#include "system.h"
#include "getargs.h"
-#include "reader.h"
+#include "symtab.h"
#include "types.h"
#include "gram.h"
#include "reduce.h"
int i;
fputs ("NULLABLE\n", out);
for (i = ntokens; i < nsyms; i++)
- fprintf (out, "\t%s: %s\n", tags[i], nullable[i] ? "yes" : "no");
+ fprintf (out, "\t%s: %s\n", symbols[i]->tag, nullable[i] ? "yes" : "no");
fputs ("\n\n", out);
}
void
set_nullable (void)
{
- short *r;
- short *s1;
- short *s2;
+ rule_number_t ruleno;
+ symbol_number_t *s1;
+ symbol_number_t *s2;
shorts *p;
- short *squeue;
- short *rcount;
- shorts **rsets;
- shorts *relts;
+ symbol_number_t *squeue = XCALLOC (symbol_number_t, nvars);
+ short *rcount = XCALLOC (short, nrules + 1);
+ /* RITEM contains all the rules, including useless productions.
+ Hence we must allocate room for useless nonterminals too. */
+ shorts **rsets = XCALLOC (shorts *, nvars) - ntokens;
+ /* This is said to be more elements than we actually use.
+ Supposedly NRITEMS - NRULES is enough. But why take the risk? */
+ shorts *relts = XCALLOC (shorts, nritems + nvars + 1);
if (trace_flag)
fprintf (stderr, "Entering set_nullable\n");
nullable = XCALLOC (char, nvars) - ntokens;
- squeue = XCALLOC (short, nvars);
s1 = s2 = squeue;
-
- rcount = XCALLOC (short, nrules + 1);
-
- /* RITEM contains all the rules, including useless productions.
- Hence we must allocate room for useless nonterminals too. */
- rsets = XCALLOC (shorts *, nvars + nuseless_nonterminals) - ntokens;
- /* This is said to be more elements than we actually use.
- Supposedly nitems - nrules is enough.
- But why take the risk? */
- relts = XCALLOC (shorts, nitems + nvars + nuseless_nonterminals + 1);
p = relts;
- for (r = ritem; *r; ++r)
- {
- /* Walk RITEM to find (i), if there are any tokens in the
- RHS, and (ii), to find RULENO. */
- int ruleno;
- int any_tokens = 0;
- short *r1;
- for (r1 = r; *r1 > 0; ++r1)
- if (ISTOKEN (*r1))
- any_tokens = 1;
- ruleno = -*r1;
-
- /* Examine the RHS of the rule. */
- if (!any_tokens)
- for (/* Nothing. */; *r > 0; ++r)
+ for (ruleno = 1; ruleno < nrules + 1; ++ruleno)
+ if (rules[ruleno].useful)
+ {
+ rule_t *rule = &rules[ruleno];
+ if (rule->rhs[0] >= 0)
{
- rcount[ruleno]++;
- p->next = rsets[*r];
- p->value = ruleno;
- rsets[*r] = p;
- p++;
+ /* This rule has a non empty RHS. */
+ item_number_t *r = NULL;
+ int any_tokens = 0;
+ for (r = rule->rhs; *r >= 0; ++r)
+ if (ISTOKEN (*r))
+ any_tokens = 1;
+
+ /* This rule has only nonterminals: schedule it for the second
+ pass. */
+ if (!any_tokens)
+ for (r = rule->rhs; *r >= 0; ++r)
+ {
+ rcount[ruleno]++;
+ p->next = rsets[*r];
+ p->value = ruleno;
+ rsets[*r] = p;
+ p++;
+ }
}
-
- /* Examine its LHS. */
- if (rule_table[ruleno].useful && !nullable[rule_table[ruleno].lhs])
- {
- nullable[rule_table[ruleno].lhs] = 1;
- *s2++ = rule_table[ruleno].lhs;
- }
- }
+ else
+ {
+ /* This rule has an empty RHS. */
+ assert (rule_number_of_item_number (rule->rhs[0]) == ruleno);
+ if (rule->useful && !nullable[rule->lhs->number])
+ {
+ nullable[rule->lhs->number] = 1;
+ *s2++ = rule->lhs->number;
+ }
+ }
+ }
while (s1 < s2)
- {
- p = rsets[*s1++];
- while (p)
- {
- int ruleno = p->value;
- p = p->next;
- if (--rcount[ruleno] == 0)
+ for (p = rsets[*s1++]; p; p = p->next)
+ {
+ ruleno = p->value;
+ if (--rcount[ruleno] == 0)
+ if (rules[ruleno].useful && !nullable[rules[ruleno].lhs->number])
{
- int symbol = rule_table[ruleno].lhs;
- if (symbol >= 0 && !nullable[symbol])
- {
- nullable[symbol] = 1;
- *s2++ = symbol;
- }
+ nullable[rules[ruleno].lhs->number] = 1;
+ *s2++ = rules[ruleno].lhs->number;
}
- }
- }
+ }
XFREE (squeue);
XFREE (rcount);