freebsd-nq/usr.bin/lex/parse.y

818 lines
16 KiB
Plaintext
Raw Normal View History

/* parse.y - parser for flex input */
%token CHAR NUMBER SECTEND SCDECL XSCDECL WHITESPACE NAME PREVCCL EOF_OP
%{
/*-
* Copyright (c) 1990 The Regents of the University of California.
* All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* Vern Paxson.
*
* The United States Government has rights in this work pursuant
* to contract no. DE-AC03-76SF00098 between the United States
* Department of Energy and the University of California.
*
* Redistribution and use in source and binary forms are permitted provided
* that: (1) source distributions retain this entire copyright notice and
* comment, and (2) distributions including binaries display the following
* acknowledgement: ``This product includes software developed by the
* University of California, Berkeley and its contributors'' in the
* documentation or other materials provided with the distribution and in
* all advertising materials mentioning features or use of this software.
* Neither the name of the University nor the names of its contributors may
* be used to endorse or promote products derived from this software without
* specific prior written permission.
* THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
*/
/* $Header: /home/daffy/u0/vern/flex/RCS/parse.y,v 2.15 93/12/09 13:57:23 vern Exp $ */
/* Some versions of bison are broken in that they use alloca() but don't
* declare it properly. The following is the patented (just kidding!)
* #ifdef chud to fix the problem, courtesy of Francois Pinard.
*/
#ifdef YYBISON
/* AIX requires this to be the first thing in the file. */
#ifdef __GNUC__
#define alloca __builtin_alloca
#else /* not __GNUC__ */
#if HAVE_ALLOCA_H
#include <alloca.h>
#else /* not HAVE_ALLOCA_H */
#ifdef _AIX
#pragma alloca
#else /* not _AIX */
char *alloca ();
#endif /* not _AIX */
#endif /* not HAVE_ALLOCA_H */
#endif /* not __GNUC__ */
#endif /* YYBISON */
/* Bletch, ^^^^ that was ugly! */
#include "flexdef.h"
int pat, scnum, eps, headcnt, trailcnt, anyccl, lastchar, i, actvp, rulelen;
int trlcontxt, xcluflg, cclsorted, varlength, variable_trail_rule;
int *active_ss;
Char clower();
void build_eof_action();
void yyerror();
static int madeany = false; /* whether we've made the '.' character class */
int previous_continued_action; /* whether the previous rule's action was '|' */
/* On some over-ambitious machines, such as DEC Alpha's, the default
* token type is "long" instead of "int"; this leads to problems with
* declaring yylval in flexdef.h. But so far, all the yacc's I've seen
* wrap their definitions of YYSTYPE with "#ifndef YYSTYPE"'s, so the
* following should ensure that the default token type is "int".
*/
#define YYSTYPE int
%}
%%
goal : initlex sect1 sect1end sect2 initforrule
{ /* add default rule */
int def_rule;
pat = cclinit();
cclnegate( pat );
def_rule = mkstate( -pat );
/* Remember the number of the default rule so we
* don't generate "can't match" warnings for it.
*/
default_rule = num_rules;
finish_rule( def_rule, false, 0, 0 );
for ( i = 1; i <= lastsc; ++i )
scset[i] = mkbranch( scset[i], def_rule );
if ( spprdflt )
add_action(
"YY_FATAL_ERROR( \"flex scanner jammed\" )" );
else
add_action( "ECHO" );
add_action( ";\n\tYY_BREAK\n" );
}
;
initlex :
{ /* initialize for processing rules */
/* Create default DFA start condition. */
scinstal( "INITIAL", false );
/* Initially, the start condition scoping is
* "no start conditions active".
*/
actvp = 0;
}
;
sect1 : sect1 startconddecl WHITESPACE namelist1 '\n'
|
| error '\n'
{ synerr( "unknown error processing section 1" ); }
;
sect1end : SECTEND
{
/* We now know how many start conditions there
* are, so create the "activity" map indicating
* which conditions are active.
*/
active_ss = allocate_integer_array( lastsc + 1 );
for ( i = 1; i <= lastsc; ++i )
active_ss[i] = 0;
}
;
startconddecl : SCDECL
{ xcluflg = false; }
| XSCDECL
{ xcluflg = true; }
;
namelist1 : namelist1 WHITESPACE NAME
{ scinstal( nmstr, xcluflg ); }
| NAME
{ scinstal( nmstr, xcluflg ); }
| error
{ synerr( "bad start condition list" ); }
;
sect2 : sect2 initforrule flexrule '\n'
|
;
initforrule :
{
/* Initialize for a parse of one rule. */
trlcontxt = variable_trail_rule = varlength = false;
trailcnt = headcnt = rulelen = 0;
current_state_type = STATE_NORMAL;
previous_continued_action = continued_action;
new_rule();
}
;
flexrule : scon '^' rule
{
pat = $3;
finish_rule( pat, variable_trail_rule,
headcnt, trailcnt );
for ( i = 1; i <= actvp; ++i )
scbol[actvsc[i]] =
mkbranch( scbol[actvsc[i]], pat );
if ( ! bol_needed )
{
bol_needed = true;
if ( performance_report > 1 )
pinpoint_message(
"'^' operator results in sub-optimal performance" );
}
}
| scon rule
{
pat = $2;
finish_rule( pat, variable_trail_rule,
headcnt, trailcnt );
for ( i = 1; i <= actvp; ++i )
scset[actvsc[i]] =
mkbranch( scset[actvsc[i]], pat );
}
| '^' rule
{
pat = $2;
finish_rule( pat, variable_trail_rule,
headcnt, trailcnt );
/* Add to all non-exclusive start conditions,
* including the default (0) start condition.
*/
for ( i = 1; i <= lastsc; ++i )
if ( ! scxclu[i] )
scbol[i] = mkbranch( scbol[i], pat );
if ( ! bol_needed )
{
bol_needed = true;
if ( performance_report > 1 )
pinpoint_message(
"'^' operator results in sub-optimal performance" );
}
}
| rule
{
pat = $1;
finish_rule( pat, variable_trail_rule,
headcnt, trailcnt );
for ( i = 1; i <= lastsc; ++i )
if ( ! scxclu[i] )
scset[i] = mkbranch( scset[i], pat );
}
| scon EOF_OP
{ build_eof_action(); }
| EOF_OP
{
/* This EOF applies to all start conditions
* which don't already have EOF actions.
*/
actvp = 0;
for ( i = 1; i <= lastsc; ++i )
if ( ! sceof[i] )
actvsc[++actvp] = i;
if ( actvp == 0 )
warn(
"all start conditions already have <<EOF>> rules" );
else
build_eof_action();
}
| error
{ synerr( "unrecognized rule" ); }
;
scon : '<' namelist2 '>'
| '<' '*' '>'
{
actvp = 0;
for ( i = 1; i <= lastsc; ++i )
actvsc[++actvp] = i;
}
;
namelist2 : namelist2 ',' sconname
| { actvp = 0; } sconname
| error
{ synerr( "bad start condition list" ); }
;
sconname : NAME
{
if ( (scnum = sclookup( nmstr )) == 0 )
format_pinpoint_message(
"undeclared start condition %s",
nmstr );
else
{
if ( ++actvp >= current_max_scs )
/* Some bozo has included multiple
* instances of start condition names.
*/
pinpoint_message(
"too many start conditions in <> construct!" );
else
actvsc[actvp] = scnum;
}
}
;
rule : re2 re
{
if ( transchar[lastst[$2]] != SYM_EPSILON )
/* Provide final transition \now/ so it
* will be marked as a trailing context
* state.
*/
$2 = link_machines( $2,
mkstate( SYM_EPSILON ) );
mark_beginning_as_normal( $2 );
current_state_type = STATE_NORMAL;
if ( previous_continued_action )
{
/* We need to treat this as variable trailing
* context so that the backup does not happen
* in the action but before the action switch
* statement. If the backup happens in the
* action, then the rules "falling into" this
* one's action will *also* do the backup,
* erroneously.
*/
if ( ! varlength || headcnt != 0 )
warn(
"trailing context made variable due to preceding '|' action" );
/* Mark as variable. */
varlength = true;
headcnt = 0;
}
if ( lex_compat || (varlength && headcnt == 0) )
{ /* variable trailing context rule */
/* Mark the first part of the rule as the
* accepting "head" part of a trailing
* context rule.
*
* By the way, we didn't do this at the
* beginning of this production because back
* then current_state_type was set up for a
* trail rule, and add_accept() can create
* a new state ...
*/
add_accept( $1,
num_rules | YY_TRAILING_HEAD_MASK );
variable_trail_rule = true;
}
else
trailcnt = rulelen;
$$ = link_machines( $1, $2 );
}
| re2 re '$'
{ synerr( "trailing context used twice" ); }
| re '$'
{
headcnt = 0;
trailcnt = 1;
rulelen = 1;
varlength = false;
current_state_type = STATE_TRAILING_CONTEXT;
if ( trlcontxt )
{
synerr( "trailing context used twice" );
$$ = mkstate( SYM_EPSILON );
}
else if ( previous_continued_action )
{
/* See the comment in the rule for "re2 re"
* above.
*/
warn(
"trailing context made variable due to preceding '|' action" );
varlength = true;
}
if ( lex_compat || varlength )
{
/* Again, see the comment in the rule for
* "re2 re" above.
*/
add_accept( $1,
num_rules | YY_TRAILING_HEAD_MASK );
variable_trail_rule = true;
}
trlcontxt = true;
eps = mkstate( SYM_EPSILON );
$$ = link_machines( $1,
link_machines( eps, mkstate( '\n' ) ) );
}
| re
{
$$ = $1;
if ( trlcontxt )
{
if ( lex_compat || (varlength && headcnt == 0) )
/* Both head and trail are
* variable-length.
*/
variable_trail_rule = true;
else
trailcnt = rulelen;
}
}
;
re : re '|' series
{
varlength = true;
$$ = mkor( $1, $3 );
}
| series
{ $$ = $1; }
;
re2 : re '/'
{
/* This rule is written separately so the
* reduction will occur before the trailing
* series is parsed.
*/
if ( trlcontxt )
synerr( "trailing context used twice" );
else
trlcontxt = true;
if ( varlength )
/* We hope the trailing context is
* fixed-length.
*/
varlength = false;
else
headcnt = rulelen;
rulelen = 0;
current_state_type = STATE_TRAILING_CONTEXT;
$$ = $1;
}
;
series : series singleton
{
/* This is where concatenation of adjacent patterns
* gets done.
*/
$$ = link_machines( $1, $2 );
}
| singleton
{ $$ = $1; }
;
singleton : singleton '*'
{
varlength = true;
$$ = mkclos( $1 );
}
| singleton '+'
{
varlength = true;
$$ = mkposcl( $1 );
}
| singleton '?'
{
varlength = true;
$$ = mkopt( $1 );
}
| singleton '{' NUMBER ',' NUMBER '}'
{
varlength = true;
if ( $3 > $5 || $3 < 0 )
{
synerr( "bad iteration values" );
$$ = $1;
}
else
{
if ( $3 == 0 )
{
if ( $5 <= 0 )
{
synerr(
"bad iteration values" );
$$ = $1;
}
else
$$ = mkopt(
mkrep( $1, 1, $5 ) );
}
else
$$ = mkrep( $1, $3, $5 );
}
}
| singleton '{' NUMBER ',' '}'
{
varlength = true;
if ( $3 <= 0 )
{
synerr( "iteration value must be positive" );
$$ = $1;
}
else
$$ = mkrep( $1, $3, INFINITY );
}
| singleton '{' NUMBER '}'
{
/* The singleton could be something like "(foo)",
* in which case we have no idea what its length
* is, so we punt here.
*/
varlength = true;
if ( $3 <= 0 )
{
synerr( "iteration value must be positive" );
$$ = $1;
}
else
$$ = link_machines( $1,
copysingl( $1, $3 - 1 ) );
}
| '.'
{
if ( ! madeany )
{
/* Create the '.' character class. */
anyccl = cclinit();
ccladd( anyccl, '\n' );
cclnegate( anyccl );
if ( useecs )
mkeccl( ccltbl + cclmap[anyccl],
ccllen[anyccl], nextecm,
ecgroup, csize, csize );
madeany = true;
}
++rulelen;
$$ = mkstate( -anyccl );
}
| fullccl
{
if ( ! cclsorted )
/* Sort characters for fast searching. We
* use a shell sort since this list could
* be large.
*/
cshell( ccltbl + cclmap[$1], ccllen[$1], true );
if ( useecs )
mkeccl( ccltbl + cclmap[$1], ccllen[$1],
nextecm, ecgroup, csize, csize );
++rulelen;
$$ = mkstate( -$1 );
}
| PREVCCL
{
++rulelen;
$$ = mkstate( -$1 );
}
| '"' string '"'
{ $$ = $2; }
| '(' re ')'
{ $$ = $2; }
| CHAR
{
++rulelen;
if ( caseins && $1 >= 'A' && $1 <= 'Z' )
$1 = clower( $1 );
$$ = mkstate( $1 );
}
;
fullccl : '[' ccl ']'
{ $$ = $2; }
| '[' '^' ccl ']'
{
cclnegate( $3 );
$$ = $3;
}
;
ccl : ccl CHAR '-' CHAR
{
if ( caseins )
{
if ( $2 >= 'A' && $2 <= 'Z' )
$2 = clower( $2 );
if ( $4 >= 'A' && $4 <= 'Z' )
$4 = clower( $4 );
}
if ( $2 > $4 )
synerr( "negative range in character class" );
else
{
for ( i = $2; i <= $4; ++i )
ccladd( $1, i );
/* Keep track if this ccl is staying in
* alphabetical order.
*/
cclsorted = cclsorted && ($2 > lastchar);
lastchar = $4;
}
$$ = $1;
}
| ccl CHAR
{
if ( caseins && $2 >= 'A' && $2 <= 'Z' )
$2 = clower( $2 );
ccladd( $1, $2 );
cclsorted = cclsorted && ($2 > lastchar);
lastchar = $2;
$$ = $1;
}
|
{
cclsorted = true;
lastchar = 0;
$$ = cclinit();
}
;
string : string CHAR
{
if ( caseins && $2 >= 'A' && $2 <= 'Z' )
$2 = clower( $2 );
++rulelen;
$$ = link_machines( $1, mkstate( $2 ) );
}
|
{ $$ = mkstate( SYM_EPSILON ); }
;
%%
/* build_eof_action - build the "<<EOF>>" action for the active start
* conditions
*/
void build_eof_action()
{
register int i;
char action_text[MAXLINE];
for ( i = 1; i <= actvp; ++i )
{
if ( sceof[actvsc[i]] )
format_pinpoint_message(
"multiple <<EOF>> rules for start condition %s",
scname[actvsc[i]] );
else
{
sceof[actvsc[i]] = true;
sprintf( action_text, "case YY_STATE_EOF(%s):\n",
scname[actvsc[i]] );
add_action( action_text );
}
}
line_directive_out( (FILE *) 0 );
/* This isn't a normal rule after all - don't count it as
* such, so we don't have any holes in the rule numbering
* (which make generating "rule can never match" warnings
* more difficult.
*/
--num_rules;
++num_eof_rules;
}
/* format_synerr - write out formatted syntax error */
void format_synerr( msg, arg )
char msg[], arg[];
{
char errmsg[MAXLINE];
(void) sprintf( errmsg, msg, arg );
synerr( errmsg );
}
/* synerr - report a syntax error */
void synerr( str )
char str[];
{
syntaxerror = true;
pinpoint_message( str );
}
/* warn - report a warning, unless -w was given */
void warn( str )
char str[];
{
line_warning( str, linenum );
}
/* format_pinpoint_message - write out a message formatted with one string,
* pinpointing its location
*/
void format_pinpoint_message( msg, arg )
char msg[], arg[];
{
char errmsg[MAXLINE];
(void) sprintf( errmsg, msg, arg );
pinpoint_message( errmsg );
}
/* pinpoint_message - write out a message, pinpointing its location */
void pinpoint_message( str )
char str[];
{
line_pinpoint( str, linenum );
}
/* line_warning - report a warning at a given line, unless -w was given */
void line_warning( str, line )
char str[];
int line;
{
char warning[MAXLINE];
if ( ! nowarn )
{
sprintf( warning, "warning, %s", str );
line_pinpoint( warning, line );
}
}
/* line_pinpoint - write out a message, pinpointing it at the given line */
void line_pinpoint( str, line )
char str[];
int line;
{
fprintf( stderr, "\"%s\", line %d: %s\n", infilename, line, str );
}
/* yyerror - eat up an error message from the parser;
* currently, messages are ignore
*/
void yyerror( msg )
char msg[];
{
}