src/reduce.c

/* Grammar reduction for Bison.
   Copyright 1988, 1989, 2000, 2001  Free Software Foundation, Inc.

   This file is part of Bison, the GNU Compiler Compiler.

   Bison 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.

   Bison 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 Bison; see the file COPYING.  If not, write to
   the Free Software Foundation, Inc., 59 Temple Place - Suite 330,
   Boston, MA 02111-1307, USA.  */


/* Reduce the grammar: Find and eliminate unreachable terminals,
   nonterminals, and productions.  David S. Bakin.  */

/* Don't eliminate unreachable terminals: They may be used by the
   user's parser.  */

#include "system.h"
#include "getargs.h"
#include "files.h"
#include "gram.h"
#include "complain.h"
#include "reduce.h"
#include "reader.h"
#include "getargs.h"

typedef unsigned *BSet;
typedef short *rule;


/* N is set of all nonterminals which are not useless.  P is set of
   all rules which have no useless nonterminals in their RHS.  V is
   the set of all accessible symbols.  */

static BSet N, P, V, V1;

static int nuseful_productions;
static int nuseless_productions;
static int nuseful_nonterminals;
static int nuseless_nonterminals;
\f
static bool
bits_equal (BSet L, BSet R, int n)
{
  int i;

  for (i = n - 1; i >= 0; i--)
    if (L[i] != R[i])
      return FALSE;
  return TRUE;
}


static int
nbits (unsigned i)
{
  int count = 0;

  while (i != 0)
    {
      i ^= (i & ((unsigned) (-(int) i)));
      ++count;
    }
  return count;
}


static int
bits_size (BSet S, int n)
{
  int i, count = 0;

  for (i = n - 1; i >= 0; i--)
    count += nbits (S[i]);
  return count;
}
\f
/*-------------------------------------------------------------------.
| Another way to do this would be with a set for each production and |
| then do subset tests against N0, but even for the C grammar the    |
| whole reducing process takes only 2 seconds on my 8Mhz AT.         |
`-------------------------------------------------------------------*/

static bool
useful_production (int i, BSet N0)
{
  rule r;
  short n;

  /* A production is useful if all of the nonterminals in its appear
     in the set of useful nonterminals.  */

  for (r = &ritem[rule_table[i].rhs]; *r > 0; r++)
    if (ISVAR (n = *r))
      if (!BITISSET (N0, n - ntokens))
	return FALSE;
  return TRUE;
}


/*---------------------------------------------------------.
| Remember that rules are 1-origin, symbols are 0-origin.  |
`---------------------------------------------------------*/

static void
useless_nonterminals (void)
{
  BSet Np, Ns;
  int i;

  /* N is set as built.  Np is set being built this iteration. P is
     set of all productions which have a RHS all in N.  */

  Np = XCALLOC (unsigned, WORDSIZE (nvars));

  /* The set being computed is a set of nonterminals which can derive
     the empty string or strings consisting of all terminals. At each
     iteration a nonterminal is added to the set if there is a
     production with that nonterminal as its LHS for which all the
     nonterminals in its RHS are already in the set.  Iterate until
     the set being computed remains unchanged.  Any nonterminals not
     in the set at that point are useless in that they will never be
     used in deriving a sentence of the language.

     This iteration doesn't use any special traversal over the
     productions.  A set is kept of all productions for which all the
     nonterminals in the RHS are in useful.  Only productions not in
     this set are scanned on each iteration.  At the end, this set is
     saved to be used when finding useful productions: only
     productions in this set will appear in the final grammar.  */

  while (1)
    {
      for (i = WORDSIZE (nvars) - 1; i >= 0; i--)
	Np[i] = N[i];
      for (i = 1; i <= nrules; i++)
	{
	  if (!BITISSET (P, i))
	    {
	      if (useful_production (i, N))
		{
		  SETBIT (Np, rule_table[i].lhs - ntokens);
		  SETBIT (P, i);
		}
	    }
	}
      if (bits_equal (N, Np, WORDSIZE (nvars)))
	break;
      Ns = Np;
      Np = N;
      N = Ns;
    }
  XFREE (N);
  N = Np;
}


static void
inaccessable_symbols (void)
{
  BSet Vp, Vs, Pp;
  int i;
  short t;
  rule r;

  /* Find out which productions are reachable and which symbols are
     used.  Starting with an empty set of productions and a set of
     symbols which only has the start symbol in it, iterate over all
     productions until the set of productions remains unchanged for an
     iteration.  For each production which has a LHS in the set of
     reachable symbols, add the production to the set of reachable
     productions, and add all of the nonterminals in the RHS of the
     production to the set of reachable symbols.

     Consider only the (partially) reduced grammar which has only
     nonterminals in N and productions in P.

     The result is the set P of productions in the reduced grammar,
     and the set V of symbols in the reduced grammar.

     Although this algorithm also computes the set of terminals which
     are reachable, no terminal will be deleted from the grammar. Some
     terminals might not be in the grammar but might be generated by
     semantic routines, and so the user might want them available with
     specified numbers.  (Is this true?)  However, the nonreachable
     terminals are printed (if running in verbose mode) so that the
     user can know.  */

  Vp = XCALLOC (unsigned, WORDSIZE (nsyms));
  Pp = XCALLOC (unsigned, WORDSIZE (nrules + 1));

  /* If the start symbol isn't useful, then nothing will be useful. */
  if (BITISSET (N, start_symbol - ntokens))
    {
      SETBIT (V, start_symbol);

      while (1)
	{
	  for (i = WORDSIZE (nsyms) - 1; i >= 0; i--)
	    Vp[i] = V[i];
	  for (i = 1; i <= nrules; i++)
	    {
	      if (!BITISSET (Pp, i)
		  && BITISSET (P, i)
		  && BITISSET (V, rule_table[i].lhs))
		{
		  for (r = &ritem[rule_table[i].rhs]; *r >= 0; r++)
		    if (ISTOKEN (t = *r) || BITISSET (N, t - ntokens))
		      SETBIT (Vp, t);
		  SETBIT (Pp, i);
		}
	    }
	  if (bits_equal (V, Vp, WORDSIZE (nsyms)))
	    break;
	  Vs = Vp;
	  Vp = V;
	  V = Vs;
	}
    }

  XFREE (V);
  V = Vp;

  /* Tokens 0, 1, and 2 are internal to Bison.  Consider them useful. */
  SETBIT (V, 0);		/* end-of-input token */
  SETBIT (V, 1);		/* error token */
  SETBIT (V, 2);		/* some undefined token */

  XFREE (P);
  P = Pp;

  nuseful_productions = bits_size (P, WORDSIZE (nrules + 1));
  nuseless_productions = nrules - nuseful_productions;

  nuseful_nonterminals = 0;
  for (i = ntokens; i < nsyms; i++)
    if (BITISSET (V, i))
      nuseful_nonterminals++;
  nuseless_nonterminals = nvars - nuseful_nonterminals;

  /* A token that was used in %prec should not be warned about.  */
  for (i = 1; i < nrules; i++)
    if (rule_table[i].precsym != 0)
      SETBIT (V1, rule_table[i].precsym);
}

static void
reduce_grammar_tables (void)
{
/* This is turned off because we would need to change the numbers
   in the case statements in the actions file.  */
#if 0
  /* remove useless productions */
  if (nuseless_productions > 0)
    {
      short np, pn, ni, pi;

      np = 0;
      ni = 0;
      for (pn = 1; pn <= nrules; pn++)
	{
	  if (BITISSET (P, pn))
	    {
	      np++;
	      if (pn != np)
		{
		  rule_table[np].lhs = rule_table[pn].lhs;
		  rline[np] = rline[pn];
		  rule_table[np].prec = rule_table[pn].prec;
		  rule_table[np].assoc = rule_table[pn].assoc;
		  rule_table[np].rhs = rule_table[pn].rhs;
		  if (rule_table[np].rhs != ni)
		    {
		      pi = rule_table[np].rhs;
		      rule_table[np].rhs = ni;
		      while (ritem[pi] >= 0)
			ritem[ni++] = ritem[pi++];
		      ritem[ni++] = -np;
		    }
		}
	      else
		{
		  while (ritem[ni++] >= 0);
		}
	    }
	}
      ritem[ni] = 0;
      nrules -= nuseless_productions;
      nitems = ni;

      /* Is it worth it to reduce the amount of memory for the
         grammar? Probably not.  */

    }
#endif /* 0 */
  /* Disable useless productions,
     since they may contain useless nonterms
     that would get mapped below to -1 and confuse everyone.  */
  if (nuseless_productions > 0)
    {
      int pn;

      for (pn = 1; pn <= nrules; pn++)
	{
	  if (!BITISSET (P, pn))
	    {
	      rule_table[pn].lhs = -1;
	    }
	}
    }

  /* remove useless symbols */
  if (nuseless_nonterminals > 0)
    {

      int i, n;
/*      short  j; JF unused */
      short *nontermmap;
      rule r;

      /* Create a map of nonterminal number to new nonterminal
	 number. -1 in the map means it was useless and is being
	 eliminated.  */

      nontermmap = XCALLOC (short, nvars) - ntokens;
      for (i = ntokens; i < nsyms; i++)
	nontermmap[i] = -1;

      n = ntokens;
      for (i = ntokens; i < nsyms; i++)
	if (BITISSET (V, i))
	  nontermmap[i] = n++;

      /* Shuffle elements of tables indexed by symbol number.  */

      for (i = ntokens; i < nsyms; i++)
	{
	  n = nontermmap[i];
	  if (n >= 0)
	    {
	      sassoc[n] = sassoc[i];
	      sprec[n] = sprec[i];
	      tags[n] = tags[i];
	    }
	  else
	    {
	      free (tags[i]);
	    }
	}

      /* Replace all symbol numbers in valid data structures.  */

      for (i = 1; i <= nrules; i++)
	{
	  /* Ignore the rules disabled above.  */
	  if (rule_table[i].lhs >= 0)
	    rule_table[i].lhs = nontermmap[rule_table[i].lhs];
	  if (ISVAR (rule_table[i].precsym))
	    /* Can this happen?  */
	    rule_table[i].precsym = nontermmap[rule_table[i].precsym];
	}

      for (r = ritem; *r; r++)
	if (ISVAR (*r))
	  *r = nontermmap[*r];

      start_symbol = nontermmap[start_symbol];

      nsyms -= nuseless_nonterminals;
      nvars -= nuseless_nonterminals;

      free (&nontermmap[ntokens]);
    }
}


/*-----------------------------------------------------------------.
| Ouput the detailed results of the reductions.  For FILE.output.  |
`-----------------------------------------------------------------*/

void
reduce_output (FILE *out)
{
  int i;
  rule r;
  bool b;

  if (nuseless_nonterminals > 0)
    {
      fprintf (out, _("Useless nonterminals:"));
      fprintf (out, "\n\n");
      for (i = ntokens; i < nsyms; i++)
	if (!BITISSET (V, i))
	  fprintf (out, "   %s\n", tags[i]);
    }
  b = FALSE;
  for (i = 0; i < ntokens; i++)
    {
      if (!BITISSET (V, i) && !BITISSET (V1, i))
	{
	  if (!b)
	    {
	      fprintf (out, "\n\n");
	      fprintf (out, _("Terminals which are not used:"));
	      fprintf (out, "\n\n");
	      b = TRUE;
	    }
	  fprintf (out, "   %s\n", tags[i]);
	}
    }

  if (nuseless_productions > 0)
    {
      fprintf (out, "\n\n");
      fprintf (out, _("Useless rules:"));
      fprintf (out, "\n\n");
      for (i = 1; i <= nrules; i++)
	if (!BITISSET (P, i))
	  {
	    fprintf (out, "#%-4d  ", i);
	    fprintf (out, "%s :\t", tags[rule_table[i].lhs]);
	    for (r = &ritem[rule_table[i].rhs]; *r >= 0; r++)
	      fprintf (out, " %s", tags[*r]);
	    fprintf (out, ";\n");
	  }
    }
  if (nuseless_nonterminals > 0 || nuseless_productions > 0 || b)
    fprintf (out, "\n\n");
}
\f
static void
dump_grammar (FILE *out)
{
  int i;
  rule r;

  fprintf (out, "REDUCED GRAMMAR\n\n");
  fprintf (out,
	 "ntokens = %d, nvars = %d, nsyms = %d, nrules = %d, nitems = %d\n\n",
	 ntokens, nvars, nsyms, nrules, nitems);
  fprintf (out, _("Variables\n---------\n\n"));
  fprintf (out, _("Value  Sprec    Sassoc    Tag\n"));
  for (i = ntokens; i < nsyms; i++)
    fprintf (out, "%5d  %5d  %5d  %s\n", i, sprec[i], sassoc[i], tags[i]);
  fprintf (out, "\n\n");
  fprintf (out, _("Rules\n-----\n\n"));
  for (i = 1; i <= nrules; i++)
    {
      fprintf (out, "%-5d(%5d%5d)%5d : (@%-5d)",
	       i,
	       rule_table[i].prec,
	       rule_table[i].assoc,
	       rule_table[i].lhs,
	       rule_table[i].rhs);
      for (r = &ritem[rule_table[i].rhs]; *r > 0; r++)
	fprintf (out, "%5d", *r);
      fprintf (out, " [%d]\n", -(*r));
    }
  fprintf (out, "\n\n");
  fprintf (out, _("Rules interpreted\n-----------------\n\n"));
  for (i = 1; i <= nrules; i++)
    {
      fprintf (out, "%-5d  %s :", i, tags[rule_table[i].lhs]);
      for (r = &ritem[rule_table[i].rhs]; *r > 0; r++)
	fprintf (out, " %s", tags[*r]);
      fputc ('\n', out);
    }
  fprintf (out, "\n\n");
}


/*-------------------------------.
| Report the results to STDERR.  |
`-------------------------------*/

static void
reduce_print (void)
{
  if (yacc_flag && nuseless_productions)
    fprintf (stderr, _("%d rules never reduced\n"), nuseless_productions);

  fprintf (stderr, _("%s contains "), infile);

  if (nuseless_nonterminals > 0)
    {
      fprintf (stderr, _("%d useless nonterminal%s"),
	       nuseless_nonterminals,
	       (nuseless_nonterminals == 1 ? "" : "s"));
    }
  if (nuseless_nonterminals > 0 && nuseless_productions > 0)
    fprintf (stderr, _(" and "));

  if (nuseless_productions > 0)
    {
      fprintf (stderr, _("%d useless rule%s"),
	       nuseless_productions, (nuseless_productions == 1 ? "" : "s"));
    }
  fprintf (stderr, "\n");
  fflush (stderr);
}
\f
void
reduce_grammar (void)
{
  bool reduced;

  /* Allocate the global sets used to compute the reduced grammar */

  N = XCALLOC (unsigned, WORDSIZE (nvars));
  P = XCALLOC (unsigned, WORDSIZE (nrules + 1));
  V = XCALLOC (unsigned, WORDSIZE (nsyms));
  V1 = XCALLOC (unsigned, WORDSIZE (nsyms));

  useless_nonterminals ();
  inaccessable_symbols ();

  reduced = (bool) (nuseless_nonterminals + nuseless_productions > 0);

  if (!reduced)
    return;

  reduce_print ();

  if (!BITISSET (N, start_symbol - ntokens))
    fatal (_("Start symbol %s does not derive any sentence"),
	   tags[start_symbol]);

  reduce_grammar_tables ();

  if (trace_flag)
    {
      dump_grammar (stderr);

      fprintf (stderr, "reduced %s defines %d terminals, %d nonterminals\
, and %d productions.\n",
	       infile, ntokens, nvars, nrules);
    }
}


/*-----------------------------------------------------------.
| Free the global sets used to compute the reduced grammar.  |
`-----------------------------------------------------------*/

void
reduce_free (void)
{
  XFREE (N);
  XFREE (V);
  XFREE (V1);
  XFREE (P);
}
Commit	Line	Data
	1	/* Grammar reduction for Bison.
	2	Copyright 1988, 1989, 2000, 2001 Free Software Foundation, Inc.
	3
	4	This file is part of Bison, the GNU Compiler Compiler.
	5
	6	Bison is free software; you can redistribute it and/or modify
	7	it under the terms of the GNU General Public License as published by
	8	the Free Software Foundation; either version 2, or (at your option)
	9	any later version.
	10
	11	Bison is distributed in the hope that it will be useful,
	12	but WITHOUT ANY WARRANTY; without even the implied warranty of
	13	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	14	GNU General Public License for more details.
	15
	16	You should have received a copy of the GNU General Public License
	17	along with Bison; see the file COPYING. If not, write to
	18	the Free Software Foundation, Inc., 59 Temple Place - Suite 330,
	19	Boston, MA 02111-1307, USA. */
	20
	21
	22	/* Reduce the grammar: Find and eliminate unreachable terminals,
	23	nonterminals, and productions. David S. Bakin. */
	24
	25	/* Don't eliminate unreachable terminals: They may be used by the
	26	user's parser. */
	27
	28	#include "system.h"
	29	#include "getargs.h"
	30	#include "files.h"
	31	#include "gram.h"
	32	#include "complain.h"
	33	#include "reduce.h"
	34	#include "reader.h"
	35	#include "getargs.h"
	36
	37	typedef unsigned *BSet;
	38	typedef short *rule;
	39
	40
	41	/* N is set of all nonterminals which are not useless. P is set of
	42	all rules which have no useless nonterminals in their RHS. V is
	43	the set of all accessible symbols. */
	44
	45	static BSet N, P, V, V1;
	46
	47	static int nuseful_productions;
	48	static int nuseless_productions;
	49	static int nuseful_nonterminals;
	50	static int nuseless_nonterminals;
	51	\f
	52	static bool
	53	bits_equal (BSet L, BSet R, int n)
	54	{
	55	int i;
	56
	57	for (i = n - 1; i >= 0; i--)
	58	if (L[i] != R[i])
	59	return FALSE;
	60	return TRUE;
	61	}
	62
	63
	64	static int
	65	nbits (unsigned i)
	66	{
	67	int count = 0;
	68
	69	while (i != 0)
	70	{
	71	i ^= (i & ((unsigned) (-(int) i)));
	72	++count;
	73	}
	74	return count;
	75	}
	76
	77
	78	static int
	79	bits_size (BSet S, int n)
	80	{
	81	int i, count = 0;
	82
	83	for (i = n - 1; i >= 0; i--)
	84	count += nbits (S[i]);
	85	return count;
	86	}
	87	\f
	88	/*-------------------------------------------------------------------.
	89	\| Another way to do this would be with a set for each production and \|
	90	\| then do subset tests against N0, but even for the C grammar the \|
	91	\| whole reducing process takes only 2 seconds on my 8Mhz AT. \|
	92	`-------------------------------------------------------------------*/
	93
	94	static bool
	95	useful_production (int i, BSet N0)
	96	{
	97	rule r;
	98	short n;
	99
	100	/* A production is useful if all of the nonterminals in its appear
	101	in the set of useful nonterminals. */
	102
	103	for (r = &ritem[rule_table[i].rhs]; *r > 0; r++)
	104	if (ISVAR (n = *r))
	105	if (!BITISSET (N0, n - ntokens))
	106	return FALSE;
	107	return TRUE;
	108	}
	109
	110
	111	/*---------------------------------------------------------.
	112	\| Remember that rules are 1-origin, symbols are 0-origin. \|
	113	`---------------------------------------------------------*/
	114
	115	static void
	116	useless_nonterminals (void)
	117	{
	118	BSet Np, Ns;
	119	int i;
	120
	121	/* N is set as built. Np is set being built this iteration. P is
	122	set of all productions which have a RHS all in N. */
	123
	124	Np = XCALLOC (unsigned, WORDSIZE (nvars));
	125
	126	/* The set being computed is a set of nonterminals which can derive
	127	the empty string or strings consisting of all terminals. At each
	128	iteration a nonterminal is added to the set if there is a
	129	production with that nonterminal as its LHS for which all the
	130	nonterminals in its RHS are already in the set. Iterate until
	131	the set being computed remains unchanged. Any nonterminals not
	132	in the set at that point are useless in that they will never be
	133	used in deriving a sentence of the language.
	134
	135	This iteration doesn't use any special traversal over the
	136	productions. A set is kept of all productions for which all the
	137	nonterminals in the RHS are in useful. Only productions not in
	138	this set are scanned on each iteration. At the end, this set is
	139	saved to be used when finding useful productions: only
	140	productions in this set will appear in the final grammar. */
	141
	142	while (1)
	143	{
	144	for (i = WORDSIZE (nvars) - 1; i >= 0; i--)
	145	Np[i] = N[i];
	146	for (i = 1; i <= nrules; i++)
	147	{
	148	if (!BITISSET (P, i))
	149	{
	150	if (useful_production (i, N))
	151	{
	152	SETBIT (Np, rule_table[i].lhs - ntokens);
	153	SETBIT (P, i);
	154	}
	155	}
	156	}
	157	if (bits_equal (N, Np, WORDSIZE (nvars)))
	158	break;
	159	Ns = Np;
	160	Np = N;
	161	N = Ns;
	162	}
	163	XFREE (N);
	164	N = Np;
	165	}
	166
	167
	168	static void
	169	inaccessable_symbols (void)
	170	{
	171	BSet Vp, Vs, Pp;
	172	int i;
	173	short t;
	174	rule r;
	175
	176	/* Find out which productions are reachable and which symbols are
	177	used. Starting with an empty set of productions and a set of
	178	symbols which only has the start symbol in it, iterate over all
	179	productions until the set of productions remains unchanged for an
	180	iteration. For each production which has a LHS in the set of
	181	reachable symbols, add the production to the set of reachable
	182	productions, and add all of the nonterminals in the RHS of the
	183	production to the set of reachable symbols.
	184
	185	Consider only the (partially) reduced grammar which has only
	186	nonterminals in N and productions in P.
	187
	188	The result is the set P of productions in the reduced grammar,
	189	and the set V of symbols in the reduced grammar.
	190
	191	Although this algorithm also computes the set of terminals which
	192	are reachable, no terminal will be deleted from the grammar. Some
	193	terminals might not be in the grammar but might be generated by
	194	semantic routines, and so the user might want them available with
	195	specified numbers. (Is this true?) However, the nonreachable
	196	terminals are printed (if running in verbose mode) so that the
	197	user can know. */
	198
	199	Vp = XCALLOC (unsigned, WORDSIZE (nsyms));
	200	Pp = XCALLOC (unsigned, WORDSIZE (nrules + 1));
	201
	202	/* If the start symbol isn't useful, then nothing will be useful. */
	203	if (BITISSET (N, start_symbol - ntokens))
	204	{
	205	SETBIT (V, start_symbol);
	206
	207	while (1)
	208	{
	209	for (i = WORDSIZE (nsyms) - 1; i >= 0; i--)
	210	Vp[i] = V[i];
	211	for (i = 1; i <= nrules; i++)
	212	{
	213	if (!BITISSET (Pp, i)
	214	&& BITISSET (P, i)
	215	&& BITISSET (V, rule_table[i].lhs))
	216	{
	217	for (r = &ritem[rule_table[i].rhs]; *r >= 0; r++)
	218	if (ISTOKEN (t = *r) \|\| BITISSET (N, t - ntokens))
	219	SETBIT (Vp, t);
	220	SETBIT (Pp, i);
	221	}
	222	}
	223	if (bits_equal (V, Vp, WORDSIZE (nsyms)))
	224	break;
	225	Vs = Vp;
	226	Vp = V;
	227	V = Vs;
	228	}
	229	}
	230
	231	XFREE (V);
	232	V = Vp;
	233
	234	/* Tokens 0, 1, and 2 are internal to Bison. Consider them useful. */
	235	SETBIT (V, 0); /* end-of-input token */
	236	SETBIT (V, 1); /* error token */
	237	SETBIT (V, 2); /* some undefined token */
	238
	239	XFREE (P);
	240	P = Pp;
	241
	242	nuseful_productions = bits_size (P, WORDSIZE (nrules + 1));
	243	nuseless_productions = nrules - nuseful_productions;
	244
	245	nuseful_nonterminals = 0;
	246	for (i = ntokens; i < nsyms; i++)
	247	if (BITISSET (V, i))
	248	nuseful_nonterminals++;
	249	nuseless_nonterminals = nvars - nuseful_nonterminals;
	250
	251	/* A token that was used in %prec should not be warned about. */
	252	for (i = 1; i < nrules; i++)
	253	if (rule_table[i].precsym != 0)
	254	SETBIT (V1, rule_table[i].precsym);
	255	}
	256
	257	static void
	258	reduce_grammar_tables (void)
	259	{
	260	/* This is turned off because we would need to change the numbers
	261	in the case statements in the actions file. */
	262	#if 0
	263	/* remove useless productions */
	264	if (nuseless_productions > 0)
	265	{
	266	short np, pn, ni, pi;
	267
	268	np = 0;
	269	ni = 0;
	270	for (pn = 1; pn <= nrules; pn++)
	271	{
	272	if (BITISSET (P, pn))
	273	{
	274	np++;
	275	if (pn != np)
	276	{
	277	rule_table[np].lhs = rule_table[pn].lhs;
	278	rline[np] = rline[pn];
	279	rule_table[np].prec = rule_table[pn].prec;
	280	rule_table[np].assoc = rule_table[pn].assoc;
	281	rule_table[np].rhs = rule_table[pn].rhs;
	282	if (rule_table[np].rhs != ni)
	283	{
	284	pi = rule_table[np].rhs;
	285	rule_table[np].rhs = ni;
	286	while (ritem[pi] >= 0)
	287	ritem[ni++] = ritem[pi++];
	288	ritem[ni++] = -np;
	289	}
	290	}
	291	else
	292	{
	293	while (ritem[ni++] >= 0);
	294	}
	295	}
	296	}
	297	ritem[ni] = 0;
	298	nrules -= nuseless_productions;
	299	nitems = ni;
	300
	301	/* Is it worth it to reduce the amount of memory for the
	302	grammar? Probably not. */
	303
	304	}
	305	#endif /* 0 */
	306	/* Disable useless productions,
	307	since they may contain useless nonterms
	308	that would get mapped below to -1 and confuse everyone. */
	309	if (nuseless_productions > 0)
	310	{
	311	int pn;
	312
	313	for (pn = 1; pn <= nrules; pn++)
	314	{
	315	if (!BITISSET (P, pn))
	316	{
	317	rule_table[pn].lhs = -1;
	318	}
	319	}
	320	}
	321
	322	/* remove useless symbols */
	323	if (nuseless_nonterminals > 0)
	324	{
	325
	326	int i, n;
	327	/* short j; JF unused */
	328	short *nontermmap;
	329	rule r;
	330
	331	/* Create a map of nonterminal number to new nonterminal
	332	number. -1 in the map means it was useless and is being
	333	eliminated. */
	334
	335	nontermmap = XCALLOC (short, nvars) - ntokens;
	336	for (i = ntokens; i < nsyms; i++)
	337	nontermmap[i] = -1;
	338
	339	n = ntokens;
	340	for (i = ntokens; i < nsyms; i++)
	341	if (BITISSET (V, i))
	342	nontermmap[i] = n++;
	343
	344	/* Shuffle elements of tables indexed by symbol number. */
	345
	346	for (i = ntokens; i < nsyms; i++)
	347	{
	348	n = nontermmap[i];
	349	if (n >= 0)
	350	{
	351	sassoc[n] = sassoc[i];
	352	sprec[n] = sprec[i];
	353	tags[n] = tags[i];
	354	}
	355	else
	356	{
	357	free (tags[i]);
	358	}
	359	}
	360
	361	/* Replace all symbol numbers in valid data structures. */
	362
	363	for (i = 1; i <= nrules; i++)
	364	{
	365	/* Ignore the rules disabled above. */
	366	if (rule_table[i].lhs >= 0)
	367	rule_table[i].lhs = nontermmap[rule_table[i].lhs];
	368	if (ISVAR (rule_table[i].precsym))
	369	/* Can this happen? */
	370	rule_table[i].precsym = nontermmap[rule_table[i].precsym];
	371	}
	372
	373	for (r = ritem; *r; r++)
	374	if (ISVAR (*r))
	375	r = nontermmap[r];
	376
	377	start_symbol = nontermmap[start_symbol];
	378
	379	nsyms -= nuseless_nonterminals;
	380	nvars -= nuseless_nonterminals;
	381
	382	free (&nontermmap[ntokens]);
	383	}
	384	}
	385
	386
	387	/*-----------------------------------------------------------------.
	388	\| Ouput the detailed results of the reductions. For FILE.output. \|
	389	`-----------------------------------------------------------------*/
	390
	391	void
	392	reduce_output (FILE *out)
	393	{
	394	int i;
	395	rule r;
	396	bool b;
	397
	398	if (nuseless_nonterminals > 0)
	399	{
	400	fprintf (out, _("Useless nonterminals:"));
	401	fprintf (out, "\n\n");
	402	for (i = ntokens; i < nsyms; i++)
	403	if (!BITISSET (V, i))
	404	fprintf (out, " %s\n", tags[i]);
	405	}
	406	b = FALSE;
	407	for (i = 0; i < ntokens; i++)
	408	{
	409	if (!BITISSET (V, i) && !BITISSET (V1, i))
	410	{
	411	if (!b)
	412	{
	413	fprintf (out, "\n\n");
	414	fprintf (out, _("Terminals which are not used:"));
	415	fprintf (out, "\n\n");
	416	b = TRUE;
	417	}
	418	fprintf (out, " %s\n", tags[i]);
	419	}
	420	}
	421
	422	if (nuseless_productions > 0)
	423	{
	424	fprintf (out, "\n\n");
	425	fprintf (out, _("Useless rules:"));
	426	fprintf (out, "\n\n");
	427	for (i = 1; i <= nrules; i++)
	428	if (!BITISSET (P, i))
	429	{
	430	fprintf (out, "#%-4d ", i);
	431	fprintf (out, "%s :\t", tags[rule_table[i].lhs]);
	432	for (r = &ritem[rule_table[i].rhs]; *r >= 0; r++)
	433	fprintf (out, " %s", tags[*r]);
	434	fprintf (out, ";\n");
	435	}
	436	}
	437	if (nuseless_nonterminals > 0 \|\| nuseless_productions > 0 \|\| b)
	438	fprintf (out, "\n\n");
	439	}
	440	\f
	441	static void
	442	dump_grammar (FILE *out)
	443	{
	444	int i;
	445	rule r;
	446
	447	fprintf (out, "REDUCED GRAMMAR\n\n");
	448	fprintf (out,
	449	"ntokens = %d, nvars = %d, nsyms = %d, nrules = %d, nitems = %d\n\n",
	450	ntokens, nvars, nsyms, nrules, nitems);
	451	fprintf (out, _("Variables\n---------\n\n"));
	452	fprintf (out, _("Value Sprec Sassoc Tag\n"));
	453	for (i = ntokens; i < nsyms; i++)
	454	fprintf (out, "%5d %5d %5d %s\n", i, sprec[i], sassoc[i], tags[i]);
	455	fprintf (out, "\n\n");
	456	fprintf (out, _("Rules\n-----\n\n"));
	457	for (i = 1; i <= nrules; i++)
	458	{
	459	fprintf (out, "%-5d(%5d%5d)%5d : (@%-5d)",
	460	i,
	461	rule_table[i].prec,
	462	rule_table[i].assoc,
	463	rule_table[i].lhs,
	464	rule_table[i].rhs);
	465	for (r = &ritem[rule_table[i].rhs]; *r > 0; r++)
	466	fprintf (out, "%5d", *r);
	467	fprintf (out, " [%d]\n", -(*r));
	468	}
	469	fprintf (out, "\n\n");
	470	fprintf (out, _("Rules interpreted\n-----------------\n\n"));
	471	for (i = 1; i <= nrules; i++)
	472	{
	473	fprintf (out, "%-5d %s :", i, tags[rule_table[i].lhs]);
	474	for (r = &ritem[rule_table[i].rhs]; *r > 0; r++)
	475	fprintf (out, " %s", tags[*r]);
	476	fputc ('\n', out);
	477	}
	478	fprintf (out, "\n\n");
	479	}
	480
	481
	482
	483	/*-------------------------------.
	484	\| Report the results to STDERR. \|
	485	`-------------------------------*/
	486
	487	static void
	488	reduce_print (void)
	489	{
	490	if (yacc_flag && nuseless_productions)
	491	fprintf (stderr, _("%d rules never reduced\n"), nuseless_productions);
	492
	493	fprintf (stderr, _("%s contains "), infile);
	494
	495	if (nuseless_nonterminals > 0)
	496	{
	497	fprintf (stderr, _("%d useless nonterminal%s"),
	498	nuseless_nonterminals,
	499	(nuseless_nonterminals == 1 ? "" : "s"));
	500	}
	501	if (nuseless_nonterminals > 0 && nuseless_productions > 0)
	502	fprintf (stderr, _(" and "));
	503
	504	if (nuseless_productions > 0)
	505	{
	506	fprintf (stderr, _("%d useless rule%s"),
	507	nuseless_productions, (nuseless_productions == 1 ? "" : "s"));
	508	}
	509	fprintf (stderr, "\n");
	510	fflush (stderr);
	511	}
	512	\f
	513	void
	514	reduce_grammar (void)
	515	{
	516	bool reduced;
	517
	518	/* Allocate the global sets used to compute the reduced grammar */
	519
	520	N = XCALLOC (unsigned, WORDSIZE (nvars));
	521	P = XCALLOC (unsigned, WORDSIZE (nrules + 1));
	522	V = XCALLOC (unsigned, WORDSIZE (nsyms));
	523	V1 = XCALLOC (unsigned, WORDSIZE (nsyms));
	524
	525	useless_nonterminals ();
	526	inaccessable_symbols ();
	527
	528	reduced = (bool) (nuseless_nonterminals + nuseless_productions > 0);
	529
	530	if (!reduced)
	531	return;
	532
	533	reduce_print ();
	534
	535	if (!BITISSET (N, start_symbol - ntokens))
	536	fatal (_("Start symbol %s does not derive any sentence"),
	537	tags[start_symbol]);
	538
	539	reduce_grammar_tables ();
	540
	541	if (trace_flag)
	542	{
	543	dump_grammar (stderr);
	544
	545	fprintf (stderr, "reduced %s defines %d terminals, %d nonterminals\
	546	, and %d productions.\n",
	547	infile, ntokens, nvars, nrules);
	548	}
	549	}
	550
	551
	552	/*-----------------------------------------------------------.
	553	\| Free the global sets used to compute the reduced grammar. \|
	554	`-----------------------------------------------------------*/
	555
	556	void
	557	reduce_free (void)
	558	{
	559	XFREE (N);
	560	XFREE (V);
	561	XFREE (V1);
	562	XFREE (P);
	563	}