/* * awk.y --- yacc/bison parser */ /* * Copyright (C) 1986, 1988, 1989, 1991-2001 the Free Software Foundation, Inc. * * This file is part of GAWK, the GNU implementation of the * AWK Programming Language. * * GAWK 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 of the License, or * (at your option) any later version. * * GAWK 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 this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA */ %{ #ifdef GAWKDEBUG #define YYDEBUG 12 #endif #include "awk.h" #define CAN_FREE TRUE #define DONT_FREE FALSE #if defined(HAVE_STDARG_H) && defined(__STDC__) && __STDC__ static void yyerror(const char *m, ...) ; #else static void yyerror(); /* va_alist */ #endif static char *get_src_buf P((void)); static int yylex P((void)); static NODE *node_common P((NODETYPE op)); static NODE *snode P((NODE *subn, NODETYPE op, int sindex)); static NODE *mkrangenode P((NODE *cpair)); static NODE *make_for_loop P((NODE *init, NODE *cond, NODE *incr)); static NODE *append_right P((NODE *list, NODE *new)); static void func_install P((NODE *params, NODE *def)); static void pop_var P((NODE *np, int freeit)); static void pop_params P((NODE *params)); static NODE *make_param P((char *name)); static NODE *mk_rexp P((NODE *exp)); static int dup_parms P((NODE *func)); static void param_sanity P((NODE *arglist)); static void parms_shadow P((const char *fname, NODE *func)); static int isnoeffect P((NODETYPE t)); static int isassignable P((NODE *n)); static void dumpintlstr P((char *str, size_t len)); static void count_args P((NODE *n)); enum defref { FUNC_DEFINE, FUNC_USE }; static void func_use P((char *name, enum defref how)); static void check_funcs P((void)); static int want_assign; /* lexical scanning kludge */ static int want_regexp; /* lexical scanning kludge */ static int can_return; /* lexical scanning kludge */ static int io_allowed = TRUE; /* lexical scanning kludge */ static int parsing_end_rule = FALSE; /* for warnings */ static char *lexptr; /* pointer to next char during parsing */ static char *lexend; static char *lexptr_begin; /* keep track of where we were for error msgs */ static char *lexeme; /* beginning of lexeme for debugging */ static char *thisline = NULL; #define YYDEBUG_LEXER_TEXT (lexeme) static int param_counter; static char *tokstart = NULL; static char *tok = NULL; static char *tokend; static long func_count; /* total number of functions */ #define HASHSIZE 1021 /* this constant only used here */ NODE *variables[HASHSIZE]; static int var_count; /* total number of global variables */ extern char *source; extern int sourceline; extern struct src *srcfiles; extern int numfiles; extern int errcount; extern NODE *begin_block; extern NODE *end_block; %} %union { long lval; AWKNUM fval; NODE *nodeval; NODETYPE nodetypeval; char *sval; NODE *(*ptrval)(); } %type function_prologue function_body %type rexp exp start program rule simp_exp %type non_post_simp_exp %type pattern %type action variable param_list %type rexpression_list opt_rexpression_list %type expression_list opt_expression_list %type statements statement if_statement opt_param_list %type opt_exp opt_variable regexp %type input_redir output_redir %type print %type func_name %type lex_builtin %token FUNC_CALL NAME REGEXP %token ERROR %token YNUMBER YSTRING %token RELOP APPEND_OP %token ASSIGNOP MATCHOP NEWLINE CONCAT_OP %token LEX_BEGIN LEX_END LEX_IF LEX_ELSE LEX_RETURN LEX_DELETE %token LEX_WHILE LEX_DO LEX_FOR LEX_BREAK LEX_CONTINUE %token LEX_PRINT LEX_PRINTF LEX_NEXT LEX_EXIT LEX_FUNCTION %token LEX_GETLINE LEX_NEXTFILE %token LEX_IN %token LEX_AND LEX_OR INCREMENT DECREMENT %token LEX_BUILTIN LEX_LENGTH /* these are just yylval numbers */ /* Lowest to highest */ %right ASSIGNOP %right '?' ':' %left LEX_OR %left LEX_AND %left LEX_GETLINE %nonassoc LEX_IN %left FUNC_CALL LEX_BUILTIN LEX_LENGTH %nonassoc ',' %nonassoc MATCHOP %nonassoc RELOP '<' '>' '|' APPEND_OP TWOWAYIO %left CONCAT_OP %left YSTRING YNUMBER %left '+' '-' %left '*' '/' '%' %right '!' UNARY %right '^' %left INCREMENT DECREMENT %left '$' %left '(' ')' %% start : opt_nls program opt_nls { expression_value = $2; check_funcs(); } ; program : rule { if ($1 != NULL) $$ = $1; else $$ = NULL; yyerrok; } | program rule /* add the rule to the tail of list */ { if ($2 == NULL) $$ = $1; else if ($1 == NULL) $$ = $2; else { if ($1->type != Node_rule_list) $1 = node($1, Node_rule_list, (NODE*) NULL); $$ = append_right($1, node($2, Node_rule_list, (NODE *) NULL)); } yyerrok; } | error { $$ = NULL; } | program error { $$ = NULL; } | /* empty */ { $$ = NULL; } ; rule : LEX_BEGIN { io_allowed = FALSE; } action { if (begin_block != NULL) { if (begin_block->type != Node_rule_list) begin_block = node(begin_block, Node_rule_list, (NODE *) NULL); (void) append_right(begin_block, node( node((NODE *) NULL, Node_rule_node, $3), Node_rule_list, (NODE *) NULL) ); } else begin_block = node((NODE *) NULL, Node_rule_node, $3); $$ = NULL; io_allowed = TRUE; yyerrok; } | LEX_END { io_allowed = FALSE; parsing_end_rule = TRUE; } action { if (end_block != NULL) { if (end_block->type != Node_rule_list) end_block = node(end_block, Node_rule_list, (NODE *) NULL); (void) append_right (end_block, node( node((NODE *) NULL, Node_rule_node, $3), Node_rule_list, (NODE *) NULL)); } else end_block = node((NODE *) NULL, Node_rule_node, $3); $$ = NULL; io_allowed = TRUE; parsing_end_rule = FALSE; yyerrok; } | LEX_BEGIN statement_term { warning(_("BEGIN blocks must have an action part")); errcount++; yyerrok; } | LEX_END statement_term { warning(_("END blocks must have an action part")); errcount++; yyerrok; } | pattern action { $$ = node($1, Node_rule_node, $2); yyerrok; } | action { $$ = node((NODE *) NULL, Node_rule_node, $1); yyerrok; } | pattern statement_term { $$ = node($1, Node_rule_node, node(node(node(make_number(0.0), Node_field_spec, (NODE *) NULL), Node_expression_list, (NODE *) NULL), Node_K_print, (NODE *) NULL)); yyerrok; } | function_prologue function_body { func_install($1, $2); $$ = NULL; yyerrok; } ; func_name : NAME { $$ = $1; } | FUNC_CALL { $$ = $1; } | lex_builtin { yyerror(_("`%s' is a built-in function, it cannot be redefined"), tokstart); errcount++; /* yyerrok; */ } ; lex_builtin : LEX_BUILTIN | LEX_LENGTH ; function_prologue : LEX_FUNCTION { param_counter = 0; } func_name '(' opt_param_list r_paren opt_nls { NODE *t; t = make_param($3); t->flags |= FUNC; $$ = append_right(t, $5); can_return = TRUE; /* check for duplicate parameter names */ if (dup_parms($$)) errcount++; } ; function_body : l_brace statements r_brace opt_semi opt_nls { $$ = $2; can_return = FALSE; } | l_brace r_brace opt_semi opt_nls { $$ = node((NODE *) NULL, Node_K_return, (NODE *) NULL); can_return = FALSE; } ; pattern : exp { $$ = $1; } | exp ',' exp { $$ = mkrangenode(node($1, Node_cond_pair, $3)); } ; regexp /* * In this rule, want_regexp tells yylex that the next thing * is a regexp so it should read up to the closing slash. */ : '/' { ++want_regexp; } REGEXP '/' { NODE *n; size_t len; getnode(n); n->type = Node_regex; len = strlen($3); n->re_exp = make_string($3, len); n->re_reg = make_regexp($3, len, FALSE, TRUE); n->re_text = NULL; n->re_flags = CONST; n->re_cnt = 1; $$ = n; } ; action : l_brace statements r_brace opt_semi opt_nls { $$ = $2; } | l_brace r_brace opt_semi opt_nls { $$ = NULL; } ; statements : statement { $$ = $1; if (do_lint && isnoeffect($$->type)) lintwarn(_("statement may have no effect")); } | statements statement { if ($1 == NULL || $1->type != Node_statement_list) $1 = node($1, Node_statement_list, (NODE *) NULL); $$ = append_right($1, node($2, Node_statement_list, (NODE *) NULL)); yyerrok; } | error { $$ = NULL; } | statements error { $$ = NULL; } ; statement_term : nls | semi opt_nls ; statement : semi opt_nls { $$ = NULL; } | l_brace r_brace { $$ = NULL; } | l_brace statements r_brace { $$ = $2; } | if_statement { $$ = $1; } | LEX_WHILE '(' exp r_paren opt_nls statement { $$ = node($3, Node_K_while, $6); } | LEX_DO opt_nls statement LEX_WHILE '(' exp r_paren opt_nls { $$ = node($6, Node_K_do, $3); } | LEX_FOR '(' NAME LEX_IN NAME r_paren opt_nls statement { /* * Efficiency hack. Recognize the special case of * * for (iggy in foo) * delete foo[iggy] * * and treat it as if it were * * delete foo * * Check that the body is a `delete a[i]' statement, * and that both the loop var and array names match. */ if ($8 != NULL && $8->type == Node_K_delete && $8->rnode != NULL && ($8->rnode->type == Node_var || $8->rnode->type == Node_param_list) && strcmp($3, $8->rnode->var_value->vname) == 0 && strcmp($5, $8->lnode->vname) == 0) { $8->type = Node_K_delete_loop; $$ = $8; } else { $$ = node($8, Node_K_arrayfor, make_for_loop(variable($3, CAN_FREE, Node_var), (NODE *) NULL, variable($5, CAN_FREE, Node_var_array))); } } | LEX_FOR '(' opt_exp semi opt_nls exp semi opt_nls opt_exp r_paren opt_nls statement { $$ = node($12, Node_K_for, (NODE *) make_for_loop($3, $6, $9)); } | LEX_FOR '(' opt_exp semi opt_nls semi opt_nls opt_exp r_paren opt_nls statement { $$ = node($11, Node_K_for, (NODE *) make_for_loop($3, (NODE *) NULL, $8)); } | LEX_BREAK statement_term /* for break, maybe we'll have to remember where to break to */ { $$ = node((NODE *) NULL, Node_K_break, (NODE *) NULL); } | LEX_CONTINUE statement_term /* similarly */ { $$ = node((NODE *) NULL, Node_K_continue, (NODE *) NULL); } | print '(' expression_list r_paren output_redir statement_term { $$ = node($3, $1, $5); if ($$->type == Node_K_printf) count_args($$); } | print opt_rexpression_list output_redir statement_term { if ($1 == Node_K_print && $2 == NULL) { static int warned = FALSE; $2 = node(node(make_number(0.0), Node_field_spec, (NODE *) NULL), Node_expression_list, (NODE *) NULL); if (do_lint && ! io_allowed && ! warned) { warned = TRUE; lintwarn( _("plain `print' in BEGIN or END rule should probably be `print \"\"'")); } } $$ = node($2, $1, $3); if ($$->type == Node_K_printf) count_args($$); } | LEX_NEXT statement_term { NODETYPE type; if (! io_allowed) yyerror(_("`next' used in BEGIN or END action")); type = Node_K_next; $$ = node((NODE *) NULL, type, (NODE *) NULL); } | LEX_NEXTFILE statement_term { if (do_lint) lintwarn(_("`nextfile' is a gawk extension")); if (do_traditional) { /* * can't use yyerror, since may have overshot * the source line */ errcount++; error(_("`nextfile' is a gawk extension")); } if (! io_allowed) { /* same thing */ errcount++; error(_("`nextfile' used in BEGIN or END action")); } $$ = node((NODE *) NULL, Node_K_nextfile, (NODE *) NULL); } | LEX_EXIT opt_exp statement_term { $$ = node($2, Node_K_exit, (NODE *) NULL); } | LEX_RETURN { if (! can_return) yyerror(_("`return' used outside function context")); } opt_exp statement_term { $$ = node($3, Node_K_return, (NODE *) NULL); } | LEX_DELETE NAME '[' expression_list ']' statement_term { $$ = node(variable($2, CAN_FREE, Node_var_array), Node_K_delete, $4); } | LEX_DELETE NAME statement_term { if (do_lint) lintwarn(_("`delete array' is a gawk extension")); if (do_traditional) { /* * can't use yyerror, since may have overshot * the source line */ errcount++; error(_("`delete array' is a gawk extension")); } $$ = node(variable($2, CAN_FREE, Node_var_array), Node_K_delete, (NODE *) NULL); } | exp statement_term { $$ = $1; } ; print : LEX_PRINT { $$ = $1; } | LEX_PRINTF { $$ = $1; } ; if_statement : LEX_IF '(' exp r_paren opt_nls statement { $$ = node($3, Node_K_if, node($6, Node_if_branches, (NODE *) NULL)); } | LEX_IF '(' exp r_paren opt_nls statement LEX_ELSE opt_nls statement { $$ = node($3, Node_K_if, node($6, Node_if_branches, $9)); } ; nls : NEWLINE { want_assign = FALSE; } | nls NEWLINE ; opt_nls : /* empty */ | nls ; input_redir : /* empty */ { $$ = NULL; } | '<' simp_exp { $$ = node($2, Node_redirect_input, (NODE *) NULL); } ; output_redir : /* empty */ { $$ = NULL; } | '>' exp { $$ = node($2, Node_redirect_output, (NODE *) NULL); } | APPEND_OP exp { $$ = node($2, Node_redirect_append, (NODE *) NULL); } | '|' exp { $$ = node($2, Node_redirect_pipe, (NODE *) NULL); } | TWOWAYIO exp { if ($2->type == Node_K_getline && $2->rnode->type == Node_redirect_twoway) yyerror(_("multistage two-way pipelines don't work")); $$ = node($2, Node_redirect_twoway, (NODE *) NULL); } ; opt_param_list : /* empty */ { $$ = NULL; } | param_list { $$ = $1; } ; param_list : NAME { $$ = make_param($1); } | param_list comma NAME { $$ = append_right($1, make_param($3)); yyerrok; } | error { $$ = NULL; } | param_list error { $$ = NULL; } | param_list comma error { $$ = NULL; } ; /* optional expression, as in for loop */ opt_exp : /* empty */ { $$ = NULL; } | exp { $$ = $1; } ; opt_rexpression_list : /* empty */ { $$ = NULL; } | rexpression_list { $$ = $1; } ; rexpression_list : rexp { $$ = node($1, Node_expression_list, (NODE *) NULL); } | rexpression_list comma rexp { $$ = append_right($1, node($3, Node_expression_list, (NODE *) NULL)); yyerrok; } | error { $$ = NULL; } | rexpression_list error { $$ = NULL; } | rexpression_list error rexp { $$ = NULL; } | rexpression_list comma error { $$ = NULL; } ; opt_expression_list : /* empty */ { $$ = NULL; } | expression_list { $$ = $1; } ; expression_list : exp { $$ = node($1, Node_expression_list, (NODE *) NULL); } | expression_list comma exp { $$ = append_right($1, node($3, Node_expression_list, (NODE *) NULL)); yyerrok; } | error { $$ = NULL; } | expression_list error { $$ = NULL; } | expression_list error exp { $$ = NULL; } | expression_list comma error { $$ = NULL; } ; /* Expressions, not including the comma operator. */ exp : variable ASSIGNOP { want_assign = FALSE; } exp { if (do_lint && $4->type == Node_regex) lintwarn(_("regular expression on right of assignment")); $$ = node($1, $2, $4); } | '(' expression_list r_paren LEX_IN NAME { $$ = node(variable($5, CAN_FREE, Node_var_array), Node_in_array, $2); } | exp '|' LEX_GETLINE opt_variable { $$ = node($4, Node_K_getline, node($1, Node_redirect_pipein, (NODE *) NULL)); } | exp TWOWAYIO LEX_GETLINE opt_variable { $$ = node($4, Node_K_getline, node($1, Node_redirect_twoway, (NODE *) NULL)); } | LEX_GETLINE opt_variable input_redir { if (do_lint && ! io_allowed && parsing_end_rule && $3 == NULL) lintwarn(_("non-redirected `getline' undefined inside END action")); $$ = node($2, Node_K_getline, $3); } | exp LEX_AND exp { $$ = node($1, Node_and, $3); } | exp LEX_OR exp { $$ = node($1, Node_or, $3); } | exp MATCHOP exp { if ($1->type == Node_regex) warning(_("regular expression on left of `~' or `!~' operator")); $$ = node($1, $2, mk_rexp($3)); } | regexp { $$ = $1; if (do_lint && tokstart[0] == '*') { /* possible C comment */ int n = strlen(tokstart) - 1; if (tokstart[n] == '*') lintwarn(_("regexp constant `/%s/' looks like a C comment, but is not"), tokstart); } } | '!' regexp %prec UNARY { $$ = node(node(make_number(0.0), Node_field_spec, (NODE *) NULL), Node_nomatch, $2); } | exp LEX_IN NAME { $$ = node(variable($3, CAN_FREE, Node_var_array), Node_in_array, $1); } | exp RELOP exp { if (do_lint && $3->type == Node_regex) lintwarn(_("regular expression on right of comparison")); $$ = node($1, $2, $3); } | exp '<' exp { $$ = node($1, Node_less, $3); } | exp '>' exp { $$ = node($1, Node_greater, $3); } | exp '?' exp ':' exp { $$ = node($1, Node_cond_exp, node($3, Node_if_branches, $5));} | simp_exp { $$ = $1; } | exp simp_exp %prec CONCAT_OP { $$ = node($1, Node_concat, $2); } ; rexp : variable ASSIGNOP { want_assign = FALSE; } rexp { $$ = node($1, $2, $4); } | rexp LEX_AND rexp { $$ = node($1, Node_and, $3); } | rexp LEX_OR rexp { $$ = node($1, Node_or, $3); } | LEX_GETLINE opt_variable input_redir { if (do_lint && ! io_allowed && $3 == NULL) lintwarn(_("non-redirected `getline' undefined inside BEGIN or END action")); $$ = node($2, Node_K_getline, $3); } | regexp { $$ = $1; } | '!' regexp %prec UNARY { $$ = node((NODE *) NULL, Node_nomatch, $2); } | rexp MATCHOP rexp { $$ = node($1, $2, mk_rexp($3)); } | rexp LEX_IN NAME { $$ = node(variable($3, CAN_FREE, Node_var_array), Node_in_array, $1); } | rexp RELOP rexp { $$ = node($1, $2, $3); } | rexp '?' rexp ':' rexp { $$ = node($1, Node_cond_exp, node($3, Node_if_branches, $5));} | simp_exp { $$ = $1; } | rexp simp_exp %prec CONCAT_OP { $$ = node($1, Node_concat, $2); } ; simp_exp : non_post_simp_exp /* Binary operators in order of decreasing precedence. */ | simp_exp '^' simp_exp { $$ = node($1, Node_exp, $3); } | simp_exp '*' simp_exp { $$ = node($1, Node_times, $3); } | simp_exp '/' simp_exp { $$ = node($1, Node_quotient, $3); } | simp_exp '%' simp_exp { $$ = node($1, Node_mod, $3); } | simp_exp '+' simp_exp { $$ = node($1, Node_plus, $3); } | simp_exp '-' simp_exp { $$ = node($1, Node_minus, $3); } | variable INCREMENT { $$ = node($1, Node_postincrement, (NODE *) NULL); } | variable DECREMENT { $$ = node($1, Node_postdecrement, (NODE *) NULL); } ; non_post_simp_exp : '!' simp_exp %prec UNARY { $$ = node($2, Node_not, (NODE *) NULL); } | '(' exp r_paren { $$ = $2; } | LEX_BUILTIN '(' opt_expression_list r_paren { $$ = snode($3, Node_builtin, (int) $1); } | LEX_LENGTH '(' opt_expression_list r_paren { $$ = snode($3, Node_builtin, (int) $1); } | LEX_LENGTH { if (do_lint) lintwarn(_("call of `length' without parentheses is not portable")); $$ = snode((NODE *) NULL, Node_builtin, (int) $1); if (do_posix) warning(_("call of `length' without parentheses is deprecated by POSIX")); } | FUNC_CALL '(' opt_expression_list r_paren { $$ = node($3, Node_func_call, make_string($1, strlen($1))); func_use($1, FUNC_USE); param_sanity($3); free($1); } | variable | INCREMENT variable { $$ = node($2, Node_preincrement, (NODE *) NULL); } | DECREMENT variable { $$ = node($2, Node_predecrement, (NODE *) NULL); } | YNUMBER { $$ = $1; } | YSTRING { $$ = $1; } | '-' simp_exp %prec UNARY { if ($2->type == Node_val) { $2->numbr = -(force_number($2)); $$ = $2; } else $$ = node($2, Node_unary_minus, (NODE *) NULL); } | '+' simp_exp %prec UNARY { /* * was: $$ = $2 * POSIX semantics: force a conversion to numeric type */ $$ = node (make_number(0.0), Node_plus, $2); } ; opt_variable : /* empty */ { $$ = NULL; } | variable { $$ = $1; } ; variable : NAME { $$ = variable($1, CAN_FREE, Node_var); } | NAME '[' expression_list ']' { if ($3 == NULL) { fatal(_("invalid subscript expression")); } else if ($3->rnode == NULL) { $$ = node(variable($1, CAN_FREE, Node_var_array), Node_subscript, $3->lnode); freenode($3); } else $$ = node(variable($1, CAN_FREE, Node_var_array), Node_subscript, $3); } | '$' non_post_simp_exp { $$ = node($2, Node_field_spec, (NODE *) NULL); } ; l_brace : '{' opt_nls ; r_brace : '}' opt_nls { yyerrok; } ; r_paren : ')' { yyerrok; } ; opt_semi : /* empty */ | semi ; semi : ';' { yyerrok; want_assign = FALSE; } ; comma : ',' opt_nls { yyerrok; } ; %% struct token { const char *operator; /* text to match */ NODETYPE value; /* node type */ int class; /* lexical class */ unsigned flags; /* # of args. allowed and compatability */ # define ARGS 0xFF /* 0, 1, 2, 3 args allowed (any combination */ # define A(n) (1<<(n)) # define VERSION_MASK 0xFF00 /* old awk is zero */ # define NOT_OLD 0x0100 /* feature not in old awk */ # define NOT_POSIX 0x0200 /* feature not in POSIX */ # define GAWKX 0x0400 /* gawk extension */ # define RESX 0x0800 /* Bell Labs Research extension */ NODE *(*ptr)(); /* function that implements this keyword */ }; /* Tokentab is sorted ascii ascending order, so it can be binary searched. */ /* Function pointers come from declarations in awk.h. */ static struct token tokentab[] = { {"BEGIN", Node_illegal, LEX_BEGIN, 0, 0}, {"END", Node_illegal, LEX_END, 0, 0}, #ifdef ARRAYDEBUG {"adump", Node_builtin, LEX_BUILTIN, GAWKX|A(1), do_adump}, #endif {"and", Node_builtin, LEX_BUILTIN, GAWKX|A(2), do_and}, {"asort", Node_builtin, LEX_BUILTIN, GAWKX|A(1)|A(2), do_asort}, {"atan2", Node_builtin, LEX_BUILTIN, NOT_OLD|A(2), do_atan2}, {"bindtextdomain", Node_builtin, LEX_BUILTIN, GAWKX|A(1)|A(2), do_bindtextdomain}, {"break", Node_K_break, LEX_BREAK, 0, 0}, {"close", Node_builtin, LEX_BUILTIN, NOT_OLD|A(1)|A(2), do_close}, {"compl", Node_builtin, LEX_BUILTIN, GAWKX|A(1), do_compl}, {"continue", Node_K_continue, LEX_CONTINUE, 0, 0}, {"cos", Node_builtin, LEX_BUILTIN, NOT_OLD|A(1), do_cos}, {"dcgettext", Node_builtin, LEX_BUILTIN, GAWKX|A(1)|A(2)|A(3), do_dcgettext}, {"delete", Node_K_delete, LEX_DELETE, NOT_OLD, 0}, {"do", Node_K_do, LEX_DO, NOT_OLD, 0}, {"else", Node_illegal, LEX_ELSE, 0, 0}, {"exit", Node_K_exit, LEX_EXIT, 0, 0}, {"exp", Node_builtin, LEX_BUILTIN, A(1), do_exp}, {"extension", Node_builtin, LEX_BUILTIN, GAWKX|A(2), do_ext}, {"fflush", Node_builtin, LEX_BUILTIN, RESX|A(0)|A(1), do_fflush}, {"for", Node_K_for, LEX_FOR, 0, 0}, {"func", Node_K_function, LEX_FUNCTION, NOT_POSIX|NOT_OLD, 0}, {"function", Node_K_function, LEX_FUNCTION, NOT_OLD, 0}, {"gensub", Node_builtin, LEX_BUILTIN, GAWKX|A(3)|A(4), do_gensub}, {"getline", Node_K_getline, LEX_GETLINE, NOT_OLD, 0}, {"gsub", Node_builtin, LEX_BUILTIN, NOT_OLD|A(2)|A(3), do_gsub}, {"if", Node_K_if, LEX_IF, 0, 0}, {"in", Node_illegal, LEX_IN, 0, 0}, {"index", Node_builtin, LEX_BUILTIN, A(2), do_index}, {"int", Node_builtin, LEX_BUILTIN, A(1), do_int}, {"length", Node_builtin, LEX_LENGTH, A(0)|A(1), do_length}, {"log", Node_builtin, LEX_BUILTIN, A(1), do_log}, {"lshift", Node_builtin, LEX_BUILTIN, GAWKX|A(2), do_lshift}, {"match", Node_builtin, LEX_BUILTIN, NOT_OLD|A(2)|A(3), do_match}, {"mktime", Node_builtin, LEX_BUILTIN, GAWKX|A(1), do_mktime}, {"next", Node_K_next, LEX_NEXT, 0, 0}, {"nextfile", Node_K_nextfile, LEX_NEXTFILE, GAWKX, 0}, {"or", Node_builtin, LEX_BUILTIN, GAWKX|A(2), do_or}, {"print", Node_K_print, LEX_PRINT, 0, 0}, {"printf", Node_K_printf, LEX_PRINTF, 0, 0}, {"rand", Node_builtin, LEX_BUILTIN, NOT_OLD|A(0), do_rand}, {"return", Node_K_return, LEX_RETURN, NOT_OLD, 0}, {"rshift", Node_builtin, LEX_BUILTIN, GAWKX|A(2), do_rshift}, {"sin", Node_builtin, LEX_BUILTIN, NOT_OLD|A(1), do_sin}, {"split", Node_builtin, LEX_BUILTIN, A(2)|A(3), do_split}, {"sprintf", Node_builtin, LEX_BUILTIN, 0, do_sprintf}, {"sqrt", Node_builtin, LEX_BUILTIN, A(1), do_sqrt}, {"srand", Node_builtin, LEX_BUILTIN, NOT_OLD|A(0)|A(1), do_srand}, #if defined(GAWKDEBUG) || defined(ARRAYDEBUG) /* || ... */ {"stopme", Node_builtin, LEX_BUILTIN, GAWKX|A(0), stopme}, #endif {"strftime", Node_builtin, LEX_BUILTIN, GAWKX|A(0)|A(1)|A(2), do_strftime}, {"strtonum", Node_builtin, LEX_BUILTIN, GAWKX|A(1), do_strtonum}, {"sub", Node_builtin, LEX_BUILTIN, NOT_OLD|A(2)|A(3), do_sub}, {"substr", Node_builtin, LEX_BUILTIN, A(2)|A(3), do_substr}, {"system", Node_builtin, LEX_BUILTIN, NOT_OLD|A(1), do_system}, {"systime", Node_builtin, LEX_BUILTIN, GAWKX|A(0), do_systime}, {"tolower", Node_builtin, LEX_BUILTIN, NOT_OLD|A(1), do_tolower}, {"toupper", Node_builtin, LEX_BUILTIN, NOT_OLD|A(1), do_toupper}, {"while", Node_K_while, LEX_WHILE, 0, 0}, {"xor", Node_builtin, LEX_BUILTIN, GAWKX|A(2), do_xor}, }; /* getfname --- return name of a builtin function (for pretty printing) */ const char * getfname(register NODE *(*fptr)()) { register int i, j; j = sizeof(tokentab) / sizeof(tokentab[0]); /* linear search, no other way to do it */ for (i = 0; i < j; i++) if (tokentab[i].ptr == fptr) return tokentab[i].operator; fatal(_("fptr %x not in tokentab\n"), fptr); return NULL; /* to stop warnings */ } /* yyerror --- print a syntax error message, show where */ /* * Function identifier purposely indented to avoid mangling * by ansi2knr. Sigh. */ static void #if defined(HAVE_STDARG_H) && defined(__STDC__) && __STDC__ yyerror(const char *m, ...) #else /* VARARGS0 */ yyerror(va_alist) va_dcl #endif { va_list args; const char *mesg = NULL; register char *bp, *cp; char *scan; char buf[120]; static char end_of_file_line[] = "(END OF FILE)"; errcount++; /* Find the current line in the input file */ if (lexptr && lexeme) { if (thisline == NULL) { cp = lexeme; if (*cp == '\n') { cp--; mesg = _("unexpected newline"); } for (; cp != lexptr_begin && *cp != '\n'; --cp) continue; if (*cp == '\n') cp++; thisline = cp; } /* NL isn't guaranteed */ bp = lexeme; while (bp < lexend && *bp && *bp != '\n') bp++; } else { thisline = end_of_file_line; bp = thisline + strlen(thisline); } msg("%.*s", (int) (bp - thisline), thisline); bp = buf; cp = buf + sizeof(buf) - 24; /* 24 more than longest msg. input */ if (lexptr != NULL) { scan = thisline; while (bp < cp && scan < lexeme) if (*scan++ == '\t') *bp++ = '\t'; else *bp++ = ' '; *bp++ = '^'; *bp++ = ' '; } #if defined(HAVE_STDARG_H) && defined(__STDC__) && __STDC__ va_start(args, m); if (mesg == NULL) mesg = m; #else va_start(args); if (mesg == NULL) mesg = va_arg(args, char *); #endif strcpy(bp, mesg); err("", buf, args); va_end(args); } /* get_src_buf --- read the next buffer of source program */ static char * get_src_buf() { static int samefile = FALSE; static int nextfile = 0; static char *buf = NULL; static int fd; int n; register char *scan; static int len = 0; static int did_newline = FALSE; int newfile; struct stat sbuf; # define SLOP 128 /* enough space to hold most source lines */ again: newfile = FALSE; if (nextfile > numfiles) return NULL; if (srcfiles[nextfile].stype == CMDLINE) { if (len == 0) { len = strlen(srcfiles[nextfile].val); if (len == 0) { /* * Yet Another Special case: * gawk '' /path/name * Sigh. */ static int warned = FALSE; if (do_lint && ! warned) { warned = TRUE; lintwarn(_("empty program text on command line")); } ++nextfile; goto again; } sourceline = 1; lexptr = lexptr_begin = srcfiles[nextfile].val; lexend = lexptr + len; } else if (! did_newline && *(lexptr-1) != '\n') { /* * The following goop is to ensure that the source * ends with a newline and that the entire current * line is available for error messages. */ int offset; did_newline = TRUE; offset = lexptr - lexeme; for (scan = lexeme; scan > lexptr_begin; scan--) if (*scan == '\n') { scan++; break; } len = lexptr - scan; emalloc(buf, char *, len+1, "get_src_buf"); memcpy(buf, scan, len); thisline = buf; lexptr = buf + len; *lexptr = '\n'; lexeme = lexptr - offset; lexptr_begin = buf; lexend = lexptr + 1; } else { len = 0; lexeme = lexptr = lexptr_begin = NULL; } if (lexptr == NULL && ++nextfile <= numfiles) goto again; return lexptr; } if (! samefile) { source = srcfiles[nextfile].val; if (source == NULL) { if (buf != NULL) { free(buf); buf = NULL; } len = 0; return lexeme = lexptr = lexptr_begin = NULL; } fd = pathopen(source); if (fd <= INVALID_HANDLE) { char *in; /* suppress file name and line no. in error mesg */ in = source; source = NULL; fatal(_("can't open source file `%s' for reading (%s)"), in, strerror(errno)); } len = optimal_bufsize(fd, & sbuf); newfile = TRUE; if (buf != NULL) free(buf); emalloc(buf, char *, len + SLOP, "get_src_buf"); lexptr_begin = buf + SLOP; samefile = TRUE; sourceline = 1; } else { /* * Here, we retain the current source line (up to length SLOP) * in the beginning of the buffer that was overallocated above */ int offset; int linelen; offset = lexptr - lexeme; for (scan = lexeme; scan > lexptr_begin; scan--) if (*scan == '\n') { scan++; break; } linelen = lexptr - scan; if (linelen > SLOP) linelen = SLOP; thisline = buf + SLOP - linelen; memcpy(thisline, scan, linelen); lexeme = buf + SLOP - offset; lexptr_begin = thisline; } n = read(fd, buf + SLOP, len); if (n == -1) fatal(_("can't read sourcefile `%s' (%s)"), source, strerror(errno)); if (n == 0) { if (newfile) { static int warned = FALSE; if (do_lint && ! warned) { warned = TRUE; lintwarn(_("source file `%s' is empty"), source); } } if (fd != fileno(stdin)) /* safety */ close(fd); samefile = FALSE; nextfile++; if (lexeme) *lexeme = '\0'; len = 0; goto again; } lexptr = buf + SLOP; lexend = lexptr + n; return buf; } /* tokadd --- add a character to the token buffer */ #define tokadd(x) (*tok++ = (x), tok == tokend ? tokexpand() : tok) /* tokexpand --- grow the token buffer */ char * tokexpand() { static int toksize = 60; int tokoffset; tokoffset = tok - tokstart; toksize *= 2; if (tokstart != NULL) erealloc(tokstart, char *, toksize, "tokexpand"); else emalloc(tokstart, char *, toksize, "tokexpand"); tokend = tokstart + toksize; tok = tokstart + tokoffset; return tok; } /* nextc --- get the next input character */ #if GAWKDEBUG int nextc() { int c; if (lexptr && lexptr < lexend) c = (int) (unsigned char) *lexptr++; else if (get_src_buf()) c = (int) (unsigned char) *lexptr++; else c = EOF; return c; } #else #define nextc() ((lexptr && lexptr < lexend) ? \ ((int) (unsigned char) *lexptr++) : \ (get_src_buf() ? ((int) (unsigned char) *lexptr++) : EOF) \ ) #endif /* pushback --- push a character back on the input */ #define pushback() (lexptr && lexptr > lexptr_begin ? lexptr-- : lexptr) /* allow_newline --- allow newline after &&, ||, ? and : */ static void allow_newline() { int c; for (;;) { c = nextc(); if (c == EOF) break; if (c == '#') { while ((c = nextc()) != '\n' && c != EOF) continue; if (c == EOF) break; } if (c == '\n') sourceline++; if (! ISSPACE(c)) { pushback(); break; } } } /* yylex --- Read the input and turn it into tokens. */ static int yylex() { register int c; int seen_e = FALSE; /* These are for numbers */ int seen_point = FALSE; int esc_seen; /* for literal strings */ int low, mid, high; static int did_newline = FALSE; char *tokkey; static int lasttok = 0, eof_warned = FALSE; int inhex = FALSE; int intlstr = FALSE; if (nextc() == EOF) { if (lasttok != NEWLINE) { lasttok = NEWLINE; if (do_lint && ! eof_warned) { lintwarn(_("source file does not end in newline")); eof_warned = TRUE; } return NEWLINE; /* fake it */ } return 0; } pushback(); #ifdef OS2 /* * added for OS/2's extproc feature of cmd.exe * (like #! in BSD sh) */ if (strncasecmp(lexptr, "extproc ", 8) == 0) { while (*lexptr && *lexptr != '\n') lexptr++; } #endif lexeme = lexptr; thisline = NULL; if (want_regexp) { int in_brack = 0; /* count brackets, [[:alnum:]] allowed */ /* * Counting brackets is non-trivial. [[] is ok, * and so is [\]], with a point being that /[/]/ as a regexp * constant has to work. * * Do not count [ or ] if either one is preceded by a \. * A `[' should be counted if * a) it is the first one so far (in_brack == 0) * b) it is the `[' in `[:' * A ']' should be counted if not preceded by a \, since * it is either closing `:]' or just a plain list. * According to POSIX, []] is how you put a ] into a set. * Try to handle that too. * * The code for \ handles \[ and \]. */ want_regexp = FALSE; tok = tokstart; for (;;) { c = nextc(); switch (c) { case '[': /* one day check for `.' and `=' too */ if (nextc() == ':' || in_brack == 0) in_brack++; pushback(); break; case ']': if (tokstart[0] == '[' && (tok == tokstart + 1 || (tok == tokstart + 2 && tokstart[1] == '^'))) /* do nothing */; else in_brack--; break; case '\\': if ((c = nextc()) == EOF) { yyerror(_("unterminated regexp ends with `\\' at end of file")); return lasttok = REGEXP; /* kludge */ } else if (c == '\n') { sourceline++; continue; } else { tokadd('\\'); tokadd(c); continue; } break; case '/': /* end of the regexp */ if (in_brack > 0) break; pushback(); tokadd('\0'); yylval.sval = tokstart; return lasttok = REGEXP; case '\n': pushback(); yyerror(_("unterminated regexp")); return lasttok = REGEXP; /* kludge */ case EOF: yyerror(_("unterminated regexp at end of file")); return lasttok = REGEXP; /* kludge */ } tokadd(c); } } retry: while ((c = nextc()) == ' ' || c == '\t') continue; lexeme = lexptr ? lexptr - 1 : lexptr; thisline = NULL; tok = tokstart; yylval.nodetypeval = Node_illegal; switch (c) { case EOF: if (lasttok != NEWLINE) { lasttok = NEWLINE; if (do_lint && ! eof_warned) { lintwarn(_("source file does not end in newline")); eof_warned = TRUE; } return NEWLINE; /* fake it */ } return 0; case '\n': sourceline++; return lasttok = NEWLINE; case '#': /* it's a comment */ while ((c = nextc()) != '\n') { if (c == EOF) { if (lasttok != NEWLINE) { lasttok = NEWLINE; if (do_lint && ! eof_warned) { lintwarn( _("source file does not end in newline")); eof_warned = TRUE; } return NEWLINE; /* fake it */ } return 0; } } sourceline++; return lasttok = NEWLINE; case '\\': #ifdef RELAXED_CONTINUATION /* * This code puports to allow comments and/or whitespace * after the `\' at the end of a line used for continuation. * Use it at your own risk. We think it's a bad idea, which * is why it's not on by default. */ if (! do_traditional) { /* strip trailing white-space and/or comment */ while ((c = nextc()) == ' ' || c == '\t') continue; if (c == '#') { if (do_lint) lintwarn( _("use of `\\ #...' line continuation is not portable")); while ((c = nextc()) != '\n') if (c == EOF) break; } pushback(); } #endif /* RELAXED_CONTINUATION */ if (nextc() == '\n') { sourceline++; goto retry; } else { yyerror(_("backslash not last character on line")); exit(1); } break; case '$': want_assign = TRUE; return lasttok = '$'; case ':': case '?': if (! do_posix) allow_newline(); return lasttok = c; case ')': case '(': case ';': case '{': case ',': want_assign = FALSE; /* fall through */ case '[': case ']': return lasttok = c; case '*': if ((c = nextc()) == '=') { yylval.nodetypeval = Node_assign_times; return lasttok = ASSIGNOP; } else if (do_posix) { pushback(); return lasttok = '*'; } else if (c == '*') { /* make ** and **= aliases for ^ and ^= */ static int did_warn_op = FALSE, did_warn_assgn = FALSE; if (nextc() == '=') { if (! did_warn_assgn) { did_warn_assgn = TRUE; if (do_lint) lintwarn(_("POSIX does not allow operator `**='")); if (do_lint_old) warning(_("old awk does not support operator `**='")); } yylval.nodetypeval = Node_assign_exp; return ASSIGNOP; } else { pushback(); if (! did_warn_op) { did_warn_op = TRUE; if (do_lint) lintwarn(_("POSIX does not allow operator `**'")); if (do_lint_old) warning(_("old awk does not support operator `**'")); } return lasttok = '^'; } } pushback(); return lasttok = '*'; case '/': if (want_assign) { if (nextc() == '=') { yylval.nodetypeval = Node_assign_quotient; return lasttok = ASSIGNOP; } pushback(); } return lasttok = '/'; case '%': if (nextc() == '=') { yylval.nodetypeval = Node_assign_mod; return lasttok = ASSIGNOP; } pushback(); return lasttok = '%'; case '^': { static int did_warn_op = FALSE, did_warn_assgn = FALSE; if (nextc() == '=') { if (do_lint_old && ! did_warn_assgn) { did_warn_assgn = TRUE; warning(_("operator `^=' is not supported in old awk")); } yylval.nodetypeval = Node_assign_exp; return lasttok = ASSIGNOP; } pushback(); if (do_lint_old && ! did_warn_op) { did_warn_op = TRUE; warning(_("operator `^' is not supported in old awk")); } return lasttok = '^'; } case '+': if ((c = nextc()) == '=') { yylval.nodetypeval = Node_assign_plus; return lasttok = ASSIGNOP; } if (c == '+') return lasttok = INCREMENT; pushback(); return lasttok = '+'; case '!': if ((c = nextc()) == '=') { yylval.nodetypeval = Node_notequal; return lasttok = RELOP; } if (c == '~') { yylval.nodetypeval = Node_nomatch; want_assign = FALSE; return lasttok = MATCHOP; } pushback(); return lasttok = '!'; case '<': if (nextc() == '=') { yylval.nodetypeval = Node_leq; return lasttok = RELOP; } yylval.nodetypeval = Node_less; pushback(); return lasttok = '<'; case '=': if (nextc() == '=') { yylval.nodetypeval = Node_equal; return lasttok = RELOP; } yylval.nodetypeval = Node_assign; pushback(); return lasttok = ASSIGNOP; case '>': if ((c = nextc()) == '=') { yylval.nodetypeval = Node_geq; return lasttok = RELOP; } else if (c == '>') { yylval.nodetypeval = Node_redirect_append; return lasttok = APPEND_OP; } yylval.nodetypeval = Node_greater; pushback(); return lasttok = '>'; case '~': yylval.nodetypeval = Node_match; want_assign = FALSE; return lasttok = MATCHOP; case '}': /* * Added did newline stuff. Easier than * hacking the grammar. */ if (did_newline) { did_newline = FALSE; return lasttok = c; } did_newline++; --lexptr; /* pick up } next time */ return lasttok = NEWLINE; case '"': string: esc_seen = FALSE; while ((c = nextc()) != '"') { if (c == '\n') { pushback(); yyerror(_("unterminated string")); exit(1); } if (c == '\\') { c = nextc(); if (c == '\n') { sourceline++; continue; } esc_seen = TRUE; tokadd('\\'); } if (c == EOF) { pushback(); yyerror(_("unterminated string")); exit(1); } tokadd(c); } yylval.nodeval = make_str_node(tokstart, tok - tokstart, esc_seen ? SCAN : 0); yylval.nodeval->flags |= PERM; if (intlstr) { yylval.nodeval->flags |= INTLSTR; intlstr = FALSE; if (do_intl) dumpintlstr(yylval.nodeval->stptr, yylval.nodeval->stlen); } return lasttok = YSTRING; case '-': if ((c = nextc()) == '=') { yylval.nodetypeval = Node_assign_minus; return lasttok = ASSIGNOP; } if (c == '-') return lasttok = DECREMENT; pushback(); return lasttok = '-'; case '.': c = nextc(); pushback(); if (! ISDIGIT(c)) return lasttok = '.'; else c = '.'; /* FALL THROUGH */ case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': /* It's a number */ for (;;) { int gotnumber = FALSE; tokadd(c); switch (c) { case 'x': case 'X': if (do_traditional) goto done; if (tok == tokstart + 2) inhex = TRUE; break; case '.': if (seen_point) { gotnumber = TRUE; break; } seen_point = TRUE; break; case 'e': case 'E': if (inhex) break; if (seen_e) { gotnumber = TRUE; break; } seen_e = TRUE; if ((c = nextc()) == '-' || c == '+') tokadd(c); else pushback(); break; case 'a': case 'A': case 'b': case 'B': case 'c': case 'C': case 'D': case 'd': case 'f': case 'F': if (do_traditional || ! inhex) goto done; /* fall through */ case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': break; default: done: gotnumber = TRUE; } if (gotnumber) break; c = nextc(); } if (c != EOF) pushback(); else if (do_lint && ! eof_warned) { lintwarn(_("source file does not end in newline")); eof_warned = TRUE; } tokadd('\0'); if (! do_traditional && isnondecimal(tokstart)) yylval.nodeval = make_number(nondec2awknum(tokstart, strlen(tokstart))); else yylval.nodeval = make_number(atof(tokstart)); yylval.nodeval->flags |= PERM; return lasttok = YNUMBER; case '&': if ((c = nextc()) == '&') { yylval.nodetypeval = Node_and; allow_newline(); want_assign = FALSE; return lasttok = LEX_AND; } pushback(); return lasttok = '&'; case '|': if ((c = nextc()) == '|') { yylval.nodetypeval = Node_or; allow_newline(); want_assign = FALSE; return lasttok = LEX_OR; } else if (! do_traditional && c == '&') { yylval.nodetypeval = Node_redirect_twoway; want_assign = FALSE; return lasttok = TWOWAYIO; } pushback(); return lasttok = '|'; } if (c != '_' && ! ISALPHA(c)) { yyerror(_("invalid char '%c' in expression"), c); exit(1); } if (! do_traditional && c == '_') { if ((c = nextc()) == '"') { intlstr = TRUE; goto string; } pushback(); c = '_'; } /* it's some type of name-type-thing. Find its length. */ tok = tokstart; while (is_identchar(c)) { tokadd(c); c = nextc(); } tokadd('\0'); emalloc(tokkey, char *, tok - tokstart, "yylex"); memcpy(tokkey, tokstart, tok - tokstart); if (c != EOF) pushback(); else if (do_lint && ! eof_warned) { lintwarn(_("source file does not end in newline")); eof_warned = TRUE; } /* See if it is a special token. */ low = 0; high = (sizeof(tokentab) / sizeof(tokentab[0])) - 1; while (low <= high) { int i; mid = (low + high) / 2; c = *tokstart - tokentab[mid].operator[0]; i = c ? c : strcmp(tokstart, tokentab[mid].operator); if (i < 0) /* token < mid */ high = mid - 1; else if (i > 0) /* token > mid */ low = mid + 1; else { if (do_lint) { if (tokentab[mid].flags & GAWKX) lintwarn(_("`%s' is a gawk extension"), tokentab[mid].operator); if (tokentab[mid].flags & RESX) lintwarn(_("`%s' is a Bell Labs extension"), tokentab[mid].operator); if (tokentab[mid].flags & NOT_POSIX) lintwarn(_("POSIX does not allow `%s'"), tokentab[mid].operator); } if (do_lint_old && (tokentab[mid].flags & NOT_OLD)) warning(_("`%s' is not supported in old awk"), tokentab[mid].operator); if ((do_traditional && (tokentab[mid].flags & GAWKX)) || (do_posix && (tokentab[mid].flags & NOT_POSIX))) break; if (tokentab[mid].class == LEX_BUILTIN || tokentab[mid].class == LEX_LENGTH ) yylval.lval = mid; else yylval.nodetypeval = tokentab[mid].value; free(tokkey); return lasttok = tokentab[mid].class; } } yylval.sval = tokkey; if (*lexptr == '(') return lasttok = FUNC_CALL; else { static short goto_warned = FALSE; want_assign = TRUE; #define SMART_ALECK 1 if (SMART_ALECK && do_lint && ! goto_warned && strcasecmp(tokkey, "goto") == 0) { goto_warned = TRUE; lintwarn(_("`goto' considered harmful!\n")); } return lasttok = NAME; } } /* node_common --- common code for allocating a new node */ static NODE * node_common(NODETYPE op) { register NODE *r; getnode(r); r->type = op; r->flags = MALLOC; if (r->type == Node_var) r->flags |= UNINITIALIZED; /* if lookahead is NL, lineno is 1 too high */ if (lexeme && *lexeme == '\n') r->source_line = sourceline - 1; else r->source_line = sourceline; r->source_file = source; return r; } /* node --- allocates a node with defined lnode and rnode. */ NODE * node(NODE *left, NODETYPE op, NODE *right) { register NODE *r; r = node_common(op); r->lnode = left; r->rnode = right; return r; } /* snode --- allocate a node with defined subnode and proc for builtin functions. Checks for arg. count and supplies defaults where possible. */ static NODE * snode(NODE *subn, NODETYPE op, int idx) { register NODE *r; register NODE *n; int nexp = 0; int args_allowed; r = node_common(op); /* traverse expression list to see how many args. given */ for (n = subn; n != NULL; n = n->rnode) { nexp++; if (nexp > 3) break; } /* check against how many args. are allowed for this builtin */ args_allowed = tokentab[idx].flags & ARGS; if (args_allowed && (args_allowed & A(nexp)) == 0) fatal(_("%d is invalid as number of arguments for %s"), nexp, tokentab[idx].operator); r->proc = tokentab[idx].ptr; /* special case processing for a few builtins */ if (nexp == 0 && r->proc == do_length) { subn = node(node(make_number(0.0), Node_field_spec, (NODE *) NULL), Node_expression_list, (NODE *) NULL); } else if (r->proc == do_match) { static short warned = FALSE; if (subn->rnode->lnode->type != Node_regex) subn->rnode->lnode = mk_rexp(subn->rnode->lnode); if (subn->rnode->rnode != NULL) { /* 3rd argument there */ if (do_lint && ! warned) { warned = TRUE; lintwarn(_("match: third argument is a gawk extension")); } if (do_traditional) fatal(_("match: third argument is a gawk extension")); } } else if (r->proc == do_sub || r->proc == do_gsub) { if (subn->lnode->type != Node_regex) subn->lnode = mk_rexp(subn->lnode); if (nexp == 2) append_right(subn, node(node(make_number(0.0), Node_field_spec, (NODE *) NULL), Node_expression_list, (NODE *) NULL)); else if (subn->rnode->rnode->lnode->type == Node_val) { if (do_lint) { char *f; f = (r->proc == do_sub) ? "sub" : "gsub"; lintwarn(_("%s: string literal as last arg of substitute has no effect"), f); } } else if (! isassignable(subn->rnode->rnode->lnode)) { if (r->proc == do_sub) yyerror(_("sub third parameter is not a changeable object")); else yyerror(_("gsub third parameter is not a changeable object")); } } else if (r->proc == do_gensub) { if (subn->lnode->type != Node_regex) subn->lnode = mk_rexp(subn->lnode); if (nexp == 3) append_right(subn, node(node(make_number(0.0), Node_field_spec, (NODE *) NULL), Node_expression_list, (NODE *) NULL)); } else if (r->proc == do_split) { if (nexp == 2) append_right(subn, node(FS_node, Node_expression_list, (NODE *) NULL)); n = subn->rnode->rnode->lnode; if (n->type != Node_regex) subn->rnode->rnode->lnode = mk_rexp(n); if (nexp == 2) subn->rnode->rnode->lnode->re_flags |= FS_DFLT; } else if (r->proc == do_close) { static short warned = FALSE; if ( nexp == 2) { if (do_lint && nexp == 2 && ! warned) { warned = TRUE; lintwarn(_("close: second argument is a gawk extension")); } if (do_traditional) fatal(_("close: second argument is a gawk extension")); } } else if (do_intl /* --gen-po */ && r->proc == do_dcgettext /* dcgettext(...) */ && subn->lnode->type == Node_val /* 1st arg is constant */ && (subn->lnode->flags & STR) != 0) { /* it's a string constant */ /* ala xgettext, dcgettext("some string" ...) dumps the string */ NODE *str = subn->lnode; if ((str->flags & INTLSTR) != 0) warning(_("use of dcgettext(_\"...\") is incorrect: remove leading underscore")); /* don't dump it, the lexer already did */ else dumpintlstr(str->stptr, str->stlen); } r->subnode = subn; if (r->proc == do_sprintf) { count_args(r); r->lnode->printf_count = r->printf_count; /* hack */ } return r; } /* * mkrangenode: * This allocates a Node_line_range node with defined condpair and * zeroes the trigger word to avoid the temptation of assuming that calling * 'node( foo, Node_line_range, 0)' will properly initialize 'triggered'. * Otherwise like node(). */ static NODE * mkrangenode(NODE *cpair) { register NODE *r; getnode(r); r->type = Node_line_range; r->condpair = cpair; r->triggered = FALSE; return r; } /* make_for_loop --- build a for loop */ static NODE * make_for_loop(NODE *init, NODE *cond, NODE *incr) { register FOR_LOOP_HEADER *r; NODE *n; emalloc(r, FOR_LOOP_HEADER *, sizeof(FOR_LOOP_HEADER), "make_for_loop"); getnode(n); n->type = Node_illegal; r->init = init; r->cond = cond; r->incr = incr; n->sub.nodep.r.hd = r; return n; } /* dup_parms --- return TRUE if there are duplicate parameters */ static int dup_parms(NODE *func) { register NODE *np; char *fname, **names; int count, i, j, dups; NODE *params; if (func == NULL) /* error earlier */ return TRUE; fname = func->param; count = func->param_cnt; params = func->rnode; if (count == 0) /* no args, no problem */ return FALSE; if (params == NULL) /* error earlier */ return TRUE; emalloc(names, char **, count * sizeof(char *), "dup_parms"); i = 0; for (np = params; np != NULL; np = np->rnode) { if (np->param == NULL) { /* error earlier, give up, go home */ free(names); return TRUE; } names[i++] = np->param; } dups = 0; for (i = 1; i < count; i++) { for (j = 0; j < i; j++) { if (strcmp(names[i], names[j]) == 0) { dups++; error( _("function `%s': parameter #%d, `%s', duplicates parameter #%d"), fname, i+1, names[j], j+1); } } } free(names); return (dups > 0 ? TRUE : FALSE); } /* parms_shadow --- check if parameters shadow globals */ static void parms_shadow(const char *fname, NODE *func) { int count, i; if (fname == NULL || func == NULL) /* error earlier */ return; count = func->lnode->param_cnt; if (count == 0) /* no args, no problem */ return; /* * Use warning() and not lintwarn() so that can warn * about all shadowed parameters. */ for (i = 0; i < count; i++) { if (lookup(func->parmlist[i]) != NULL) { warning( _("function `%s': parameter `%s' shadows global variable"), fname, func->parmlist[i]); } } } /* * install: * Install a name in the symbol table, even if it is already there. * Caller must check against redefinition if that is desired. */ NODE * install(char *name, NODE *value) { register NODE *hp; register size_t len; register int bucket; var_count++; len = strlen(name); bucket = hash(name, len, (unsigned long) HASHSIZE); getnode(hp); hp->type = Node_hashnode; hp->hnext = variables[bucket]; variables[bucket] = hp; hp->hlength = len; hp->hvalue = value; hp->hname = name; hp->hvalue->vname = name; return hp->hvalue; } /* lookup --- find the most recent hash node for name installed by install */ NODE * lookup(const char *name) { register NODE *bucket; register size_t len; len = strlen(name); for (bucket = variables[hash(name, len, (unsigned long) HASHSIZE)]; bucket != NULL; bucket = bucket->hnext) if (bucket->hlength == len && STREQN(bucket->hname, name, len)) return bucket->hvalue; return NULL; } /* var_comp --- compare two variable names */ static int var_comp(const void *v1, const void *v2) { NODE **npp1, **npp2; NODE *n1, *n2; int minlen; npp1 = (NODE **) v1; npp2 = (NODE **) v2; n1 = *npp1; n2 = *npp2; if (n1->hlength > n2->hlength) minlen = n1->hlength; else minlen = n2->hlength; return strncmp(n1->hname, n2->hname, minlen); } /* valinfo --- dump var info */ static void valinfo(NODE *n, FILE *fp) { if (n->flags & STRING) { fprintf(fp, "string ("); pp_string_fp(fp, n->stptr, n->stlen, '"', FALSE); fprintf(fp, ")\n"); } else if (n->flags & NUMBER) fprintf(fp, "number (%.17g)\n", n->numbr); else if (n->flags & STR) { fprintf(fp, "string value ("); pp_string_fp(fp, n->stptr, n->stlen, '"', FALSE); fprintf(fp, ")\n"); } else if (n->flags & NUM) fprintf(fp, "number value (%.17g)\n", n->numbr); else fprintf(fp, "?? flags %s\n", flags2str(n->flags)); } /* dump_vars --- dump the symbol table */ void dump_vars(const char *fname) { int i, j; NODE **table; NODE *p; FILE *fp; emalloc(table, NODE **, var_count * sizeof(NODE *), "dump_vars"); if (fname == NULL) fp = stderr; else if ((fp = fopen(fname, "w")) == NULL) { warning(_("could not open `%s' for writing (%s)"), fname, strerror(errno)); warning(_("sending profile to standard error")); fp = stderr; } for (i = j = 0; i < HASHSIZE; i++) for (p = variables[i]; p != NULL; p = p->hnext) table[j++] = p; assert(j == var_count); /* Shazzam! */ qsort(table, j, sizeof(NODE *), var_comp); for (i = 0; i < j; i++) { p = table[i]; if (p->hvalue->type == Node_func) continue; fprintf(fp, "%.*s: ", (int) p->hlength, p->hname); if (p->hvalue->type == Node_var_array) fprintf(fp, "array, %ld elements\n", p->hvalue->table_size); else if (p->hvalue->type == Node_var) valinfo(p->hvalue->var_value, fp); else { NODE **lhs = get_lhs(p->hvalue, NULL, FALSE); valinfo(*lhs, fp); } } if (fp != stderr && fclose(fp) != 0) warning(_("%s: close failed (%s)"), fname, strerror(errno)); free(table); } /* release_all_vars --- free all variable memory */ void release_all_vars() { int i; NODE *p, *next; for (i = 0; i < HASHSIZE; i++) for (p = variables[i]; p != NULL; p = next) { next = p->hnext; if (p->hvalue->type == Node_func) continue; else if (p->hvalue->type == Node_var_array) assoc_clear(p->hvalue); else if (p->hvalue->type == Node_var) unref(p->hvalue->var_value); else { NODE **lhs = get_lhs(p->hvalue, NULL, FALSE); unref((*lhs)->var_value); } unref(p); } } /* finfo --- for use in comparison and sorting of function names */ struct finfo { char *name; size_t nlen; NODE *func; }; /* fcompare --- comparison function for qsort */ static int fcompare(const void *p1, const void *p2) { struct finfo *f1, *f2; int minlen; f1 = (struct finfo *) p1; f2 = (struct finfo *) p2; if (f1->nlen > f2->nlen) minlen = f2->nlen; else minlen = f1->nlen; return strncmp(f1->name, f2->name, minlen); } /* dump_funcs --- print all functions */ void dump_funcs() { int i, j; NODE *p; static struct finfo *tab = NULL; if (func_count == 0) return; if (tab == NULL) emalloc(tab, struct finfo *, func_count * sizeof(struct finfo), "dump_funcs"); for (i = j = 0; i < HASHSIZE; i++) { for (p = variables[i]; p != NULL; p = p->hnext) { if (p->hvalue->type == Node_func) { tab[j].name = p->hname; tab[j].nlen = p->hlength; tab[j].func = p->hvalue; j++; } } } assert(j == func_count); /* Shazzam! */ qsort(tab, func_count, sizeof(struct finfo), fcompare); for (i = 0; i < j; i++) pp_func(tab[i].name, tab[i].nlen, tab[i].func); free(tab); } /* shadow_funcs --- check all functions for parameters that shadow globals */ void shadow_funcs() { int i, j; NODE *p; struct finfo *tab; static int calls = 0; if (func_count == 0) return; if (calls++ != 0) fatal(_("shadow_funcs() called twice!")); emalloc(tab, struct finfo *, func_count * sizeof(struct finfo), "shadow_funcs"); for (i = j = 0; i < HASHSIZE; i++) { for (p = variables[i]; p != NULL; p = p->hnext) { if (p->hvalue->type == Node_func) { tab[j].name = p->hname; tab[j].nlen = p->hlength; tab[j].func = p->hvalue; j++; } } } assert(j == func_count); /* Shazzam! */ qsort(tab, func_count, sizeof(struct finfo), fcompare); for (i = 0; i < j; i++) parms_shadow(tab[i].name, tab[i].func); free(tab); } /* * append_right: * Add new to the rightmost branch of LIST. This uses n^2 time, so we make * a simple attempt at optimizing it. */ static NODE * append_right(NODE *list, NODE *new) { register NODE *oldlist; static NODE *savefront = NULL, *savetail = NULL; if (list == NULL || new == NULL) return list; oldlist = list; if (savefront == oldlist) { savetail = savetail->rnode = new; return oldlist; } else savefront = oldlist; while (list->rnode != NULL) list = list->rnode; savetail = list->rnode = new; return oldlist; } /* * func_install: * check if name is already installed; if so, it had better have Null value, * in which case def is added as the value. Otherwise, install name with def * as value. * * Extra work, build up and save a list of the parameter names in a table * and hang it off params->parmlist. This is used to set the `vname' field * of each function parameter during a function call. See eval.c. */ static void func_install(NODE *params, NODE *def) { NODE *r, *n, *thisfunc; char **pnames, *names, *sp; size_t pcount = 0, space = 0; int i; /* check for function foo(foo) { ... }. bleah. */ for (n = params->rnode; n != NULL; n = n->rnode) { if (strcmp(n->param, params->param) == 0) fatal(_("function `%s': can't use function name as parameter name"), params->param); } thisfunc = NULL; /* turn off warnings */ /* symbol table managment */ pop_var(params, FALSE); r = lookup(params->param); if (r != NULL) { fatal(_("function name `%s' previously defined"), params->param); } else { thisfunc = node(params, Node_func, def); (void) install(params->param, thisfunc); } /* figure out amount of space to allocate */ for (n = params->rnode; n != NULL; n = n->rnode) { pcount++; space += strlen(n->param) + 1; } /* allocate it and fill it in */ if (pcount != 0) { emalloc(names, char *, space, "func_install"); emalloc(pnames, char **, pcount * sizeof(char *), "func_install"); sp = names; for (i = 0, n = params->rnode; i < pcount; i++, n = n->rnode) { pnames[i] = sp; strcpy(sp, n->param); sp += strlen(n->param) + 1; } thisfunc->parmlist = pnames; } else { thisfunc->parmlist = NULL; } /* remove params from symbol table */ pop_params(params->rnode); /* update lint table info */ func_use(params->param, FUNC_DEFINE); func_count++; /* used by profiling / pretty printer */ } /* pop_var --- remove a variable from the symbol table */ static void pop_var(NODE *np, int freeit) { register NODE *bucket, **save; register size_t len; char *name; name = np->param; len = strlen(name); save = &(variables[hash(name, len, (unsigned long) HASHSIZE)]); for (bucket = *save; bucket != NULL; bucket = bucket->hnext) { if (len == bucket->hlength && STREQN(bucket->hname, name, len)) { var_count--; *save = bucket->hnext; freenode(bucket); if (freeit) free(np->param); return; } save = &(bucket->hnext); } } /* pop_params --- remove list of function parameters from symbol table */ /* * pop parameters out of the symbol table. do this in reverse order to * avoid reading freed memory if there were duplicated parameters. */ static void pop_params(NODE *params) { if (params == NULL) return; pop_params(params->rnode); pop_var(params, TRUE); } /* make_param --- make NAME into a function parameter */ static NODE * make_param(char *name) { NODE *r; getnode(r); r->type = Node_param_list; r->rnode = NULL; r->param = name; r->param_cnt = param_counter++; return (install(name, r)); } static struct fdesc { char *name; short used; short defined; struct fdesc *next; } *ftable[HASHSIZE]; /* func_use --- track uses and definitions of functions */ static void func_use(char *name, enum defref how) { struct fdesc *fp; int len; int ind; len = strlen(name); ind = hash(name, len, HASHSIZE); for (fp = ftable[ind]; fp != NULL; fp = fp->next) { if (strcmp(fp->name, name) == 0) { if (how == FUNC_DEFINE) fp->defined++; else fp->used++; return; } } /* not in the table, fall through to allocate a new one */ emalloc(fp, struct fdesc *, sizeof(struct fdesc), "func_use"); memset(fp, '\0', sizeof(struct fdesc)); emalloc(fp->name, char *, len + 1, "func_use"); strcpy(fp->name, name); if (how == FUNC_DEFINE) fp->defined++; else fp->used++; fp->next = ftable[ind]; ftable[ind] = fp; } /* check_funcs --- verify functions that are called but not defined */ static void check_funcs() { struct fdesc *fp, *next; int i; for (i = 0; i < HASHSIZE; i++) { for (fp = ftable[i]; fp != NULL; fp = fp->next) { #ifdef REALLYMEAN /* making this the default breaks old code. sigh. */ if (fp->defined == 0) { error( _("function `%s' called but never defined"), fp->name); errcount++; } #else if (do_lint && fp->defined == 0) lintwarn( _("function `%s' called but never defined"), fp->name); #endif if (do_lint && fp->used == 0) { lintwarn(_("function `%s' defined but never called"), fp->name); } } } /* now let's free all the memory */ for (i = 0; i < HASHSIZE; i++) { for (fp = ftable[i]; fp != NULL; fp = next) { next = fp->next; free(fp->name); free(fp); } } } /* param_sanity --- look for parameters that are regexp constants */ static void param_sanity(NODE *arglist) { NODE *argp, *arg; int i; for (i = 1, argp = arglist; argp != NULL; argp = argp->rnode, i++) { arg = argp->lnode; if (arg->type == Node_regex) warning(_("regexp constant for parameter #%d yields boolean value"), i); } } /* variable --- make sure NAME is in the symbol table */ NODE * variable(char *name, int can_free, NODETYPE type) { register NODE *r; static int env_loaded = FALSE; static int procinfo_loaded = FALSE; if (! env_loaded && STREQ(name, "ENVIRON")) { load_environ(); env_loaded = TRUE; } if (! do_traditional && ! procinfo_loaded && STREQ(name, "PROCINFO")) { load_procinfo(); procinfo_loaded = TRUE; } if ((r = lookup(name)) == NULL) r = install(name, node(Nnull_string, type, (NODE *) NULL)); else if (can_free) free(name); return r; } /* mk_rexp --- make a regular expression constant */ static NODE * mk_rexp(NODE *exp) { NODE *n; if (exp->type == Node_regex) return exp; getnode(n); n->type = Node_regex; n->re_exp = exp; n->re_text = NULL; n->re_reg = NULL; n->re_flags = 0; n->re_cnt = 1; return n; } /* isnoeffect --- when used as a statement, has no side effects */ /* * To be completely general, we should recursively walk the parse * tree, to make sure that all the subexpressions also have no effect. * Instead, we just weaken the actual warning that's printed, up above * in the grammar. */ static int isnoeffect(NODETYPE type) { switch (type) { case Node_times: case Node_quotient: case Node_mod: case Node_plus: case Node_minus: case Node_subscript: case Node_concat: case Node_exp: case Node_unary_minus: case Node_field_spec: case Node_and: case Node_or: case Node_equal: case Node_notequal: case Node_less: case Node_greater: case Node_leq: case Node_geq: case Node_match: case Node_nomatch: case Node_not: case Node_val: case Node_in_array: case Node_NF: case Node_NR: case Node_FNR: case Node_FS: case Node_RS: case Node_FIELDWIDTHS: case Node_IGNORECASE: case Node_OFS: case Node_ORS: case Node_OFMT: case Node_CONVFMT: case Node_BINMODE: case Node_LINT: return TRUE; default: break; /* keeps gcc -Wall happy */ } return FALSE; } /* isassignable --- can this node be assigned to? */ static int isassignable(register NODE *n) { switch (n->type) { case Node_var: case Node_FIELDWIDTHS: case Node_RS: case Node_FS: case Node_FNR: case Node_NR: case Node_NF: case Node_IGNORECASE: case Node_OFMT: case Node_CONVFMT: case Node_ORS: case Node_OFS: case Node_LINT: case Node_BINMODE: case Node_field_spec: case Node_subscript: return TRUE; case Node_param_list: return ((n->flags & FUNC) == 0); /* ok if not func name */ default: break; /* keeps gcc -Wall happy */ } return FALSE; } /* stopme --- for debugging */ NODE * stopme(NODE *tree) { return tmp_number((AWKNUM) 0.0); } /* dumpintlstr --- write out an initial .po file entry for the string */ static void dumpintlstr(char *str, size_t len) { char *cp; /* See the GNU gettext distribution for details on the file format */ if (source != NULL) { /* ala the gettext sources, remove leading `./'s */ for (cp = source; cp[0] == '.' && cp[1] == '/'; cp += 2) continue; printf("#: %s:%d\n", cp, sourceline); } printf("msgid "); fflush(stdout); pp_string_fp(stdout, str, len, '"', TRUE); putchar('\n'); printf("msgstr \"\"\n\n"); } /* count_args --- count the number of printf arguments */ static void count_args(NODE *tree) { size_t count = 0; NODE *save_tree; assert(tree->type == Node_K_printf || (tree->type == Node_builtin && tree->proc == do_sprintf)); save_tree = tree; tree = tree->lnode; /* printf format string */ for (count = 0; tree != NULL; tree = tree->rnode) count++; save_tree->printf_count = count; }