One way to accomplish this is to construct a list of the variables during the parse of the declaration section and then check variable references against the those on the list. Such a list is called a symbol table. Symbol tables may be implemented using lists, trees, and hash-tables.
We modify the Lex file to assign the global variable yylval to the identifier string since the information will be needed by the attribute grammar.
The symbol table for Simple consists of a linked list of identifiers,
initially empty. Here is the declaration of a node, initialization of the
list to empty,
| struct symrec { char *name; /* name of symbol */ struct symrec *next; /* link field */ }; typedef struct symrec symrec; symrec *sym_table = (symrec *)0; symrec *putsym (); symrec *getsym (); |
and two operations: putsym to put an identifier into the table, and
getsym which returns a pointer to the symbol table entry corresponding
to an identifier.
symrec * putsym ( char *sym_name )
{
symrec *ptr;
ptr = (symrec *) malloc (sizeof(symrec));
ptr$->$name = (char *) malloc (strlen(sym_name)+1);
strcpy (ptr$->$name,sym_name);
ptr$->$next = (struct symrec *)sym_table;
sym_table = ptr;
return ptr;
}
symrec * getsym ( char *sym_name ){ symrec *ptr; for (ptr = sym_table; ptr != (symrec *) 0; ptr = (symrec *)ptr$->$next) if (strcmp (ptr$->$name,sym_name) == 0) return ptr; return 0; } |
| %{ #include $<$stdlib.h$>$ /* For malloc in symbol table */ #include $<$string.h$>$ /* For strcmp in symbol table */ #include $<$stdio.h$>$ /* For error messages */ #include "ST.h" /* The Symbol Table Module */ #define YYDEBUG 1 /* For debugging */ install ( char *sym_name ) { symrec *s; s = getsym (sym_name); if (s == 0) s = putsym (sym_name); else { errors++; printf( "%s is already defined\n", sym_name ); } } context_check( char *sym_name ) { if ( getsym( sym_name ) == 0 ) printf( "%s is an undeclared identifier\n", sym_name ); } %} Parser declarations %% Grammar rules and actions %% C subroutines |
Since the scanner (the Lex file) will be returning identifiers, a semantic
record (static semantics) is required to hold the value and IDENT
is associated with that semantic record.
| C declarations %union { /* SEMANTIC RECORD */ char *id; /* For returning identifiers */ } %token INT SKIP IF THEN ELSE FI WHILE DO END %token <id> IDENT /* Simple identifier */ %left '-' '+' %left '*' '/' %right '^' %% Grammar rules and actions %% C subroutines |
| C and parser declarations %% ... declarations : /* empty */ | INTEGER id_seq IDENTIFIER '.' { install( $3 ); } ; id_seq : /* empty */ | id_seq IDENTIFIER ',' { install( $2 ); } ; command : SKIP | READ IDENTIFIER { context_check( $2 ); } | IDENT ASSGNOP exp { context_check( $2 ); } ... exp : INT | IDENT { context_check( $1 ); } ... %% C subroutines |
In this implementation the parse tree is implicitly annotated with the information concerning whether a variable is assigned to a value before it is referenced in an expression. The annotations to the parse tree are collected into the symbol table.
| %union { char *id; } |
The semantic value is copied from the global variable yytext
(which contains the input text) to yylval.id. Since the function
strdup is used (from the library string.h) the library
must be included. The resulting scanner file is:
| %{ #include <string.h> /* for strdup */ #include "Simple.tab.h" /* for token definitions and yylval */ %} DIGIT [0-9] ID [a-z][a-z0-9]* %% ":=" { return(ASSGNOP); } {DIGIT}+ { return(NUMBER); } do { return(DO); } else { return(ELSE); } end { return(END); } fi { return(FI); } if { return(IF); } in { return(IN); } integer { return(INTEGER); } let { return(LET); } read { return(READ); } skip { return(SKIP); } then { return(THEN); } while { return(WHILE); } write { return(WRITE); } {ID} { yylval.id = (char *) strdup(yytext); return(IDENTIFIER);} [ \t\n]+ /* eat up whitespace */ . { return(yytext[0]);} %% |