src/LR0.c

/* Generate the nondeterministic finite state machine for Bison.

   Copyright (C) 1984, 1986, 1989, 2000, 2001, 2002, 2004 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., 51 Franklin Street, Fifth Floor,
   Boston, MA 02110-1301, USA.  */


/* See comments in state.h for the data structures that represent it.
   The entry point is generate_states.  */

#include "system.h"

#include <bitset.h>
#include <quotearg.h>

#include "LR0.h"
#include "closure.h"
#include "complain.h"
#include "getargs.h"
#include "gram.h"
#include "gram.h"
#include "lalr.h"
#include "reader.h"
#include "reduce.h"
#include "state.h"
#include "symtab.h"

typedef struct state_list
{
  struct state_list *next;
  state *state;
} state_list;

static state_list *first_state = NULL;
static state_list *last_state = NULL;


/*------------------------------------------------------------------.
| A state was just discovered from another state.  Queue it for     |
| later examination, in order to find its transitions.  Return it.  |
`------------------------------------------------------------------*/

static state *
state_list_append (symbol_number sym, size_t core_size, item_number *core)
{
  state_list *node = xmalloc (sizeof *node);
  state *s = state_new (sym, core_size, core);

  if (trace_flag & trace_automaton)
    fprintf (stderr, "state_list_append (state = %d, symbol = %d (%s))\n",
	     nstates, sym, symbols[sym]->tag);

  /* If this is the endtoken, and this is not the initial state, then
     this is the final state.  */
  if (sym == 0 && first_state)
    final_state = s;

  node->next = NULL;
  node->state = s;

  if (!first_state)
    first_state = node;
  if (last_state)
    last_state->next = node;
  last_state = node;

  return s;
}

static int nshifts;
static symbol_number *shift_symbol;

static rule **redset;
static state **shiftset;

static item_number **kernel_base;
static int *kernel_size;
static item_number *kernel_items;

\f
static void
allocate_itemsets (void)
{
  symbol_number i;
  rule_number r;
  item_number *rhsp;

  /* Count the number of occurrences of all the symbols in RITEMS.
     Note that useless productions (hence useless nonterminals) are
     browsed too, hence we need to allocate room for _all_ the
     symbols.  */
  size_t count = 0;
  size_t *symbol_count = xcalloc (nsyms + nuseless_nonterminals,
				  sizeof *symbol_count);

  for (r = 0; r < nrules; ++r)
    for (rhsp = rules[r].rhs; *rhsp >= 0; ++rhsp)
      {
	count++;
	symbol_count[*rhsp]++;
      }

  /* See comments before new_itemsets.  All the vectors of items
     live inside KERNEL_ITEMS.  The number of active items after
     some symbol S cannot be more than the number of times that S
     appears as an item, which is SYMBOL_COUNT[S].
     We allocate that much space for each symbol.  */

  kernel_base = xnmalloc (nsyms, sizeof *kernel_base);
  kernel_items = xnmalloc (count, sizeof *kernel_items);

  count = 0;
  for (i = 0; i < nsyms; i++)
    {
      kernel_base[i] = kernel_items + count;
      count += symbol_count[i];
    }

  free (symbol_count);
  kernel_size = xnmalloc (nsyms, sizeof *kernel_size);
}


static void
allocate_storage (void)
{
  allocate_itemsets ();

  shiftset = xnmalloc (nsyms, sizeof *shiftset);
  redset = xnmalloc (nrules, sizeof *redset);
  state_hash_new ();
  shift_symbol = xnmalloc (nsyms, sizeof *shift_symbol);
}


static void
free_storage (void)
{
  free (shift_symbol);
  free (redset);
  free (shiftset);
  free (kernel_base);
  free (kernel_size);
  free (kernel_items);
  state_hash_free ();
}


/*---------------------------------------------------------------.
| Find which symbols can be shifted in S, and for each one       |
| record which items would be active after that shift.  Uses the |
| contents of itemset.                                           |
|                                                                |
| shift_symbol is set to a vector of the symbols that can be     |
| shifted.  For each symbol in the grammar, kernel_base[symbol]  |
| points to a vector of item numbers activated if that symbol is |
| shifted, and kernel_size[symbol] is their numbers.             |
`---------------------------------------------------------------*/

static void
new_itemsets (state *s)
{
  size_t i;

  if (trace_flag & trace_automaton)
    fprintf (stderr, "Entering new_itemsets, state = %d\n", s->number);

  memset (kernel_size, 0, nsyms * sizeof *kernel_size);

  nshifts = 0;

  for (i = 0; i < nritemset; ++i)
    if (ritem[itemset[i]] >= 0)
      {
	symbol_number sym = item_number_as_symbol_number (ritem[itemset[i]]);
	if (!kernel_size[sym])
	  {
	    shift_symbol[nshifts] = sym;
	    nshifts++;
	  }

	kernel_base[sym][kernel_size[sym]] = itemset[i] + 1;
	kernel_size[sym]++;
      }
}


/*--------------------------------------------------------------.
| Find the state we would get to (from the current state) by    |
| shifting SYM.  Create a new state if no equivalent one exists |
| already.  Used by append_states.                              |
`--------------------------------------------------------------*/

static state *
get_state (symbol_number sym, size_t core_size, item_number *core)
{
  state *sp;

  if (trace_flag & trace_automaton)
    fprintf (stderr, "Entering get_state, symbol = %d (%s)\n",
	     sym, symbols[sym]->tag);

  sp = state_hash_lookup (core_size, core);
  if (!sp)
    sp = state_list_append (sym, core_size, core);

  if (trace_flag & trace_automaton)
    fprintf (stderr, "Exiting get_state => %d\n", sp->number);

  return sp;
}

/*---------------------------------------------------------------.
| Use the information computed by new_itemsets to find the state |
| numbers reached by each shift transition from S.		 |
|                                                                |
| SHIFTSET is set up as a vector of those states.                |
`---------------------------------------------------------------*/

static void
append_states (state *s)
{
  int i;

  if (trace_flag & trace_automaton)
    fprintf (stderr, "Entering append_states, state = %d\n", s->number);

  /* First sort shift_symbol into increasing order.  */

  for (i = 1; i < nshifts; i++)
    {
      symbol_number sym = shift_symbol[i];
      int j;
      for (j = i; 0 < j && sym < shift_symbol[j - 1]; j--)
	shift_symbol[j] = shift_symbol[j - 1];
      shift_symbol[j] = sym;
    }

  for (i = 0; i < nshifts; i++)
    {
      symbol_number sym = shift_symbol[i];
      shiftset[i] = get_state (sym, kernel_size[sym], kernel_base[sym]);
    }
}


/*----------------------------------------------------------------.
| Find which rules can be used for reduction transitions from the |
| current state and make a reductions structure for the state to  |
| record their rule numbers.                                      |
`----------------------------------------------------------------*/

static void
save_reductions (state *s)
{
  int count = 0;
  size_t i;

  /* Find and count the active items that represent ends of rules. */
  for (i = 0; i < nritemset; ++i)
    {
      int item = ritem[itemset[i]];
      if (item < 0)
	redset[count++] = &rules[item_number_as_rule_number (item)];
    }

  /* Make a reductions structure and copy the data into it.  */
  state_reductions_set (s, count, redset);
}

\f
/*---------------.
| Build STATES.  |
`---------------*/

static void
set_states (void)
{
  states = xcalloc (nstates, sizeof *states);

  while (first_state)
    {
      state_list *this = first_state;

      /* Pessimization, but simplification of the code: make sure all
	 the states have valid transitions and reductions members,
	 even if reduced to 0.  It is too soon for errs, which are
	 computed later, but set_conflicts.  */
      state *s = this->state;
      if (!s->transitions)
	state_transitions_set (s, 0, 0);
      if (!s->reductions)
	state_reductions_set (s, 0, 0);

      states[s->number] = s;

      first_state = this->next;
      free (this);
    }
  first_state = NULL;
  last_state = NULL;
}


/*-------------------------------------------------------------------.
| Compute the nondeterministic finite state machine (see state.h for |
| details) from the grammar.                                         |
`-------------------------------------------------------------------*/

void
generate_states (void)
{
  item_number initial_core = 0;
  state_list *list = NULL;
  allocate_storage ();
  new_closure (nritems);

  /* Create the initial state.  The 0 at the lhs is the index of the
     item of this initial rule.  */
  state_list_append (0, 1, &initial_core);

  list = first_state;

  while (list)
    {
      state *s = list->state;
      if (trace_flag & trace_automaton)
	fprintf (stderr, "Processing state %d (reached by %s)\n",
		 s->number,
		 symbols[s->accessing_symbol]->tag);
      /* Set up ruleset and itemset for the transitions out of this
         state.  ruleset gets a 1 bit for each rule that could reduce
         now.  itemset gets a vector of all the items that could be
         accepted next.  */
      closure (s->items, s->nitems);
      /* Record the reductions allowed out of this state.  */
      save_reductions (s);
      /* Find the itemsets of the states that shifts can reach.  */
      new_itemsets (s);
      /* Find or create the core structures for those states.  */
      append_states (s);

      /* Create the shifts structures for the shifts to those states,
	 now that the state numbers transitioning to are known.  */
      state_transitions_set (s, nshifts, shiftset);

      /* states are queued when they are created; process them all.
	 */
      list = list->next;
    }

  /* discard various storage */
  free_closure ();
  free_storage ();

  /* Set up STATES. */
  set_states ();
}
Commit	Line	Data
	1	/* Generate the nondeterministic finite state machine for Bison.
	2
	3	Copyright (C) 1984, 1986, 1989, 2000, 2001, 2002, 2004 Free
	4	Software Foundation, Inc.
	5
	6	This file is part of Bison, the GNU Compiler Compiler.
	7
	8	Bison is free software; you can redistribute it and/or modify
	9	it under the terms of the GNU General Public License as published by
	10	the Free Software Foundation; either version 2, or (at your option)
	11	any later version.
	12
	13	Bison is distributed in the hope that it will be useful,
	14	but WITHOUT ANY WARRANTY; without even the implied warranty of
	15	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	16	GNU General Public License for more details.
	17
	18	You should have received a copy of the GNU General Public License
	19	along with Bison; see the file COPYING. If not, write to
	20	the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
	21	Boston, MA 02110-1301, USA. */
	22
	23
	24	/* See comments in state.h for the data structures that represent it.
	25	The entry point is generate_states. */
	26
	27	#include "system.h"
	28
	29	#include <bitset.h>
	30	#include <quotearg.h>
	31
	32	#include "LR0.h"
	33	#include "closure.h"
	34	#include "complain.h"
	35	#include "getargs.h"
	36	#include "gram.h"
	37	#include "gram.h"
	38	#include "lalr.h"
	39	#include "reader.h"
	40	#include "reduce.h"
	41	#include "state.h"
	42	#include "symtab.h"
	43
	44	typedef struct state_list
	45	{
	46	struct state_list *next;
	47	state *state;
	48	} state_list;
	49
	50	static state_list *first_state = NULL;
	51	static state_list *last_state = NULL;
	52
	53
	54	/*------------------------------------------------------------------.
	55	\| A state was just discovered from another state. Queue it for \|
	56	\| later examination, in order to find its transitions. Return it. \|
	57	`------------------------------------------------------------------*/
	58
	59	static state *
	60	state_list_append (symbol_number sym, size_t core_size, item_number *core)
	61	{
	62	state_list node = xmalloc (sizeof node);
	63	state *s = state_new (sym, core_size, core);
	64
	65	if (trace_flag & trace_automaton)
	66	fprintf (stderr, "state_list_append (state = %d, symbol = %d (%s))\n",
	67	nstates, sym, symbols[sym]->tag);
	68
	69	/* If this is the endtoken, and this is not the initial state, then
	70	this is the final state. */
	71	if (sym == 0 && first_state)
	72	final_state = s;
	73
	74	node->next = NULL;
	75	node->state = s;
	76
	77	if (!first_state)
	78	first_state = node;
	79	if (last_state)
	80	last_state->next = node;
	81	last_state = node;
	82
	83	return s;
	84	}
	85
	86	static int nshifts;
	87	static symbol_number *shift_symbol;
	88
	89	static rule **redset;
	90	static state **shiftset;
	91
	92	static item_number **kernel_base;
	93	static int *kernel_size;
	94	static item_number *kernel_items;
	95
	96	\f
	97	static void
	98	allocate_itemsets (void)
	99	{
	100	symbol_number i;
	101	rule_number r;
	102	item_number *rhsp;
	103
	104	/* Count the number of occurrences of all the symbols in RITEMS.
	105	Note that useless productions (hence useless nonterminals) are
	106	browsed too, hence we need to allocate room for _all_ the
	107	symbols. */
	108	size_t count = 0;
	109	size_t *symbol_count = xcalloc (nsyms + nuseless_nonterminals,
	110	sizeof *symbol_count);
	111
	112	for (r = 0; r < nrules; ++r)
	113	for (rhsp = rules[r].rhs; *rhsp >= 0; ++rhsp)
	114	{
	115	count++;
	116	symbol_count[*rhsp]++;
	117	}
	118
	119	/* See comments before new_itemsets. All the vectors of items
	120	live inside KERNEL_ITEMS. The number of active items after
	121	some symbol S cannot be more than the number of times that S
	122	appears as an item, which is SYMBOL_COUNT[S].
	123	We allocate that much space for each symbol. */
	124
	125	kernel_base = xnmalloc (nsyms, sizeof *kernel_base);
	126	kernel_items = xnmalloc (count, sizeof *kernel_items);
	127
	128	count = 0;
	129	for (i = 0; i < nsyms; i++)
	130	{
	131	kernel_base[i] = kernel_items + count;
	132	count += symbol_count[i];
	133	}
	134
	135	free (symbol_count);
	136	kernel_size = xnmalloc (nsyms, sizeof *kernel_size);
	137	}
	138
	139
	140	static void
	141	allocate_storage (void)
	142	{
	143	allocate_itemsets ();
	144
	145	shiftset = xnmalloc (nsyms, sizeof *shiftset);
	146	redset = xnmalloc (nrules, sizeof *redset);
	147	state_hash_new ();
	148	shift_symbol = xnmalloc (nsyms, sizeof *shift_symbol);
	149	}
	150
	151
	152	static void
	153	free_storage (void)
	154	{
	155	free (shift_symbol);
	156	free (redset);
	157	free (shiftset);
	158	free (kernel_base);
	159	free (kernel_size);
	160	free (kernel_items);
	161	state_hash_free ();
	162	}
	163
	164
	165
	166
	167	/*---------------------------------------------------------------.
	168	\| Find which symbols can be shifted in S, and for each one \|
	169	\| record which items would be active after that shift. Uses the \|
	170	\| contents of itemset. \|
	171	\| \|
	172	\| shift_symbol is set to a vector of the symbols that can be \|
	173	\| shifted. For each symbol in the grammar, kernel_base[symbol] \|
	174	\| points to a vector of item numbers activated if that symbol is \|
	175	\| shifted, and kernel_size[symbol] is their numbers. \|
	176	`---------------------------------------------------------------*/
	177
	178	static void
	179	new_itemsets (state *s)
	180	{
	181	size_t i;
	182
	183	if (trace_flag & trace_automaton)
	184	fprintf (stderr, "Entering new_itemsets, state = %d\n", s->number);
	185
	186	memset (kernel_size, 0, nsyms * sizeof *kernel_size);
	187
	188	nshifts = 0;
	189
	190	for (i = 0; i < nritemset; ++i)
	191	if (ritem[itemset[i]] >= 0)
	192	{
	193	symbol_number sym = item_number_as_symbol_number (ritem[itemset[i]]);
	194	if (!kernel_size[sym])
	195	{
	196	shift_symbol[nshifts] = sym;
	197	nshifts++;
	198	}
	199
	200	kernel_base[sym][kernel_size[sym]] = itemset[i] + 1;
	201	kernel_size[sym]++;
	202	}
	203	}
	204
	205
	206
	207	/*--------------------------------------------------------------.
	208	\| Find the state we would get to (from the current state) by \|
	209	\| shifting SYM. Create a new state if no equivalent one exists \|
	210	\| already. Used by append_states. \|
	211	`--------------------------------------------------------------*/
	212
	213	static state *
	214	get_state (symbol_number sym, size_t core_size, item_number *core)
	215	{
	216	state *sp;
	217
	218	if (trace_flag & trace_automaton)
	219	fprintf (stderr, "Entering get_state, symbol = %d (%s)\n",
	220	sym, symbols[sym]->tag);
	221
	222	sp = state_hash_lookup (core_size, core);
	223	if (!sp)
	224	sp = state_list_append (sym, core_size, core);
	225
	226	if (trace_flag & trace_automaton)
	227	fprintf (stderr, "Exiting get_state => %d\n", sp->number);
	228
	229	return sp;
	230	}
	231
	232	/*---------------------------------------------------------------.
	233	\| Use the information computed by new_itemsets to find the state \|
	234	\| numbers reached by each shift transition from S. \|
	235	\| \|
	236	\| SHIFTSET is set up as a vector of those states. \|
	237	`---------------------------------------------------------------*/
	238
	239	static void
	240	append_states (state *s)
	241	{
	242	int i;
	243
	244	if (trace_flag & trace_automaton)
	245	fprintf (stderr, "Entering append_states, state = %d\n", s->number);
	246
	247	/* First sort shift_symbol into increasing order. */
	248
	249	for (i = 1; i < nshifts; i++)
	250	{
	251	symbol_number sym = shift_symbol[i];
	252	int j;
	253	for (j = i; 0 < j && sym < shift_symbol[j - 1]; j--)
	254	shift_symbol[j] = shift_symbol[j - 1];
	255	shift_symbol[j] = sym;
	256	}
	257
	258	for (i = 0; i < nshifts; i++)
	259	{
	260	symbol_number sym = shift_symbol[i];
	261	shiftset[i] = get_state (sym, kernel_size[sym], kernel_base[sym]);
	262	}
	263	}
	264
	265
	266	/*----------------------------------------------------------------.
	267	\| Find which rules can be used for reduction transitions from the \|
	268	\| current state and make a reductions structure for the state to \|
	269	\| record their rule numbers. \|
	270	`----------------------------------------------------------------*/
	271
	272	static void
	273	save_reductions (state *s)
	274	{
	275	int count = 0;
	276	size_t i;
	277
	278	/* Find and count the active items that represent ends of rules. */
	279	for (i = 0; i < nritemset; ++i)
	280	{
	281	int item = ritem[itemset[i]];
	282	if (item < 0)
	283	redset[count++] = &rules[item_number_as_rule_number (item)];
	284	}
	285
	286	/* Make a reductions structure and copy the data into it. */
	287	state_reductions_set (s, count, redset);
	288	}
	289
	290	\f
	291	/*---------------.
	292	\| Build STATES. \|
	293	`---------------*/
	294
	295	static void
	296	set_states (void)
	297	{
	298	states = xcalloc (nstates, sizeof *states);
	299
	300	while (first_state)
	301	{
	302	state_list *this = first_state;
	303
	304	/* Pessimization, but simplification of the code: make sure all
	305	the states have valid transitions and reductions members,
	306	even if reduced to 0. It is too soon for errs, which are
	307	computed later, but set_conflicts. */
	308	state *s = this->state;
	309	if (!s->transitions)
	310	state_transitions_set (s, 0, 0);
	311	if (!s->reductions)
	312	state_reductions_set (s, 0, 0);
	313
	314	states[s->number] = s;
	315
	316	first_state = this->next;
	317	free (this);
	318	}
	319	first_state = NULL;
	320	last_state = NULL;
	321	}
	322
	323
	324	/*-------------------------------------------------------------------.
	325	\| Compute the nondeterministic finite state machine (see state.h for \|
	326	\| details) from the grammar. \|
	327	`-------------------------------------------------------------------*/
	328
	329	void
	330	generate_states (void)
	331	{
	332	item_number initial_core = 0;
	333	state_list *list = NULL;
	334	allocate_storage ();
	335	new_closure (nritems);
	336
	337	/* Create the initial state. The 0 at the lhs is the index of the
	338	item of this initial rule. */
	339	state_list_append (0, 1, &initial_core);
	340
	341	list = first_state;
	342
	343	while (list)
	344	{
	345	state *s = list->state;
	346	if (trace_flag & trace_automaton)
	347	fprintf (stderr, "Processing state %d (reached by %s)\n",
	348	s->number,
	349	symbols[s->accessing_symbol]->tag);
	350	/* Set up ruleset and itemset for the transitions out of this
	351	state. ruleset gets a 1 bit for each rule that could reduce
	352	now. itemset gets a vector of all the items that could be
	353	accepted next. */
	354	closure (s->items, s->nitems);
	355	/* Record the reductions allowed out of this state. */
	356	save_reductions (s);
	357	/* Find the itemsets of the states that shifts can reach. */
	358	new_itemsets (s);
	359	/* Find or create the core structures for those states. */
	360	append_states (s);
	361
	362	/* Create the shifts structures for the shifts to those states,
	363	now that the state numbers transitioning to are known. */
	364	state_transitions_set (s, nshifts, shiftset);
	365
	366	/* states are queued when they are created; process them all.
	367	*/
	368	list = list->next;
	369	}
	370
	371	/* discard various storage */
	372	free_closure ();
	373	free_storage ();
	374
	375	/* Set up STATES. */
	376	set_states ();
	377	}