR] = get_identifier ("__ars"); IDENTIFIER_OPNAME_P (ansi_assopname[(int) RSHIFT_EXPR]) = 1; ansi_opname[(int) NE_EXPR] = get_identifier ("__ne"); IDENTIFIER_OPNAME_P (ansi_opname[(int) NE_EXPR]) = 1; ansi_opname[(int) GT_EXPR] = get_identifier ("__gt"); IDENTIFIER_OPNAME_P (ansi_opname[(int) GT_EXPR]) = 1; ansi_opname[(int) GE_EXPR] = get_identifier ("__ge"); IDENTIFIER_OPNAME_P (ansi_opname[(int) GE_EXPR]) = 1; ansi_opname[(int) BIT_IOR_EXPR] = get_identifier ("__or"); IDENTIFIER_OPNAME_P (ansi_opname[(int) BIT_IOR_EXPR]) = 1; ansi_assopname[(int) BIT_IOR_EXPR] = get_identifier ("__aor"); IDENTIFIER_OPNAME_P (ansi_assopname[(int) BIT_IOR_EXPR]) = 1; ansi_opname[(int) TRUTH_ANDIF_EXPR] = get_identifier ("__aa"); IDENTIFIER_OPNAME_P (ansi_opname[(int) TRUTH_ANDIF_EXPR]) = 1; ansi_opname[(int) TRUTH_NOT_EXPR] = get_identifier ("__nt"); IDENTIFIER_OPNAME_P (ansi_opname[(int) TRUTH_NOT_EXPR]) = 1; ansi_opname[(int) PREINCREMENT_EXPR] = get_identifier ("__pp"); IDENTIFIER_OPNAME_P (ansi_opname[(int) PREINCREMENT_EXPR]) = 1; ansi_opname[(int) POSTINCREMENT_EXPR] = ansi_opname[(int) PREINCREMENT_EXPR]; ansi_opname[(int) MODIFY_EXPR] = get_identifier ("__as"); IDENTIFIER_OPNAME_P (ansi_opname[(int) MODIFY_EXPR]) = 1; ansi_assopname[(int) NOP_EXPR] = ansi_opname[(int) MODIFY_EXPR]; ansi_opname[(int) COMPOUND_EXPR] = get_identifier ("__cm"); IDENTIFIER_OPNAME_P (ansi_opname[(int) COMPOUND_EXPR]) = 1; ansi_opname[(int) EXACT_DIV_EXPR] = get_identifier ("__dv"); IDENTIFIER_OPNAME_P (ansi_opname[(int) EXACT_DIV_EXPR]) = 1; ansi_assopname[(int) EXACT_DIV_EXPR] = get_identifier ("__adv"); IDENTIFIER_OPNAME_P (ansi_assopname[(int) EXACT_DIV_EXPR]) = 1; ansi_opname[(int) TRUNC_DIV_EXPR] = ansi_opname[(int) EXACT_DIV_EXPR]; ansi_opname[(int) CEIL_DIV_EXPR] = ansi_opname[(int) EXACT_DIV_EXPR]; ansi_opname[(int) FLOOR_DIV_EXPR] = ansi_opname[(int) EXACT_DIV_EXPR]; ansi_opname[(int) ROUND_DIV_EXPR] = ansi_opname[(int) EXACT_DIV_EXPR]; ansi_opname[(int) PLUS_EXPR] = get_identifier ("__pl"); ansi_assopname[(int) TRUNC_DIV_EXPR] = ansi_assopname[(int) EXACT_DIV_EXPR]; ansi_assopname[(int) CEIL_DIV_EXPR] = ansi_assopname[(int) EXACT_DIV_EXPR]; ansi_assopname[(int) FLOOR_DIV_EXPR] = ansi_assopname[(int) EXACT_DIV_EXPR]; ansi_assopname[(int) ROUND_DIV_EXPR] = ansi_assopname[(int) EXACT_DIV_EXPR]; IDENTIFIER_OPNAME_P (ansi_opname[(int) PLUS_EXPR]) = 1; ansi_assopname[(int) PLUS_EXPR] = get_identifier ("__apl"); IDENTIFIER_OPNAME_P (ansi_assopname[(int) PLUS_EXPR]) = 1; ansi_opname[(int) CONVERT_EXPR] = ansi_opname[(int) PLUS_EXPR]; ansi_assopname[(int) CONVERT_EXPR] = ansi_assopname[(int) PLUS_EXPR]; ansi_opname[(int) LSHIFT_EXPR] = get_identifier ("__ls"); IDENTIFIER_OPNAME_P (ansi_opname[(int) LSHIFT_EXPR]) = 1; ansi_assopname[(int) LSHIFT_EXPR] = get_identifier ("__als"); IDENTIFIER_OPNAME_P (ansi_assopname[(int) LSHIFT_EXPR]) = 1; ansi_opname[(int) EQ_EXPR] = get_identifier ("__eq"); IDENTIFIER_OPNAME_P (ansi_opname[(int) EQ_EXPR]) = 1; ansi_opname[(int) LT_EXPR] = get_identifier ("__lt"); IDENTIFIER_OPNAME_P (ansi_opname[(int) LT_EXPR]) = 1; ansi_opname[(int) LE_EXPR] = get_identifier ("__le"); IDENTIFIER_OPNAME_P (ansi_opname[(int) LE_EXPR]) = 1; ansi_opname[(int) BIT_AND_EXPR] = get_identifier ("__ad"); IDENTIFIER_OPNAME_P (ansi_opname[(int) BIT_AND_EXPR]) = 1; ansi_assopname[(int) BIT_AND_EXPR] = get_identifier ("__aad"); IDENTIFIER_OPNAME_P (ansi_assopname[(int) BIT_AND_EXPR]) = 1; ansi_opname[(int) ADDR_EXPR] = ansi_opname[(int) BIT_AND_EXPR]; ansi_assopname[(int) ADDR_EXPR] = ansi_assopname[(int) BIT_AND_EXPR]; ansi_opname[(int) BIT_XOR_EXPR] = get_identifier ("__er"); IDENTIFIER_OPNAME_P (ansi_opname[(int) BIT_XOR_EXPR]) = 1; ansi_assopname[(int) BIT_XOR_EXPR] = get_identifier ("__aer"); IDENTIFIER_OPNAME_P (ansi_assopname[(int) BIT_XOR_EXPR]) = 1; ansi_opname[(int) TRUTH_ORIF_EXPR] = get_identifier ("__oo"); IDENTIFIER_OPNAME_P (ansi_opname[(int) TRUTH_ORIF_EXPR]) = 1; ansi_opname[(int) BIT_NOT_EXPR] = get_identifier ("__co"); IDENTIFIER_OPNAME_P (ansi_opname[(int) BIT_NOT_EXPR]) = 1; ansi_opname[(int) PREDECREMENT_EXPR] = get_identifier ("__mm"); IDENTIFIER_OPNAME_P (ansi_opname[(int) PREDECREMENT_EXPR]) = 1; ansi_opname[(int) POSTDECREMENT_EXPR] = ansi_opname[(int) PREDECREMENT_EXPR]; ansi_opname[(int) COMPONENT_REF] = get_identifier ("__rf"); IDENTIFIER_OPNAME_P (ansi_opname[(int) COMPONENT_REF]) = 1; ansi_opname[(int) MEMBER_REF] = get_identifier ("__rm"); IDENTIFIER_OPNAME_P (ansi_opname[(int) MEMBER_REF]) = 1; ansi_opname[(int) CALL_EXPR] = get_identifier ("__cl"); IDENTIFIER_OPNAME_P (ansi_opname[(int) CALL_EXPR]) = 1; ansi_opname[(int) ARRAY_REF] = get_identifier ("__vc"); IDENTIFIER_OPNAME_P (ansi_opname[(int) ARRAY_REF]) = 1; ansi_opname[(int) NEW_EXPR] = get_identifier ("__nw"); IDENTIFIER_OPNAME_P (ansi_opname[(int) NEW_EXPR]) = 1; ansi_opname[(int) DELETE_EXPR] = get_identifier ("__dl"); IDENTIFIER_OPNAME_P (ansi_opname[(int) DELETE_EXPR]) = 1; ansi_opname[(int) VEC_NEW_EXPR] = get_identifier ("__vn"); IDENTIFIER_OPNAME_P (ansi_opname[(int) VEC_NEW_EXPR]) = 1; ansi_opname[(int) VEC_DELETE_EXPR] = get_identifier ("__vd"); IDENTIFIER_OPNAME_P (ansi_opname[(int) VEC_DELETE_EXPR]) = 1; ansi_opname[(int) TYPE_EXPR] = get_identifier (OPERATOR_TYPENAME_FORMAT); IDENTIFIER_OPNAME_P (ansi_opname[(int) TYPE_EXPR]) = 1; /* This is not true: these operators are not defined in ANSI, but we need them anyway. */ ansi_opname[(int) MIN_EXPR] = get_identifier ("__mn"); IDENTIFIER_OPNAME_P (ansi_opname[(int) MIN_EXPR]) = 1; ansi_opname[(int) MAX_EXPR] = get_identifier ("__mx"); IDENTIFIER_OPNAME_P (ansi_opname[(int) MAX_EXPR]) = 1; ansi_opname[(int) COND_EXPR] = get_identifier ("__cn"); IDENTIFIER_OPNAME_P (ansi_opname[(int) COND_EXPR]) = 1; ansi_opname[(int) SIZEOF_EXPR] = get_identifier ("__sz"); IDENTIFIER_OPNAME_P (ansi_opname[(int) SIZEOF_EXPR]) = 1; init_method (); init_error (); gcc_obstack_init (&inline_text_obstack); inline_text_firstobj = (char *) obstack_alloc (&inline_text_obstack, 0); internal_filename = ggc_alloc_string (INTERNAL_FILENAME, sizeof (INTERNAL_FILENAME)); /* Start it at 0, because check_newline is called at the very beginning and will increment it to 1. */ lineno = 0; input_filename = internal_filename; current_function_decl = NULL; maxtoken = 40; token_buffer = (char *) xmalloc (maxtoken + 2); ridpointers[(int) RID_INT] = get_identifier ("int"); ridpointers[(int) RID_BOOL] = get_identifier ("bool"); ridpointers[(int) RID_CHAR] = get_identifier ("char"); ridpointers[(int) RID_VOID] = get_identifier ("void"); ridpointers[(int) RID_FLOAT] = get_identifier ("float"); ridpointers[(int) RID_DOUBLE] = get_identifier ("double"); ridpointers[(int) RID_SHORT] = get_identifier ("short"); ridpointers[(int) RID_LONG] = get_identifier ("long"); ridpointers[(int) RID_UNSIGNED] = get_identifier ("unsigned"); ridpointers[(int) RID_SIGNED] = get_identifier ("signed"); ridpointers[(int) RID_INLINE] = get_identifier ("inline"); ridpointers[(int) RID_CONST] = get_identifier ("const"); ridpointers[(int) RID_RESTRICT] = get_identifier ("__restrict"); ridpointers[(int) RID_VOLATILE] = get_identifier ("volatile"); ridpointers[(int) RID_AUTO] = get_identifier ("auto"); ridpointers[(int) RID_STATIC] = get_identifier ("static"); ridpointers[(int) RID_EXTERN] = get_identifier ("extern"); ridpointers[(int) RID_TYPEDEF] = get_identifier ("typedef"); ridpointers[(int) RID_REGISTER] = get_identifier ("register"); ridpointers[(int) RID_COMPLEX] = get_identifier ("__complex"); /* C++ extensions. These are probably not correctly named. */ ridpointers[(int) RID_WCHAR] = get_identifier ("__wchar_t"); class_type_node = build_int_2 (class_type, 0); TREE_TYPE (class_type_node) = class_type_node; ridpointers[(int) RID_CLASS] = class_type_node; record_type_node = build_int_2 (record_type, 0); TREE_TYPE (record_type_node) = record_type_node; ridpointers[(int) RID_RECORD] = record_type_node; union_type_node = build_int_2 (union_type, 0); TREE_TYPE (union_type_node) = union_type_node; ridpointers[(int) RID_UNION] = union_type_node; enum_type_node = build_int_2 (enum_type, 0); TREE_TYPE (enum_type_node) = enum_type_node; ridpointers[(int) RID_ENUM] = enum_type_node; ridpointers[(int) RID_VIRTUAL] = get_identifier ("virtual"); ridpointers[(int) RID_EXPLICIT] = get_identifier ("explicit"); ridpointers[(int) RID_EXPORT] = get_identifier ("export"); ridpointers[(int) RID_FRIEND] = get_identifier ("friend"); ridpointers[(int) RID_PUBLIC] = get_identifier ("public"); ridpointers[(int) RID_PRIVATE] = get_identifier ("private"); ridpointers[(int) RID_PROTECTED] = get_identifier ("protected"); ridpointers[(int) RID_TEMPLATE] = get_identifier ("template"); /* This is for ANSI C++. */ ridpointers[(int) RID_MUTABLE] = get_identifier ("mutable"); /* Create the built-in __null node. Note that we can't yet call for type_for_size here because integer_type_node and so forth are not set up. Therefore, we don't set the type of these nodes until init_decl_processing. */ null_node = build_int_2 (0, 0); ridpointers[RID_NULL] = null_node; opname_tab[(int) COMPONENT_REF] = "->"; opname_tab[(int) MEMBER_REF] = "->*"; opname_tab[(int) INDIRECT_REF] = "*"; opname_tab[(int) ARRAY_REF] = "[]"; opname_tab[(int) MODIFY_EXPR] = "="; opname_tab[(int) INIT_EXPR] = "="; opname_tab[(int) NEW_EXPR] = "new"; opname_tab[(int) DELETE_EXPR] = "delete"; opname_tab[(int) VEC_NEW_EXPR] = "new []"; opname_tab[(int) VEC_DELETE_EXPR] = "delete []"; opname_tab[(int) COND_EXPR] = "?:"; opname_tab[(int) CALL_EXPR] = "()"; opname_tab[(int) PLUS_EXPR] = "+"; opname_tab[(int) MINUS_EXPR] = "-"; opname_tab[(int) MULT_EXPR] = "*"; opname_tab[(int) TRUNC_DIV_EXPR] = "/"; opname_tab[(int) CEIL_DIV_EXPR] = "(ceiling /)"; opname_tab[(int) FLOOR_DIV_EXPR] = "(floor /)"; opname_tab[(int) ROUND_DIV_EXPR] = "(round /)"; opname_tab[(int) TRUNC_MOD_EXPR] = "%"; opname_tab[(int) CEIL_MOD_EXPR] = "(ceiling %)"; opname_tab[(int) FLOOR_MOD_EXPR] = "(floor %)"; opname_tab[(int) ROUND_MOD_EXPR] = "(round %)"; opname_tab[(int) EXACT_DIV_EXPR] = "/"; opname_tab[(int) NEGATE_EXPR] = "-"; opname_tab[(int) MIN_EXPR] = "?"; opname_tab[(int) ABS_EXPR] = "abs"; opname_tab[(int) FFS_EXPR] = "ffs"; opname_tab[(int) LSHIFT_EXPR] = "<<"; opname_tab[(int) RSHIFT_EXPR] = ">>"; opname_tab[(int) BIT_IOR_EXPR] = "|"; opname_tab[(int) BIT_XOR_EXPR] = "^"; opname_tab[(int) BIT_AND_EXPR] = "&"; opname_tab[(int) BIT_ANDTC_EXPR] = "&~"; opname_tab[(int) BIT_NOT_EXPR] = "~"; opname_tab[(int) TRUTH_ANDIF_EXPR] = "&&"; opname_tab[(int) TRUTH_ORIF_EXPR] = "||"; opname_tab[(int) TRUTH_AND_EXPR] = "strict &&"; opname_tab[(int) TRUTH_OR_EXPR] = "strict ||"; opname_tab[(int) TRUTH_NOT_EXPR] = "!"; opname_tab[(int) LT_EXPR] = "<"; opname_tab[(int) LE_EXPR] = "<="; opname_tab[(int) GT_EXPR] = ">"; opname_tab[(int) GE_EXPR] = ">="; opname_tab[(int) EQ_EXPR] = "=="; opname_tab[(int) NE_EXPR] = "!="; opname_tab[(int) IN_EXPR] = "in"; opname_tab[(int) RANGE_EXPR] = "..."; opname_tab[(int) CONVERT_EXPR] = "+"; opname_tab[(int) ADDR_EXPR] = "&"; opname_tab[(int) PREDECREMENT_EXPR] = "--"; opname_tab[(int) PREINCREMENT_EXPR] = "++"; opname_tab[(int) POSTDECREMENT_EXPR] = "--"; opname_tab[(int) POSTINCREMENT_EXPR] = "++"; opname_tab[(int) COMPOUND_EXPR] = ","; assignop_tab[(int) NOP_EXPR] = "="; assignop_tab[(int) PLUS_EXPR] = "+="; assignop_tab[(int) CONVERT_EXPR] = "+="; assignop_tab[(int) MINUS_EXPR] = "-="; assignop_tab[(int) NEGATE_EXPR] = "-="; assignop_tab[(int) MULT_EXPR] = "*="; assignop_tab[(int) INDIRECT_REF] = "*="; assignop_tab[(int) TRUNC_DIV_EXPR] = "/="; assignop_tab[(int) EXACT_DIV_EXPR] = "(exact /=)"; assignop_tab[(int) CEIL_DIV_EXPR] = "(ceiling /=)"; assignop_tab[(int) FLOOR_DIV_EXPR] = "(floor /=)"; assignop_tab[(int) ROUND_DIV_EXPR] = "(round /=)"; assignop_tab[(int) TRUNC_MOD_EXPR] = "%="; assignop_tab[(int) CEIL_MOD_EXPR] = "(ceiling %=)"; assignop_tab[(int) FLOOR_MOD_EXPR] = "(floor %=)"; assignop_tab[(int) ROUND_MOD_EXPR] = "(round %=)"; assignop_tab[(int) MIN_EXPR] = "?="; assignop_tab[(int) LSHIFT_EXPR] = "<<="; assignop_tab[(int) RSHIFT_EXPR] = ">>="; assignop_tab[(int) BIT_IOR_EXPR] = "|="; assignop_tab[(int) BIT_XOR_EXPR] = "^="; assignop_tab[(int) BIT_AND_EXPR] = "&="; assignop_tab[(int) ADDR_EXPR] = "&="; init_filename_times (); /* Some options inhibit certain reserved words. Clear those words out of the hash table so they won't be recognized. */ #define UNSET_RESERVED_WORD(STRING) \ do { struct resword *s = is_reserved_word (STRING, sizeof (STRING) - 1); \ if (s) s->name = ""; } while (0) #if 0 /* let's parse things, and if they use it, then give them an error. */ if (!flag_exceptions) { UNSET_RESERVED_WORD ("throw"); UNSET_RESERVED_WORD ("try"); UNSET_RESERVED_WORD ("catch"); } #endif if (!flag_rtti || flag_no_gnu_keywords) { UNSET_RESERVED_WORD ("classof"); UNSET_RESERVED_WORD ("headof"); } if (flag_no_asm || flag_no_gnu_keywords) UNSET_RESERVED_WORD ("typeof"); if (! flag_operator_names) { /* These are new ANSI keywords that may break code. */ UNSET_RESERVED_WORD ("and"); UNSET_RESERVED_WORD ("and_eq"); UNSET_RESERVED_WORD ("bitand"); UNSET_RESERVED_WORD ("bitor"); UNSET_RESERVED_WORD ("compl"); UNSET_RESERVED_WORD ("not"); UNSET_RESERVED_WORD ("not_eq"); UNSET_RESERVED_WORD ("or"); UNSET_RESERVED_WORD ("or_eq"); UNSET_RESERVED_WORD ("xor"); UNSET_RESERVED_WORD ("xor_eq"); } token_count = init_cpp_parse (); interface_unknown = 1; ggc_add_tree_root (ansi_opname, LAST_CPLUS_TREE_CODE); ggc_add_tree_root (ansi_assopname, LAST_CPLUS_TREE_CODE); ggc_add_string_root (&internal_filename, 1); ggc_add_tree_root (ridpointers, RID_MAX); ggc_add_tree_root (&defarg_fns, 1); ggc_add_tree_root (&defarg_parm, 1); ggc_add_tree_root (&this_filename_time, 1); ggc_add_tree_root (&filename_times, 1); ggc_add_root (&impl_file_chain, 1, sizeof (impl_file_chain), mark_impl_file_chain); return filename; } void finish_parse () { #if USE_CPPLIB cpp_finish (&parse_in); errorcount += parse_in.errors; #else fclose (finput); #endif } void reinit_parse_for_function () { current_base_init_list = NULL_TREE; current_member_init_list = NULL_TREE; } inline void yyprint (file, yychar, yylval) FILE *file; int yychar; YYSTYPE yylval; { tree t; switch (yychar) { case IDENTIFIER: case TYPENAME: case TYPESPEC: case PTYPENAME: case PFUNCNAME: case IDENTIFIER_DEFN: case TYPENAME_DEFN: case PTYPENAME_DEFN: case SCSPEC: case PRE_PARSED_CLASS_DECL: t = yylval.ttype; if (TREE_CODE (t) == TYPE_DECL || TREE_CODE (t) == TEMPLATE_DECL) { fprintf (file, " `%s'", IDENTIFIER_POINTER (DECL_NAME (t))); break; } my_friendly_assert (TREE_CODE (t) == IDENTIFIER_NODE, 224); if (IDENTIFIER_POINTER (t)) fprintf (file, " `%s'", IDENTIFIER_POINTER (t)); break; case AGGR: if (yylval.ttype == class_type_node) fprintf (file, " `class'"); else if (yylval.ttype == record_type_node) fprintf (file, " `struct'"); else if (yylval.ttype == union_type_node) fprintf (file, " `union'"); else if (yylval.ttype == enum_type_node) fprintf (file, " `enum'"); else my_friendly_abort (80); break; case CONSTANT: t = yylval.ttype; if (TREE_CODE (t) == INTEGER_CST) fprintf (file, #if HOST_BITS_PER_WIDE_INT == 64 #if HOST_BITS_PER_WIDE_INT == HOST_BITS_PER_INT " 0x%x%016x", #else #if HOST_BITS_PER_WIDE_INT == HOST_BITS_PER_LONG " 0x%lx%016lx", #else " 0x%llx%016llx", #endif #endif #else #if HOST_BITS_PER_WIDE_INT != HOST_BITS_PER_INT " 0x%lx%08lx", #else " 0x%x%08x", #endif #endif TREE_INT_CST_HIGH (t), TREE_INT_CST_LOW (t)); break; } } #if defined(GATHER_STATISTICS) && defined(REDUCE_LENGTH) static int *reduce_count; #endif int *token_count; #if 0 #define REDUCE_LENGTH (sizeof (yyr2) / sizeof (yyr2[0])) #define TOKEN_LENGTH (256 + sizeof (yytname) / sizeof (yytname[0])) #endif #ifdef GATHER_STATISTICS #ifdef REDUCE_LENGTH void yyhook (yyn) int yyn; { reduce_count[yyn] += 1; } static int reduce_cmp (p, q) int *p, *q; { return reduce_count[*q] - reduce_count[*p]; } static int token_cmp (p, q) int *p, *q; { return token_count[*q] - token_count[*p]; } #endif #endif void print_parse_statistics () { #ifdef GATHER_STATISTICS #ifdef REDUCE_LENGTH #if YYDEBUG != 0 int i; int maxlen = REDUCE_LENGTH; unsigned *sorted; if (reduce_count[-1] == 0) return; if (TOKEN_LENGTH > REDUCE_LENGTH) maxlen = TOKEN_LENGTH; sorted = (unsigned *) alloca (sizeof (int) * maxlen); for (i = 0; i < TOKEN_LENGTH; i++) sorted[i] = i; qsort (sorted, TOKEN_LENGTH, sizeof (int), token_cmp); for (i = 0; i < TOKEN_LENGTH; i++) { int idx = sorted[i]; if (token_count[idx] == 0) break; if (token_count[idx] < token_count[-1]) break; fprintf (stderr, "token %d, `%s', count = %d\n", idx, yytname[YYTRANSLATE (idx)], token_count[idx]); } fprintf (stderr, "\n"); for (i = 0; i < REDUCE_LENGTH; i++) sorted[i] = i; qsort (sorted, REDUCE_LENGTH, sizeof (int), reduce_cmp); for (i = 0; i < REDUCE_LENGTH; i++) { int idx = sorted[i]; if (reduce_count[idx] == 0) break; if (reduce_count[idx] < reduce_count[-1]) break; fprintf (stderr, "rule %d, line %d, count = %d\n", idx, yyrline[idx], reduce_count[idx]); } fprintf (stderr, "\n"); #endif #endif #endif } /* Sets the value of the 'yydebug' variable to VALUE. This is a function so we don't have to have YYDEBUG defined in order to build the compiler. */ void set_yydebug (value) int value; { #if YYDEBUG != 0 extern int yydebug; yydebug = value; #else warning ("YYDEBUG not defined."); #endif } /* Mark ARG (which is really a struct impl_files **) for GC. */ static void mark_impl_file_chain (arg) void *arg; { struct impl_files *ifs; ifs = *(struct impl_files **) arg; while (ifs) { ggc_mark_string (ifs->filename); ifs = ifs->next; } } /* Helper function to load global variables with interface information. */ void extract_interface_info () { tree fileinfo = 0; if (flag_alt_external_templates) { struct tinst_level *til = tinst_for_decl (); if (til) fileinfo = get_time_identifier (til->file); } if (!fileinfo) fileinfo = get_time_identifier (input_filename); fileinfo = TIME_IDENTIFIER_FILEINFO (fileinfo); interface_only = TREE_INT_CST_LOW (fileinfo); interface_unknown = TREE_INT_CST_HIGH (fileinfo); } /* Return nonzero if S is not considered part of an INTERFACE/IMPLEMENTATION pair. Otherwise, return 0. */ static int interface_strcmp (s) const char *s; { /* Set the interface/implementation bits for this scope. */ struct impl_files *ifiles; const char *s1; for (ifiles = impl_file_chain; ifiles; ifiles = ifiles->next) { const char *t1 = ifiles->filename; s1 = s; if (*s1 != *t1 || *s1 == 0) continue; while (*s1 == *t1 && *s1 != 0) s1++, t1++; /* A match. */ if (*s1 == *t1) return 0; /* Don't get faked out by xxx.yyy.cc vs xxx.zzz.cc. */ if (index (s1, '.') || index (t1, '.')) continue; if (*s1 == '\0' || s1[-1] != '.' || t1[-1] != '.') continue; /* A match. */ return 0; } /* No matches. */ return 1; } static void cp_pragma_interface (main_filename) char *main_filename; { tree fileinfo = TIME_IDENTIFIER_FILEINFO (get_time_identifier (input_filename)); if (impl_file_chain == 0) { /* If this is zero at this point, then we are auto-implementing. */ if (main_input_filename == 0) main_input_filename = input_filename; #ifdef AUTO_IMPLEMENT filename = file_name_nondirectory (main_input_filename); fi = get_time_identifier (filename); fi = TIME_IDENTIFIER_FILEINFO (fi); TREE_INT_CST_LOW (fi) = 0; TREE_INT_CST_HIGH (fi) = 1; /* Get default. */ impl_file_chain = (struct impl_files *) xmalloc (sizeof (struct impl_files)); impl_file_chain->filename = ggc_alloc_string (filename, -1); impl_file_chain->next = 0; #endif } interface_only = interface_strcmp (main_filename); #ifdef MULTIPLE_SYMBOL_SPACES if (! interface_only) interface_unknown = 0; #else /* MULTIPLE_SYMBOL_SPACES */ interface_unknown = 0; #endif /* MULTIPLE_SYMBOL_SPACES */ TREE_INT_CST_LOW (fileinfo) = interface_only; TREE_INT_CST_HIGH (fileinfo) = interface_unknown; } /* Note that we have seen a #pragma implementation for the key MAIN_FILENAME. We used to only allow this at toplevel, but that restriction was buggy in older compilers and it seems reasonable to allow it in the headers themselves, too. It only needs to precede the matching #p interface. We don't touch interface_only or interface_unknown; the user must specify a matching #p interface for this to have any effect. */ static void cp_pragma_implementation (main_filename) char *main_filename; { struct impl_files *ifiles = impl_file_chain; for (; ifiles; ifiles = ifiles->next) { if (! strcmp (ifiles->filename, main_filename)) break; } if (ifiles == 0) { ifiles = (struct impl_files*) xmalloc (sizeof (struct impl_files)); ifiles->filename = ggc_alloc_string (main_filename, -1); ifiles->next = impl_file_chain; impl_file_chain = ifiles; } } /* Set up the state required to correctly handle the definition of the inline function whose preparsed state has been saved in PI. */ static void begin_definition_of_inclass_inline (pi) struct pending_inline* pi; { tree context; if (!pi->fndecl) return; /* If this is an inline function in a local class, we must make sure that we save all pertinent information about the function surrounding the local class. */ context = decl_function_context (pi->fndecl); if (context) push_function_context_to (context); feed_input (pi->buf, pi->len, pi->filename, pi->lineno); yychar = PRE_PARSED_FUNCTION_DECL; yylval.pi = pi; /* Pass back a handle to the rest of the inline functions, so that they can be processed later. */ DECL_PENDING_INLINE_INFO (pi->fndecl) = 0; DECL_PENDING_INLINE_P (pi->fndecl) = 0; interface_unknown = pi->interface == 1; interface_only = pi->interface == 0; } /* Called from the top level: if there are any pending inlines to do, set up to process them now. This function sets up the first function to be parsed; after it has been, the rule for fndef in parse.y will call process_next_inline to start working on the next one. */ void do_pending_inlines () { struct pending_inline *t; /* Oops, we're still dealing with the last batch. */ if (yychar == PRE_PARSED_FUNCTION_DECL) return; /* Reverse the pending inline functions, since they were cons'd instead of appended. */ { struct pending_inline *prev = 0, *tail; t = pending_inlines; pending_inlines = 0; for (; t; t = tail) { tail = t->next; t->next = prev; t->deja_vu = 1; prev = t; } t = prev; } if (t == 0) return; /* Now start processing the first inline function. */ begin_definition_of_inclass_inline (t); } /* Called from the fndecl rule in the parser when the function just parsed was declared using a PRE_PARSED_FUNCTION_DECL (i.e. came from do_pending_inlines). */ void process_next_inline (i) struct pending_inline *i; { tree context; context = decl_function_context (i->fndecl); if (context) pop_function_context_from (context); i = i->next; if (yychar == YYEMPTY) yychar = yylex (); if (yychar != END_OF_SAVED_INPUT) { error ("parse error at end of saved function text"); /* restore_pending_input will abort unless yychar is either END_OF_SAVED_INPUT or YYEMPTY; since we already know we're hosed, feed back YYEMPTY. */ } yychar = YYEMPTY; end_input (); if (i) begin_definition_of_inclass_inline (i); else extract_interface_info (); } /* Since inline methods can refer to text which has not yet been seen, we store the text of the method in a structure which is placed in the DECL_PENDING_INLINE_INFO field of the FUNCTION_DECL. After parsing the body of the class definition, the FUNCTION_DECL's are scanned to see which ones have this field set. Those are then digested one at a time. This function's FUNCTION_DECL will have a bit set in its common so that we know to watch out for it. */ static void consume_string (this_obstack, matching_char) register struct obstack *this_obstack; int matching_char; { register int c; int starting_lineno; #if USE_CPPLIB if (cpp_token == CPP_STRING) { /* The C preprocessor will warn about newlines in strings. */ obstack_grow (this_obstack, yy_cur, (yy_lim - yy_cur)); yy_cur = yy_lim; lineno = parse_in.lineno; return; } #endif starting_lineno = lineno; do { c = getch (); if (c == EOF) { int save_lineno = lineno; lineno = starting_lineno; if (matching_char == '"') error ("end of file encountered inside string constant"); else error ("end of file encountered inside character constant"); lineno = save_lineno; return; } if (c == '\\') { obstack_1grow (this_obstack, c); c = getch (); obstack_1grow (this_obstack, c); /* Make sure we continue the loop */ c = 0; continue; } if (c == '\n') { if (pedantic) pedwarn ("ISO C++ forbids newline in string constant"); lineno++; } obstack_1grow (this_obstack, c); } while (c != matching_char); } struct pending_input { int yychar, eof; YYSTYPE yylval; struct obstack token_obstack; int first_token; }; struct pending_input * save_pending_input () { struct pending_input *p; p = (struct pending_input *) xmalloc (sizeof (struct pending_input)); p->yychar = yychar; p->yylval = yylval; p->eof = end_of_file; yychar = YYEMPTY; p->first_token = first_token; p->token_obstack = token_obstack; first_token = 0; gcc_obstack_init (&token_obstack); end_of_file = 0; return p; } void restore_pending_input (p) struct pending_input *p; { my_friendly_assert (yychar == YYEMPTY || yychar == END_OF_SAVED_INPUT, 230); yychar = p->yychar; yylval = p->yylval; first_token = p->first_token; obstack_free (&token_obstack, (char *) 0); token_obstack = p->token_obstack; end_of_file = p->eof; free (p); } /* Unget character CH from the input stream. If RESCAN is non-zero, then we want to `see' this character as the next input token. */ void yyungetc (ch, rescan) int ch; int rescan; { /* Unget a character from the input stream. */ if (yychar == YYEMPTY || rescan == 0) { /* If we're putting back a brace, undo the change in indent_level from the first time we saw it. */ if (ch == '{') indent_level--; else if (ch == '}') indent_level++; put_back (ch); } else { yychar = ch; } } void clear_inline_text_obstack () { obstack_free (&inline_text_obstack, inline_text_firstobj); } /* This function stores away the text for an inline function that should be processed later. It decides how much later, and may need to move the info between obstacks; therefore, the caller should not refer to the T parameter after calling this function. */ static void store_pending_inline (decl, t) tree decl; struct pending_inline *t; { t->fndecl = decl; DECL_PENDING_INLINE_INFO (decl) = t; DECL_PENDING_INLINE_P (decl) = 1; /* Because we use obstacks, we must process these in precise order. */ t->next = pending_inlines; pending_inlines = t; } void reinit_parse_for_method (yychar, decl) int yychar; tree decl; { int len; int starting_lineno = lineno; char *starting_filename = input_filename; reinit_parse_for_block (yychar, &inline_text_obstack); len = obstack_object_size (&inline_text_obstack); if (decl == void_type_node || (current_class_type && TYPE_REDEFINED (current_class_type))) { /* Happens when we get two declarations of the same function in the same scope. */ char *buf = obstack_finish (&inline_text_obstack); obstack_free (&inline_text_obstack, buf); return; } else { struct pending_inline *t; char *buf = obstack_finish (&inline_text_obstack); t = (struct pending_inline *) obstack_alloc (&inline_text_obstack, sizeof (struct pending_inline)); t->lineno = starting_lineno; t->filename = starting_filename; t->token = YYEMPTY; t->token_value = 0; t->buf = buf; t->len = len; t->deja_vu = 0; #if 0 if (interface_unknown && processing_template_defn && flag_external_templates && ! DECL_IN_SYSTEM_HEADER (decl)) warn_if_unknown_interface (decl); #endif t->interface = (interface_unknown ? 1 : (interface_only ? 0 : 2)); store_pending_inline (decl, t); } } /* Consume a block -- actually, a method beginning with `:' or `{' -- and save it away on the specified obstack. */ void reinit_parse_for_block (pyychar, obstackp) int pyychar; struct obstack *obstackp; { register int c; int blev = 1; int starting_lineno = lineno; char *starting_filename = input_filename; int len; int look_for_semicolon = 0; int look_for_lbrac = 0; if (pyychar == '{') { obstack_1grow (obstackp, '{'); /* We incremented indent_level in yylex; undo that. */ indent_level--; } else if (pyychar == '=') look_for_semicolon = 1; else if (pyychar == ':') { obstack_1grow (obstackp, pyychar); /* Add a space so we don't get confused by ': ::A(20)'. */ obstack_1grow (obstackp, ' '); look_for_lbrac = 1; blev = 0; } else if (pyychar == RETURN_KEYWORD) { obstack_grow (obstackp, "return", 6); look_for_lbrac = 1; blev = 0; } else if (pyychar == TRY) { obstack_grow (obstackp, "try", 3); look_for_lbrac = 1; blev = 0; } else { yyerror ("parse error in method specification"); obstack_1grow (obstackp, '{'); } c = getch (); while (c != EOF) { int this_lineno = lineno; saving_parse_to_obstack = 1; c = skip_white_space (c); saving_parse_to_obstack = 0; /* Don't lose our cool if there are lots of comments. */ if (lineno == this_lineno + 1) obstack_1grow (obstackp, '\n'); else if (lineno == this_lineno) ; else if (lineno - this_lineno < 10) { int i; for (i = lineno - this_lineno; i > 0; i--) obstack_1grow (obstackp, '\n'); } else { char buf[16]; sprintf (buf, "\n# %d \"", lineno); len = strlen (buf); obstack_grow (obstackp, buf, len); len = strlen (input_filename); obstack_grow (obstackp, input_filename, len); obstack_1grow (obstackp, '\"'); obstack_1grow (obstackp, '\n'); } while (c > ' ') /* ASCII dependent... */ { obstack_1grow (obstackp, c); if (c == '{') { look_for_lbrac = 0; blev++; } else if (c == '}') { blev--; if (blev == 0 && !look_for_semicolon) { if (pyychar == TRY) { if (peekyylex () == CATCH) { yylex (); obstack_grow (obstackp, " catch ", 7); look_for_lbrac = 1; } else { yychar = '{'; goto done; } } else { goto done; } } } else if (c == '\\') { /* Don't act on the next character...e.g, doing an escaped double-quote. */ c = getch (); if (c == EOF) { error_with_file_and_line (starting_filename, starting_lineno, "end of file read inside definition"); goto done; } obstack_1grow (obstackp, c); } else if (c == '\"') consume_string (obstackp, c); else if (c == '\'') consume_string (obstackp, c); else if (c == ';') { if (look_for_lbrac) { error ("function body for constructor missing"); obstack_1grow (obstackp, '{'); obstack_1grow (obstackp, '}'); len += 2; goto done; } else if (look_for_semicolon && blev == 0) goto done; } c = getch (); } if (c == EOF) { error_with_file_and_line (starting_filename, starting_lineno, "end of file read inside definition"); goto done; } else if (c != '\n') { obstack_1grow (obstackp, c); c = getch (); } } done: obstack_1grow (obstackp, '\0'); } /* Consume a no-commas expression -- actually, a default argument -- and save it away on the specified obstack. */ static void reinit_parse_for_expr (obstackp) struct obstack *obstackp; { register int c; int starting_lineno = lineno; char *starting_filename = input_filename; int len; int plev = 0; c = getch (); while (c != EOF) { int this_lineno = lineno; saving_parse_to_obstack = 1; c = skip_white_space (c); saving_parse_to_obstack = 0; /* Don't lose our cool if there are lots of comments. */ if (lineno == this_lineno + 1) obstack_1grow (obstackp, '\n'); else if (lineno == this_lineno) ; else if (lineno - this_lineno < 10) { int i; for (i = lineno - this_lineno; i > 0; --i) obstack_1grow (obstackp, '\n'); } else { char buf[16]; sprintf (buf, "\n# %d \"", lineno); len = strlen (buf); obstack_grow (obstackp, buf, len); len = strlen (input_filename); obstack_grow (obstackp, input_filename, len); obstack_1grow (obstackp, '\"'); obstack_1grow (obstackp, '\n'); } while (c > ' ') /* ASCII dependent... */ { if (plev <= 0 && (c == ')' || c == ',')) { put_back (c); goto done; } obstack_1grow (obstackp, c); if (c == '(' || c == '[') ++plev; else if (c == ']' || c == ')') --plev; else if (c == '\\') { /* Don't act on the next character...e.g, doing an escaped double-quote. */ c = getch (); if (c == EOF) { error_with_file_and_line (starting_filename, starting_lineno, "end of file read inside definition"); goto done; } obstack_1grow (obstackp, c); } else if (c == '\"') consume_string (obstackp, c); else if (c == '\'') consume_string (obstackp, c); c = getch (); } if (c == EOF) { error_with_file_and_line (starting_filename, starting_lineno, "end of file read inside definition"); goto done; } else if (c != '\n') { obstack_1grow (obstackp, c); c = getch (); } } done: obstack_1grow (obstackp, '\0'); } int do_snarf_defarg; /* Decide whether the default argument we are about to see should be gobbled up as text for later parsing. */ void maybe_snarf_defarg () { if (current_class_type && TYPE_BEING_DEFINED (current_class_type)) do_snarf_defarg = 1; } tree snarf_defarg () { int len; char *buf; tree arg; reinit_parse_for_expr (&inline_text_obstack); len = obstack_object_size (&inline_text_obstack); buf = obstack_finish (&inline_text_obstack); arg = make_node (DEFAULT_ARG); DEFARG_LENGTH (arg) = len - 1; DEFARG_POINTER (arg) = buf; return arg; } /* Called from grokfndecl to note a function decl with unparsed default arguments for later processing. Also called from grokdeclarator for function types with unparsed defargs; the call from grokfndecl will always come second, so we can overwrite the entry from the type. */ void add_defarg_fn (decl) tree decl; { if (TREE_CODE (decl) == FUNCTION_DECL) TREE_VALUE (defarg_fns) = decl; else defarg_fns = tree_cons (current_class_type, decl, defarg_fns); } /* Helper for do_pending_defargs. Starts the parsing of a default arg. */ static void feed_defarg (f, p) tree f, p; { tree d = TREE_PURPOSE (p); char *file; int line; if (TREE_CODE (f) == FUNCTION_DECL) { line = DECL_SOURCE_LINE (f); file = DECL_SOURCE_FILE (f); } else { line = lineno; file = input_filename; } feed_input (DEFARG_POINTER (d), DEFARG_LENGTH (d), file, line); yychar = DEFARG_MARKER; yylval.ttype = p; } /* Helper for do_pending_defargs. Ends the parsing of a default arg. */ static void finish_defarg () { if (yychar == YYEMPTY) yychar = yylex (); if (yychar != END_OF_SAVED_INPUT) { error ("parse error at end of saved function text"); /* restore_pending_input will abort unless yychar is either END_OF_SAVED_INPUT or YYEMPTY; since we already know we're hosed, feed back YYEMPTY. */ } yychar = YYEMPTY; end_input (); } /* Main function for deferred parsing of default arguments. Called from the parser. */ void do_pending_defargs () { if (defarg_parm) finish_defarg (); for (; defarg_fns; defarg_fns = TREE_CHAIN (defarg_fns)) { tree defarg_fn = TREE_VALUE (defarg_fns); if (defarg_parm == NULL_TREE) { push_nested_class (TREE_PURPOSE (defarg_fns), 1); pushlevel (0); if (TREE_CODE (defarg_fn) == FUNCTION_DECL) maybe_begin_member_template_processing (defarg_fn); if (TREE_CODE (defarg_fn) == FUNCTION_DECL) { #if 0 tree p; for (p = DECL_ARGUMENTS (defarg_fn); p; p = TREE_CHAIN (p)) pushdecl (copy_node (p)); #endif defarg_parm = TYPE_ARG_TYPES (TREE_TYPE (defarg_fn)); } else defarg_parm = TYPE_ARG_TYPES (defarg_fn); } else defarg_parm = TREE_CHAIN (defarg_parm); for (; defarg_parm; defarg_parm = TREE_CHAIN (defarg_parm)) if (TREE_PURPOSE (defarg_parm) && TREE_CODE (TREE_PURPOSE (defarg_parm)) == DEFAULT_ARG) { feed_defarg (defarg_fn, defarg_parm); /* Return to the parser, which will process this defarg and call us again. */ return; } if (TREE_CODE (defarg_fn) == FUNCTION_DECL) { maybe_end_member_template_processing (); check_default_args (defarg_fn); } poplevel (0, 0, 0); pop_nested_class (); } } /* Build a default function named NAME for type TYPE. KIND says what to build. When KIND == 0, build default destructor. When KIND == 1, build virtual destructor. When KIND == 2, build default constructor. When KIND == 3, build default X(const X&) constructor. When KIND == 4, build default X(X&) constructor. When KIND == 5, build default operator = (const X&). When KIND == 6, build default operator = (X&). */ tree cons_up_default_function (type, full_name, kind) tree type, full_name; int kind; { tree declspecs = NULL_TREE; tree fn, args = NULL_TREE; tree argtype; int retref = 0; tree name = constructor_name (full_name); switch (kind) { /* Destructors. */ case 0: name = build_parse_node (BIT_NOT_EXPR, name); args = void_list_node; break; case 2: /* Default constructor. */ args = void_list_node; break; case 3: type = build_qualified_type (type, TYPE_QUAL_CONST); /* Fall through... */ case 4: /* According to ARM $12.8, the default copy ctor will be declared, but not defined, unless it's needed. */ argtype = build_reference_type (type); args = tree_cons (NULL_TREE, build_tree_list (hash_tree_chain (argtype, NULL_TREE), get_identifier ("_ctor_arg")), void_list_node); break; case 5: case 6: retref = 1; declspecs = build_decl_list (NULL_TREE, type); if (kind == 5) type = build_qualified_type (type, TYPE_QUAL_CONST); name = ansi_opname [(int) MODIFY_EXPR]; argtype = build_reference_type (type); args = tree_cons (NULL_TREE, build_tree_list (hash_tree_chain (argtype, NULL_TREE), get_identifier ("_ctor_arg")), void_list_node); break; default: my_friendly_abort (59); } declspecs = decl_tree_cons (NULL_TREE, ridpointers [(int) RID_INLINE], declspecs); TREE_PARMLIST (args) = 1; { tree declarator = make_call_declarator (name, args, NULL_TREE, NULL_TREE); if (retref) declarator = build_parse_node (ADDR_EXPR, declarator); fn = grokfield (declarator, declspecs, NULL_TREE, NULL_TREE, NULL_TREE); } if (fn == void_type_node) return fn; if (kind > 2) SET_DECL_ARTIFICIAL (TREE_CHAIN (DECL_ARGUMENTS (fn))); #if 0 if (processing_template_defn) { SET_DECL_IMPLICIT_INSTANTIATION (fn); repo_template_used (fn); } #endif #if 0 if (CLASSTYPE_INTERFACE_KNOWN (type)) { DECL_INTERFACE_KNOWN (fn) = 1; DECL_NOT_REALLY_EXTERN (fn) = (!CLASSTYPE_INTERFACE_ONLY (type) && flag_implement_inlines); } else #endif DECL_NOT_REALLY_EXTERN (fn) = 1; mark_inline_for_output (fn); #ifdef DEBUG_DEFAULT_FUNCTIONS { char *fn_type = NULL; tree t = name; switch (kind) { case 0: fn_type = "default destructor"; break; case 1: fn_type = "virtual destructor"; break; case 2: fn_type = "default constructor"; break; case 3: fn_type = "default X(const X&)"; break; case 4: fn_type = "default X(X&)"; break; } if (fn_type) { if (TREE_CODE (name) == BIT_NOT_EXPR) t = TREE_OPERAND (name, 0); fprintf (stderr, "[[[[ %s for %s:\n%s]]]]\n", fn_type, IDENTIFIER_POINTER (t), func_buf); } } #endif /* DEBUG_DEFAULT_FUNCTIONS */ /* Show that this function was generated by the compiler. */ SET_DECL_ARTIFICIAL (fn); return fn; } /* Heuristic to tell whether the user is missing a semicolon after a struct or enum declaration. Emit an error message if we know the user has blown it. */ void check_for_missing_semicolon (type) tree type; { if (yychar < 0) yychar = yylex (); if ((yychar > 255 && yychar != SCSPEC && yychar != IDENTIFIER && yychar != TYPENAME && yychar != CV_QUALIFIER && yychar != SELFNAME) || end_of_file) { if (ANON_AGGRNAME_P (TYPE_IDENTIFIER (type))) error ("semicolon missing after %s declaration", TREE_CODE (type) == ENUMERAL_TYPE ? "enum" : "struct"); else cp_error ("semicolon missing after declaration of `%T'", type); shadow_tag (build_tree_list (0, type)); } /* Could probably also hack cases where class { ... } f (); appears. */ clear_anon_tags (); } void note_got_semicolon (type) tree type; { if (TREE_CODE_CLASS (TREE_CODE (type)) != 't') my_friendly_abort (60); if (CLASS_TYPE_P (type)) CLASSTYPE_GOT_SEMICOLON (type) = 1; } void note_list_got_semicolon (declspecs) tree declspecs; { tree link; for (link = declspecs; link; link = TREE_CHAIN (link)) { tree type = TREE_VALUE (link); if (TREE_CODE_CLASS (TREE_CODE (type)) == 't') note_got_semicolon (type); } clear_anon_tags (); } /* Iff C is a carriage return, warn about it - if appropriate - and return nonzero. */ static int whitespace_cr (c) int c; { static int newline_warning = 0; if (c == '\r') { /* ANSI C says the effects of a carriage return in a source file are undefined. */ if (pedantic && !newline_warning) { warning ("carriage return in source file"); warning ("(we only warn about the first carriage return)"); newline_warning = 1; } return 1; } return 0; } /* If C is not whitespace, return C. Otherwise skip whitespace and return first nonwhite char read. */ static int skip_white_space (c) register int c; { for (;;) { switch (c) { /* We don't recognize comments here, because cpp output can include / and * consecutively as operators. Also, there's no need, since cpp removes all comments. */ case '\n': if (linemode) { put_back (c); return EOF; } c = check_newline (); break; case ' ': case '\t': case '\f': case '\v': case '\b': #if USE_CPPLIB /* While processing a # directive we don't get CPP_HSPACE tokens, so we also need to handle whitespace the normal way. */ if (cpp_token == CPP_HSPACE) c = yy_get_token (); else #endif c = getch (); break; case '\r': whitespace_cr (c); c = getch (); break; case '\\': c = getch (); if (c == '\n') lineno++; else error ("stray '\\' in program"); c = getch (); break; default: return (c); } } } /* Make the token buffer longer, preserving the data in it. P should point to just beyond the last valid character in the old buffer. The value we return is a pointer to the new buffer at a place corresponding to P. */ static void extend_token_buffer_to (size) int size; { do maxtoken = maxtoken * 2 + 10; while (maxtoken < size); token_buffer = (char *) xrealloc (token_buffer, maxtoken + 2); } static char * extend_token_buffer (p) const char *p; { int offset = p - token_buffer; extend_token_buffer_to (offset); return token_buffer + offset; } #if defined HANDLE_PRAGMA /* Local versions of these macros, that can be passed as function pointers. */ static int pragma_getc () { return getch (); } static void pragma_ungetc (arg) int arg; { put_back (arg); } #endif static int read_line_number (num) int *num; { register int token = real_yylex (); if (token == CONSTANT && TREE_CODE (yylval.ttype) == INTEGER_CST) { *num = TREE_INT_CST_LOW (yylval.ttype); return 1; } else { if (token != END_OF_LINE) error ("invalid #-line"); return 0; } } /* At the beginning of a line, increment the line number and process any #-directive on this line. If the line is a #-directive, read the entire line and return a newline. Otherwise, return the line's first non-whitespace character. Note that in the case of USE_CPPLIB, we get the whole line as one CPP_DIRECTIVE token. */ static int check_newline () { register int c; register int token; int saw_line; enum { act_none, act_push, act_pop } action; int action_number, l; int entering_c_header; char *new_file; restart: /* Read first nonwhite char on the line. Do this before incrementing the line number, in case we're at the end of saved text. */ #ifdef USE_CPPLIB c = getch (); /* In some cases where we're leaving an include file, we can get multiple CPP_HSPACE tokens in a row, so we need to loop. */ while (cpp_token == CPP_HSPACE) c = yy_get_token (); #else do c = getch (); while (c == ' ' || c == '\t'); #endif lineno++; if (c != '#') { /* Sequences of multiple newlines are very common; optimize them. */ if (c == '\n') goto restart; /* If not #, return it so caller will use it. */ return c; } /* Don't read beyond this line. */ saw_line = 0; linemode = 1; #if USE_CPPLIB if (cpp_token == CPP_VSPACE) { /* Format is " ". Only the line number is interesting, and even that we can get more efficiently than scanning the line. */ yy_cur = yy_lim - 1; lineno = parse_in.lineno - 1; goto skipline; } #endif token = real_yylex (); if (token == IDENTIFIER) { /* If a letter follows, then if the word here is `line', skip it and ignore it; otherwise, ignore the line, with an error if the word isn't `pragma'. */ const char *name = IDENTIFIER_POINTER (yylval.ttype); if (!strcmp (name, "pragma")) { token = real_yylex (); if (token != IDENTIFIER || TREE_CODE (yylval.ttype) != IDENTIFIER_NODE) goto skipline; /* If this is 1, we handled it; if it's -1, it was one we wanted but had something wrong with it. Only if it's 0 was it not handled. */ if (handle_cp_pragma (IDENTIFIER_POINTER (yylval.ttype))) goto skipline; #ifdef HANDLE_PRAGMA /* We invoke HANDLE_PRAGMA before HANDLE_GENERIC_PRAGMAS (if both are defined), in order to give the back end a chance to override the interpretation of SYSV style pragmas. */ if (HANDLE_PRAGMA (pragma_getc, pragma_ungetc, IDENTIFIER_POINTER (yylval.ttype))) goto skipline; #endif /* HANDLE_PRAGMA */ #ifdef HANDLE_GENERIC_PRAGMAS if (handle_generic_pragma (token)) goto skipline; #endif /* HANDLE_GENERIC_PRAGMAS */ /* Issue a warning message if we have been asked to do so. Ignoring unknown pragmas in system header file unless an explcit -Wunknown-pragmas has been given. */ if (warn_unknown_pragmas > 1 || (warn_unknown_pragmas && ! in_system_header)) warning ("ignoring pragma: %s", token_buffer); goto skipline; } else if (!strcmp (name, "define")) { debug_define (lineno, GET_DIRECTIVE_LINE ()); goto skipline; } else if (!strcmp (name, "undef")) { debug_undef (lineno, GET_DIRECTIVE_LINE ()); goto skipline; } else if (!strcmp (name, "line")) { saw_line = 1; token = real_yylex (); goto linenum; } else if (!strcmp (name, "ident")) { /* #ident. The pedantic warning is now in cccp.c. */ /* Here we have just seen `#ident '. A string constant should follow. */ token = real_yylex (); if (token == END_OF_LINE) goto skipline; if (token != STRING || TREE_CODE (yylval.ttype) != STRING_CST) { error ("invalid #ident"); goto skipline; } if (! flag_no_ident) { #ifdef ASM_OUTPUT_IDENT ASM_OUTPUT_IDENT (asm_out_file, TREE_STRING_POINTER (yylval.ttype)); #endif } /* Skip the rest of this line. */ goto skipline; } error ("undefined or invalid # directive `%s'", name); goto skipline; } /* If the # is the only nonwhite char on the line, just ignore it. Check the new newline. */ if (token == END_OF_LINE) goto skipline; linenum: /* Here we have either `#line' or `# '. In either case, it should be a line number; a digit should follow. */ if (token != CONSTANT || TREE_CODE (yylval.ttype) != INTEGER_CST) { error ("invalid #-line"); goto skipline; } /* subtract one, because it is the following line that gets the specified number */ l = TREE_INT_CST_LOW (yylval.ttype) - 1; /* More follows: it must be a string constant (filename). It would be neat to use cpplib to quickly process the string, but (1) we don't have a handy tokenization of the string, and (2) I don't know how well that would work in the presense of filenames that contain wide characters. */ if (saw_line || saving_parse_to_obstack) { /* Don't treat \ as special if we are processing #line 1 "...". If you want it to be treated specially, use # 1 "...". Also ignore these if saving to an obstack for later parsing. */ ignore_escape_flag = 1; } /* Read the string constant. */ token = real_yylex (); ignore_escape_flag = 0; if (token == END_OF_LINE) { /* No more: store the line number and check following line. */ lineno = l; goto skipline; } if (token != STRING || TREE_CODE (yylval.ttype) != STRING_CST) { error ("invalid #line"); goto skipline; } /* Changing files again. This means currently collected time is charged against header time, and body time starts back at 0. */ if (flag_detailed_statistics) { int this_time = my_get_run_time (); tree time_identifier = get_time_identifier (TREE_STRING_POINTER (yylval.ttype)); header_time += this_time - body_time; TREE_INT_CST_LOW (TIME_IDENTIFIER_TIME (this_filename_time)) += this_time - body_time; this_filename_time = time_identifier; body_time = this_time; } new_file = TREE_STRING_POINTER (yylval.ttype); GNU_xref_file (new_file); if (main_input_filename == 0) { struct impl_files *ifiles = impl_file_chain; if (ifiles) { while (ifiles->next) ifiles = ifiles->next; ifiles->filename = file_name_nondirectory (new_file); } main_input_filename = new_file; } action = act_none; action_number = 0; /* Each change of file name reinitializes whether we are now in a system header. */ in_system_header = 0; entering_c_header = 0; if (!read_line_number (&action_number) && input_file_stack) { input_file_stack->name = input_filename = new_file; input_file_stack->line = lineno = l; } /* `1' after file name means entering new file. `2' after file name means just left a file. */ if (action_number == 1) { action = act_push; read_line_number (&action_number); } else if (action_number == 2) { action = act_pop; read_line_number (&action_number); } if (action_number == 3) { /* `3' after file name means this is a system header file. */ in_system_header = 1; read_line_number (&action_number); } if (action_number == 4) { /* `4' after file name means this is a C header file. */ entering_c_header = 1; read_line_number (&action_number); } /* Do the actions implied by the preceding numbers. */ if (action == act_push) { /* Pushing to a new file. */ push_srcloc (new_file, l); input_file_stack->indent_level = indent_level; debug_start_source_file (input_filename); if (c_header_level) ++c_header_level; else if (entering_c_header) { c_header_level = 1; ++pending_lang_change; } } else if (action == act_pop) { /* Popping out of a file. */ if (input_file_stack->next) { if (c_header_level && --c_header_level == 0) { if (entering_c_header) warning ("badly nested C headers from preprocessor"); --pending_lang_change; } if (indent_level != input_file_stack->indent_level) { warning_with_file_and_line (input_filename, lineno, "This file contains more `%c's than `%c's.", indent_level > input_file_stack->indent_level ? '{' : '}', indent_level > input_file_stack->indent_level ? '}' : '{'); } pop_srcloc (); input_file_stack->name = new_file; lineno = l; debug_end_source_file (input_file_stack->line); } else error ("#-lines for entering and leaving files don't match"); } extract_interface_info (); /* skip the rest of this line. */ skipline: linemode = 0; end_of_file = 0; do c = getch (); while (c != '\n' && c != EOF); return c; } #ifdef HANDLE_GENERIC_PRAGMAS /* Handle a #pragma directive. TOKEN is the token we read after `#pragma'. Processes the entire input line and return non-zero iff the pragma has been successfully parsed. */ /* This function has to be in this file, in order to get at the token types. */ static int handle_generic_pragma (token) register int token; { for (;;) { switch (token) { case IDENTIFIER: case TYPENAME: case STRING: case CONSTANT: handle_pragma_token (token_buffer, yylval.ttype); break; case LEFT_RIGHT: handle_pragma_token ("(", NULL_TREE); handle_pragma_token (")", NULL_TREE); break; case END_OF_LINE: return handle_pragma_token (NULL_PTR, NULL_TREE); default: handle_pragma_token (token_buffer, NULL_TREE); } token = real_yylex (); } } #endif /* HANDLE_GENERIC_PRAGMAS */ static int handle_cp_pragma (pname) const char *pname; { register int token; if (! strcmp (pname, "vtable")) { /* More follows: it must be a string constant (class name). */ token = real_yylex (); if (token != STRING || TREE_CODE (yylval.ttype) != STRING_CST) { error ("invalid #pragma vtable"); return -1; } pending_vtables = tree_cons (NULL_TREE, get_identifier (TREE_STRING_POINTER (yylval.ttype)), pending_vtables); token = real_yylex (); if (token != END_OF_LINE) warning ("trailing characters ignored"); return 1; } else if (! strcmp (pname, "unit")) { /* More follows: it must be a string constant (unit name). */ token = real_yylex (); if (token != STRING || TREE_CODE (yylval.ttype) != STRING_CST) { error ("invalid #pragma unit"); return -1; } token = real_yylex (); if (token != END_OF_LINE) warning ("trailing characters ignored"); return 1; } else if (! strcmp (pname, "interface")) { char *main_filename = input_filename; main_filename = file_name_nondirectory (main_filename); token = real_yylex (); if (token != END_OF_LINE) { if (token != STRING || TREE_CODE (yylval.ttype) != STRING_CST) { error ("invalid `#pragma interface'"); return -1; } main_filename = TREE_STRING_POINTER (yylval.ttype); token = real_yylex (); } if (token != END_OF_LINE) warning ("garbage after `#pragma interface' ignored"); cp_pragma_interface (main_filename); return 1; } else if (! strcmp (pname, "implementation")) { char *main_filename = main_input_filename ? main_input_filename : input_filename; main_filename = file_name_nondirectory (main_filename); token = real_yylex (); if (token != END_OF_LINE) { if (token != STRING || TREE_CODE (yylval.ttype) != STRING_CST) { error ("invalid `#pragma implementation'"); return -1; } main_filename = TREE_STRING_POINTER (yylval.ttype); token = real_yylex (); } if (token != END_OF_LINE) warning ("garbage after `#pragma implementation' ignored"); cp_pragma_implementation (main_filename); return 1; } return 0; } void do_pending_lang_change () { for (; pending_lang_change > 0; --pending_lang_change) push_lang_context (lang_name_c); for (; pending_lang_change < 0; ++pending_lang_change) pop_lang_context (); } #define ENDFILE -1 /* token that represents end-of-file */ /* Read an escape sequence, returning its equivalent as a character, or store 1 in *ignore_ptr if it is backslash-newline. */ static int readescape (ignore_ptr) int *ignore_ptr; { register int c = getch (); register int code; register unsigned count; unsigned firstdig = 0; int nonnull; switch (c) { case 'x': code = 0; count = 0; nonnull = 0; while (1) { c = getch (); if (! ISXDIGIT (c)) { put_back (c); break; } code *= 16; if (c >= 'a' && c <= 'f') code += c - 'a' + 10; if (c >= 'A' && c <= 'F') code += c - 'A' + 10; if (c >= '0' && c <= '9') code += c - '0'; if (code != 0 || count != 0) { if (count == 0) firstdig = code; count++; } nonnull = 1; } if (! nonnull) error ("\\x used with no following hex digits"); else if (count == 0) /* Digits are all 0's. Ok. */ ; else if ((count - 1) * 4 >= TYPE_PRECISION (integer_type_node) || (count > 1 && (((unsigned)1 << (TYPE_PRECISION (integer_type_node) - (count - 1) * 4)) <= firstdig))) pedwarn ("hex escape out of range"); return code; case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': code = 0; count = 0; while ((c <= '7') && (c >= '0') && (count++ < 3)) { code = (code * 8) + (c - '0'); c = getch (); } put_back (c); return code; case '\\': case '\'': case '"': return c; case '\n': lineno++; *ignore_ptr = 1; return 0; case 'n': return TARGET_NEWLINE; case 't': return TARGET_TAB; case 'r': return TARGET_CR; case 'f': return TARGET_FF; case 'b': return TARGET_BS; case 'a': return TARGET_BELL; case 'v': return TARGET_VT; case 'e': case 'E': if (pedantic) pedwarn ("non-ISO-standard escape sequence, `\\%c'", c); return 033; case '?': return c; /* `\(', etc, are used at beginning of line to avoid confusing Emacs. */ case '(': case '{': case '[': /* `\%' is used to prevent SCCS from getting confused. */ case '%': if (pedantic) pedwarn ("unknown escape sequence `\\%c'", c); return c; } if (ISGRAPH (c)) pedwarn ("unknown escape sequence `\\%c'", c); else pedwarn ("unknown escape sequence: `\\' followed by char code 0x%x", c); return c; } void yyerror (string) const char *string; { extern int end_of_file; /* We can't print string and character constants well because the token_buffer contains the result of processing escapes. */ if (end_of_file) { if (input_redirected ()) error ("%s at end of saved text", string); else error ("%s at end of input", string); } else if (token_buffer[0] == 0) error ("%s at null character", string); else if (token_buffer[0] == '"') error ("%s before string constant", string); else if (token_buffer[0] == '\'') error ("%s before character constant", string); else if (!ISGRAPH ((unsigned char)token_buffer[0])) error ("%s before character 0%o", string, (unsigned char) token_buffer[0]); else error ("%s before `%s'", string, token_buffer); } /* Value is 1 (or 2) if we should try to make the next identifier look like a typename (when it may be a local variable or a class variable). Value is 0 if we treat this name in a default fashion. */ int looking_for_typename; inline int identifier_type (decl) tree decl; { tree t; if (TREE_CODE (decl) == TEMPLATE_DECL) { if (TREE_CODE (DECL_RESULT (decl)) == TYPE_DECL) return PTYPENAME; else if (looking_for_template) return PFUNCNAME; } if (looking_for_template && really_overloaded_fn (decl)) { /* See through a baselink. */ if (TREE_CODE (decl) == TREE_LIST) decl = TREE_VALUE (decl); for (t = decl; t != NULL_TREE; t = OVL_CHAIN (t)) if (DECL_FUNCTION_TEMPLATE_P (OVL_FUNCTION (t))) return PFUNCNAME; } if (TREE_CODE (decl) == NAMESPACE_DECL) return NSNAME; if (TREE_CODE (decl) != TYPE_DECL) return IDENTIFIER; if (DECL_ARTIFICIAL (decl) && TREE_TYPE (decl) == current_class_type) return SELFNAME; /* A constructor declarator for a template type will get here as an implicit typename, a TYPENAME_TYPE with a type. */ t = got_scope; if (t && TREE_CODE (t) == TYPENAME_TYPE) t = TREE_TYPE (t); decl = TREE_TYPE (decl); if (TREE_CODE (decl) == TYPENAME_TYPE) decl = TREE_TYPE (decl); if (t && t == decl) return SELFNAME; return TYPENAME; } void see_typename () { /* Only types expected, not even namespaces. */ looking_for_typename = 2; if (yychar < 0) if ((yychar = yylex ()) < 0) yychar = 0; looking_for_typename = 0; if (yychar == IDENTIFIER) { lastiddecl = lookup_name (yylval.ttype, -2); if (lastiddecl == 0) { if (flag_labels_ok) lastiddecl = IDENTIFIER_LABEL_VALUE (yylval.ttype); } else yychar = identifier_type (lastiddecl); } } /* Return true if d is in a global scope. */ static int is_global (d) tree d; { while (1) switch (TREE_CODE (d)) { case ERROR_MARK: return 1; case OVERLOAD: d = OVL_FUNCTION (d); continue; case TREE_LIST: d = TREE_VALUE (d); continue; default: my_friendly_assert (TREE_CODE_CLASS (TREE_CODE (d)) == 'd', 980629); return DECL_NAMESPACE_SCOPE_P (d); } } tree do_identifier (token, parsing, args) register tree token; int parsing; tree args; { register tree id; int lexing = (parsing == 1); int in_call = (parsing == 2); if (! lexing || IDENTIFIER_OPNAME_P (token)) id = lookup_name (token, 0); else id = lastiddecl; /* Do Koenig lookup if appropriate (inside templates we build lookup expressions instead). [basic.lookup.koenig]: If the ordinary unqualified lookup of the name finds the declaration of a class member function, the associated namespaces and classes are not considered. */ if (args && !current_template_parms && (!id || is_global (id))) id = lookup_arg_dependent (token, id, args); /* Remember that this name has been used in the class definition, as per [class.scope0] */ if (id && parsing) maybe_note_name_used_in_class (token, id); if (id == error_mark_node) { /* lookup_name quietly returns error_mark_node if we're parsing, as we don't want to complain about an identifier that ends up being used as a declarator. So we call it again to get the error message. */ id = lookup_name (token, 0); return error_mark_node; } if (!id) { if (current_template_parms) return build_min_nt (LOOKUP_EXPR, token); else if (IDENTIFIER_OPNAME_P (token)) { if (token != ansi_opname[ERROR_MARK]) cp_error ("`%D' not defined", token); id = error_mark_node; } else if (in_call && ! flag_strict_prototype) { id = implicitly_declare (token); } else if (current_function_decl == 0) { cp_error ("`%D' was not declared in this scope", token); id = error_mark_node; } else { if (IDENTIFIER_NAMESPACE_VALUE (token) != error_mark_node || IDENTIFIER_ERROR_LOCUS (token) != current_function_decl) { static int undeclared_variable_notice; cp_error ("`%D' undeclared (first use this function)", token); if (! undeclared_variable_notice) { error ("(Each undeclared identifier is reported only once"); error ("for each function it appears in.)"); undeclared_variable_notice = 1; } } id = error_mark_node; /* Prevent repeated error messages. */ SET_IDENTIFIER_NAMESPACE_VALUE (token, error_mark_node); SET_IDENTIFIER_ERROR_LOCUS (token, current_function_decl); } } if (TREE_CODE (id) == VAR_DECL && DECL_DEAD_FOR_LOCAL (id)) { tree shadowed = DECL_SHADOWED_FOR_VAR (id); while (shadowed != NULL_TREE && TREE_CODE (shadowed) == VAR_DECL && DECL_DEAD_FOR_LOCAL (shadowed)) shadowed = DECL_SHADOWED_FOR_VAR (shadowed); if (!shadowed) shadowed = IDENTIFIER_NAMESPACE_VALUE (DECL_NAME (id)); if (shadowed) { if (!DECL_ERROR_REPORTED (id)) { warning ("name lookup of `%s' changed", IDENTIFIER_POINTER (token)); cp_warning_at (" matches this `%D' under ISO standard rules", shadowed); cp_warning_at (" matches this `%D' under old rules", id); DECL_ERROR_REPORTED (id) = 1; } id = shadowed; } else if (!DECL_ERROR_REPORTED (id)) { DECL_ERROR_REPORTED (id) = 1; if (TYPE_NEEDS_DESTRUCTOR (TREE_TYPE (id))) { error ("name lookup of `%s' changed for new ISO `for' scoping", IDENTIFIER_POINTER (token)); cp_error_at (" cannot use obsolete binding at `%D' because it has a destructor", id); id = error_mark_node; } else { pedwarn ("name lookup of `%s' changed for new ISO `for' scoping", IDENTIFIER_POINTER (token)); cp_pedwarn_at (" using obsolete binding at `%D'", id); } } } /* TREE_USED is set in `hack_identifier'. */ if (TREE_CODE (id) == CONST_DECL) { /* Check access. */ if (IDENTIFIER_CLASS_VALUE (token) == id) enforce_access (CP_DECL_CONTEXT(id), id); if (!processing_template_decl || DECL_TEMPLATE_PARM_P (id)) id = DECL_INITIAL (id); } else id = hack_identifier (id, token); /* We must look up dependent names when the template is instantiated, not while parsing it. For now, we don't distinguish between dependent and independent names. So, for example, we look up all overloaded functions at instantiation-time, even though in some cases we should just use the DECL we have here. We also use LOOKUP_EXPRs to find things like local variables, rather than creating TEMPLATE_DECLs for the local variables and then finding matching instantiations. */ if (current_template_parms && (is_overloaded_fn (id) /* Some local VAR_DECLs (such as those for local variables in member functions of local classes) are built on the permanent obstack. */ || (TREE_CODE (id) == VAR_DECL && CP_DECL_CONTEXT (id) && TREE_CODE (CP_DECL_CONTEXT (id)) == FUNCTION_DECL) || TREE_CODE (id) == PARM_DECL || TREE_CODE (id) == RESULT_DECL || TREE_CODE (id) == USING_DECL)) id = build_min_nt (LOOKUP_EXPR, token); return id; } tree do_scoped_id (token, parsing) tree token; int parsing; { tree id; /* during parsing, this is ::name. Otherwise, it is black magic. */ if (parsing) { id = make_node (CPLUS_BINDING); if (!qualified_lookup_using_namespace (token, global_namespace, id, 0)) id = NULL_TREE; else id = BINDING_VALUE (id); } else id = IDENTIFIER_GLOBAL_VALUE (token); if (parsing && yychar == YYEMPTY) yychar = yylex (); if (! id) { if (processing_template_decl) { id = build_min_nt (LOOKUP_EXPR, token); LOOKUP_EXPR_GLOBAL (id) = 1; return id; } if (parsing && (yychar == '(' || yychar == LEFT_RIGHT) && ! flag_strict_prototype) id = implicitly_declare (token); else { if (IDENTIFIER_NAMESPACE_VALUE (token) != error_mark_node) cp_error ("`::%D' undeclared (first use here)", token); id = error_mark_node; /* Prevent repeated error messages. */ SET_IDENTIFIER_NAMESPACE_VALUE (token, error_mark_node); } } else { if (TREE_CODE (id) == ADDR_EXPR) mark_used (TREE_OPERAND (id, 0)); else if (TREE_CODE (id) != OVERLOAD) mark_used (id); } if (TREE_CODE (id) == CONST_DECL && ! processing_template_decl) { /* XXX CHS - should we set TREE_USED of the constant? */ id = DECL_INITIAL (id); /* This is to prevent an enum whose value is 0 from being considered a null pointer constant. */ id = build1 (NOP_EXPR, TREE_TYPE (id), id); TREE_CONSTANT (id) = 1; } if (processing_template_decl) { if (is_overloaded_fn (id)) { id = build_min_nt (LOOKUP_EXPR, token); LOOKUP_EXPR_GLOBAL (id) = 1; return id; } /* else just use the decl */ } return convert_from_reference (id); } tree identifier_typedecl_value (node) tree node; { tree t, type; type = IDENTIFIER_TYPE_VALUE (node); if (type == NULL_TREE) return NULL_TREE; if (IDENTIFIER_BINDING (node)) { t = IDENTIFIER_VALUE (node); if (t && TREE_CODE (t) == TYPE_DECL && TREE_TYPE (t) == type) return t; } if (IDENTIFIER_NAMESPACE_VALUE (node)) { t = IDENTIFIER_NAMESPACE_VALUE (node); if (t && TREE_CODE (t) == TYPE_DECL && TREE_TYPE (t) == type) return t; } /* Will this one ever happen? */ if (TYPE_MAIN_DECL (type)) return TYPE_MAIN_DECL (type); /* We used to do an internal error of 62 here, but instead we will handle the return of a null appropriately in the callers. */ return NULL_TREE; } struct pf_args { /* Input */ int base; char * p; /* I/O */ int c; /* Output */ int imag; tree type; int conversion_errno; REAL_VALUE_TYPE value; }; static void parse_float (data) PTR data; { struct pf_args * args = (struct pf_args *) data; int fflag = 0, lflag = 0; /* Copy token_buffer now, while it has just the number and not the suffixes; once we add `f' or `i', REAL_VALUE_ATOF may not work any more. */ char *copy = (char *) alloca (args->p - token_buffer + 1); bcopy (token_buffer, copy, args->p - token_buffer + 1); args->imag = 0; args->conversion_errno = 0; args->type = double_type_node; while (1) { int lose = 0; /* Read the suffixes to choose a data type. */ switch (args->c) { case 'f': case 'F': if (fflag) error ("more than one `f' in numeric constant"); fflag = 1; break; case 'l': case 'L': if (lflag) error ("more than one `l' in numeric constant"); lflag = 1; break; case 'i': case 'I': if (args->imag) error ("more than one `i' or `j' in numeric constant"); else if (pedantic) pedwarn ("ISO C++ forbids imaginary numeric constants"); args->imag = 1; break; default: lose = 1; } if (lose) break; if (args->p >= token_buffer + maxtoken - 3) args->p = extend_token_buffer (args->p); *(args->p++) = args->c; *(args->p) = 0; args->c = getch (); } /* The second argument, machine_mode, of REAL_VALUE_ATOF tells the desired precision of the binary result of decimal-to-binary conversion. */ if (fflag) { if (lflag) error ("both `f' and `l' in floating constant"); args->type = float_type_node; errno = 0; if (args->base == 16) args->value = REAL_VALUE_HTOF (copy, TYPE_MODE (args->type)); else args->value = REAL_VALUE_ATOF (copy, TYPE_MODE (args->type)); args->conversion_errno = errno; /* A diagnostic is required here by some ANSI C testsuites. This is not pedwarn, because some people don't want an error for this. */ if (REAL_VALUE_ISINF (args->value) && pedantic) warning ("floating point number exceeds range of `float'"); } else if (lflag) { args->type = long_double_type_node; errno = 0; if (args->base == 16) args->value = REAL_VALUE_HTOF (copy, TYPE_MODE (args->type)); else args->value = REAL_VALUE_ATOF (copy, TYPE_MODE (args->type)); args->conversion_errno = errno; if (REAL_VALUE_ISINF (args->value) && pedantic) warning ("floating point number exceeds range of `long double'"); } else { errno = 0; if (args->base == 16) args->value = REAL_VALUE_HTOF (copy, TYPE_MODE (args->type)); else args->value = REAL_VALUE_ATOF (copy, TYPE_MODE (args->type)); args->conversion_errno = errno; if (REAL_VALUE_ISINF (args->value) && pedantic) warning ("floating point number exceeds range of `double'"); } } /* Get the next character, staying within the current token if possible. If we're lexing a token, we don't want to look beyond the end of the token cpplib has prepared for us; otherwise, we end up reading in the next token, which screws up feed_input. So just return a null character. */ static int token_getch () { #if USE_CPPLIB if (yy_cur == yy_lim) return '\0'; #endif return getch (); } static void token_put_back (ch) int ch; { #if USE_CPPLIB if (ch == '\0') return; #endif put_back (ch); } /* Read a single token from the input stream, and assign it lexical semantics. Note: We used to do token pasting here, to produce compound tokens like LEFT_RIGHT and EXTERN_LANG_STRING. That's now handled in spew.c, along with symbol table interaction and other context-sensitivity. */ int real_yylex () { register int c; register char *p; register int value; int wide_flag = 0; c = getch (); /* Effectively do c = skip_white_space (c) but do it faster in the usual cases. */ while (1) switch (c) { case ' ': case '\t': case '\f': case '\v': case '\b': #if USE_CPPLIB if (cpp_token == CPP_HSPACE) c = yy_get_token (); else #endif c = getch (); break; case '\r': /* Call skip_white_space so we can warn if appropriate. */ case '\n': case '/': case '\\': c = skip_white_space (c); default: goto found_nonwhite; } found_nonwhite: token_buffer[0] = c; token_buffer[1] = 0; /* yylloc.first_line = lineno; */ switch (c) { case EOF: end_of_file = 1; token_buffer[0] = 0; if (linemode) value = END_OF_LINE; else if (input_redirected ()) value = END_OF_SAVED_INPUT; else value = ENDFILE; break; case 'L': #if USE_CPPLIB if (cpp_token == CPP_NAME) goto letter; #endif /* Capital L may start a wide-string or wide-character constant. */ { register int c = token_getch (); if (c == '\'') { wide_flag = 1; goto char_constant; } if (c == '"') { wide_flag = 1; goto string_constant; } token_put_back (c); } case 'A': case 'B': case 'C': case 'D': case 'E': case 'F': case 'G': case 'H': case 'I': case 'J': case 'K': case 'M': case 'N': case 'O': case 'P': case 'Q': case 'R': case 'S': case 'T': case 'U': case 'V': case 'W': case 'X': case 'Y': case 'Z': case 'a': case 'b': case 'c': case 'd': case 'e': case 'f': case 'g': case 'h': case 'i': case 'j': case 'k': case 'l': case 'm': case 'n': case 'o': case 'p': case 'q': case 'r': case 's': case 't': case 'u': case 'v': case 'w': case 'x': case 'y': case 'z': case '_': case '$': #if USE_CPPLIB letter: if (cpp_token == CPP_NAME) { /* Note that one character has already been read from yy_cur into token_buffer. Also, cpplib complains about $ in identifiers, so we don't have to. */ int len = yy_lim - yy_cur + 1; if (len >= maxtoken) extend_token_buffer_to (len + 1); memcpy (token_buffer + 1, yy_cur, len); p = token_buffer + len; yy_cur = yy_lim; } else #endif { p = token_buffer; while (ISALNUM (c) || (c == '_') || c == '$') { /* Make sure this char really belongs in an identifier. */ if (c == '$') { if (! dollars_in_ident) error ("`$' in identifier"); else if (pedantic) pedwarn ("`$' in identifier"); } if (p >= token_buffer + maxtoken) p = extend_token_buffer (p); *p++ = c; c = token_getch (); } *p = 0; token_put_back (c); } value = IDENTIFIER; yylval.itype = 0; /* Try to recognize a keyword. Uses minimum-perfect hash function */ { register struct resword *ptr; if ((ptr = is_reserved_word (token_buffer, p - token_buffer))) { if (ptr->rid) { if (ptr->token == VISSPEC) { switch (ptr->rid) { case RID_PUBLIC: yylval.ttype = access_public_node; break; case RID_PRIVATE: yylval.ttype = access_private_node; break; case RID_PROTECTED: yylval.ttype = access_protected_node; break; default: my_friendly_abort (63); } } else yylval.ttype = ridpointers[(int) ptr->rid]; } else switch (ptr->token) { case EQCOMPARE: yylval.code = NE_EXPR; token_buffer[0] = '!'; token_buffer[1] = '='; token_buffer[2] = 0; break; case ASSIGN: if (strcmp ("and_eq", token_buffer) == 0) { yylval.code = BIT_AND_EXPR; token_buffer[0] = '&'; } else if (strcmp ("or_eq", token_buffer) == 0) { yylval.code = BIT_IOR_EXPR; token_buffer[0] = '|'; } else if (strcmp ("xor_eq", token_buffer) == 0) { yylval.code = BIT_XOR_EXPR; token_buffer[0] = '^'; } token_buffer[1] = '='; token_buffer[2] = 0; break; case '&': yylval.code = BIT_AND_EXPR; token_buffer[0] = '&'; token_buffer[1] = 0; break; case '|': yylval.code = BIT_IOR_EXPR; token_buffer[0] = '|'; token_buffer[1] = 0; break; case '^': yylval.code = BIT_XOR_EXPR; token_buffer[0] = '^'; token_buffer[1] = 0; break; } value = (int) ptr->token; } } /* If we did not find a keyword, look for an identifier (or a typename). */ if (value == IDENTIFIER || value == TYPESPEC) GNU_xref_ref (current_function_decl, token_buffer); if (value == IDENTIFIER) { register tree tmp = get_identifier (token_buffer); #if !defined(VMS) && defined(JOINER) /* Make sure that user does not collide with our internal naming scheme. */ if (JOINER == '$' && (THIS_NAME_P (tmp) || VPTR_NAME_P (tmp) || DESTRUCTOR_NAME_P (tmp) || VTABLE_NAME_P (tmp) || TEMP_NAME_P (tmp) || ANON_AGGRNAME_P (tmp) || ANON_PARMNAME_P (tmp))) warning ("identifier name `%s' conflicts with GNU C++ internal naming strategy", token_buffer); #endif yylval.ttype = tmp; } if (value == NEW && ! global_bindings_p ()) { value = NEW; goto done; } break; case '.': #if USE_CPPLIB if (yy_cur < yy_lim) #endif { /* It's hard to preserve tokenization on '.' because it could be a symbol by itself, or it could be the start of a floating point number and cpp won't tell us. */ register int c1 = token_getch (); token_buffer[1] = c1; if (c1 == '*') { value = DOT_STAR; token_buffer[2] = 0; goto done; } if (c1 == '.') { c1 = token_getch (); if (c1 == '.') { token_buffer[2] = c1; token_buffer[3] = 0; value = ELLIPSIS; goto done; } error ("parse error at `..'"); } if (ISDIGIT (c1)) { token_put_back (c1); goto number; } token_put_back (c1); } value = '.'; token_buffer[1] = 0; break; case '0': case '1': /* Optimize for most frequent case. */ { register int cond; #if USE_CPPLIB cond = (yy_cur == yy_lim); #else register int c1 = token_getch (); token_put_back (c1); cond = (! ISALNUM (c1) && c1 != '.'); #endif if (cond) { yylval.ttype = (c == '0') ? integer_zero_node : integer_one_node; value = CONSTANT; break; } /*FALLTHRU*/ } case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': number: { int base = 10; int count = 0; int largest_digit = 0; int numdigits = 0; int overflow = 0; /* We actually store only HOST_BITS_PER_CHAR bits in each part. The code below which fills the parts array assumes that a host int is at least twice as wide as a host char, and that HOST_BITS_PER_WIDE_INT is an even multiple of HOST_BITS_PER_CHAR. Two HOST_WIDE_INTs is the largest int literal we can store. In order to detect overflow below, the number of parts (TOTAL_PARTS) must be exactly the number of parts needed to hold the bits of two HOST_WIDE_INTs. */ #define TOTAL_PARTS ((HOST_BITS_PER_WIDE_INT / HOST_BITS_PER_CHAR) * 2) unsigned int parts[TOTAL_PARTS]; enum anon1 { NOT_FLOAT, AFTER_POINT, TOO_MANY_POINTS, AFTER_EXPON } floatflag = NOT_FLOAT; for (count = 0; count < TOTAL_PARTS; count++) parts[count] = 0; p = token_buffer; *p++ = c; if (c == '0') { *p++ = (c = token_getch ()); if ((c == 'x') || (c == 'X')) { base = 16; *p++ = (c = token_getch ()); } /* Leading 0 forces octal unless the 0 is the only digit. */ else if (c >= '0' && c <= '9') { base = 8; numdigits++; } else numdigits++; } /* Read all the digits-and-decimal-points. */ while (c == '.' || (ISALNUM (c) && c != 'l' && c != 'L' && c != 'u' && c != 'U' && c != 'i' && c != 'I' && c != 'j' && c != 'J' && (floatflag == NOT_FLOAT || ((base != 16) && (c != 'f') && (c != 'F')) || base == 16))) { if (c == '.') { if (base == 16 && pedantic) pedwarn ("floating constant may not be in radix 16"); if (floatflag == TOO_MANY_POINTS) /* We have already emitted an error. Don't need another. */ ; else if (floatflag == AFTER_POINT || floatflag == AFTER_EXPON) { error ("malformed floating constant"); floatflag = TOO_MANY_POINTS; /* Avoid another error from atof by forcing all characters from here on to be ignored. */ p[-1] = '\0'; } else floatflag = AFTER_POINT; if (base == 8) base = 10; *p++ = c = token_getch (); /* Accept '.' as the start of a floating-point number only when it is followed by a digit. */ if (p == token_buffer + 2 && !ISDIGIT (c)) my_friendly_abort (990710); } else { /* It is not a decimal point. It should be a digit (perhaps a hex digit). */ if (ISDIGIT (c)) { c = c - '0'; } else if (base <= 10) { if (c == 'e' || c == 'E') { base = 10; floatflag = AFTER_EXPON; break; /* start of exponent */ } error ("nondigits in number and not hexadecimal"); c = 0; } else if (base == 16 && (c == 'p' || c == 'P')) { floatflag = AFTER_EXPON; break; /* start of exponent */ } else if (c >= 'a') { c = c - 'a' + 10; } else { c = c - 'A' + 10; } if (c >= largest_digit) largest_digit = c; numdigits++; for (count = 0; count < TOTAL_PARTS; count++) { parts[count] *= base; if (count) { parts[count] += (parts[count-1] >> HOST_BITS_PER_CHAR); parts[count-1] &= (1 << HOST_BITS_PER_CHAR) - 1; } else parts[0] += c; } /* If the highest-order part overflows (gets larger than a host char will hold) then the whole number has overflowed. Record this and truncate the highest-order part. */ if (parts[TOTAL_PARTS - 1] >> HOST_BITS_PER_CHAR) { overflow = 1; parts[TOTAL_PARTS - 1] &= (1 << HOST_BITS_PER_CHAR) - 1; } if (p >= token_buffer + maxtoken - 3) p = extend_token_buffer (p); *p++ = (c = token_getch ()); } } /* This can happen on input like `int i = 0x;' */ if (numdigits == 0) error ("numeric constant with no digits"); if (largest_digit >= base) error ("numeric constant contains digits beyond the radix"); /* Remove terminating char from the token buffer and delimit the string. */ *--p = 0; if (floatflag != NOT_FLOAT) { tree type; int imag, conversion_errno; REAL_VALUE_TYPE value; struct pf_args args; /* Read explicit exponent if any, and put it in tokenbuf. */ if ((base == 10 && ((c == 'e') || (c == 'E'))) || (base == 16 && (c == 'p' || c == 'P'))) { if (p >= token_buffer + maxtoken - 3) p = extend_token_buffer (p); *p++ = c; c = token_getch (); if ((c == '+') || (c == '-')) { *p++ = c; c = token_getch (); } /* Exponent is decimal, even if string is a hex float. */ if (! ISDIGIT (c)) error ("floating constant exponent has no digits"); while (ISDIGIT (c)) { if (p >= token_buffer + maxtoken - 3) p = extend_token_buffer (p); *p++ = c; c = token_getch (); } } if (base == 16 && floatflag != AFTER_EXPON) error ("hexadecimal floating constant has no exponent"); *p = 0; /* Setup input for parse_float() */ args.base = base; args.p = p; args.c = c; /* Convert string to a double, checking for overflow. */ if (do_float_handler (parse_float, (PTR) &args)) { /* Receive output from parse_float() */ value = args.value; } else { /* We got an exception from parse_float() */ error ("floating constant out of range"); value = dconst0; } /* Receive output from parse_float() */ c = args.c; imag = args.imag; type = args.type; conversion_errno = args.conversion_errno; #ifdef ERANGE /* ERANGE is also reported for underflow, so test the value to distinguish overflow from that. */ if (conversion_errno == ERANGE && pedantic && (REAL_VALUES_LESS (dconst1, value) || REAL_VALUES_LESS (value, dconstm1))) warning ("floating point number exceeds range of `double'"); #endif /* If the result is not a number, assume it must have been due to some error message above, so silently convert it to a zero. */ if (REAL_VALUE_ISNAN (value)) value = dconst0; /* Create a node with determined type and value. */ if (imag) yylval.ttype = build_complex (NULL_TREE, convert (type, integer_zero_node), build_real (type, value)); else yylval.ttype = build_real (type, value); } else { tree type; HOST_WIDE_INT high, low; int spec_unsigned = 0; int spec_long = 0; int spec_long_long = 0; int spec_imag = 0; int warn = 0; int i; while (1) { if (c == 'u' || c == 'U') { if (spec_unsigned) error ("two `u's in integer constant"); spec_unsigned = 1; } else if (c == 'l' || c == 'L') { if (spec_long) { if (spec_long_long) error ("three `l's in integer constant"); else if (pedantic && ! in_system_header && warn_long_long) pedwarn ("ISO C++ forbids long long integer constants"); spec_long_long = 1; } spec_long = 1; } else if (c == 'i' || c == 'j' || c == 'I' || c == 'J') { if (spec_imag) error ("more than one `i' or `j' in numeric constant"); else if (pedantic) pedwarn ("ISO C++ forbids imaginary numeric constants"); spec_imag = 1; } else break; if (p >= token_buffer + maxtoken - 3) p = extend_token_buffer (p); *p++ = c; c = token_getch (); } /* If the literal overflowed, pedwarn about it now. */ if (overflow) { warn = 1; pedwarn ("integer constant is too large for this configuration of the compiler - truncated to %d bits", HOST_BITS_PER_WIDE_INT * 2); } /* This is simplified by the fact that our constant is always positive. */ high = low = 0; for (i = 0; i < HOST_BITS_PER_WIDE_INT / HOST_BITS_PER_CHAR; i++) { high |= ((HOST_WIDE_INT) parts[i + (HOST_BITS_PER_WIDE_INT / HOST_BITS_PER_CHAR)] << (i * HOST_BITS_PER_CHAR)); low |= (HOST_WIDE_INT) parts[i] << (i * HOST_BITS_PER_CHAR); } yylval.ttype = build_int_2 (low, high); TREE_TYPE (yylval.ttype) = long_long_unsigned_type_node; /* Calculate the ANSI type. */ if (! spec_long && ! spec_unsigned && int_fits_type_p (yylval.ttype, integer_type_node)) type = integer_type_node; else if (! spec_long && (base != 10 || spec_unsigned) && int_fits_type_p (yylval.ttype, unsigned_type_node)) type = unsigned_type_node; else if (! spec_unsigned && !spec_long_long && int_fits_type_p (yylval.ttype, long_integer_type_node)) type = long_integer_type_node; else if (! spec_long_long && int_fits_type_p (yylval.ttype, long_unsigned_type_node)) type = long_unsigned_type_node; else if (! spec_unsigned && int_fits_type_p (yylval.ttype, long_long_integer_type_node)) type = long_long_integer_type_node; else if (int_fits_type_p (yylval.ttype, long_long_unsigned_type_node)) type = long_long_unsigned_type_node; else if (! spec_unsigned && int_fits_type_p (yylval.ttype, widest_integer_literal_type_node)) type = widest_integer_literal_type_node; else type = widest_unsigned_literal_type_node; if (pedantic && !spec_long_long && !warn && (TYPE_PRECISION (long_integer_type_node) < TYPE_PRECISION (type))) { warn = 1; pedwarn ("integer constant larger than the maximum value of an unsigned long int"); } if (base == 10 && ! spec_unsigned && TREE_UNSIGNED (type)) warning ("decimal constant is so large that it is unsigned"); if (spec_imag) { if (TYPE_PRECISION (type) <= TYPE_PRECISION (integer_type_node)) yylval.ttype = build_complex (NULL_TREE, integer_zero_node, convert (integer_type_node, yylval.ttype)); else error ("complex integer constant is too wide for `__complex int'"); } else TREE_TYPE (yylval.ttype) = type; /* If it's still an integer (not a complex), and it doesn't fit in the type we choose for it, then pedwarn. */ if (! warn && TREE_CODE (TREE_TYPE (yylval.ttype)) == INTEGER_TYPE && ! int_fits_type_p (yylval.ttype, TREE_TYPE (yylval.ttype))) pedwarn ("integer constant is larger than the maximum value for its type"); } token_put_back (c); *p = 0; if (ISALNUM (c) || c == '.' || c == '_' || c == '$' || ((c == '-' || c == '+') && (p[-1] == 'e' || p[-1] == 'E'))) error ("missing white space after number `%s'", token_buffer); value = CONSTANT; break; } case '\'': char_constant: { register int result = 0; register int num_chars = 0; int chars_seen = 0; unsigned width = TYPE_PRECISION (char_type_node); int max_chars; #ifdef MULTIBYTE_CHARS int longest_char = local_mb_cur_max (); local_mbtowc (NULL_PTR, NULL_PTR, 0); #endif max_chars = TYPE_PRECISION (integer_type_node) / width; if (wide_flag) width = WCHAR_TYPE_SIZE; while (1) { tryagain: c = token_getch (); if (c == '\'' || c == EOF) break; ++chars_seen; if (c == '\\') { int ignore = 0; c = readescape (&ignore); if (ignore) goto tryagain; if (width < HOST_BITS_PER_INT && (unsigned) c >= ((unsigned)1 << width)) pedwarn ("escape sequence out of range for character"); #ifdef MAP_CHARACTER if (ISPRINT (c)) c = MAP_CHARACTER (c); #endif } else if (c == '\n') { if (pedantic) pedwarn ("ISO C++ forbids newline in character constant"); lineno++; } else { #ifdef MULTIBYTE_CHARS wchar_t wc; int i; int char_len = -1; for (i = 1; i <= longest_char; ++i) { if (i > maxtoken - 4) extend_token_buffer (token_buffer); token_buffer[i] = c; char_len = local_mbtowc (& wc, token_buffer + 1, i); if (char_len != -1) break; c = token_getch (); } if (char_len > 1) { /* mbtowc sometimes needs an extra char before accepting */ if (char_len < i) token_put_back (c); if (! wide_flag) { /* Merge character into result; ignore excess chars. */ for (i = 1; i <= char_len; ++i) { if (i > max_chars) break; if (width < HOST_BITS_PER_INT) result = (result << width) | (token_buffer[i] & ((1 << width) - 1)); else result = token_buffer[i]; } num_chars += char_len; goto tryagain; } c = wc; } else { if (char_len == -1) { warning ("Ignoring invalid multibyte character"); /* Replace all but the first byte. */ for (--i; i > 1; --i) token_put_back (token_buffer[i]); wc = token_buffer[1]; } #ifdef MAP_CHARACTER c = MAP_CHARACTER (wc); #else c = wc; #endif } #else /* ! MULTIBYTE_CHARS */ #ifdef MAP_CHARACTER c = MAP_CHARACTER (c); #endif #endif /* ! MULTIBYTE_CHARS */ } if (wide_flag) { if (chars_seen == 1) /* only keep the first one */ result = c; goto tryagain; } /* Merge character into result; ignore excess chars. */ num_chars += (width / TYPE_PRECISION (char_type_node)); if (num_chars < max_chars + 1) { if (width < HOST_BITS_PER_INT) result = (result << width) | (c & ((1 << width) - 1)); else result = c; } } if (c != '\'') error ("malformatted character constant"); else if (chars_seen == 0) error ("empty character constant"); else if (num_chars > max_chars) { num_chars = max_chars; error ("character constant too long"); } else if (chars_seen != 1 && warn_multichar) warning ("multi-character character constant"); /* If char type is signed, sign-extend the constant. */ if (! wide_flag) { int num_bits = num_chars * width; if (num_bits == 0) /* We already got an error; avoid invalid shift. */ yylval.ttype = build_int_2 (0, 0); else if (TREE_UNSIGNED (char_type_node) || ((result >> (num_bits - 1)) & 1) == 0) yylval.ttype = build_int_2 (result & (~(unsigned HOST_WIDE_INT) 0 >> (HOST_BITS_PER_WIDE_INT - num_bits)), 0); else yylval.ttype = build_int_2 (result | ~(~(unsigned HOST_WIDE_INT) 0 >> (HOST_BITS_PER_WIDE_INT - num_bits)), -1); /* In C, a character constant has type 'int'; in C++, 'char'. */ if (chars_seen <= 1) TREE_TYPE (yylval.ttype) = char_type_node; else TREE_TYPE (yylval.ttype) = integer_type_node; } else { yylval.ttype = build_int_2 (result, 0); TREE_TYPE (yylval.ttype) = wchar_type_node; } value = CONSTANT; break; } case '"': string_constant: { unsigned width = wide_flag ? WCHAR_TYPE_SIZE : TYPE_PRECISION (char_type_node); #ifdef MULTIBYTE_CHARS int longest_char = local_mb_cur_max (); local_mbtowc (NULL_PTR, NULL_PTR, 0); #endif c = token_getch (); p = token_buffer + 1; while (c != '"' && c != EOF) { /* ignore_escape_flag is set for reading the filename in #line. */ if (!ignore_escape_flag && c == '\\') { int ignore = 0; c = readescape (&ignore); if (ignore) goto skipnewline; if (width < HOST_BITS_PER_INT && (unsigned) c >= ((unsigned)1 << width)) pedwarn ("escape sequence out of range for character"); } else if (c == '\n') { if (pedantic) pedwarn ("ISO C++ forbids newline in string constant"); lineno++; } else { #ifdef MULTIBYTE_CHARS wchar_t wc; int i; int char_len = -1; for (i = 0; i < longest_char; ++i) { if (p + i >= token_buffer + maxtoken) p = extend_token_buffer (p); p[i] = c; char_len = local_mbtowc (& wc, p, i + 1); if (char_len != -1) break; c = token_getch (); } if (char_len == -1) { warning ("Ignoring invalid multibyte character"); /* Replace all except the first byte. */ token_put_back (c); for (--i; i > 0; --i) token_put_back (p[i]); char_len = 1; } /* mbtowc sometimes needs an extra char before accepting */ if (char_len <= i) token_put_back (c); if (! wide_flag) { p += (i + 1); c = token_getch (); continue; } c = wc; #endif /* MULTIBYTE_CHARS */ } /* Add this single character into the buffer either as a wchar_t or as a single byte. */ if (wide_flag) { unsigned width = TYPE_PRECISION (char_type_node); unsigned bytemask = (1 << width) - 1; int byte; if (p + WCHAR_BYTES > token_buffer + maxtoken) p = extend_token_buffer (p); for (byte = 0; byte < WCHAR_BYTES; ++byte) { int value; if (byte >= (int) sizeof (c)) value = 0; else value = (c >> (byte * width)) & bytemask; if (BYTES_BIG_ENDIAN) p[WCHAR_BYTES - byte - 1] = value; else p[byte] = value; } p += WCHAR_BYTES; } else { if (p >= token_buffer + maxtoken) p = extend_token_buffer (p); *p++ = c; } skipnewline: c = token_getch (); } /* Terminate the string value, either with a single byte zero or with a wide zero. */ if (wide_flag) { if (p + WCHAR_BYTES > token_buffer + maxtoken) p = extend_token_buffer (p); bzero (p, WCHAR_BYTES); p += WCHAR_BYTES; } else { if (p >= token_buffer + maxtoken) p = extend_token_buffer (p); *p++ = 0; } if (c == EOF) error ("Unterminated string constant"); /* We have read the entire constant. Construct a STRING_CST for the result. */ yylval.ttype = build_string (p - (token_buffer + 1), token_buffer + 1); if (wide_flag) TREE_TYPE (yylval.ttype) = wchar_array_type_node; else TREE_TYPE (yylval.ttype) = char_array_type_node; value = STRING; break; } case '+': case '-': case '&': case '|': case ':': case '<': case '>': case '*': case '/': case '%': case '^': case '!': case '=': { register int c1; combine: switch (c) { case '+': yylval.code = PLUS_EXPR; break; case '-': yylval.code = MINUS_EXPR; break; case '&': yylval.code = BIT_AND_EXPR; break; case '|': yylval.code = BIT_IOR_EXPR; break; case '*': yylval.code = MULT_EXPR; break; case '/': yylval.code = TRUNC_DIV_EXPR; break; case '%': yylval.code = TRUNC_MOD_EXPR; break; case '^': yylval.code = BIT_XOR_EXPR; break; case LSHIFT: yylval.code = LSHIFT_EXPR; break; case RSHIFT: yylval.code = RSHIFT_EXPR; break; case '<': yylval.code = LT_EXPR; break; case '>': yylval.code = GT_EXPR; break; } token_buffer[1] = c1 = token_getch (); token_buffer[2] = 0; if (c1 == '=') { switch (c) { case '<': value = ARITHCOMPARE; yylval.code = LE_EXPR; goto done; case '>': value = ARITHCOMPARE; yylval.code = GE_EXPR; goto done; case '!': value = EQCOMPARE; yylval.code = NE_EXPR; goto done; case '=': value = EQCOMPARE; yylval.code = EQ_EXPR; goto done; } value = ASSIGN; goto done; } else if (c == c1) switch (c) { case '+': value = PLUSPLUS; goto done; case '-': value = MINUSMINUS; goto done; case '&': value = ANDAND; goto done; case '|': value = OROR; goto done; case '<': c = LSHIFT; goto combine; case '>': c = RSHIFT; goto combine; case ':': value = SCOPE; yylval.itype = 1; goto done; } else if (c1 == '?' && (c == '<' || c == '>')) { token_buffer[3] = 0; c1 = token_getch (); yylval.code = (c == '<' ? MIN_EXPR : MAX_EXPR); if (c1 == '=') { /* ?= expression. */ token_buffer[2] = c1; value = ASSIGN; } else { value = MIN_MAX; token_put_back (c1); } if (pedantic) pedwarn ("use of `operator %s' is not standard C++", token_buffer); goto done; } else switch (c) { case '-': if (c1 == '>') { c1 = token_getch (); if (c1 == '*') value = POINTSAT_STAR; else { token_put_back (c1); value = POINTSAT; } goto done; } break; /* digraphs */ case ':': if (c1 == '>') { value = ']'; goto done; } break; case '<': if (c1 == '%') { value = '{'; indent_level++; goto done; } if (c1 == ':') { value = '['; goto done; } break; case '%': if (c1 == '>') { value = '}'; indent_level--; goto done; } break; } token_put_back (c1); token_buffer[1] = 0; /* Here the C frontend changes < and > to ARITHCOMPARE. We don't do that because of templates. */ value = c; break; } case 0: /* Don't make yyparse think this is eof. */ value = 1; break; case '{': indent_level++; value = c; break; case '}': indent_level--; value = c; break; default: value = c; } done: /* yylloc.last_line = lineno; */ #ifdef GATHER_STATISTICS #ifdef REDUCE_LENGTH token_count[value] += 1; #endif #endif return value; } int is_rid (t) tree t; { return !!is_reserved_word (IDENTIFIER_POINTER (t), IDENTIFIER_LENGTH (t)); } #ifdef GATHER_STATISTICS /* The original for tree_node_kind is in the toplevel tree.c; changes there need to be brought into here, unless this were actually put into a header instead. */ /* Statistics-gathering stuff. */ typedef enum { d_kind, t_kind, b_kind, s_kind, r_kind, e_kind, c_kind, id_kind, op_id_kind, perm_list_kind, temp_list_kind, vec_kind, x_kind, lang_decl, lang_type, all_kinds } tree_node_kind; extern int tree_node_counts[]; extern int tree_node_sizes[]; #endif tree build_lang_decl (code, name, type) enum tree_code code; tree name; tree type; { tree t; t = build_decl (code, name, type); retrofit_lang_decl (t); return t; } /* Add DECL_LANG_SPECIFIC info to T. Called from build_lang_decl and pushdecl (for functions generated by the backend). */ void retrofit_lang_decl (t) tree t; { struct lang_decl *ld; size_t size; if (CAN_HAVE_FULL_LANG_DECL_P (t)) size = sizeof (struct lang_decl); else size = sizeof (struct lang_decl_flags); ld = (struct lang_decl *) ggc_alloc (size); memset (ld, 0, size); DECL_LANG_SPECIFIC (t) = ld; if (current_lang_name == lang_name_cplusplus) DECL_LANGUAGE (t) = lang_cplusplus; else if (current_lang_name == lang_name_c) DECL_LANGUAGE (t) = lang_c; else if (current_lang_name == lang_name_java) DECL_LANGUAGE (t) = lang_java; else my_friendly_abort (64); if (CAN_HAVE_FULL_LANG_DECL_P (t)) DECL_MAIN_VARIANT (t) = t; #ifdef GATHER_STATISTICS tree_node_counts[(int)lang_decl] += 1; tree_node_sizes[(int)lang_decl] += size; #endif } void copy_lang_decl (node) tree node; { int size; struct lang_decl *ld; if (! DECL_LANG_SPECIFIC (node)) return; if (!CAN_HAVE_FULL_LANG_DECL_P (node)) size = sizeof (struct lang_decl_flags); else size = sizeof (struct lang_decl); ld = (struct lang_decl *) ggc_alloc (size); bcopy ((char *)DECL_LANG_SPECIFIC (node), (char *)ld, size); DECL_LANG_SPECIFIC (node) = ld; } tree cp_make_lang_type (code) enum tree_code code; { register tree t = make_node (code); /* Set up some flags that give proper default behavior. */ if (IS_AGGR_TYPE_CODE (code)) { struct lang_type *pi; pi = (struct lang_type *) ggc_alloc (sizeof (struct lang_type)); bzero ((char *) pi, (int) sizeof (struct lang_type)); TYPE_LANG_SPECIFIC (t) = pi; SET_CLASSTYPE_INTERFACE_UNKNOWN_X (t, interface_unknown); CLASSTYPE_INTERFACE_ONLY (t) = interface_only; /* Make sure this is laid out, for ease of use later. In the presence of parse errors, the normal was of assuring this might not ever get executed, so we lay it out *immediately*. */ build_pointer_type (t); #ifdef GATHER_STATISTICS tree_node_counts[(int)lang_type] += 1; tree_node_sizes[(int)lang_type] += sizeof (struct lang_type); #endif } else /* We use TYPE_ALIAS_SET for the CLASSTYPE_MARKED bits. But, TYPE_ALIAS_SET is initialized to -1 by default, so we must clear it here. */ TYPE_ALIAS_SET (t) = 0; /* We need to allocate a TYPE_BINFO even for TEMPLATE_TYPE_PARMs since they can be virtual base types, and we then need a canonical binfo for them. Ideally, this would be done lazily for all types. */ if (IS_AGGR_TYPE_CODE (code) || code == TEMPLATE_TYPE_PARM) TYPE_BINFO (t) = make_binfo (integer_zero_node, t, NULL_TREE, NULL_TREE); return t; } tree make_aggr_type (code) enum tree_code code; { tree t = cp_make_lang_type (code); if (IS_AGGR_TYPE_CODE (code)) SET_IS_AGGR_TYPE (t, 1); return t; } void dump_time_statistics () { register tree prev = 0, decl, next; int this_time = my_get_run_time (); TREE_INT_CST_LOW (TIME_IDENTIFIER_TIME (this_filename_time)) += this_time - body_time; fprintf (stderr, "\n******\n"); print_time ("header files (total)", header_time); print_time ("main file (total)", this_time - body_time); fprintf (stderr, "ratio = %g : 1\n", (double)header_time / (double)(this_time - body_time)); fprintf (stderr, "\n******\n"); for (decl = filename_times; decl; decl = next) { next = IDENTIFIER_GLOBAL_VALUE (decl); SET_IDENTIFIER_GLOBAL_VALUE (decl, prev); prev = decl; } for (decl = prev; decl; decl = IDENTIFIER_GLOBAL_VALUE (decl)) print_time (IDENTIFIER_POINTER (decl), TREE_INT_CST_LOW (TIME_IDENTIFIER_TIME (decl))); } void compiler_error VPARAMS ((const char *msg, ...)) { #ifndef ANSI_PROTOTYPES const char *msg; #endif char buf[1024]; va_list ap; VA_START (ap, msg); #ifndef ANSI_PROTOTYPES msg = va_arg (ap, const char *); #endif vsprintf (buf, msg, ap); va_end (ap); error_with_file_and_line (input_filename, lineno, "%s (compiler error)", buf); } /* Return the type-qualifier corresponding to the identifier given by RID. */ int cp_type_qual_from_rid (rid) tree rid; { if (rid == ridpointers[(int) RID_CONST]) return TYPE_QUAL_CONST; else if (rid == ridpointers[(int) RID_VOLATILE]) return TYPE_QUAL_VOLATILE; else if (rid == ridpointers[(int) RID_RESTRICT]) return TYPE_QUAL_RESTRICT; my_friendly_abort (0); return TYPE_UNQUALIFIED; }