1 |
- Info file bison.info, produced by Makeinfo, -*- Text -*- from input
file bison.texinfo.
This file documents the Bison parser generator.
Copyright (C) 1988, 1989, 1990 Free Software Foundation, Inc.
Permission is granted to make and distribute verbatim copies of
this manual provided the copyright notice and this permission notice
are preserved on all copies.
Permission is granted to copy and distribute modified versions of
this manual under the conditions for verbatim copying, provided also
that the sections entitled "GNU General Public License" and
"Conditions for Using Bison" are included exactly as in the original,
and provided that the entire resulting derived work is distributed
under the terms of a permission notice identical to this one.
Permission is granted to copy and distribute translations of this
manual into another language, under the above conditions for modified
versions, except that the sections entitled "GNU General Public
License", "Conditions for Using Bison" and this permission notice may
be included in translations approved by the Free Software Foundation
instead of in the original English.
File: bison.info, Node: Rpcalc Lexer, Next: Rpcalc Main, Prev: Rpcalc Expr, Up: RPN Calc
The `rpcalc' Lexical Analyzer
-----------------------------
The lexical analyzer's job is low-level parsing: converting
characters or sequences of characters into tokens. The Bison parser
gets its tokens by calling the lexical analyzer. *Note Lexical::.
Only a simple lexical analyzer is needed for the RPN calculator.
This lexical analyzer skips blanks and tabs, then reads in numbers as
`double' and returns them as `NUM' tokens. Any other character that
isn't part of a number is a separate token. Note that the token-code
for such a single-character token is the character itself.
The return value of the lexical analyzer function is a numeric code
which represents a token type. The same text used in Bison rules to
stand for this token type is also a C expression for the numeric code
for the type. This works in two ways. If the token type is a
character literal, then its numeric code is the ASCII code for that
character; you can use the same character literal in the lexical
analyzer to express the number. If the token type is an identifier,
that identifier is defined by Bison as a C macro whose definition is
the appropriate number. In this example, therefore, `NUM' becomes a
macro for `yylex' to use.
The semantic value of the token (if it has one) is stored into the
global variable `yylval', which is where the Bison parser will look
for it. (The C data type of `yylval' is `YYSTYPE', which was defined
at the beginning of the grammar; *note Rpcalc Decls::..)
A token type code of zero is returned if the end-of-file is
encountered. (Bison recognizes any nonpositive value as indicating
the end of the input.)
Here is the code for the lexical analyzer:
/* Lexical analyzer returns a double floating point
number on the stack and the token NUM, or the ASCII
character read if not a number. Skips all blanks
and tabs, returns 0 for EOF. */
#include <ctype.h>
yylex ()
{
int c;
/* skip white space */
while ((c = getchar ()) == ' ' || c == '\t')
;
/* process numbers */
if (c == '.' || isdigit (c))
{
ungetc (c, stdin);
scanf ("%lf", &yylval);
return NUM;
}
/* return end-of-file */
if (c == EOF)
return 0;
/* return single chars */
return c;
}
File: bison.info, Node: Rpcalc Main, Next: Rpcalc Error, Prev: Rpcalc Lexer, Up: RPN Calc
The Controlling Function
------------------------
In keeping with the spirit of this example, the controlling
function is kept to the bare minimum. The only requirement is that it
call `yyparse' to start the process of parsing.
main ()
{
yyparse ();
}
File: bison.info, Node: Rpcalc Error, Next: Rpcalc Gen, Prev: Rpcalc Main, Up: RPN Calc
The Error Reporting Routine
---------------------------
When `yyparse' detects a syntax error, it calls the error reporting
function `yyerror' to print an error message (usually but not always
`"parse error"'). It is up to the programmer to supply `yyerror'
(*note Interface::.), so here is the definition we will use:
#include <stdio.h>
yyerror (s) /* Called by yyparse on error */
char *s;
{
printf ("%s\n", s);
}
After `yyerror' returns, the Bison parser may recover from the error
and continue parsing if the grammar contains a suitable error rule
(*note Error Recovery::.). Otherwise, `yyparse' returns nonzero. We
have not written any error rules in this example, so any invalid input
will cause the calculator program to exit. This is not clean behavior
for a real calculator, but it is adequate in the first example.
File: bison.info, Node: Rpcalc Gen, Next: Rpcalc Compile, Prev: Rpcalc Error, Up: RPN Calc
Running Bison to Make the Parser
--------------------------------
Before running Bison to produce a parser, we need to decide how to
arrange all the source code in one or more source files. For such a
simple example, the easiest thing is to put everything in one file.
The definitions of `yylex', `yyerror' and `main' go at the end, in the
"additional C code" section of the file (*note Grammar Layout::.).
For a large project, you would probably have several source files,
and use `make' to arrange to recompile them.
With all the source in a single file, you use the following command
to convert it into a parser file:
bison FILE_NAME.y
In this example the file was called `rpcalc.y' (for "Reverse Polish
CALCulator"). Bison produces a file named `FILE_NAME.tab.c', removing
the `.y' from the original file name. The file output by Bison
contains the source code for `yyparse'. The additional functions in
the input file (`yylex', `yyerror' and `main') are copied verbatim to
the output.
File: bison.info, Node: Rpcalc Compile, Prev: Rpcalc Gen, Up: RPN Calc
Compiling the Parser File
-------------------------
Here is how to compile and run the parser file:
# List files in current directory.
% ls
rpcalc.tab.c rpcalc.y
# Compile the Bison parser.
# `-lm' tells compiler to search math library for `pow'.
% cc rpcalc.tab.c -lm -o rpcalc
# List files again.
% ls
rpcalc rpcalc.tab.c rpcalc.y
The file `rpcalc' now contains the executable code. Here is an
example session using `rpcalc'.
% rpcalc
4 9 +
13
3 7 + 3 4 5 *+-
-13
3 7 + 3 4 5 * + - n Note the unary minus, `n'
13
5 6 / 4 n +
-3.166666667
3 4 ^ Exponentiation
81
^D End-of-file indicator
%
File: bison.info, Node: Infix Calc, Next: Simple Error Recovery, Prev: RPN Calc, Up: Examples
Infix Notation Calculator: `calc'
=================================
We now modify rpcalc to handle infix operators instead of postfix.
Infix notation involves the concept of operator precedence and the
need for parentheses nested to arbitrary depth. Here is the Bison
code for `calc.y', an infix desk-top calculator.
/* Infix notation calculator--calc */
%{
#define YYSTYPE double
#include <math.h>
%}
/* BISON Declarations */
%token NUM
%left '-' '+'
%left '*' '/'
%left NEG /* negation--unary minus */
%right '^' /* exponentiation */
/* Grammar follows */
%%
input: /* empty string */
| input line
;
line: '\n'
| exp '\n' { printf ("\t%.10g\n", $1); }
;
exp: NUM { $$ = $1; }
| exp '+' exp { $$ = $1 + $3; }
| exp '-' exp { $$ = $1 - $3; }
| exp '*' exp { $$ = $1 * $3; }
| exp '/' exp { $$ = $1 / $3; }
| '-' exp %prec NEG { $$ = -$2; }
| exp '^' exp { $$ = pow ($1, $3); }
| '(' exp ')' { $$ = $2; }
;
%%
The functions `yylex', `yyerror' and `main' can be the same as before.
There are two important new features shown in this code.
In the second section (Bison declarations), `%left' declares token
types and says they are left-associative operators. The declarations
`%left' and `%right' (right associativity) take the place of `%token'
which is used to declare a token type name without associativity.
(These tokens are single-character literals, which ordinarily don't
need to be declared. We declare them here to specify the
associativity.)
Operator precedence is determined by the line ordering of the
declarations; the higher the line number of the declaration (lower on
the page or screen), the higher the precedence. Hence, exponentiation
has the highest precedence, unary minus (`NEG') is next, followed by
`*' and `/', and so on. *Note Precedence::.
The other important new feature is the `%prec' in the grammar
section for the unary minus operator. The `%prec' simply instructs
Bison that the rule `| '-' exp' has the same precedence as `NEG'--in
this case the next-to-highest. *Note Contextual Precedence::.
Here is a sample run of `calc.y':
% calc
4 + 4.5 - (34/(8*3+-3))
6.880952381
-56 + 2
-54
3 ^ 2
9
File: bison.info, Node: Simple Error Recovery, Next: Multi-function Calc, Prev: Infix Calc, Up: Examples
Simple Error Recovery
=====================
Up to this point, this manual has not addressed the issue of "error
recovery"--how to continue parsing after the parser detects a syntax
error. All we have handled is error reporting with `yyerror'. Recall
that by default `yyparse' returns after calling `yyerror'. This means
that an erroneous input line causes the calculator program to exit.
Now we show how to rectify this deficiency.
The Bison language itself includes the reserved word `error', which
may be included in the grammar rules. In the example below it has
been added to one of the alternatives for `line':
line: '\n'
| exp '\n' { printf ("\t%.10g\n", $1); }
| error '\n' { yyerrok; }
;
This addition to the grammar allows for simple error recovery in
the event of a parse error. If an expression that cannot be evaluated
is read, the error will be recognized by the third rule for `line',
and parsing will continue. (The `yyerror' function is still called
upon to print its message as well.) The action executes the statement
`yyerrok', a macro defined automatically by Bison; its meaning is that
error recovery is complete (*note Error Recovery::.). Note the
difference between `yyerrok' and `yyerror'; neither one is a misprint.
This form of error recovery deals with syntax errors. There are
other kinds of errors; for example, division by zero, which raises an
exception signal that is normally fatal. A real calculator program
must handle this signal and use `longjmp' to return to `main' and
resume parsing input lines; it would also have to discard the rest of
the current line of input. We won't discuss this issue further
because it is not specific to Bison programs.
File: bison.info, Node: Multi-function Calc, Next: Exercises, Prev: Simple Error Recovery, Up: Examples
Multi-Function Calculator: `mfcalc'
===================================
Now that the basics of Bison have been discussed, it is time to
move on to a more advanced problem. The above calculators provided
only five functions, `+', `-', `*', `/' and `^'. It would be nice to
have a calculator that provides other mathematical functions such as
`sin', `cos', etc.
It is easy to add new operators to the infix calculator as long as
they are only single-character literals. The lexical analyzer `yylex'
passes back all non-number characters as tokens, so new grammar rules
suffice for adding a new operator. But we want something more
flexible: built-in functions whose syntax has this form:
FUNCTION_NAME (ARGUMENT)
At the same time, we will add memory to the calculator, by allowing you
to create named variables, store values in them, and use them later.
Here is a sample session with the multi-function calculator:
% acalc
pi = 3.141592653589
3.1415926536
sin(pi)
0.0000000000
alpha = beta1 = 2.3
2.3000000000
alpha
2.3000000000
ln(alpha)
0.8329091229
exp(ln(beta1))
2.3000000000
%
Note that multiple assignment and nested function calls are
permitted.
* Menu:
* Decl: Mfcalc Decl. Bison declarations for multi-function calculator.
* Rules: Mfcalc Rules. Grammar rules for the calculator.
* Symtab: Mfcalc Symtab. Symbol table management subroutines.
File: bison.info, Node: Mfcalc Decl, Next: Mfcalc Rules, Prev: Multi-function Calc, Up: Multi-function Calc
Declarations for `mfcalc'
-------------------------
Here are the C and Bison declarations for the multi-function
calculator.
%{
#include <math.h> /* For math functions, cos(), sin(), etc. */
#include "calc.h" /* Contains definition of `symrec' */
%}
%union {
double val; /* For returning numbers. */
symrec *tptr; /* For returning symbol-table pointers */
}
%token <val> NUM /* Simple double precision number */
%token <tptr> VAR FNCT /* Variable and Function */
%type <val> exp
%right '='
%left '-' '+'
%left '*' '/'
%left NEG /* Negation--unary minus */
%right '^' /* Exponentiation */
/* Grammar follows */
%%
The above grammar introduces only two new features of the Bison
language. These features allow semantic values to have various data
types (*note Multiple Types::.).
The `%union' declaration specifies the entire list of possible
types; this is instead of defining `YYSTYPE'. The allowable types are
now double-floats (for `exp' and `NUM') and pointers to entries in the
symbol table. *Note Union Decl::.
Since values can now have various types, it is necessary to
associate a type with each grammar symbol whose semantic value is
used. These symbols are `NUM', `VAR', `FNCT', and `exp'. Their
declarations are augmented with information about their data type
(placed between angle brackets).
The Bison construct `%type' is used for declaring nonterminal
symbols, just as `%token' is used for declaring token types. We have
not used `%type' before because nonterminal symbols are normally
declared implicitly by the rules that define them. But `exp' must be
declared explicitly so we can specify its value type. *Note Type
Decl::.
File: bison.info, Node: Mfcalc Rules, Next: Mfcalc Symtab, Prev: Mfcalc Decl, Up: Multi-function Calc
Grammar Rules for `mfcalc'
--------------------------
Here are the grammar rules for the multi-function calculator. Most
of them are copied directly from `calc'; three rules, those which
mention `VAR' or `FNCT', are new.
input: /* empty */
| input line
;
line:
'\n'
| exp '\n' { printf ("\t%.10g\n", $1); }
| error '\n' { yyerrok; }
;
exp: NUM { $$ = $1; }
| VAR { $$ = $1->value.var; }
| VAR '=' exp { $$ = $3; $1->value.var = $3; }
| FNCT '(' exp ')' { $$ = (*($1->value.fnctptr))($3); }
| exp '+' exp { $$ = $1 + $3; }
| exp '-' exp { $$ = $1 - $3; }
| exp '*' exp { $$ = $1 * $3; }
| exp '/' exp { $$ = $1 / $3; }
| '-' exp %prec NEG { $$ = -$2; }
| exp '^' exp { $$ = pow ($1, $3); }
| '(' exp ')' { $$ = $2; }
;
/* End of grammar */
%%
File: bison.info, Node: Mfcalc Symtab, Prev: Mfcalc Rules, Up: Multi-function Calc
The `mfcalc' Symbol Table
-------------------------
The multi-function calculator requires a symbol table to keep track
of the names and meanings of variables and functions. This doesn't
affect the grammar rules (except for the actions) or the Bison
declarations, but it requires some additional C functions for support.
The symbol table itself consists of a linked list of records. Its
definition, which is kept in the header `calc.h', is as follows. It
provides for either functions or variables to be placed in the table.
/* Data type for links in the chain of symbols. */
struct symrec
{
char *name; /* name of symbol */
int type; /* type of symbol: either VAR or FNCT */
union {
double var; /* value of a VAR */
double (*fnctptr)(); /* value of a FNCT */
} value;
struct symrec *next; /* link field */
};
typedef struct symrec symrec;
/* The symbol table: a chain of `struct symrec'. */
extern symrec *sym_table;
symrec *putsym ();
symrec *getsym ();
The new version of `main' includes a call to `init_table', a
function that initializes the symbol table. Here it is, and
`init_table' as well:
#include <stdio.h>
main ()
{
init_table ();
yyparse ();
}
yyerror (s) /* Called by yyparse on error */
char *s;
{
printf ("%s\n", s);
}
struct init
{
char *fname;
double (*fnct)();
};
struct init arith_fncts[]
= {
"sin", sin,
"cos", cos,
"atan", atan,
"ln", log,
"exp", exp,
"sqrt", sqrt,
0, 0
};
/* The symbol table: a chain of `struct symrec'. */
symrec *sym_table = (symrec *)0;
init_table () /* puts arithmetic functions in table. */
{
int i;
symrec *ptr;
for (i = 0; arith_fncts[i].fname != 0; i++)
{
ptr = putsym (arith_fncts[i].fname, FNCT);
ptr->value.fnctptr = arith_fncts[i].fnct;
}
}
By simply editing the initialization list and adding the necessary
include files, you can add additional functions to the calculator.
Two important functions allow look-up and installation of symbols
in the symbol table. The function `putsym' is passed a name and the
type (`VAR' or `FNCT') of the object to be installed. The object is
linked to the front of the list, and a pointer to the object is
returned. The function `getsym' is passed the name of the symbol to
look up. If found, a pointer to that symbol is returned; otherwise
zero is returned.
symrec *
putsym (sym_name,sym_type)
char *sym_name;
int sym_type;
{
symrec *ptr;
ptr = (symrec *) malloc (sizeof (symrec));
ptr->name = (char *) malloc (strlen (sym_name) + 1);
strcpy (ptr->name,sym_name);
ptr->type = sym_type;
ptr->value.var = 0; /* set value to 0 even if fctn. */
ptr->next = (struct symrec *)sym_table;
sym_table = ptr;
return ptr;
}
symrec *
getsym (sym_name)
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;
}
The function `yylex' must now recognize variables, numeric values,
and the single-character arithmetic operators. Strings of alphanumeric
characters with a leading nondigit are recognized as either variables
or functions depending on what the symbol table says about them.
The string is passed to `getsym' for look up in the symbol table.
If the name appears in the table, a pointer to its location and its
type (`VAR' or `FNCT') is returned to `yyparse'. If it is not already
in the table, then it is installed as a `VAR' using `putsym'. Again,
a pointer and its type (which must be `VAR') is returned to `yyparse'.
No change is needed in the handling of numeric values and arithmetic
operators in `yylex'.
#include <ctype.h>
yylex ()
{
int c;
/* Ignore whitespace, get first nonwhite character. */
while ((c = getchar ()) == ' ' || c == '\t');
if (c == EOF)
return 0;
/* Char starts a number => parse the number. */
if (c == '.' || isdigit (c))
{
ungetc (c, stdin);
scanf ("%lf", &yylval.val);
return NUM;
}
/* Char starts an identifier => read the name. */
if (isalpha (c))
{
symrec *s;
static char *symbuf = 0;
static int length = 0;
int i;
/* Initially make the buffer long enough
for a 40-character symbol name. */
if (length == 0)
length = 40, symbuf = (char *)malloc (length + 1);
i = 0;
do
{
/* If buffer is full, make it bigger. */
if (i == length)
{
length *= 2;
symbuf = (char *)realloc (symbuf, length + 1);
}
/* Add this character to the buffer. */
symbuf[i++] = c;
/* Get another character. */
c = getchar ();
}
while (c != EOF && isalnum (c));
ungetc (c, stdin);
symbuf[i] = '\0';
s = getsym (symbuf);
if (s == 0)
s = putsym (symbuf, VAR);
yylval.tptr = s;
return s->type;
}
/* Any other character is a token by itself. */
return c;
}
This program is both powerful and flexible. You may easily add new
functions, and it is a simple job to modify this code to install
predefined variables such as `pi' or `e' as well.
File: bison.info, Node: Exercises, Prev: Multi-function calc, Up: Examples
Exercises
=========
1. Add some new functions from `math.h' to the initialization list.
2. Add another array that contains constants and their values. Then
modify `init_table' to add these constants to the symbol table.
It will be easiest to give the constants type `VAR'.
3. Make the program report an error if the user refers to an
uninitialized variable in any way except to store a value in it.
File: bison.info, Node: Grammar File, Next: Interface, Prev: Examples, Up: Top
Bison Grammar Files
*******************
Bison takes as input a context-free grammar specification and
produces a C-language function that recognizes correct instances of
the grammar.
The Bison grammar input file conventionally has a name ending in
`.y'.
* Menu:
* Grammar Outline:: Overall layout of the grammar file.
* Symbols:: Terminal and nonterminal symbols.
* Rules:: How to write grammar rules.
* Recursion:: Writing recursive rules.
* Semantics:: Semantic values and actions.
* Declarations:: All kinds of Bison declarations are described here.
* Multiple Parsers:: Putting more than one Bison parser in one program.
File: bison.info, Node: Grammar Outline, Next: Symbols, Prev: Grammar File, Up: Grammar File
Outline of a Bison Grammar
==========================
A Bison grammar file has four main sections, shown here with the
appropriate delimiters:
%{
C DECLARATIONS
%}
BISON DECLARATIONS
%%
GRAMMAR RULES
%%
ADDITIONAL C CODE
Comments enclosed in `/* ... */' may appear in any of the sections.
* Menu:
* C Declarations:: Syntax and usage of the C declarations section.
* Bison Declarations:: Syntax and usage of the Bison declarations section.
* Grammar Rules:: Syntax and usage of the grammar rules section.
* C Code:: Syntax and usage of the additional C code section.
File: bison.info, Node: C Declarations, Next: Bison Declarations, Prev: Grammar Outline, Up: Grammar Outline
The C Declarations Section
--------------------------
The C DECLARATIONS section contains macro definitions and
declarations of functions and variables that are used in the actions
in the grammar rules. These are copied to the beginning of the parser
file so that they precede the definition of `yyparse'. You can use
`#include' to get the declarations from a header file. If you don't
need any C declarations, you may omit the `%{' and `%}' delimiters
that bracket this section.
File: bison.info, Node: Bison Declarations, Next: Grammar Rules, Prev: C Declarations, Up: Grammar Outline
The Bison Declarations Section
------------------------------
The BISON DECLARATIONS section contains declarations that define
terminal and nonterminal symbols, specify precedence, and so on. In
some simple grammars you may not need any declarations. *Note
Declarations::.
File: bison.info, Node: Grammar Rules, Next: C Code, Prev: Bison Declarations, Up: Grammar Outline
The Grammar Rules Section
-------------------------
The "grammar rules" section contains one or more Bison grammar
rules, and nothing else. *Note Rules::.
There must always be at least one grammar rule, and the first `%%'
(which precedes the grammar rules) may never be omitted even if it is
the first thing in the file.
File: bison.info, Node: C Code, Prev: Grammar Rules, Up: Grammar Outline
The Additional C Code Section
-----------------------------
The ADDITIONAL C CODE section is copied verbatim to the end of the
parser file, just as the C DECLARATIONS section is copied to the
beginning. This is the most convenient place to put anything that you
want to have in the parser file but which need not come before the
definition of `yyparse'. For example, the definitions of `yylex' and
`yyerror' often go here. *Note Interface::.
If the last section is empty, you may omit the `%%' that separates
it from the grammar rules.
The Bison parser itself contains many static variables whose names
start with `yy' and many macros whose names start with `YY'. It is a
good idea to avoid using any such names (except those documented in
this manual) in the additional C code section of the grammar file.
File: bison.info, Node: Symbols, Next: Rules, Prev: Grammar Outline, Up: Grammar File
Symbols, Terminal and Nonterminal
=================================
"Symbols" in Bison grammars represent the grammatical
classifications of the language.
A "terminal symbol" (also known as a "token type") represents a
class of syntactically equivalent tokens. You use the symbol in
grammar rules to mean that a token in that class is allowed. The
symbol is represented in the Bison parser by a numeric code, and the
`yylex' function returns a token type code to indicate what kind of
token has been read. You don't need to know what the code value is;
you can use the symbol to stand for it.
A "nonterminal symbol" stands for a class of syntactically
equivalent groupings. The symbol name is used in writing grammar
rules. By convention, it should be all lower case.
Symbol names can contain letters, digits (not at the beginning),
underscores and periods. Periods make sense only in nonterminals.
There are two ways of writing terminal symbols in the grammar:
* A "named token type" is written with an identifier, like an
identifier in C. By convention, it should be all upper case.
Each such name must be defined with a Bison declaration such as
`%token'. *Note Token Decl::.
* A "character token type" (or "literal token") is written in the
grammar using the same syntax used in C for character constants;
for example, `'+'' is a character token type. A character token
type doesn't need to be declared unless you need to specify its
semantic value data type (*note Value Type::.), associativity, or
precedence (*note Precedence::.).
By convention, a character token type is used only to represent a
token that consists of that particular character. Thus, the token
type `'+'' is used to represent the character `+' as a token.
Nothing enforces this convention, but if you depart from it, your
program will confuse other readers.
All the usual escape sequences used in character literals in C
can be used in Bison as well, but you must not use the null
character as a character literal because its ASCII code, zero, is
the code `yylex' returns for end-of-input (*note Calling
Convention::.).
How you choose to write a terminal symbol has no effect on its
grammatical meaning. That depends only on where it appears in rules
and on when the parser function returns that symbol.
The value returned by `yylex' is always one of the terminal symbols
(or 0 for end-of-input). Whichever way you write the token type in the
grammar rules, you write it the same way in the definition of `yylex'.
The numeric code for a character token type is simply the ASCII code
for the character, so `yylex' can use the identical character constant
to generate the requisite code. Each named token type becomes a C
macro in the parser file, so `yylex' can use the name to stand for the
code. (This is why periods don't make sense in terminal symbols.)
*Note Calling Convention::.
If `yylex' is defined in a separate file, you need to arrange for
the token-type macro definitions to be available there. Use the `-d'
option when you run Bison, so that it will write these macro
definitions into a separate header file `NAME.tab.h' which you can
include in the other source files that need it. *Note Invocation::.
The symbol `error' is a terminal symbol reserved for error recovery
(*note Error Recovery::.); you shouldn't use it for any other purpose.
In particular, `yylex' should never return this value.
File: bison.info, Node: Rules, Next: Recursion, Prev: Symbols, Up: Grammar File
Syntax of Grammar Rules
=======================
A Bison grammar rule has the following general form:
RESULT: COMPONENTS...
;
where RESULT is the nonterminal symbol that this rule describes and
COMPONENTS are various terminal and nonterminal symbols that are put
together by this rule (*note Symbols::.).
For example,
exp: exp '+' exp
;
says that two groupings of type `exp', with a `+' token in between,
can be combined into a larger grouping of type `exp'.
Whitespace in rules is significant only to separate symbols. You
can add extra whitespace as you wish.
Scattered among the components can be ACTIONS that determine the
semantics of the rule. An action looks like this:
{C STATEMENTS}
Usually there is only one action and it follows the components. *Note
Actions::.
Multiple rules for the same RESULT can be written separately or can
be joined with the vertical-bar character `|' as follows:
RESULT: RULE1-COMPONENTS...
| RULE2-COMPONENTS...
...
;
They are still considered distinct rules even when joined in this way.
If COMPONENTS in a rule is empty, it means that RESULT can match
the empty string. For example, here is how to define a
comma-separated sequence of zero or more `exp' groupings:
expseq: /* empty */
| expseq1
;
expseq1: exp
| expseq1 ',' exp
;
It is customary to write a comment `/* empty */' in each rule with no
components.
File: bison.info, Node: Recursion, Next: Semantics, Prev: Rules, Up: Grammar File
Recursive Rules
===============
A rule is called "recursive" when its RESULT nonterminal appears
also on its right hand side. Nearly all Bison grammars need to use
recursion, because that is the only way to define a sequence of any
number of somethings. Consider this recursive definition of a
comma-separated sequence of one or more expressions:
expseq1: exp
| expseq1 ',' exp
;
Since the recursive use of `expseq1' is the leftmost symbol in the
right hand side, we call this "left recursion". By contrast, here the
same construct is defined using "right recursion":
expseq1: exp
| exp ',' expseq1
;
Any kind of sequence can be defined using either left recursion or
right recursion, but you should always use left recursion, because it
can parse a sequence of any number of elements with bounded stack
space. Right recursion uses up space on the Bison stack in proportion
to the number of elements in the sequence, because all the elements
must be shifted onto the stack before the rule can be applied even
once. *Note The Algorithm of the Bison Parser: Algorithm, for further
explanation of this.
"Indirect" or "mutual" recursion occurs when the result of the rule
does not appear directly on its right hand side, but does appear in
rules for other nonterminals which do appear on its right hand side.
For example:
expr: primary
| primary '+' primary
;
primary: constant
| '(' expr ')'
;
defines two mutually-recursive nonterminals, since each refers to the
other.
File: bison.info, Node: Semantics, Next: Declarations, Prev: Recursion, Up: Grammar File
Defining Language Semantics
===========================
The grammar rules for a language determine only the syntax. The
semantics are determined by the semantic values associated with
various tokens and groupings, and by the actions taken when various
groupings are recognized.
For example, the calculator calculates properly because the value
associated with each expression is the proper number; it adds properly
because the action for the grouping `X + Y' is to add the numbers
associated with X and Y.
* Menu:
* Value Type:: Specifying one data type for all semantic values.
* Multiple Types:: Specifying several alternative data types.
* Actions:: An action is the semantic definition of a grammar rule.
* Action Types:: Specifying data types for actions to operate on.
* Mid-Rule Actions:: Most actions go at the end of a rule.
This says when, why and how to use the exceptional
action in the middle of a rule.
File: bison.info, Node: Value Type, Next: Multiple Types, Prev: Semantics, Up: Semantics
Data Types of Semantic Values
-----------------------------
In a simple program it may be sufficient to use the same data type
for the semantic values of all language constructs. This was true in
the RPN and infix calculator examples (*note RPN Calc::.).
Bison's default is to use type `int' for all semantic values. To
specify some other type, define `YYSTYPE' as a macro, like this:
#define YYSTYPE double
This macro definition must go in the C declarations section of the
grammar file (*note Grammar Outline::.).
File: bison.info, Node: Multiple Types, Next: Actions, Prev: Value Type, Up: Semantics
More Than One Value Type
------------------------
In most programs, you will need different data types for different
kinds of tokens and groupings. For example, a numeric constant may
need type `int' or `long', while a string constant needs type `char *',
and an identifier might need a pointer to an entry in the symbol table.
To use more than one data type for semantic values in one parser,
Bison requires you to do two things:
* Specify the entire collection of possible data types, with the
`%union' Bison declaration (*note Union Decl::.).
* Choose one of those types for each symbol (terminal or
nonterminal) for which semantic values are used. This is done
for tokens with the `%token' Bison declaration (*note Token
Decl::.) and for groupings with the `%type' Bison declaration
(*note Type Decl::.).
File: bison.info, Node: Actions, Next: Action Types, Prev: Multiple Types, Up: Semantics
Actions
-------
An action accompanies a syntactic rule and contains C code to be
executed each time an instance of that rule is recognized. The task
of most actions is to compute a semantic value for the grouping built
by the rule from the semantic values associated with tokens or smaller
groupings.
An action consists of C statements surrounded by braces, much like a
compound statement in C. It can be placed at any position in the
rule; it is executed at that position. Most rules have just one
action at the end of the rule, following all the components. Actions
in the middle of a rule are tricky and used only for special purposes
(*note Mid-Rule Actions::.).
The C code in an action can refer to the semantic values of the
components matched by the rule with the construct `$N', which stands
for the value of the Nth component. The semantic value for the
grouping being constructed is `$$'. (Bison translates both of these
constructs into array element references when it copies the actions
into the parser file.)
Here is a typical example:
exp: ...
| exp '+' exp
{ $$ = $1 + $3; }
This rule constructs an `exp' from two smaller `exp' groupings
connected by a plus-sign token. In the action, `$1' and `$3' refer to
the semantic values of the two component `exp' groupings, which are
the first and third symbols on the right hand side of the rule. The
sum is stored into `$$' so that it becomes the semantic value of the
addition-expression just recognized by the rule. If there were a
useful semantic value associated with the `+' token, it could be
referred to as `$2'.
`$N' with N zero or negative is allowed for reference to tokens and
groupings on the stack *before* those that match the current rule.
This is a very risky practice, and to use it reliably you must be
certain of the context in which the rule is applied. Here is a case
in which you can use this reliably:
foo: expr bar '+' expr { ... }
| expr bar '-' expr { ... }
;
bar: /* empty */
{ previous_expr = $0; }
;
As long as `bar' is used only in the fashion shown here, `$0'
always refers to the `expr' which precedes `bar' in the definition of
`foo'.
File: bison.info, Node: Action Types, Next: Mid-Rule Actions, Prev: Actions, Up: Semantics
Data Types of Values in Actions
-------------------------------
If you have chosen a single data type for semantic values, the `$$'
and `$N' constructs always have that data type.
If you have used `%union' to specify a variety of data types, then
you must declare a choice among these types for each terminal or
nonterminal symbol that can have a semantic value. Then each time you
use `$$' or `$N', its data type is determined by which symbol it
refers to in the rule. In this example,
exp: ...
| exp '+' exp
{ $$ = $1 + $3; }
`$1' and `$3' refer to instances of `exp', so they all have the data
type declared for the nonterminal symbol `exp'. If `$2' were used, it
would have the data type declared for the terminal symbol `'+'',
whatever that might be.
Alternatively, you can specify the data type when you refer to the
value, by inserting `<TYPE>' after the `$' at the beginning of the
reference. For example, if you have defined types as shown here:
%union {
int itype;
double dtype;
}
then you can write `$<itype>1' to refer to the first subunit of the
rule as an integer, or `$<dtype>1' to refer to it as a double.
File: bison.info, Node: Mid-Rule Actions, Prev: Action Types, Up: Semantics
Actions in Mid-Rule
-------------------
Occasionally it is useful to put an action in the middle of a rule.
These actions are written just like usual end-of-rule actions, but they
are executed before the parser even recognizes the following
components.
A mid-rule action may refer to the components preceding it using
`$N', but it may not refer to subsequent components because it is run
before they are parsed.
The mid-rule action itself counts as one of the components of the
rule. This makes a difference when there is another action later in
the same rule (and usually there is another at the end): you have to
count the actions along with the symbols when working out which number
N to use in `$N'.
The mid-rule action can also have a semantic value. This can be set
within that action by an assignment to `$$', and can referred to by
actions later in the rule using `$N'. Since there is no symbol to
name the action, there is no way to declare a data type for the value
in advance, so you must use the `$<...>' construct to specify a data
type each time you refer to this value.
There is no way to set the value of the entire rule with a mid-rule
action, because assignments to `$$' do not have that effect. The only
way to set the value for the entire rule is with an ordinary action at
the end of the rule.
Here is an example from a hypothetical compiler, handling a `let'
statement that looks like `let (VARIABLE) STATEMENT' and serves to
create a variable named VARIABLE temporarily for the duration of
STATEMENT. To parse this construct, we must put VARIABLE into the
symbol table while STATEMENT is parsed, then remove it afterward.
Here is how it is done:
stmt: LET '(' var ')'
{ $<context>$ = push_context ();
declare_variable ($3); }
stmt { $$ = $6;
pop_context ($<context>5); }
As soon as `let (VARIABLE)' has been recognized, the first action is
run. It saves a copy of the current semantic context (the list of
accessible variables) as its semantic value, using alternative
`context' in the data-type union. Then it calls `declare_variable' to
add the new variable to that list. Once the first action is finished,
the embedded statement `stmt' can be parsed. Note that the mid-rule
action is component number 5, so the `stmt' is component number 6.
After the embedded statement is parsed, its semantic value becomes
the value of the entire `let'-statement. Then the semantic value from
the earlier action is used to restore the prior list of variables.
This removes the temporary `let'-variable from the list so that it
won't appear to exist while the rest of the program is parsed.
Taking action before a rule is completely recognized often leads to
conflicts since the parser must commit to a parse in order to execute
the action. For example, the following two rules, without mid-rule
actions, can coexist in a working parser because the parser can shift
the open-brace token and look at what follows before deciding whether
there is a declaration or not:
compound: '{' declarations statements '}'
| '{' statements '}'
;
But when we add a mid-rule action as follows, the rules become
nonfunctional:
compound: { prepare_for_local_variables (); }
'{' declarations statements '}'
| '{' statements '}'
;
Now the parser is forced to decide whether to run the mid-rule action
when it has read no farther than the open-brace. In other words, it
must commit to using one rule or the other, without sufficient
information to do it correctly. (The open-brace token is what is
called the "look-ahead" token at this time, since the parser is still
deciding what to do about it. *Note Look-Ahead::.)
You might think that you could correct the problem by putting
identical actions into the two rules, like this:
compound: { prepare_for_local_variables (); }
'{' declarations statements '}'
| { prepare_for_local_variables (); }
'{' statements '}'
;
But this does not help, because Bison does not realize that the two
actions are identical. (Bison never tries to understand the C code in
an action.)
If the grammar is such that a declaration can be distinguished from
a statement by the first token (which is true in C), then one solution
which does work is to put the action after the open-brace, like this:
compound: '{' { prepare_for_local_variables (); }
declarations statements '}'
| '{' statements '}'
;
Now the first token of the following declaration or statement, which
would in any case tell Bison which rule to use, can still do so.
Another solution is to bury the action inside a nonterminal symbol
which serves as a subroutine:
subroutine: /* empty */
{ prepare_for_local_variables (); }
;
compound: subroutine
'{' declarations statements '}'
| subroutine
'{' statements '}'
;
Now Bison can execute the action in the rule for `subroutine' without
deciding which rule for `compound' it will eventually use. Note that
the action is now at the end of its rule. Any mid-rule action can be
converted to an end-of-rule action in this way, and this is what Bison
actually does to implement mid-rule actions.
File: bison.info, Node: Declarations, Next: Multiple Parsers, Prev: Semantics, Up: Grammar File
Bison Declarations
==================
The "Bison declarations" section of a Bison grammar defines the
symbols used in formulating the grammar and the data types of semantic
values. *Note Symbols::.
All token type names (but not single-character literal tokens such
as `'+'' and `'*'') must be declared. Nonterminal symbols must be
declared if you need to specify which data type to use for the semantic
value (*note Multiple Types::.).
The first rule in the file also specifies the start symbol, by
default. If you want some other symbol to be the start symbol, you
must declare it explicitly (*note Language and Grammar::.).
* Menu:
* Token Decl:: Declaring terminal symbols.
* Precedence Decl:: Declaring terminals with precedence and associativity.
* Union Decl:: Declaring the set of all semantic value types.
* Type Decl:: Declaring the choice of type for a nonterminal symbol.
* Expect Decl:: Suppressing warnings about shift/reduce conflicts.
* Start Decl:: Specifying the start symbol.
* Pure Decl:: Requesting a reentrant parser.
* Decl Summary:: Table of all Bison declarations.
File: bison.info, Node: Token Decl, Next: Precedence Decl, Prev: Declarations, Up: Declarations
Token Type Names
----------------
The basic way to declare a token type name (terminal symbol) is as
follows:
%token NAME
Bison will convert this into a `#define' directive in the parser,
so that the function `yylex' (if it is in this file) can use the name
NAME to stand for this token type's code.
Alternatively you can use `%left', `%right', or `%nonassoc' instead
of `%token', if you wish to specify precedence. *Note Precedence
Decl::.
You can explicitly specify the numeric code for a token type by
appending an integer value in the field immediately following the
token name:
%token NUM 300
It is generally best, however, to let Bison choose the numeric codes
for all token types. Bison will automatically select codes that don't
conflict with each other or with ASCII characters.
In the event that the stack type is a union, you must augment the
`%token' or other token declaration to include the data type
alternative delimited by angle-brackets (*note Multiple Types::.).
For example:
%union { /* define stack type */
double val;
symrec *tptr;
}
%token <val> NUM /* define token NUM and its type */
File: bison.info, Node: Precedence Decl, Next: Union Decl, Prev: Token Decl, Up: Declarations
Operator Precedence
-------------------
Use the `%left', `%right' or `%nonassoc' declaration to declare a
token and specify its precedence and associativity, all at once.
These are called "precedence declarations". *Note Precedence::, for
general information on operator precedence.
The syntax of a precedence declaration is the same as that of
`%token': either
%left SYMBOLS...
or
%left <TYPE> SYMBOLS...
And indeed any of these declarations serves the purposes of
`%token'. But in addition, they specify the associativity and
relative precedence for all the SYMBOLS:
* The associativity of an operator OP determines how repeated uses
of the operator nest: whether `X OP Y OP Z' is parsed by grouping
X with Y first or by grouping Y with Z first. `%left' specifies
left-associativity (grouping X with Y first) and `%right'
specifies right-associativity (grouping Y with Z first).
`%nonassoc' specifies no associativity, which means that `X OP Y
OP Z' is considered a syntax error.
* The precedence of an operator determines how it nests with other
operators. All the tokens declared in a single precedence
declaration have equal precedence and nest together according to
their associativity. When two tokens declared in different
precedence declarations associate, the one declared later has the
higher precedence and is grouped first.
File: bison.info, Node: Union Decl, Next: Type Decl, Prev: Precedence Decl, Up: Declarations
The Collection of Value Types
-----------------------------
The `%union' declaration specifies the entire collection of possible
data types for semantic values. The keyword `%union' is followed by a
pair of braces containing the same thing that goes inside a `union' in
C.
For example:
%union {
double val;
symrec *tptr;
}
This says that the two alternative types are `double' and `symrec *'.
They are given names `val' and `tptr'; these names are used in the
`%token' and `%type' declarations to pick one of the types for a
terminal or nonterminal symbol (*note Type Decl::.).
Note that, unlike making a `union' declaration in C, you do not
write a semicolon after the closing brace.
|