ref: c116550e6a41572796e4db65e4f6acbcb3d9d6f8
dir: /man/1/yacc/
.TH YACC 1
.SH NAME
yacc \- yet another compiler-compiler (Limbo version)
.SH SYNOPSIS
.B yacc
[
.I option ...
]
.I grammar
.SH DESCRIPTION
.I Yacc
converts a context-free grammar and translation code
into a set of
tables for an LR(1) parser and translator.
The grammar may be ambiguous;
specified precedence rules are used to break ambiguities.
.PP
The output from
.I yacc
is a Limbo module
.B y.tab.b
containing the parse function
.B yyparse
which must be provided with a
.B YYLEX
adt providing the parser access to a lexical analyser
routine
.BR lex() ,
an error routine
.BR error() ,
and any other context required.
.PP
The options are
.TP "\w'\fL-o \fIoutput\fLXX'u"
.BI -o " output
Direct output to the specified file instead of
.BR y.tab.b .
.TP
.BI -D n
Create file
.BR y.debug ,
containing diagnostic messages.
To incorporate them in the parser, give an
.I n
greater than zero.
The amount of
diagnostic output from the parser is regulated by
value
.IR n :
.RS
.TP
1
Report errors.
.TP
2
Also report reductions.
.TP
3
Also report the name of each token returned by
.LR yylex .
.RE
.TP
.B -v
Create file
.BR y.output ,
containing a description of the parsing tables and of
conflicts arising from ambiguities in the grammar.
.TP
.B -d
Create file
.BR y.tab.m ,
containing the module
declaration for the parser, along with
definitions of the constants
that associate
.IR yacc -assigned
`token codes' with user-declared `token names'.
Include it in source files other than
.B y.tab.b
to give access to the token codes and the parser module.
.TP
.BI -s " stem
Change the prefix
.L y
of the file names
.BR y.tab.b ,
.BR y.tab.m ,
.BR y.debug ,
and
.B y.output
to
.IR stem .
.TP
.B -m
Normally
.I yacc
defines the type of the
.B y.tab.b
module within the text of the module according
to the contents of the
.B %module
directive.
Giving the
.B -m
option suppresses this behaviour, leaving the implementation
free to define the module's type from an external
.B .m
file. The module's type name is still taken from the
.B %module
directive.
.TP
.BI -n " size
Specify the initial
.I size
of the token stack created for the
parser (default: 200).
.SS Differences from C yacc
The Limbo
.I yacc
is in many respects identical to the C
.IR yacc .
The differences are summarised below:
.PP
Comments follow the Limbo convention (a
.B #
symbol gives a comment until the end of the line).
.PP
A
.B %module
directive is required, which replaces the
.B %union
directive. It is of the form:
.RS
.IP
.B %module
.I modname
.B {
.br
.I module types, functions and constants
.br
.B }
.RE
.B Modname
will be the module's implementation type;
the body of the directive, augmented with
.B con
definitions for the
.IR yacc -assigned
token codes, gives the type of the module,
unless the
.B -m
option is given, in which case no module
definition is emitted.
.PP
A type
.B YYSTYPE
must be defined, giving the type
associated with
.I yacc
tokens. If
the angle bracket construction is used after
any of the
.BR %token ,
.BR %left ,
.BR %right ,
.BR %nonassoc
or
.B %type
directives in order to associate a type with a token or production,
the word inside the angle brackets
refers to a member of
an instance of
.BR YYSTYPE ,
which should be an adt.
.PP
An adt
.B YYLEX
must be defined, providing context to the parser.
The definition must consist of at least the following:
.EX
YYLEX: adt {
lval: YYSTYPE;
lex: fn(l: self ref YYLEX): int;
error: fn(l: self ref YYLEX, msg: string);
}
.EE
.B Lex
should invoke a lexical analyser to return the
next token for
.I yacc
to analyse. The value of the token should
be left in
.BR lval .
.B Error
will be called when a parse error occurs.
.B Msg
is a string describing the error.
.PP
.B Yyparse
takes one argument, a reference to the
.B YYLEX
adt that will be used to provide it with tokens.
.PP
The parser is fully re-entrant;
.I i.e.
it does not
hold any parse state in any global variables
within the module.
.SH EXAMPLE
The following is a small but complete example of the
use of Limbo
.I yacc
to build a simple calculator.
.EX
%{
include "sys.m";
sys: Sys;
include "bufio.m";
bufio: Bufio;
Iobuf: import bufio;
include "draw.m";
YYSTYPE: adt { v: real; };
YYLEX: adt {
lval: YYSTYPE;
lex: fn(l: self ref YYLEX): int;
error: fn(l: self ref YYLEX, msg: string);
};
%}
%module Calc{
init: fn(ctxt: ref Draw->Context, args: list of string);
}
%left '+' '-'
%left '*' '/'
%type <v> exp uexp term
%token <v> REAL
%%
top :
| top '\en'
| top exp '\en'
{
sys->print("%g\en", $2);
}
| top error '\en'
;
exp : uexp
| exp '*' exp { $$ = $1 * $3; }
| exp '/' exp { $$ = $1 / $3; }
| exp '+' exp { $$ = $1 + $3; }
| exp '-' exp { $$ = $1 - $3; }
;
uexp : term
| '+' uexp { $$ = $2; }
| '-' uexp { $$ = -$2; }
;
term : REAL
| '(' exp ')'
{
$$ = $2;
}
;
%%
in: ref Iobuf;
stderr: ref Sys->FD;
init(nil: ref Draw->Context, nil: list of string)
{
sys = load Sys Sys->PATH;
bufio = load Bufio Bufio->PATH;
in = bufio->fopen(sys->fildes(0), Bufio->OREAD);
stderr = sys->fildes(2);
lex := ref YYLEX;
yyparse(lex);
}
YYLEX.error(nil: self ref YYLEX, err: string)
{
sys->fprint(stderr, "%s\en", err);
}
YYLEX.lex(lex: self ref YYLEX): int
{
for(;;){
c := in.getc();
case c{
' ' or '\et' =>
;
'-' or '+' or '*' or '/' or '\en' or '(' or ')' =>
return c;
'0' to '9' or '.' =>
s := "";
i := 0;
s[i++] = c;
while((c = in.getc()) >= '0' && c <= '9' ||
c == '.' ||
c == 'e' || c == 'E')
s[i++] = c;
in.ungetc();
lex.lval.v = real s;
return REAL;
* =>
return -1;
}
}
}
.EE
.SH FILES
.TF /lib/yaccpar
.TP
.B y.output
.TP
.B y.tab.b
.TP
.B y.tab.m
.TP
.B y.debug
.TP
.B /lib/yaccpar
parser prototype
.SH SOURCE
.B /appl/cmd/yacc.b
.SH "SEE ALSO"
S. C. Johnson and R. Sethi,
``Yacc: A parser generator'',
.I
Unix Research System Programmer's Manual,
Tenth Edition, Volume 2
.br
B. W. Kernighan and Rob Pike,
.I
The UNIX Programming Environment,
Prentice Hall, 1984
.SH BUGS
The parser may not have full information when it writes to
.B y.debug
so that the names of the tokens returned by
.L yylex
may be missing.