/* A Bison parser, made by GNU Bison 2.3. */ /* Skeleton implementation for Bison GLR parsers in C Copyright (C) 2002, 2003, 2004, 2005, 2006 Free Software Foundation, Inc. This program 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, or (at your option) any later version. This program 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ /* As a special exception, you may create a larger work that contains part or all of the Bison parser skeleton and distribute that work under terms of your choice, so long as that work isn't itself a parser generator using the skeleton or a modified version thereof as a parser skeleton. Alternatively, if you modify or redistribute the parser skeleton itself, you may (at your option) remove this special exception, which will cause the skeleton and the resulting Bison output files to be licensed under the GNU General Public License without this special exception. This special exception was added by the Free Software Foundation in version 2.2 of Bison. */ /* C GLR parser skeleton written by Paul Hilfinger. */ /* Identify Bison output. */ #define YYBISON 1 /* Bison version. */ #define YYBISON_VERSION "2.3" /* Skeleton name. */ #define YYSKELETON_NAME "glr.c" /* Pure parsers. */ #define YYPURE 0 /* Using locations. */ #define YYLSP_NEEDED 1 /* Copy the first part of user declarations. */ #line 1 "glr-regr14.y" #ifdef HAVE_CONFIG_H # include /* We don't need perfect functions for these tests. */ # undef malloc # undef memcmp # undef realloc #endif #if ! defined YYSTYPE && ! defined YYSTYPE_IS_DECLARED typedef union #line 31 "glr-regr14.y" { char value; } /* Line 204 of glr.c. */ #line 77 "glr-regr14.c" YYSTYPE; # define YYSTYPE_IS_DECLARED 1 # define YYSTYPE_IS_TRIVIAL 1 #endif #if ! defined YYLTYPE && ! defined YYLTYPE_IS_DECLARED typedef struct YYLTYPE { int first_line; int first_column; int last_line; int last_column; } YYLTYPE; # define YYLTYPE_IS_DECLARED 1 # define YYLTYPE_IS_TRIVIAL 1 #endif /* Enabling traces. */ #ifndef YYDEBUG # define YYDEBUG 0 #endif /* Enabling verbose error messages. */ #ifdef YYERROR_VERBOSE # undef YYERROR_VERBOSE # define YYERROR_VERBOSE 1 #else # define YYERROR_VERBOSE 0 #endif /* Enabling the token table. */ #ifndef YYTOKEN_TABLE # define YYTOKEN_TABLE 0 #endif /* Default (constant) value used for initialization for null right-hand sides. Unlike the standard yacc.c template, here we set the default value of $$ to a zeroed-out value. Since the default value is undefined, this behavior is technically correct. */ static YYSTYPE yyval_default; /* Copy the second part of user declarations. */ #line 33 "glr-regr14.y" #include static void yyerror (char const *); static int yylex (void); static void print_look_ahead (char const *); static char merge (union YYSTYPE, union YYSTYPE); #define USE(value) /* Line 234 of glr.c. */ #line 135 "glr-regr14.c" #include #include #include #include #ifndef YY_ # if YYENABLE_NLS # if ENABLE_NLS # include /* INFRINGES ON USER NAME SPACE */ # define YY_(msgid) dgettext ("bison-runtime", msgid) # endif # endif # ifndef YY_ # define YY_(msgid) msgid # endif #endif /* Suppress unused-variable warnings by "using" E. */ #if ! defined lint || defined __GNUC__ # define YYUSE(e) ((void) (e)) #else # define YYUSE(e) /* empty */ #endif /* Identity function, used to suppress warnings about constant conditions. */ #ifndef lint # define YYID(n) (n) #else #if (defined __STDC__ || defined __C99__FUNC__ \ || defined __cplusplus || defined _MSC_VER) static int YYID (int i) #else static int YYID (i) int i; #endif { return i; } #endif #ifndef YYFREE # define YYFREE free #endif #ifndef YYMALLOC # define YYMALLOC malloc #endif #ifndef YYREALLOC # define YYREALLOC realloc #endif #define YYSIZEMAX ((size_t) -1) #ifdef __cplusplus typedef bool yybool; #else typedef unsigned char yybool; #endif #define yytrue 1 #define yyfalse 0 #ifndef YYSETJMP # include # define YYJMP_BUF jmp_buf # define YYSETJMP(env) setjmp (env) # define YYLONGJMP(env, val) longjmp (env, val) #endif /*-----------------. | GCC extensions. | `-----------------*/ #ifndef __attribute__ /* This feature is available in gcc versions 2.5 and later. */ # if (! defined __GNUC__ || __GNUC__ < 2 \ || (__GNUC__ == 2 && __GNUC_MINOR__ < 5) || __STRICT_ANSI__) # define __attribute__(Spec) /* empty */ # endif #endif #define YYOPTIONAL_LOC(Name) Name #ifndef YYASSERT # define YYASSERT(condition) ((void) ((condition) || (abort (), 0))) #endif /* YYFINAL -- State number of the termination state. */ #define YYFINAL 5 /* YYLAST -- Last index in YYTABLE. */ #define YYLAST 15 /* YYNTOKENS -- Number of terminals. */ #define YYNTOKENS 7 /* YYNNTS -- Number of nonterminals. */ #define YYNNTS 13 /* YYNRULES -- Number of rules. */ #define YYNRULES 18 /* YYNRULES -- Number of states. */ #define YYNSTATES 25 /* YYMAXRHS -- Maximum number of symbols on right-hand side of rule. */ #define YYMAXRHS 6 /* YYMAXLEFT -- Maximum number of symbols to the left of a handle accessed by $0, $-1, etc., in any rule. */ #define YYMAXLEFT 0 /* YYTRANSLATE(X) -- Bison symbol number corresponding to X. */ #define YYUNDEFTOK 2 #define YYMAXUTOK 257 #define YYTRANSLATE(YYX) \ ((YYX <= 0) ? YYEOF : \ (unsigned int) (YYX) <= YYMAXUTOK ? yytranslate[YYX] : YYUNDEFTOK) /* YYTRANSLATE[YYLEX] -- Bison symbol number corresponding to YYLEX. */ static const unsigned char yytranslate[] = { 0, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 3, 4, 5, 6, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 1, 2 }; #if YYDEBUG /* YYPRHS[YYN] -- Index of the first RHS symbol of rule number YYN in YYRHS. */ static const unsigned char yyprhs[] = { 0, 0, 3, 7, 12, 19, 20, 21, 23, 24, 25, 26, 27, 30, 33, 36, 39, 42, 45 }; /* YYRHS -- A `-1'-separated list of the rules' RHS. */ static const signed char yyrhs[] = { 8, 0, -1, 9, 5, 15, -1, 10, 3, 4, 11, -1, 12, 13, 3, 11, 4, 14, -1, -1, -1, 3, -1, -1, -1, -1, -1, 16, 15, -1, 17, 15, -1, 18, 15, -1, 6, 19, -1, 6, 19, -1, 6, 19, -1, -1 }; /* YYRLINE[YYN] -- source line where rule number YYN was defined. */ static const unsigned char yyrline[] = { 0, 49, 49, 57, 61, 69, 74, 77, 83, 88, 95, 101, 102, 103, 104, 107, 116, 125, 134 }; #endif #if YYDEBUG || YYERROR_VERBOSE || YYTOKEN_TABLE /* YYTNAME[SYMBOL-NUM] -- String name of the symbol SYMBOL-NUM. First, the terminals, then, starting at YYNTOKENS, nonterminals. */ static const char *const yytname[] = { "$end", "error", "$undefined", "'a'", "'b'", "'c'", "'d'", "$accept", "start", "merge", "nonconflict1", "nonconflict2", "conflict", "defstate_look", "defstate_shift", "stack_explosion", "alt1", "alt2", "alt3", "no_look", 0 }; #endif /* YYR1[YYN] -- Symbol number of symbol that rule YYN derives. */ static const unsigned char yyr1[] = { 0, 7, 8, 9, 9, 10, 11, 11, 12, 13, 14, 15, 15, 15, 15, 16, 17, 18, 19 }; /* YYR2[YYN] -- Number of symbols composing right hand side of rule YYN. */ static const unsigned char yyr2[] = { 0, 2, 3, 4, 6, 0, 0, 1, 0, 0, 0, 0, 2, 2, 2, 2, 2, 2, 0 }; /* YYDPREC[RULE-NUM] -- Dynamic precedence of rule #RULE-NUM (0 if none). */ static const unsigned char yydprec[] = { 0, 0, 0, 1, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; /* YYMERGER[RULE-NUM] -- Index of merging function for rule #RULE-NUM. */ static const unsigned char yymerger[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 0, 0, 0, 0 }; /* YYDEFACT[S] -- default rule to reduce with in state S when YYTABLE doesn't specify something else to do. Zero means the default is an error. */ static const unsigned char yydefact[] = { 5, 0, 0, 0, 9, 1, 11, 0, 0, 18, 2, 11, 11, 11, 6, 6, 15, 12, 13, 14, 7, 3, 0, 10, 4 }; /* YYPDEFGOTO[NTERM-NUM]. */ static const signed char yydefgoto[] = { -1, 1, 2, 3, 21, 4, 8, 24, 10, 11, 12, 13, 16 }; /* YYPACT[STATE-NUM] -- Index in YYTABLE of the portion describing STATE-NUM. */ #define YYPACT_NINF -11 static const signed char yypact[] = { 1, 5, 2, 6, -11, -11, 4, 7, 9, -11, -11, 4, 4, 4, 10, 10, 0, -11, -11, -11, -11, -11, 11, -11, -11 }; /* YYPGOTO[NTERM-NUM]. */ static const signed char yypgoto[] = { -11, -11, -11, -11, -7, -11, -11, -11, -10, -11, -11, -11, -11 }; /* YYTABLE[YYPACT[STATE-NUM]]. What to do in state STATE-NUM. If positive, shift that token. If negative, reduce the rule which number is the opposite. If zero, do what YYDEFACT says. If YYTABLE_NINF, syntax error. */ #define YYTABLE_NINF -16 static const signed char yytable[] = { -15, 17, 18, 19, -5, 5, -15, 6, 22, 7, 9, 14, 15, 20, 0, 23 }; /* YYCONFLP[YYPACT[STATE-NUM]] -- Pointer into YYCONFL of start of list of conflicting reductions corresponding to action entry for state STATE-NUM in yytable. 0 means no conflicts. The list in yyconfl is terminated by a rule number of 0. */ static const unsigned char yyconflp[] = { 3, 0, 0, 0, 1, 0, 6, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; /* YYCONFL[I] -- lists of conflicting rule numbers, each terminated by 0, pointed into by YYCONFLP. */ static const short int yyconfl[] = { 0, 8, 0, 16, 17, 0, 16, 17, 0 }; static const signed char yycheck[] = { 0, 11, 12, 13, 3, 0, 6, 5, 15, 3, 6, 4, 3, 3, -1, 4 }; /* YYSTOS[STATE-NUM] -- The (internal number of the) accessing symbol of state STATE-NUM. */ static const unsigned char yystos[] = { 0, 8, 9, 10, 12, 0, 5, 3, 13, 6, 15, 16, 17, 18, 4, 3, 19, 15, 15, 15, 3, 11, 11, 4, 14 }; /* Prevent warning if -Wmissing-prototypes. */ int yyparse (void); /* Error token number */ #define YYTERROR 1 /* YYLLOC_DEFAULT -- Set CURRENT to span from RHS[1] to RHS[N]. If N is 0, then set CURRENT to the empty location which ends the previous symbol: RHS[0] (always defined). */ #define YYRHSLOC(Rhs, K) ((Rhs)[K].yystate.yyloc) #ifndef YYLLOC_DEFAULT # define YYLLOC_DEFAULT(Current, Rhs, N) \ do \ if (YYID (N)) \ { \ (Current).first_line = YYRHSLOC (Rhs, 1).first_line; \ (Current).first_column = YYRHSLOC (Rhs, 1).first_column; \ (Current).last_line = YYRHSLOC (Rhs, N).last_line; \ (Current).last_column = YYRHSLOC (Rhs, N).last_column; \ } \ else \ { \ (Current).first_line = (Current).last_line = \ YYRHSLOC (Rhs, 0).last_line; \ (Current).first_column = (Current).last_column = \ YYRHSLOC (Rhs, 0).last_column; \ } \ while (YYID (0)) /* YY_LOCATION_PRINT -- Print the location on the stream. This macro was not mandated originally: define only if we know we won't break user code: when these are the locations we know. */ # define YY_LOCATION_PRINT(File, Loc) \ fprintf (File, "%d.%d-%d.%d", \ (Loc).first_line, (Loc).first_column, \ (Loc).last_line, (Loc).last_column) #endif #ifndef YY_LOCATION_PRINT # define YY_LOCATION_PRINT(File, Loc) ((void) 0) #endif /* YYLEX -- calling `yylex' with the right arguments. */ #define YYLEX yylex () YYSTYPE yylval; YYLTYPE yylloc; int yynerrs; int yychar; static const int YYEOF = 0; static const int YYEMPTY = -2; typedef enum { yyok, yyaccept, yyabort, yyerr } YYRESULTTAG; #define YYCHK(YYE) \ do { YYRESULTTAG yyflag = YYE; if (yyflag != yyok) return yyflag; } \ while (YYID (0)) #if YYDEBUG # ifndef YYFPRINTF # define YYFPRINTF fprintf # endif # define YYDPRINTF(Args) \ do { \ if (yydebug) \ YYFPRINTF Args; \ } while (YYID (0)) /*--------------------------------. | Print this symbol on YYOUTPUT. | `--------------------------------*/ /*ARGSUSED*/ static void yy_symbol_value_print (FILE *yyoutput, int yytype, YYSTYPE const * const yyvaluep, YYLTYPE const * const yylocationp) { if (!yyvaluep) return; YYUSE (yylocationp); # ifdef YYPRINT if (yytype < YYNTOKENS) YYPRINT (yyoutput, yytoknum[yytype], *yyvaluep); # else YYUSE (yyoutput); # endif switch (yytype) { default: break; } } /*--------------------------------. | Print this symbol on YYOUTPUT. | `--------------------------------*/ static void yy_symbol_print (FILE *yyoutput, int yytype, YYSTYPE const * const yyvaluep, YYLTYPE const * const yylocationp) { if (yytype < YYNTOKENS) YYFPRINTF (yyoutput, "token %s (", yytname[yytype]); else YYFPRINTF (yyoutput, "nterm %s (", yytname[yytype]); YY_LOCATION_PRINT (yyoutput, *yylocationp); YYFPRINTF (yyoutput, ": "); yy_symbol_value_print (yyoutput, yytype, yyvaluep, yylocationp); YYFPRINTF (yyoutput, ")"); } # define YY_SYMBOL_PRINT(Title, Type, Value, Location) \ do { \ if (yydebug) \ { \ YYFPRINTF (stderr, "%s ", Title); \ yy_symbol_print (stderr, Type, \ Value, Location); \ YYFPRINTF (stderr, "\n"); \ } \ } while (YYID (0)) /* Nonzero means print parse trace. It is left uninitialized so that multiple parsers can coexist. */ int yydebug; #else /* !YYDEBUG */ # define YYDPRINTF(Args) # define YY_SYMBOL_PRINT(Title, Type, Value, Location) #endif /* !YYDEBUG */ /* YYINITDEPTH -- initial size of the parser's stacks. */ #ifndef YYINITDEPTH # define YYINITDEPTH 200 #endif /* YYMAXDEPTH -- maximum size the stacks can grow to (effective only if the built-in stack extension method is used). Do not make this value too large; the results are undefined if SIZE_MAX < YYMAXDEPTH * sizeof (GLRStackItem) evaluated with infinite-precision integer arithmetic. */ #ifndef YYMAXDEPTH # define YYMAXDEPTH 10000 #endif /* Minimum number of free items on the stack allowed after an allocation. This is to allow allocation and initialization to be completed by functions that call yyexpandGLRStack before the stack is expanded, thus insuring that all necessary pointers get properly redirected to new data. */ #define YYHEADROOM 2 #ifndef YYSTACKEXPANDABLE # if (! defined __cplusplus \ || (defined YYLTYPE_IS_TRIVIAL && YYLTYPE_IS_TRIVIAL \ && defined YYSTYPE_IS_TRIVIAL && YYSTYPE_IS_TRIVIAL)) # define YYSTACKEXPANDABLE 1 # else # define YYSTACKEXPANDABLE 0 # endif #endif #if YYSTACKEXPANDABLE # define YY_RESERVE_GLRSTACK(Yystack) \ do { \ if (Yystack->yyspaceLeft < YYHEADROOM) \ yyexpandGLRStack (Yystack); \ } while (YYID (0)) #else # define YY_RESERVE_GLRSTACK(Yystack) \ do { \ if (Yystack->yyspaceLeft < YYHEADROOM) \ yyMemoryExhausted (Yystack); \ } while (YYID (0)) #endif #if YYERROR_VERBOSE # ifndef yystpcpy # if defined __GLIBC__ && defined _STRING_H && defined _GNU_SOURCE # define yystpcpy stpcpy # else /* Copy YYSRC to YYDEST, returning the address of the terminating '\0' in YYDEST. */ static char * yystpcpy (char *yydest, const char *yysrc) { char *yyd = yydest; const char *yys = yysrc; while ((*yyd++ = *yys++) != '\0') continue; return yyd - 1; } # endif # endif # ifndef yytnamerr /* Copy to YYRES the contents of YYSTR after stripping away unnecessary quotes and backslashes, so that it's suitable for yyerror. The heuristic is that double-quoting is unnecessary unless the string contains an apostrophe, a comma, or backslash (other than backslash-backslash). YYSTR is taken from yytname. If YYRES is null, do not copy; instead, return the length of what the result would have been. */ static size_t yytnamerr (char *yyres, const char *yystr) { if (*yystr == '"') { size_t yyn = 0; char const *yyp = yystr; for (;;) switch (*++yyp) { case '\'': case ',': goto do_not_strip_quotes; case '\\': if (*++yyp != '\\') goto do_not_strip_quotes; /* Fall through. */ default: if (yyres) yyres[yyn] = *yyp; yyn++; break; case '"': if (yyres) yyres[yyn] = '\0'; return yyn; } do_not_strip_quotes: ; } if (! yyres) return strlen (yystr); return yystpcpy (yyres, yystr) - yyres; } # endif #endif /* !YYERROR_VERBOSE */ /** State numbers, as in LALR(1) machine */ typedef int yyStateNum; /** Rule numbers, as in LALR(1) machine */ typedef int yyRuleNum; /** Grammar symbol */ typedef short int yySymbol; /** Item references, as in LALR(1) machine */ typedef short int yyItemNum; typedef struct yyGLRState yyGLRState; typedef struct yyGLRStateSet yyGLRStateSet; typedef struct yySemanticOption yySemanticOption; typedef union yyGLRStackItem yyGLRStackItem; typedef struct yyGLRStack yyGLRStack; struct yyGLRState { /** Type tag: always true. */ yybool yyisState; /** Type tag for yysemantics. If true, yysval applies, otherwise * yyfirstVal applies. */ yybool yyresolved; /** Number of corresponding LALR(1) machine state. */ yyStateNum yylrState; /** Preceding state in this stack */ yyGLRState* yypred; /** Source position of the first token produced by my symbol */ size_t yyposn; union { /** First in a chain of alternative reductions producing the * non-terminal corresponding to this state, threaded through * yynext. */ yySemanticOption* yyfirstVal; /** Semantic value for this state. */ YYSTYPE yysval; } yysemantics; /** Source location for this state. */ YYLTYPE yyloc; }; struct yyGLRStateSet { yyGLRState** yystates; /** During nondeterministic operation, yylookaheadNeeds tracks which * stacks have actually needed the current lookahead. During deterministic * operation, yylookaheadNeeds[0] is not maintained since it would merely * duplicate yychar != YYEMPTY. */ yybool* yylookaheadNeeds; size_t yysize, yycapacity; }; struct yySemanticOption { /** Type tag: always false. */ yybool yyisState; /** Rule number for this reduction */ yyRuleNum yyrule; /** The last RHS state in the list of states to be reduced. */ yyGLRState* yystate; /** The lookahead for this reduction. */ int yyrawchar; YYSTYPE yyval; YYLTYPE yyloc; /** Next sibling in chain of options. To facilitate merging, * options are chained in decreasing order by address. */ yySemanticOption* yynext; }; /** Type of the items in the GLR stack. The yyisState field * indicates which item of the union is valid. */ union yyGLRStackItem { yyGLRState yystate; yySemanticOption yyoption; }; struct yyGLRStack { int yyerrState; /* To compute the location of the error token. */ yyGLRStackItem yyerror_range[3]; YYJMP_BUF yyexception_buffer; yyGLRStackItem* yyitems; yyGLRStackItem* yynextFree; size_t yyspaceLeft; yyGLRState* yysplitPoint; yyGLRState* yylastDeleted; yyGLRStateSet yytops; }; #if YYSTACKEXPANDABLE static void yyexpandGLRStack (yyGLRStack* yystackp); #endif static void yyFail (yyGLRStack* yystackp, const char* yymsg) __attribute__ ((__noreturn__)); static void yyFail (yyGLRStack* yystackp, const char* yymsg) { if (yymsg != NULL) yyerror (yymsg); YYLONGJMP (yystackp->yyexception_buffer, 1); } static void yyMemoryExhausted (yyGLRStack* yystackp) __attribute__ ((__noreturn__)); static void yyMemoryExhausted (yyGLRStack* yystackp) { YYLONGJMP (yystackp->yyexception_buffer, 2); } #if YYDEBUG || YYERROR_VERBOSE /** A printable representation of TOKEN. */ static inline const char* yytokenName (yySymbol yytoken) { if (yytoken == YYEMPTY) return ""; return yytname[yytoken]; } #endif /** Fill in YYVSP[YYLOW1 .. YYLOW0-1] from the chain of states starting * at YYVSP[YYLOW0].yystate.yypred. Leaves YYVSP[YYLOW1].yystate.yypred * containing the pointer to the next state in the chain. */ static void yyfillin (yyGLRStackItem *, int, int) __attribute__ ((__unused__)); static void yyfillin (yyGLRStackItem *yyvsp, int yylow0, int yylow1) { yyGLRState* s; int i; s = yyvsp[yylow0].yystate.yypred; for (i = yylow0-1; i >= yylow1; i -= 1) { YYASSERT (s->yyresolved); yyvsp[i].yystate.yyresolved = yytrue; yyvsp[i].yystate.yysemantics.yysval = s->yysemantics.yysval; yyvsp[i].yystate.yyloc = s->yyloc; s = yyvsp[i].yystate.yypred = s->yypred; } } /* Do nothing if YYNORMAL or if *YYLOW <= YYLOW1. Otherwise, fill in * YYVSP[YYLOW1 .. *YYLOW-1] as in yyfillin and set *YYLOW = YYLOW1. * For convenience, always return YYLOW1. */ static inline int yyfill (yyGLRStackItem *, int *, int, yybool) __attribute__ ((__unused__)); static inline int yyfill (yyGLRStackItem *yyvsp, int *yylow, int yylow1, yybool yynormal) { if (!yynormal && yylow1 < *yylow) { yyfillin (yyvsp, *yylow, yylow1); *yylow = yylow1; } return yylow1; } /** Perform user action for rule number YYN, with RHS length YYRHSLEN, * and top stack item YYVSP. YYLVALP points to place to put semantic * value ($$), and yylocp points to place for location information * (@$). Returns yyok for normal return, yyaccept for YYACCEPT, * yyerr for YYERROR, yyabort for YYABORT. */ /*ARGSUSED*/ static YYRESULTTAG yyuserAction (yyRuleNum yyn, int yyrhslen, yyGLRStackItem* yyvsp, YYSTYPE* yyvalp, YYLTYPE* YYOPTIONAL_LOC (yylocp), yyGLRStack* yystackp ) { yybool yynormal __attribute__ ((__unused__)) = (yystackp->yysplitPoint == NULL); int yylow; # undef yyerrok # define yyerrok (yystackp->yyerrState = 0) # undef YYACCEPT # define YYACCEPT return yyaccept # undef YYABORT # define YYABORT return yyabort # undef YYERROR # define YYERROR return yyerrok, yyerr # undef YYRECOVERING # define YYRECOVERING() (yystackp->yyerrState != 0) # undef yyclearin # define yyclearin (yychar = YYEMPTY) # undef YYFILL # define YYFILL(N) yyfill (yyvsp, &yylow, N, yynormal) # undef YYBACKUP # define YYBACKUP(Token, Value) \ return yyerror (YY_("syntax error: cannot back up")), \ yyerrok, yyerr yylow = 1; if (yyrhslen == 0) *yyvalp = yyval_default; else *yyvalp = yyvsp[YYFILL (1-yyrhslen)].yystate.yysemantics.yysval; YYLLOC_DEFAULT ((*yylocp), (yyvsp - yyrhslen), yyrhslen); yystackp->yyerror_range[1].yystate.yyloc = *yylocp; switch (yyn) { case 2: #line 49 "glr-regr14.y" { USE ((((yyGLRStackItem const *)yyvsp)[YYFILL ((2) - (3))].yystate.yysemantics.yysval.value)); USE ((((yyGLRStackItem const *)yyvsp)[YYFILL ((3) - (3))].yystate.yysemantics.yysval.value)); print_look_ahead ("start <- merge 'c' stack_explosion"); ;} break; case 3: #line 57 "glr-regr14.y" { USE ((((yyGLRStackItem const *)yyvsp)[YYFILL ((2) - (4))].yystate.yysemantics.yysval.value)); USE ((((yyGLRStackItem const *)yyvsp)[YYFILL ((3) - (4))].yystate.yysemantics.yysval.value)); print_look_ahead ("merge <- nonconflict1 'a' 'b' nonconflict2"); ;} break; case 4: #line 61 "glr-regr14.y" { USE ((((yyGLRStackItem const *)yyvsp)[YYFILL ((3) - (6))].yystate.yysemantics.yysval.value)); USE ((((yyGLRStackItem const *)yyvsp)[YYFILL ((5) - (6))].yystate.yysemantics.yysval.value)); print_look_ahead ("merge <- conflict defstate_look 'a' nonconflict2 'b'" " defstate_shift"); ;} break; case 5: #line 69 "glr-regr14.y" { print_look_ahead ("nonconflict1 <- empty string"); ;} break; case 6: #line 74 "glr-regr14.y" { print_look_ahead ("nonconflict2 <- empty string"); ;} break; case 7: #line 77 "glr-regr14.y" { USE ((((yyGLRStackItem const *)yyvsp)[YYFILL ((1) - (1))].yystate.yysemantics.yysval.value)); print_look_ahead ("nonconflict2 <- 'a'"); ;} break; case 8: #line 83 "glr-regr14.y" { print_look_ahead ("conflict <- empty string"); ;} break; case 9: #line 88 "glr-regr14.y" { print_look_ahead ("defstate_look <- empty string"); ;} break; case 10: #line 95 "glr-regr14.y" { print_look_ahead ("defstate_shift <- empty string"); ;} break; case 11: #line 101 "glr-regr14.y" { ((*yyvalp).value) = '\0'; ;} break; case 12: #line 102 "glr-regr14.y" { ((*yyvalp).value) = (((yyGLRStackItem const *)yyvsp)[YYFILL ((2) - (2))].yystate.yysemantics.yysval.value); ;} break; case 13: #line 103 "glr-regr14.y" { ((*yyvalp).value) = (((yyGLRStackItem const *)yyvsp)[YYFILL ((2) - (2))].yystate.yysemantics.yysval.value); ;} break; case 14: #line 104 "glr-regr14.y" { ((*yyvalp).value) = (((yyGLRStackItem const *)yyvsp)[YYFILL ((2) - (2))].yystate.yysemantics.yysval.value); ;} break; case 15: #line 107 "glr-regr14.y" { USE ((((yyGLRStackItem const *)yyvsp)[YYFILL ((1) - (2))].yystate.yysemantics.yysval.value)); if (yychar != 'd' && yychar != YYEOF) { fprintf (stderr, "Incorrect lookahead during stack explosion.\n"); } ;} break; case 16: #line 116 "glr-regr14.y" { USE ((((yyGLRStackItem const *)yyvsp)[YYFILL ((1) - (2))].yystate.yysemantics.yysval.value)); if (yychar != 'd' && yychar != YYEOF) { fprintf (stderr, "Incorrect lookahead during stack explosion.\n"); } ;} break; case 17: #line 125 "glr-regr14.y" { USE ((((yyGLRStackItem const *)yyvsp)[YYFILL ((1) - (2))].yystate.yysemantics.yysval.value)); if (yychar != 'd' && yychar != YYEOF) { fprintf (stderr, "Incorrect lookahead during stack explosion.\n"); } ;} break; case 18: #line 134 "glr-regr14.y" { if (yychar != YYEMPTY) { fprintf (stderr, "Found lookahead where shouldn't during stack explosion.\n"); } ;} break; /* Line 930 of glr.c. */ #line 1028 "glr-regr14.c" default: break; } return yyok; # undef yyerrok # undef YYABORT # undef YYACCEPT # undef YYERROR # undef YYBACKUP # undef yyclearin # undef YYRECOVERING } /*ARGSUSED*/ static void yyuserMerge (int yyn, YYSTYPE* yy0, YYSTYPE* yy1) { YYUSE (yy0); YYUSE (yy1); switch (yyn) { case 1: yy0->value = merge (*yy0, *yy1); break; default: break; } } /* Bison grammar-table manipulation. */ /*-----------------------------------------------. | Release the memory associated to this symbol. | `-----------------------------------------------*/ /*ARGSUSED*/ static void yydestruct (const char *yymsg, int yytype, YYSTYPE *yyvaluep, YYLTYPE *yylocationp) { YYUSE (yyvaluep); YYUSE (yylocationp); if (!yymsg) yymsg = "Deleting"; YY_SYMBOL_PRINT (yymsg, yytype, yyvaluep, yylocationp); switch (yytype) { default: break; } } /** Number of symbols composing the right hand side of rule #RULE. */ static inline int yyrhsLength (yyRuleNum yyrule) { return yyr2[yyrule]; } static void yydestroyGLRState (char const *yymsg, yyGLRState *yys) { if (yys->yyresolved) yydestruct (yymsg, yystos[yys->yylrState], &yys->yysemantics.yysval, &yys->yyloc); else { #if YYDEBUG if (yydebug) { if (yys->yysemantics.yyfirstVal) YYFPRINTF (stderr, "%s unresolved ", yymsg); else YYFPRINTF (stderr, "%s incomplete ", yymsg); yy_symbol_print (stderr, yystos[yys->yylrState], NULL, &yys->yyloc); YYFPRINTF (stderr, "\n"); } #endif if (yys->yysemantics.yyfirstVal) { yySemanticOption *yyoption = yys->yysemantics.yyfirstVal; yyGLRState *yyrh; int yyn; for (yyrh = yyoption->yystate, yyn = yyrhsLength (yyoption->yyrule); yyn > 0; yyrh = yyrh->yypred, yyn -= 1) yydestroyGLRState (yymsg, yyrh); } } } /** Left-hand-side symbol for rule #RULE. */ static inline yySymbol yylhsNonterm (yyRuleNum yyrule) { return yyr1[yyrule]; } #define yyis_pact_ninf(yystate) \ ((yystate) == YYPACT_NINF) /** True iff LR state STATE has only a default reduction (regardless * of token). */ static inline yybool yyisDefaultedState (yyStateNum yystate) { return yyis_pact_ninf (yypact[yystate]); } /** The default reduction for STATE, assuming it has one. */ static inline yyRuleNum yydefaultAction (yyStateNum yystate) { return yydefact[yystate]; } #define yyis_table_ninf(yytable_value) \ YYID (0) /** Set *YYACTION to the action to take in YYSTATE on seeing YYTOKEN. * Result R means * R < 0: Reduce on rule -R. * R = 0: Error. * R > 0: Shift to state R. * Set *CONFLICTS to a pointer into yyconfl to 0-terminated list of * conflicting reductions. */ static inline void yygetLRActions (yyStateNum yystate, int yytoken, int* yyaction, const short int** yyconflicts) { int yyindex = yypact[yystate] + yytoken; if (yyindex < 0 || YYLAST < yyindex || yycheck[yyindex] != yytoken) { *yyaction = -yydefact[yystate]; *yyconflicts = yyconfl; } else if (! yyis_table_ninf (yytable[yyindex])) { *yyaction = yytable[yyindex]; *yyconflicts = yyconfl + yyconflp[yyindex]; } else { *yyaction = 0; *yyconflicts = yyconfl + yyconflp[yyindex]; } } static inline yyStateNum yyLRgotoState (yyStateNum yystate, yySymbol yylhs) { int yyr; yyr = yypgoto[yylhs - YYNTOKENS] + yystate; if (0 <= yyr && yyr <= YYLAST && yycheck[yyr] == yystate) return yytable[yyr]; else return yydefgoto[yylhs - YYNTOKENS]; } static inline yybool yyisShiftAction (int yyaction) { return 0 < yyaction; } static inline yybool yyisErrorAction (int yyaction) { return yyaction == 0; } /* GLRStates */ /** Return a fresh GLRStackItem. Callers should call * YY_RESERVE_GLRSTACK afterwards to make sure there is sufficient * headroom. */ static inline yyGLRStackItem* yynewGLRStackItem (yyGLRStack* yystackp, yybool yyisState) { yyGLRStackItem* yynewItem = yystackp->yynextFree; yystackp->yyspaceLeft -= 1; yystackp->yynextFree += 1; yynewItem->yystate.yyisState = yyisState; return yynewItem; } /** Add a new semantic action that will execute the action for rule * RULENUM on the semantic values in RHS to the list of * alternative actions for STATE. Assumes that RHS comes from * stack #K of *STACKP. */ static void yyaddDeferredAction (yyGLRStack* yystackp, size_t yyk, yyGLRState* yystate, yyGLRState* rhs, yyRuleNum yyrule) { yySemanticOption* yynewOption = &yynewGLRStackItem (yystackp, yyfalse)->yyoption; yynewOption->yystate = rhs; yynewOption->yyrule = yyrule; if (yystackp->yytops.yylookaheadNeeds[yyk]) { yynewOption->yyrawchar = yychar; yynewOption->yyval = yylval; yynewOption->yyloc = yylloc; } else yynewOption->yyrawchar = YYEMPTY; yynewOption->yynext = yystate->yysemantics.yyfirstVal; yystate->yysemantics.yyfirstVal = yynewOption; YY_RESERVE_GLRSTACK (yystackp); } /* GLRStacks */ /** Initialize SET to a singleton set containing an empty stack. */ static yybool yyinitStateSet (yyGLRStateSet* yyset) { yyset->yysize = 1; yyset->yycapacity = 16; yyset->yystates = (yyGLRState**) YYMALLOC (16 * sizeof yyset->yystates[0]); if (! yyset->yystates) return yyfalse; yyset->yystates[0] = NULL; yyset->yylookaheadNeeds = (yybool*) YYMALLOC (16 * sizeof yyset->yylookaheadNeeds[0]); if (! yyset->yylookaheadNeeds) { YYFREE (yyset->yystates); return yyfalse; } return yytrue; } static void yyfreeStateSet (yyGLRStateSet* yyset) { YYFREE (yyset->yystates); YYFREE (yyset->yylookaheadNeeds); } /** Initialize STACK to a single empty stack, with total maximum * capacity for all stacks of SIZE. */ static yybool yyinitGLRStack (yyGLRStack* yystackp, size_t yysize) { yystackp->yyerrState = 0; yynerrs = 0; yystackp->yyspaceLeft = yysize; yystackp->yyitems = (yyGLRStackItem*) YYMALLOC (yysize * sizeof yystackp->yynextFree[0]); if (!yystackp->yyitems) return yyfalse; yystackp->yynextFree = yystackp->yyitems; yystackp->yysplitPoint = NULL; yystackp->yylastDeleted = NULL; return yyinitStateSet (&yystackp->yytops); } #if YYSTACKEXPANDABLE # define YYRELOC(YYFROMITEMS,YYTOITEMS,YYX,YYTYPE) \ &((YYTOITEMS) - ((YYFROMITEMS) - (yyGLRStackItem*) (YYX)))->YYTYPE /** If STACK is expandable, extend it. WARNING: Pointers into the stack from outside should be considered invalid after this call. We always expand when there are 1 or fewer items left AFTER an allocation, so that we can avoid having external pointers exist across an allocation. */ static void yyexpandGLRStack (yyGLRStack* yystackp) { yyGLRStackItem* yynewItems; yyGLRStackItem* yyp0, *yyp1; size_t yysize, yynewSize; size_t yyn; yysize = yystackp->yynextFree - yystackp->yyitems; if (YYMAXDEPTH - YYHEADROOM < yysize) yyMemoryExhausted (yystackp); yynewSize = 2*yysize; if (YYMAXDEPTH < yynewSize) yynewSize = YYMAXDEPTH; yynewItems = (yyGLRStackItem*) YYMALLOC (yynewSize * sizeof yynewItems[0]); if (! yynewItems) yyMemoryExhausted (yystackp); for (yyp0 = yystackp->yyitems, yyp1 = yynewItems, yyn = yysize; 0 < yyn; yyn -= 1, yyp0 += 1, yyp1 += 1) { *yyp1 = *yyp0; if (*(yybool *) yyp0) { yyGLRState* yys0 = &yyp0->yystate; yyGLRState* yys1 = &yyp1->yystate; if (yys0->yypred != NULL) yys1->yypred = YYRELOC (yyp0, yyp1, yys0->yypred, yystate); if (! yys0->yyresolved && yys0->yysemantics.yyfirstVal != NULL) yys1->yysemantics.yyfirstVal = YYRELOC(yyp0, yyp1, yys0->yysemantics.yyfirstVal, yyoption); } else { yySemanticOption* yyv0 = &yyp0->yyoption; yySemanticOption* yyv1 = &yyp1->yyoption; if (yyv0->yystate != NULL) yyv1->yystate = YYRELOC (yyp0, yyp1, yyv0->yystate, yystate); if (yyv0->yynext != NULL) yyv1->yynext = YYRELOC (yyp0, yyp1, yyv0->yynext, yyoption); } } if (yystackp->yysplitPoint != NULL) yystackp->yysplitPoint = YYRELOC (yystackp->yyitems, yynewItems, yystackp->yysplitPoint, yystate); for (yyn = 0; yyn < yystackp->yytops.yysize; yyn += 1) if (yystackp->yytops.yystates[yyn] != NULL) yystackp->yytops.yystates[yyn] = YYRELOC (yystackp->yyitems, yynewItems, yystackp->yytops.yystates[yyn], yystate); YYFREE (yystackp->yyitems); yystackp->yyitems = yynewItems; yystackp->yynextFree = yynewItems + yysize; yystackp->yyspaceLeft = yynewSize - yysize; } #endif static void yyfreeGLRStack (yyGLRStack* yystackp) { YYFREE (yystackp->yyitems); yyfreeStateSet (&yystackp->yytops); } /** Assuming that S is a GLRState somewhere on STACK, update the * splitpoint of STACK, if needed, so that it is at least as deep as * S. */ static inline void yyupdateSplit (yyGLRStack* yystackp, yyGLRState* yys) { if (yystackp->yysplitPoint != NULL && yystackp->yysplitPoint > yys) yystackp->yysplitPoint = yys; } /** Invalidate stack #K in STACK. */ static inline void yymarkStackDeleted (yyGLRStack* yystackp, size_t yyk) { if (yystackp->yytops.yystates[yyk] != NULL) yystackp->yylastDeleted = yystackp->yytops.yystates[yyk]; yystackp->yytops.yystates[yyk] = NULL; } /** Undelete the last stack that was marked as deleted. Can only be done once after a deletion, and only when all other stacks have been deleted. */ static void yyundeleteLastStack (yyGLRStack* yystackp) { if (yystackp->yylastDeleted == NULL || yystackp->yytops.yysize != 0) return; yystackp->yytops.yystates[0] = yystackp->yylastDeleted; yystackp->yytops.yysize = 1; YYDPRINTF ((stderr, "Restoring last deleted stack as stack #0.\n")); yystackp->yylastDeleted = NULL; } static inline void yyremoveDeletes (yyGLRStack* yystackp) { size_t yyi, yyj; yyi = yyj = 0; while (yyj < yystackp->yytops.yysize) { if (yystackp->yytops.yystates[yyi] == NULL) { if (yyi == yyj) { YYDPRINTF ((stderr, "Removing dead stacks.\n")); } yystackp->yytops.yysize -= 1; } else { yystackp->yytops.yystates[yyj] = yystackp->yytops.yystates[yyi]; /* In the current implementation, it's unnecessary to copy yystackp->yytops.yylookaheadNeeds[yyi] since, after yyremoveDeletes returns, the parser immediately either enters deterministic operation or shifts a token. However, it doesn't hurt, and the code might evolve to need it. */ yystackp->yytops.yylookaheadNeeds[yyj] = yystackp->yytops.yylookaheadNeeds[yyi]; if (yyj != yyi) { YYDPRINTF ((stderr, "Rename stack %lu -> %lu.\n", (unsigned long int) yyi, (unsigned long int) yyj)); } yyj += 1; } yyi += 1; } } /** Shift to a new state on stack #K of STACK, corresponding to LR state * LRSTATE, at input position POSN, with (resolved) semantic value SVAL. */ static inline void yyglrShift (yyGLRStack* yystackp, size_t yyk, yyStateNum yylrState, size_t yyposn, YYSTYPE* yyvalp, YYLTYPE* yylocp) { yyGLRState* yynewState = &yynewGLRStackItem (yystackp, yytrue)->yystate; yynewState->yylrState = yylrState; yynewState->yyposn = yyposn; yynewState->yyresolved = yytrue; yynewState->yypred = yystackp->yytops.yystates[yyk]; yynewState->yysemantics.yysval = *yyvalp; yynewState->yyloc = *yylocp; yystackp->yytops.yystates[yyk] = yynewState; YY_RESERVE_GLRSTACK (yystackp); } /** Shift stack #K of YYSTACK, to a new state corresponding to LR * state YYLRSTATE, at input position YYPOSN, with the (unresolved) * semantic value of YYRHS under the action for YYRULE. */ static inline void yyglrShiftDefer (yyGLRStack* yystackp, size_t yyk, yyStateNum yylrState, size_t yyposn, yyGLRState* rhs, yyRuleNum yyrule) { yyGLRState* yynewState = &yynewGLRStackItem (yystackp, yytrue)->yystate; yynewState->yylrState = yylrState; yynewState->yyposn = yyposn; yynewState->yyresolved = yyfalse; yynewState->yypred = yystackp->yytops.yystates[yyk]; yynewState->yysemantics.yyfirstVal = NULL; yystackp->yytops.yystates[yyk] = yynewState; /* Invokes YY_RESERVE_GLRSTACK. */ yyaddDeferredAction (yystackp, yyk, yynewState, rhs, yyrule); } /** Pop the symbols consumed by reduction #RULE from the top of stack * #K of STACK, and perform the appropriate semantic action on their * semantic values. Assumes that all ambiguities in semantic values * have been previously resolved. Set *VALP to the resulting value, * and *LOCP to the computed location (if any). Return value is as * for userAction. */ static inline YYRESULTTAG yydoAction (yyGLRStack* yystackp, size_t yyk, yyRuleNum yyrule, YYSTYPE* yyvalp, YYLTYPE* yylocp) { int yynrhs = yyrhsLength (yyrule); if (yystackp->yysplitPoint == NULL) { /* Standard special case: single stack. */ yyGLRStackItem* rhs = (yyGLRStackItem*) yystackp->yytops.yystates[yyk]; YYASSERT (yyk == 0); yystackp->yynextFree -= yynrhs; yystackp->yyspaceLeft += yynrhs; yystackp->yytops.yystates[0] = & yystackp->yynextFree[-1].yystate; return yyuserAction (yyrule, yynrhs, rhs, yyvalp, yylocp, yystackp); } else { /* At present, doAction is never called in nondeterministic * mode, so this branch is never taken. It is here in * anticipation of a future feature that will allow immediate * evaluation of selected actions in nondeterministic mode. */ int yyi; yyGLRState* yys; yyGLRStackItem yyrhsVals[YYMAXRHS + YYMAXLEFT + 1]; yys = yyrhsVals[YYMAXRHS + YYMAXLEFT].yystate.yypred = yystackp->yytops.yystates[yyk]; if (yynrhs == 0) /* Set default location. */ yyrhsVals[YYMAXRHS + YYMAXLEFT - 1].yystate.yyloc = yys->yyloc; for (yyi = 0; yyi < yynrhs; yyi += 1) { yys = yys->yypred; YYASSERT (yys); } yyupdateSplit (yystackp, yys); yystackp->yytops.yystates[yyk] = yys; return yyuserAction (yyrule, yynrhs, yyrhsVals + YYMAXRHS + YYMAXLEFT - 1, yyvalp, yylocp, yystackp); } } #if !YYDEBUG # define YY_REDUCE_PRINT(Args) #else # define YY_REDUCE_PRINT(Args) \ do { \ if (yydebug) \ yy_reduce_print Args; \ } while (YYID (0)) /*----------------------------------------------------------. | Report that the RULE is going to be reduced on stack #K. | `----------------------------------------------------------*/ /*ARGSUSED*/ static inline void yy_reduce_print (yyGLRStack* yystackp, size_t yyk, yyRuleNum yyrule, YYSTYPE* yyvalp, YYLTYPE* yylocp) { int yynrhs = yyrhsLength (yyrule); yybool yynormal __attribute__ ((__unused__)) = (yystackp->yysplitPoint == NULL); yyGLRStackItem* yyvsp = (yyGLRStackItem*) yystackp->yytops.yystates[yyk]; int yylow = 1; int yyi; YYUSE (yyvalp); YYUSE (yylocp); YYFPRINTF (stderr, "Reducing stack %lu by rule %d (line %lu):\n", (unsigned long int) yyk, yyrule - 1, (unsigned long int) yyrline[yyrule]); /* The symbols being reduced. */ for (yyi = 0; yyi < yynrhs; yyi++) { fprintf (stderr, " $%d = ", yyi + 1); yy_symbol_print (stderr, yyrhs[yyprhs[yyrule] + yyi], &(((yyGLRStackItem const *)yyvsp)[YYFILL ((yyi + 1) - (yynrhs))].yystate.yysemantics.yysval) , &(((yyGLRStackItem const *)yyvsp)[YYFILL ((yyi + 1) - (yynrhs))].yystate.yyloc) ); fprintf (stderr, "\n"); } } #endif /** Pop items off stack #K of STACK according to grammar rule RULE, * and push back on the resulting nonterminal symbol. Perform the * semantic action associated with RULE and store its value with the * newly pushed state, if FORCEEVAL or if STACK is currently * unambiguous. Otherwise, store the deferred semantic action with * the new state. If the new state would have an identical input * position, LR state, and predecessor to an existing state on the stack, * it is identified with that existing state, eliminating stack #K from * the STACK. In this case, the (necessarily deferred) semantic value is * added to the options for the existing state's semantic value. */ static inline YYRESULTTAG yyglrReduce (yyGLRStack* yystackp, size_t yyk, yyRuleNum yyrule, yybool yyforceEval) { size_t yyposn = yystackp->yytops.yystates[yyk]->yyposn; if (yyforceEval || yystackp->yysplitPoint == NULL) { YYSTYPE yysval; YYLTYPE yyloc; YY_REDUCE_PRINT ((yystackp, yyk, yyrule, &yysval, &yyloc)); YYCHK (yydoAction (yystackp, yyk, yyrule, &yysval, &yyloc)); YY_SYMBOL_PRINT ("-> $$ =", yyr1[yyrule], &yysval, &yyloc); yyglrShift (yystackp, yyk, yyLRgotoState (yystackp->yytops.yystates[yyk]->yylrState, yylhsNonterm (yyrule)), yyposn, &yysval, &yyloc); } else { size_t yyi; int yyn; yyGLRState* yys, *yys0 = yystackp->yytops.yystates[yyk]; yyStateNum yynewLRState; for (yys = yystackp->yytops.yystates[yyk], yyn = yyrhsLength (yyrule); 0 < yyn; yyn -= 1) { yys = yys->yypred; YYASSERT (yys); } yyupdateSplit (yystackp, yys); yynewLRState = yyLRgotoState (yys->yylrState, yylhsNonterm (yyrule)); YYDPRINTF ((stderr, "Reduced stack %lu by rule #%d; action deferred. Now in state %d.\n", (unsigned long int) yyk, yyrule - 1, yynewLRState)); for (yyi = 0; yyi < yystackp->yytops.yysize; yyi += 1) if (yyi != yyk && yystackp->yytops.yystates[yyi] != NULL) { yyGLRState* yyp, *yysplit = yystackp->yysplitPoint; yyp = yystackp->yytops.yystates[yyi]; while (yyp != yys && yyp != yysplit && yyp->yyposn >= yyposn) { if (yyp->yylrState == yynewLRState && yyp->yypred == yys) { yyaddDeferredAction (yystackp, yyk, yyp, yys0, yyrule); yymarkStackDeleted (yystackp, yyk); YYDPRINTF ((stderr, "Merging stack %lu into stack %lu.\n", (unsigned long int) yyk, (unsigned long int) yyi)); return yyok; } yyp = yyp->yypred; } } yystackp->yytops.yystates[yyk] = yys; yyglrShiftDefer (yystackp, yyk, yynewLRState, yyposn, yys0, yyrule); } return yyok; } static size_t yysplitStack (yyGLRStack* yystackp, size_t yyk) { if (yystackp->yysplitPoint == NULL) { YYASSERT (yyk == 0); yystackp->yysplitPoint = yystackp->yytops.yystates[yyk]; } if (yystackp->yytops.yysize >= yystackp->yytops.yycapacity) { yyGLRState** yynewStates; yybool* yynewLookaheadNeeds; yynewStates = NULL; if (yystackp->yytops.yycapacity > (YYSIZEMAX / (2 * sizeof yynewStates[0]))) yyMemoryExhausted (yystackp); yystackp->yytops.yycapacity *= 2; yynewStates = (yyGLRState**) YYREALLOC (yystackp->yytops.yystates, (yystackp->yytops.yycapacity * sizeof yynewStates[0])); if (yynewStates == NULL) yyMemoryExhausted (yystackp); yystackp->yytops.yystates = yynewStates; yynewLookaheadNeeds = (yybool*) YYREALLOC (yystackp->yytops.yylookaheadNeeds, (yystackp->yytops.yycapacity * sizeof yynewLookaheadNeeds[0])); if (yynewLookaheadNeeds == NULL) yyMemoryExhausted (yystackp); yystackp->yytops.yylookaheadNeeds = yynewLookaheadNeeds; } yystackp->yytops.yystates[yystackp->yytops.yysize] = yystackp->yytops.yystates[yyk]; yystackp->yytops.yylookaheadNeeds[yystackp->yytops.yysize] = yystackp->yytops.yylookaheadNeeds[yyk]; yystackp->yytops.yysize += 1; return yystackp->yytops.yysize-1; } /** True iff Y0 and Y1 represent identical options at the top level. * That is, they represent the same rule applied to RHS symbols * that produce the same terminal symbols. */ static yybool yyidenticalOptions (yySemanticOption* yyy0, yySemanticOption* yyy1) { if (yyy0->yyrule == yyy1->yyrule) { yyGLRState *yys0, *yys1; int yyn; for (yys0 = yyy0->yystate, yys1 = yyy1->yystate, yyn = yyrhsLength (yyy0->yyrule); yyn > 0; yys0 = yys0->yypred, yys1 = yys1->yypred, yyn -= 1) if (yys0->yyposn != yys1->yyposn) return yyfalse; return yytrue; } else return yyfalse; } /** Assuming identicalOptions (Y0,Y1), destructively merge the * alternative semantic values for the RHS-symbols of Y1 and Y0. */ static void yymergeOptionSets (yySemanticOption* yyy0, yySemanticOption* yyy1) { yyGLRState *yys0, *yys1; int yyn; for (yys0 = yyy0->yystate, yys1 = yyy1->yystate, yyn = yyrhsLength (yyy0->yyrule); yyn > 0; yys0 = yys0->yypred, yys1 = yys1->yypred, yyn -= 1) { if (yys0 == yys1) break; else if (yys0->yyresolved) { yys1->yyresolved = yytrue; yys1->yysemantics.yysval = yys0->yysemantics.yysval; } else if (yys1->yyresolved) { yys0->yyresolved = yytrue; yys0->yysemantics.yysval = yys1->yysemantics.yysval; } else { yySemanticOption** yyz0p; yySemanticOption* yyz1; yyz0p = &yys0->yysemantics.yyfirstVal; yyz1 = yys1->yysemantics.yyfirstVal; while (YYID (yytrue)) { if (yyz1 == *yyz0p || yyz1 == NULL) break; else if (*yyz0p == NULL) { *yyz0p = yyz1; break; } else if (*yyz0p < yyz1) { yySemanticOption* yyz = *yyz0p; *yyz0p = yyz1; yyz1 = yyz1->yynext; (*yyz0p)->yynext = yyz; } yyz0p = &(*yyz0p)->yynext; } yys1->yysemantics.yyfirstVal = yys0->yysemantics.yyfirstVal; } } } /** Y0 and Y1 represent two possible actions to take in a given * parsing state; return 0 if no combination is possible, * 1 if user-mergeable, 2 if Y0 is preferred, 3 if Y1 is preferred. */ static int yypreference (yySemanticOption* y0, yySemanticOption* y1) { yyRuleNum r0 = y0->yyrule, r1 = y1->yyrule; int p0 = yydprec[r0], p1 = yydprec[r1]; if (p0 == p1) { if (yymerger[r0] == 0 || yymerger[r0] != yymerger[r1]) return 0; else return 1; } if (p0 == 0 || p1 == 0) return 0; if (p0 < p1) return 3; if (p1 < p0) return 2; return 0; } static YYRESULTTAG yyresolveValue (yyGLRState* yys, yyGLRStack* yystackp); /** Resolve the previous N states starting at and including state S. If result * != yyok, some states may have been left unresolved possibly with empty * semantic option chains. Regardless of whether result = yyok, each state * has been left with consistent data so that yydestroyGLRState can be invoked * if necessary. */ static YYRESULTTAG yyresolveStates (yyGLRState* yys, int yyn, yyGLRStack* yystackp) { if (0 < yyn) { YYASSERT (yys->yypred); YYCHK (yyresolveStates (yys->yypred, yyn-1, yystackp)); if (! yys->yyresolved) YYCHK (yyresolveValue (yys, yystackp)); } return yyok; } /** Resolve the states for the RHS of OPT, perform its user action, and return * the semantic value and location. Regardless of whether result = yyok, all * RHS states have been destroyed (assuming the user action destroys all RHS * semantic values if invoked). */ static YYRESULTTAG yyresolveAction (yySemanticOption* yyopt, yyGLRStack* yystackp, YYSTYPE* yyvalp, YYLTYPE* yylocp) { yyGLRStackItem yyrhsVals[YYMAXRHS + YYMAXLEFT + 1]; int yynrhs; int yychar_current; YYSTYPE yylval_current; YYLTYPE yylloc_current; YYRESULTTAG yyflag; yynrhs = yyrhsLength (yyopt->yyrule); yyflag = yyresolveStates (yyopt->yystate, yynrhs, yystackp); if (yyflag != yyok) { yyGLRState *yys; for (yys = yyopt->yystate; yynrhs > 0; yys = yys->yypred, yynrhs -= 1) yydestroyGLRState ("Cleanup: popping", yys); return yyflag; } yyrhsVals[YYMAXRHS + YYMAXLEFT].yystate.yypred = yyopt->yystate; if (yynrhs == 0) /* Set default location. */ yyrhsVals[YYMAXRHS + YYMAXLEFT - 1].yystate.yyloc = yyopt->yystate->yyloc; yychar_current = yychar; yylval_current = yylval; yylloc_current = yylloc; yychar = yyopt->yyrawchar; yylval = yyopt->yyval; yylloc = yyopt->yyloc; yyflag = yyuserAction (yyopt->yyrule, yynrhs, yyrhsVals + YYMAXRHS + YYMAXLEFT - 1, yyvalp, yylocp, yystackp); yychar = yychar_current; yylval = yylval_current; yylloc = yylloc_current; return yyflag; } #if YYDEBUG static void yyreportTree (yySemanticOption* yyx, int yyindent) { int yynrhs = yyrhsLength (yyx->yyrule); int yyi; yyGLRState* yys; yyGLRState* yystates[1 + YYMAXRHS]; yyGLRState yyleftmost_state; for (yyi = yynrhs, yys = yyx->yystate; 0 < yyi; yyi -= 1, yys = yys->yypred) yystates[yyi] = yys; if (yys == NULL) { yyleftmost_state.yyposn = 0; yystates[0] = &yyleftmost_state; } else yystates[0] = yys; if (yyx->yystate->yyposn < yys->yyposn + 1) YYFPRINTF (stderr, "%*s%s -> \n", yyindent, "", yytokenName (yylhsNonterm (yyx->yyrule)), yyx->yyrule - 1); else YYFPRINTF (stderr, "%*s%s -> \n", yyindent, "", yytokenName (yylhsNonterm (yyx->yyrule)), yyx->yyrule - 1, (unsigned long int) (yys->yyposn + 1), (unsigned long int) yyx->yystate->yyposn); for (yyi = 1; yyi <= yynrhs; yyi += 1) { if (yystates[yyi]->yyresolved) { if (yystates[yyi-1]->yyposn+1 > yystates[yyi]->yyposn) YYFPRINTF (stderr, "%*s%s \n", yyindent+2, "", yytokenName (yyrhs[yyprhs[yyx->yyrule]+yyi-1])); else YYFPRINTF (stderr, "%*s%s \n", yyindent+2, "", yytokenName (yyrhs[yyprhs[yyx->yyrule]+yyi-1]), (unsigned long int) (yystates[yyi - 1]->yyposn + 1), (unsigned long int) yystates[yyi]->yyposn); } else yyreportTree (yystates[yyi]->yysemantics.yyfirstVal, yyindent+2); } } #endif /*ARGSUSED*/ static YYRESULTTAG yyreportAmbiguity (yySemanticOption* yyx0, yySemanticOption* yyx1) { YYUSE (yyx0); YYUSE (yyx1); #if YYDEBUG YYFPRINTF (stderr, "Ambiguity detected.\n"); YYFPRINTF (stderr, "Option 1,\n"); yyreportTree (yyx0, 2); YYFPRINTF (stderr, "\nOption 2,\n"); yyreportTree (yyx1, 2); YYFPRINTF (stderr, "\n"); #endif yyerror (YY_("syntax is ambiguous")); return yyabort; } /** Starting at and including state S1, resolve the location for each of the * previous N1 states that is unresolved. The first semantic option of a state * is always chosen. */ static void yyresolveLocations (yyGLRState* yys1, int yyn1, yyGLRStack *yystackp) { if (0 < yyn1) { yyresolveLocations (yys1->yypred, yyn1 - 1, yystackp); if (!yys1->yyresolved) { yySemanticOption *yyoption; yyGLRStackItem yyrhsloc[1 + YYMAXRHS]; int yynrhs; int yychar_current; YYSTYPE yylval_current; YYLTYPE yylloc_current; yyoption = yys1->yysemantics.yyfirstVal; YYASSERT (yyoption != NULL); yynrhs = yyrhsLength (yyoption->yyrule); if (yynrhs > 0) { yyGLRState *yys; int yyn; yyresolveLocations (yyoption->yystate, yynrhs, yystackp); for (yys = yyoption->yystate, yyn = yynrhs; yyn > 0; yys = yys->yypred, yyn -= 1) yyrhsloc[yyn].yystate.yyloc = yys->yyloc; } else { /* Both yyresolveAction and yyresolveLocations traverse the GSS in reverse rightmost order. It is only necessary to invoke yyresolveLocations on a subforest for which yyresolveAction would have been invoked next had an ambiguity not been detected. Thus the location of the previous state (but not necessarily the previous state itself) is guaranteed to be resolved already. */ yyGLRState *yyprevious = yyoption->yystate; yyrhsloc[0].yystate.yyloc = yyprevious->yyloc; } yychar_current = yychar; yylval_current = yylval; yylloc_current = yylloc; yychar = yyoption->yyrawchar; yylval = yyoption->yyval; yylloc = yyoption->yyloc; YYLLOC_DEFAULT ((yys1->yyloc), yyrhsloc, yynrhs); yychar = yychar_current; yylval = yylval_current; yylloc = yylloc_current; } } } /** Resolve the ambiguity represented in state S, perform the indicated * actions, and set the semantic value of S. If result != yyok, the chain of * semantic options in S has been cleared instead or it has been left * unmodified except that redundant options may have been removed. Regardless * of whether result = yyok, S has been left with consistent data so that * yydestroyGLRState can be invoked if necessary. */ static YYRESULTTAG yyresolveValue (yyGLRState* yys, yyGLRStack* yystackp) { yySemanticOption* yyoptionList = yys->yysemantics.yyfirstVal; yySemanticOption* yybest; yySemanticOption** yypp; yybool yymerge; YYSTYPE yysval; YYRESULTTAG yyflag; YYLTYPE *yylocp = &yys->yyloc; yybest = yyoptionList; yymerge = yyfalse; for (yypp = &yyoptionList->yynext; *yypp != NULL; ) { yySemanticOption* yyp = *yypp; if (yyidenticalOptions (yybest, yyp)) { yymergeOptionSets (yybest, yyp); *yypp = yyp->yynext; } else { switch (yypreference (yybest, yyp)) { case 0: yyresolveLocations (yys, 1, yystackp); return yyreportAmbiguity (yybest, yyp); break; case 1: yymerge = yytrue; break; case 2: break; case 3: yybest = yyp; yymerge = yyfalse; break; default: /* This cannot happen so it is not worth a YYASSERT (yyfalse), but some compilers complain if the default case is omitted. */ break; } yypp = &yyp->yynext; } } if (yymerge) { yySemanticOption* yyp; int yyprec = yydprec[yybest->yyrule]; yyflag = yyresolveAction (yybest, yystackp, &yysval, yylocp); if (yyflag == yyok) for (yyp = yybest->yynext; yyp != NULL; yyp = yyp->yynext) { if (yyprec == yydprec[yyp->yyrule]) { YYSTYPE yysval_other; YYLTYPE yydummy; yyflag = yyresolveAction (yyp, yystackp, &yysval_other, &yydummy); if (yyflag != yyok) { yydestruct ("Cleanup: discarding incompletely merged value for", yystos[yys->yylrState], &yysval, yylocp); break; } yyuserMerge (yymerger[yyp->yyrule], &yysval, &yysval_other); } } } else yyflag = yyresolveAction (yybest, yystackp, &yysval, yylocp); if (yyflag == yyok) { yys->yyresolved = yytrue; yys->yysemantics.yysval = yysval; } else yys->yysemantics.yyfirstVal = NULL; return yyflag; } static YYRESULTTAG yyresolveStack (yyGLRStack* yystackp) { if (yystackp->yysplitPoint != NULL) { yyGLRState* yys; int yyn; for (yyn = 0, yys = yystackp->yytops.yystates[0]; yys != yystackp->yysplitPoint; yys = yys->yypred, yyn += 1) continue; YYCHK (yyresolveStates (yystackp->yytops.yystates[0], yyn, yystackp )); } return yyok; } static void yycompressStack (yyGLRStack* yystackp) { yyGLRState* yyp, *yyq, *yyr; if (yystackp->yytops.yysize != 1 || yystackp->yysplitPoint == NULL) return; for (yyp = yystackp->yytops.yystates[0], yyq = yyp->yypred, yyr = NULL; yyp != yystackp->yysplitPoint; yyr = yyp, yyp = yyq, yyq = yyp->yypred) yyp->yypred = yyr; yystackp->yyspaceLeft += yystackp->yynextFree - yystackp->yyitems; yystackp->yynextFree = ((yyGLRStackItem*) yystackp->yysplitPoint) + 1; yystackp->yyspaceLeft -= yystackp->yynextFree - yystackp->yyitems; yystackp->yysplitPoint = NULL; yystackp->yylastDeleted = NULL; while (yyr != NULL) { yystackp->yynextFree->yystate = *yyr; yyr = yyr->yypred; yystackp->yynextFree->yystate.yypred = &yystackp->yynextFree[-1].yystate; yystackp->yytops.yystates[0] = &yystackp->yynextFree->yystate; yystackp->yynextFree += 1; yystackp->yyspaceLeft -= 1; } } static YYRESULTTAG yyprocessOneStack (yyGLRStack* yystackp, size_t yyk, size_t yyposn) { int yyaction; const short int* yyconflicts; yyRuleNum yyrule; while (yystackp->yytops.yystates[yyk] != NULL) { yyStateNum yystate = yystackp->yytops.yystates[yyk]->yylrState; YYDPRINTF ((stderr, "Stack %lu Entering state %d\n", (unsigned long int) yyk, yystate)); YYASSERT (yystate != YYFINAL); if (yyisDefaultedState (yystate)) { yyrule = yydefaultAction (yystate); if (yyrule == 0) { YYDPRINTF ((stderr, "Stack %lu dies.\n", (unsigned long int) yyk)); yymarkStackDeleted (yystackp, yyk); return yyok; } YYCHK (yyglrReduce (yystackp, yyk, yyrule, yyfalse)); } else { yySymbol yytoken; yystackp->yytops.yylookaheadNeeds[yyk] = yytrue; if (yychar == YYEMPTY) { YYDPRINTF ((stderr, "Reading a token: ")); yychar = YYLEX; yytoken = YYTRANSLATE (yychar); YY_SYMBOL_PRINT ("Next token is", yytoken, &yylval, &yylloc); } else yytoken = YYTRANSLATE (yychar); yygetLRActions (yystate, yytoken, &yyaction, &yyconflicts); while (*yyconflicts != 0) { size_t yynewStack = yysplitStack (yystackp, yyk); YYDPRINTF ((stderr, "Splitting off stack %lu from %lu.\n", (unsigned long int) yynewStack, (unsigned long int) yyk)); YYCHK (yyglrReduce (yystackp, yynewStack, *yyconflicts, yyfalse)); YYCHK (yyprocessOneStack (yystackp, yynewStack, yyposn)); yyconflicts += 1; } if (yyisShiftAction (yyaction)) break; else if (yyisErrorAction (yyaction)) { YYDPRINTF ((stderr, "Stack %lu dies.\n", (unsigned long int) yyk)); yymarkStackDeleted (yystackp, yyk); break; } else YYCHK (yyglrReduce (yystackp, yyk, -yyaction, yyfalse)); } } return yyok; } /*ARGSUSED*/ static void yyreportSyntaxError (yyGLRStack* yystackp) { if (yystackp->yyerrState == 0) { #if YYERROR_VERBOSE int yyn; yyn = yypact[yystackp->yytops.yystates[0]->yylrState]; if (YYPACT_NINF < yyn && yyn <= YYLAST) { yySymbol yytoken = YYTRANSLATE (yychar); size_t yysize0 = yytnamerr (NULL, yytokenName (yytoken)); size_t yysize = yysize0; size_t yysize1; yybool yysize_overflow = yyfalse; char* yymsg = NULL; enum { YYERROR_VERBOSE_ARGS_MAXIMUM = 5 }; char const *yyarg[YYERROR_VERBOSE_ARGS_MAXIMUM]; int yyx; char *yyfmt; char const *yyf; static char const yyunexpected[] = "syntax error, unexpected %s"; static char const yyexpecting[] = ", expecting %s"; static char const yyor[] = " or %s"; char yyformat[sizeof yyunexpected + sizeof yyexpecting - 1 + ((YYERROR_VERBOSE_ARGS_MAXIMUM - 2) * (sizeof yyor - 1))]; char const *yyprefix = yyexpecting; /* Start YYX at -YYN if negative to avoid negative indexes in YYCHECK. */ int yyxbegin = yyn < 0 ? -yyn : 0; /* Stay within bounds of both yycheck and yytname. */ int yychecklim = YYLAST - yyn + 1; int yyxend = yychecklim < YYNTOKENS ? yychecklim : YYNTOKENS; int yycount = 1; yyarg[0] = yytokenName (yytoken); yyfmt = yystpcpy (yyformat, yyunexpected); for (yyx = yyxbegin; yyx < yyxend; ++yyx) if (yycheck[yyx + yyn] == yyx && yyx != YYTERROR) { if (yycount == YYERROR_VERBOSE_ARGS_MAXIMUM) { yycount = 1; yysize = yysize0; yyformat[sizeof yyunexpected - 1] = '\0'; break; } yyarg[yycount++] = yytokenName (yyx); yysize1 = yysize + yytnamerr (NULL, yytokenName (yyx)); yysize_overflow |= yysize1 < yysize; yysize = yysize1; yyfmt = yystpcpy (yyfmt, yyprefix); yyprefix = yyor; } yyf = YY_(yyformat); yysize1 = yysize + strlen (yyf); yysize_overflow |= yysize1 < yysize; yysize = yysize1; if (!yysize_overflow) yymsg = (char *) YYMALLOC (yysize); if (yymsg) { char *yyp = yymsg; int yyi = 0; while ((*yyp = *yyf)) { if (*yyp == '%' && yyf[1] == 's' && yyi < yycount) { yyp += yytnamerr (yyp, yyarg[yyi++]); yyf += 2; } else { yyp++; yyf++; } } yyerror (yymsg); YYFREE (yymsg); } else { yyerror (YY_("syntax error")); yyMemoryExhausted (yystackp); } } else #endif /* YYERROR_VERBOSE */ yyerror (YY_("syntax error")); yynerrs += 1; } } /* Recover from a syntax error on *YYSTACKP, assuming that *YYSTACKP->YYTOKENP, yylval, and yylloc are the syntactic category, semantic value, and location of the look-ahead. */ /*ARGSUSED*/ static void yyrecoverSyntaxError (yyGLRStack* yystackp) { size_t yyk; int yyj; if (yystackp->yyerrState == 3) /* We just shifted the error token and (perhaps) took some reductions. Skip tokens until we can proceed. */ while (YYID (yytrue)) { yySymbol yytoken; if (yychar == YYEOF) yyFail (yystackp, NULL); if (yychar != YYEMPTY) { /* We throw away the lookahead, but the error range of the shifted error token must take it into account. */ yyGLRState *yys = yystackp->yytops.yystates[0]; yyGLRStackItem yyerror_range[3]; yyerror_range[1].yystate.yyloc = yys->yyloc; yyerror_range[2].yystate.yyloc = yylloc; YYLLOC_DEFAULT ((yys->yyloc), yyerror_range, 2); yytoken = YYTRANSLATE (yychar); yydestruct ("Error: discarding", yytoken, &yylval, &yylloc); } YYDPRINTF ((stderr, "Reading a token: ")); yychar = YYLEX; yytoken = YYTRANSLATE (yychar); YY_SYMBOL_PRINT ("Next token is", yytoken, &yylval, &yylloc); yyj = yypact[yystackp->yytops.yystates[0]->yylrState]; if (yyis_pact_ninf (yyj)) return; yyj += yytoken; if (yyj < 0 || YYLAST < yyj || yycheck[yyj] != yytoken) { if (yydefact[yystackp->yytops.yystates[0]->yylrState] != 0) return; } else if (yytable[yyj] != 0 && ! yyis_table_ninf (yytable[yyj])) return; } /* Reduce to one stack. */ for (yyk = 0; yyk < yystackp->yytops.yysize; yyk += 1) if (yystackp->yytops.yystates[yyk] != NULL) break; if (yyk >= yystackp->yytops.yysize) yyFail (yystackp, NULL); for (yyk += 1; yyk < yystackp->yytops.yysize; yyk += 1) yymarkStackDeleted (yystackp, yyk); yyremoveDeletes (yystackp); yycompressStack (yystackp); /* Now pop stack until we find a state that shifts the error token. */ yystackp->yyerrState = 3; while (yystackp->yytops.yystates[0] != NULL) { yyGLRState *yys = yystackp->yytops.yystates[0]; yyj = yypact[yys->yylrState]; if (! yyis_pact_ninf (yyj)) { yyj += YYTERROR; if (0 <= yyj && yyj <= YYLAST && yycheck[yyj] == YYTERROR && yyisShiftAction (yytable[yyj])) { /* Shift the error token having adjusted its location. */ YYLTYPE yyerrloc; yystackp->yyerror_range[2].yystate.yyloc = yylloc; YYLLOC_DEFAULT (yyerrloc, (yystackp->yyerror_range), 2); YY_SYMBOL_PRINT ("Shifting", yystos[yytable[yyj]], &yylval, &yyerrloc); yyglrShift (yystackp, 0, yytable[yyj], yys->yyposn, &yylval, &yyerrloc); yys = yystackp->yytops.yystates[0]; break; } } yystackp->yyerror_range[1].yystate.yyloc = yys->yyloc; yydestroyGLRState ("Error: popping", yys); yystackp->yytops.yystates[0] = yys->yypred; yystackp->yynextFree -= 1; yystackp->yyspaceLeft += 1; } if (yystackp->yytops.yystates[0] == NULL) yyFail (yystackp, NULL); } #define YYCHK1(YYE) \ do { \ switch (YYE) { \ case yyok: \ break; \ case yyabort: \ goto yyabortlab; \ case yyaccept: \ goto yyacceptlab; \ case yyerr: \ goto yyuser_error; \ default: \ goto yybuglab; \ } \ } while (YYID (0)) /*----------. | yyparse. | `----------*/ int yyparse (void) { int yyresult; yyGLRStack yystack; yyGLRStack* const yystackp = &yystack; size_t yyposn; YYDPRINTF ((stderr, "Starting parse\n")); yychar = YYEMPTY; yylval = yyval_default; #if YYLTYPE_IS_TRIVIAL yylloc.first_line = yylloc.last_line = 1; yylloc.first_column = yylloc.last_column = 0; #endif if (! yyinitGLRStack (yystackp, YYINITDEPTH)) goto yyexhaustedlab; switch (YYSETJMP (yystack.yyexception_buffer)) { case 0: break; case 1: goto yyabortlab; case 2: goto yyexhaustedlab; default: goto yybuglab; } yyglrShift (&yystack, 0, 0, 0, &yylval, &yylloc); yyposn = 0; while (YYID (yytrue)) { /* For efficiency, we have two loops, the first of which is specialized to deterministic operation (single stack, no potential ambiguity). */ /* Standard mode */ while (YYID (yytrue)) { yyRuleNum yyrule; int yyaction; const short int* yyconflicts; yyStateNum yystate = yystack.yytops.yystates[0]->yylrState; YYDPRINTF ((stderr, "Entering state %d\n", yystate)); if (yystate == YYFINAL) goto yyacceptlab; if (yyisDefaultedState (yystate)) { yyrule = yydefaultAction (yystate); if (yyrule == 0) { yystack.yyerror_range[1].yystate.yyloc = yylloc; yyreportSyntaxError (&yystack); goto yyuser_error; } YYCHK1 (yyglrReduce (&yystack, 0, yyrule, yytrue)); } else { yySymbol yytoken; if (yychar == YYEMPTY) { YYDPRINTF ((stderr, "Reading a token: ")); yychar = YYLEX; yytoken = YYTRANSLATE (yychar); YY_SYMBOL_PRINT ("Next token is", yytoken, &yylval, &yylloc); } else yytoken = YYTRANSLATE (yychar); yygetLRActions (yystate, yytoken, &yyaction, &yyconflicts); if (*yyconflicts != 0) break; if (yyisShiftAction (yyaction)) { YY_SYMBOL_PRINT ("Shifting", yytoken, &yylval, &yylloc); if (yychar != YYEOF) yychar = YYEMPTY; yyposn += 1; yyglrShift (&yystack, 0, yyaction, yyposn, &yylval, &yylloc); if (0 < yystack.yyerrState) yystack.yyerrState -= 1; } else if (yyisErrorAction (yyaction)) { yystack.yyerror_range[1].yystate.yyloc = yylloc; yyreportSyntaxError (&yystack); goto yyuser_error; } else YYCHK1 (yyglrReduce (&yystack, 0, -yyaction, yytrue)); } } while (YYID (yytrue)) { yySymbol yytoken_to_shift; size_t yys; for (yys = 0; yys < yystack.yytops.yysize; yys += 1) yystackp->yytops.yylookaheadNeeds[yys] = yychar != YYEMPTY; /* yyprocessOneStack returns one of three things: - An error flag. If the caller is yyprocessOneStack, it immediately returns as well. When the caller is finally yyparse, it jumps to an error label via YYCHK1. - yyok, but yyprocessOneStack has invoked yymarkStackDeleted (&yystack, yys), which sets the top state of yys to NULL. Thus, yyparse's following invocation of yyremoveDeletes will remove the stack. - yyok, when ready to shift a token. Except in the first case, yyparse will invoke yyremoveDeletes and then shift the next token onto all remaining stacks. This synchronization of the shift (that is, after all preceding reductions on all stacks) helps prevent double destructor calls on yylval in the event of memory exhaustion. */ for (yys = 0; yys < yystack.yytops.yysize; yys += 1) YYCHK1 (yyprocessOneStack (&yystack, yys, yyposn)); yyremoveDeletes (&yystack); if (yystack.yytops.yysize == 0) { yyundeleteLastStack (&yystack); if (yystack.yytops.yysize == 0) yyFail (&yystack, YY_("syntax error")); YYCHK1 (yyresolveStack (&yystack)); YYDPRINTF ((stderr, "Returning to deterministic operation.\n")); yystack.yyerror_range[1].yystate.yyloc = yylloc; yyreportSyntaxError (&yystack); goto yyuser_error; } /* If any yyglrShift call fails, it will fail after shifting. Thus, a copy of yylval will already be on stack 0 in the event of a failure in the following loop. Thus, yychar is set to YYEMPTY before the loop to make sure the user destructor for yylval isn't called twice. */ yytoken_to_shift = YYTRANSLATE (yychar); yychar = YYEMPTY; yyposn += 1; for (yys = 0; yys < yystack.yytops.yysize; yys += 1) { int yyaction; const short int* yyconflicts; yyStateNum yystate = yystack.yytops.yystates[yys]->yylrState; yygetLRActions (yystate, yytoken_to_shift, &yyaction, &yyconflicts); /* Note that yyconflicts were handled by yyprocessOneStack. */ YYDPRINTF ((stderr, "On stack %lu, ", (unsigned long int) yys)); YY_SYMBOL_PRINT ("shifting", yytoken_to_shift, &yylval, &yylloc); yyglrShift (&yystack, yys, yyaction, yyposn, &yylval, &yylloc); YYDPRINTF ((stderr, "Stack %lu now in state #%d\n", (unsigned long int) yys, yystack.yytops.yystates[yys]->yylrState)); } if (yystack.yytops.yysize == 1) { YYCHK1 (yyresolveStack (&yystack)); YYDPRINTF ((stderr, "Returning to deterministic operation.\n")); yycompressStack (&yystack); break; } } continue; yyuser_error: yyrecoverSyntaxError (&yystack); yyposn = yystack.yytops.yystates[0]->yyposn; } yyacceptlab: yyresult = 0; goto yyreturn; yybuglab: YYASSERT (yyfalse); goto yyabortlab; yyabortlab: yyresult = 1; goto yyreturn; yyexhaustedlab: yyerror (YY_("memory exhausted")); yyresult = 2; goto yyreturn; yyreturn: if (yychar != YYEOF && yychar != YYEMPTY) yydestruct ("Cleanup: discarding lookahead", YYTRANSLATE (yychar), &yylval, &yylloc); /* If the stack is well-formed, pop the stack until it is empty, destroying its entries as we go. But free the stack regardless of whether it is well-formed. */ if (yystack.yyitems) { yyGLRState** yystates = yystack.yytops.yystates; if (yystates) { size_t yysize = yystack.yytops.yysize; size_t yyk; for (yyk = 0; yyk < yysize; yyk += 1) if (yystates[yyk]) { while (yystates[yyk]) { yyGLRState *yys = yystates[yyk]; yystack.yyerror_range[1].yystate.yyloc = yys->yyloc; yydestroyGLRState ("Cleanup: popping", yys); yystates[yyk] = yys->yypred; yystack.yynextFree -= 1; yystack.yyspaceLeft += 1; } break; } } yyfreeGLRStack (&yystack); } /* Make sure YYID is used. */ return YYID (yyresult); } /* DEBUGGING ONLY */ #ifdef YYDEBUG static void yypstack (yyGLRStack* yystackp, size_t yyk) __attribute__ ((__unused__)); static void yypdumpstack (yyGLRStack* yystackp) __attribute__ ((__unused__)); static void yy_yypstack (yyGLRState* yys) { if (yys->yypred) { yy_yypstack (yys->yypred); fprintf (stderr, " -> "); } fprintf (stderr, "address@hidden", yys->yylrState, (unsigned long int) yys->yyposn); } static void yypstates (yyGLRState* yyst) { if (yyst == NULL) fprintf (stderr, ""); else yy_yypstack (yyst); fprintf (stderr, "\n"); } static void yypstack (yyGLRStack* yystackp, size_t yyk) { yypstates (yystackp->yytops.yystates[yyk]); } #define YYINDEX(YYX) \ ((YYX) == NULL ? -1 : (yyGLRStackItem*) (YYX) - yystackp->yyitems) static void yypdumpstack (yyGLRStack* yystackp) { yyGLRStackItem* yyp; size_t yyi; for (yyp = yystackp->yyitems; yyp < yystackp->yynextFree; yyp += 1) { fprintf (stderr, "%3lu. ", (unsigned long int) (yyp - yystackp->yyitems)); if (*(yybool *) yyp) { fprintf (stderr, "Res: %d, LR State: %d, posn: %lu, pred: %ld", yyp->yystate.yyresolved, yyp->yystate.yylrState, (unsigned long int) yyp->yystate.yyposn, (long int) YYINDEX (yyp->yystate.yypred)); if (! yyp->yystate.yyresolved) fprintf (stderr, ", firstVal: %ld", (long int) YYINDEX (yyp->yystate.yysemantics.yyfirstVal)); } else { fprintf (stderr, "Option. rule: %d, state: %ld, next: %ld", yyp->yyoption.yyrule - 1, (long int) YYINDEX (yyp->yyoption.yystate), (long int) YYINDEX (yyp->yyoption.yynext)); } fprintf (stderr, "\n"); } fprintf (stderr, "Tops:"); for (yyi = 0; yyi < yystackp->yytops.yysize; yyi += 1) fprintf (stderr, "%lu: %ld; ", (unsigned long int) yyi, (long int) YYINDEX (yystackp->yytops.yystates[yyi])); fprintf (stderr, "\n"); } #endif #line 143 "glr-regr14.y" static void yyerror (char const *msg) { fprintf (stderr, "%s\n", msg); } static int yylex (void) { static char const *input = "abcdddd"; static int i = 0; yylloc.first_line = yylloc.last_line = 1; yylloc.first_column = yylloc.last_column = i + 1; yylval.value = input[i] + 'A' - 'a'; return input[i++]; } static void print_look_ahead (char const *reduction) { printf ("%s:\n yychar=", reduction); if (yychar == YYEMPTY) printf ("YYEMPTY"); else if (yychar == YYEOF) printf ("YYEOF"); else { printf ("'%c', yylval='", yychar); if (yylval.value > ' ') printf ("%c", yylval.value); printf ("', yylloc=(%d,%d),(%d,%d)", yylloc.first_line, yylloc.first_column, yylloc.last_line, yylloc.last_column); } printf ("\n"); } static char merge (union YYSTYPE s1, union YYSTYPE s2) { char dummy = s1.value + s2.value; return dummy; } int main (void) { yychar = '#'; /* Not a token in the grammar. */ yylval.value = '!'; return yyparse (); }