1 /* dfa - DFA construction routines */
2
3 /*-
4 * Copyright (c) 1990 The Regents of the University of California.
5 * All rights reserved.
6 *
7 * This code is derived from software contributed to Berkeley by
8 * Vern Paxson.
9 *
10 * The United States Government has rights in this work pursuant
11 * to contract no. DE-AC03-76SF00098 between the United States
12 * Department of Energy and the University of California.
13 *
14 * Redistribution and use in source and binary forms are permitted provided
15 * that: (1) source distributions retain this entire copyright notice and
16 * comment, and (2) distributions including binaries display the following
17 * acknowledgement: ``This product includes software developed by the
18 * University of California, Berkeley and its contributors'' in the
19 * documentation or other materials provided with the distribution and in
20 * all advertising materials mentioning features or use of this software.
21 * Neither the name of the University nor the names of its contributors may
22 * be used to endorse or promote products derived from this software without
23 * specific prior written permission.
24 * THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR IMPLIED
25 * WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED WARRANTIES OF
26 * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
27 */
28
29 /* $Header: /home/daffy/u0/vern/flex/RCS/dfa.c,v 2.26 95/04/20 13:53:14 vern Exp $ */
30 #include <sys/cdefs.h>
31 __FBSDID("$FreeBSD: stable/9/usr.bin/lex/dfa.c 179549 2008-06-04 19:50:34Z dwmalone $");
32
33 #include "flexdef.h"
34
35
36 /* declare functions that have forward references */
37
38 void dump_associated_rules PROTO((FILE*, int));
39 void dump_transitions PROTO((FILE*, int[]));
40 void sympartition PROTO((int[], int, int[], int[]));
41 int symfollowset PROTO((int[], int, int, int[]));
42
43
44 /* check_for_backing_up - check a DFA state for backing up
45 *
46 * synopsis
47 * void check_for_backing_up( int ds, int state[numecs] );
48 *
49 * ds is the number of the state to check and state[] is its out-transitions,
50 * indexed by equivalence class.
51 */
52
check_for_backing_up(ds,state)53 void check_for_backing_up( ds, state )
54 int ds;
55 int state[];
56 {
57 if ( (reject && ! dfaacc[ds].dfaacc_set) ||
58 (! reject && ! dfaacc[ds].dfaacc_state) )
59 { /* state is non-accepting */
60 ++num_backing_up;
61
62 if ( backing_up_report )
63 {
64 fprintf( backing_up_file,
65 _( "State #%d is non-accepting -\n" ), ds );
66
67 /* identify the state */
68 dump_associated_rules( backing_up_file, ds );
69
70 /* Now identify it further using the out- and
71 * jam-transitions.
72 */
73 dump_transitions( backing_up_file, state );
74
75 putc( '\n', backing_up_file );
76 }
77 }
78 }
79
80
81 /* check_trailing_context - check to see if NFA state set constitutes
82 * "dangerous" trailing context
83 *
84 * synopsis
85 * void check_trailing_context( int nfa_states[num_states+1], int num_states,
86 * int accset[nacc+1], int nacc );
87 *
88 * NOTES
89 * Trailing context is "dangerous" if both the head and the trailing
90 * part are of variable size \and/ there's a DFA state which contains
91 * both an accepting state for the head part of the rule and NFA states
92 * which occur after the beginning of the trailing context.
93 *
94 * When such a rule is matched, it's impossible to tell if having been
95 * in the DFA state indicates the beginning of the trailing context or
96 * further-along scanning of the pattern. In these cases, a warning
97 * message is issued.
98 *
99 * nfa_states[1 .. num_states] is the list of NFA states in the DFA.
100 * accset[1 .. nacc] is the list of accepting numbers for the DFA state.
101 */
102
check_trailing_context(nfa_states,num_states,accset,nacc)103 void check_trailing_context( nfa_states, num_states, accset, nacc )
104 int *nfa_states, num_states;
105 int *accset;
106 int nacc;
107 {
108 int i, j;
109
110 for ( i = 1; i <= num_states; ++i )
111 {
112 int ns = nfa_states[i];
113 int type = state_type[ns];
114 int ar = assoc_rule[ns];
115
116 if ( type == STATE_NORMAL || rule_type[ar] != RULE_VARIABLE )
117 { /* do nothing */
118 }
119
120 else if ( type == STATE_TRAILING_CONTEXT )
121 {
122 /* Potential trouble. Scan set of accepting numbers
123 * for the one marking the end of the "head". We
124 * assume that this looping will be fairly cheap
125 * since it's rare that an accepting number set
126 * is large.
127 */
128 for ( j = 1; j <= nacc; ++j )
129 if ( accset[j] & YY_TRAILING_HEAD_MASK )
130 {
131 line_warning(
132 _( "dangerous trailing context" ),
133 rule_linenum[ar] );
134 return;
135 }
136 }
137 }
138 }
139
140
141 /* dump_associated_rules - list the rules associated with a DFA state
142 *
143 * Goes through the set of NFA states associated with the DFA and
144 * extracts the first MAX_ASSOC_RULES unique rules, sorts them,
145 * and writes a report to the given file.
146 */
147
dump_associated_rules(file,ds)148 void dump_associated_rules( file, ds )
149 FILE *file;
150 int ds;
151 {
152 int i, j;
153 int num_associated_rules = 0;
154 int rule_set[MAX_ASSOC_RULES + 1];
155 int *dset = dss[ds];
156 int size = dfasiz[ds];
157
158 for ( i = 1; i <= size; ++i )
159 {
160 int rule_num = rule_linenum[assoc_rule[dset[i]]];
161
162 for ( j = 1; j <= num_associated_rules; ++j )
163 if ( rule_num == rule_set[j] )
164 break;
165
166 if ( j > num_associated_rules )
167 { /* new rule */
168 if ( num_associated_rules < MAX_ASSOC_RULES )
169 rule_set[++num_associated_rules] = rule_num;
170 }
171 }
172
173 bubble( rule_set, num_associated_rules );
174
175 fprintf( file, _( " associated rule line numbers:" ) );
176
177 for ( i = 1; i <= num_associated_rules; ++i )
178 {
179 if ( i % 8 == 1 )
180 putc( '\n', file );
181
182 fprintf( file, "\t%d", rule_set[i] );
183 }
184
185 putc( '\n', file );
186 }
187
188
189 /* dump_transitions - list the transitions associated with a DFA state
190 *
191 * synopsis
192 * dump_transitions( FILE *file, int state[numecs] );
193 *
194 * Goes through the set of out-transitions and lists them in human-readable
195 * form (i.e., not as equivalence classes); also lists jam transitions
196 * (i.e., all those which are not out-transitions, plus EOF). The dump
197 * is done to the given file.
198 */
199
dump_transitions(file,state)200 void dump_transitions( file, state )
201 FILE *file;
202 int state[];
203 {
204 int i, ec;
205 int out_char_set[CSIZE];
206
207 for ( i = 0; i < csize; ++i )
208 {
209 ec = ABS( ecgroup[i] );
210 out_char_set[i] = state[ec];
211 }
212
213 fprintf( file, _( " out-transitions: " ) );
214
215 list_character_set( file, out_char_set );
216
217 /* now invert the members of the set to get the jam transitions */
218 for ( i = 0; i < csize; ++i )
219 out_char_set[i] = ! out_char_set[i];
220
221 fprintf( file, _( "\n jam-transitions: EOF " ) );
222
223 list_character_set( file, out_char_set );
224
225 putc( '\n', file );
226 }
227
228
229 /* epsclosure - construct the epsilon closure of a set of ndfa states
230 *
231 * synopsis
232 * int *epsclosure( int t[num_states], int *numstates_addr,
233 * int accset[num_rules+1], int *nacc_addr,
234 * int *hashval_addr );
235 *
236 * NOTES
237 * The epsilon closure is the set of all states reachable by an arbitrary
238 * number of epsilon transitions, which themselves do not have epsilon
239 * transitions going out, unioned with the set of states which have non-null
240 * accepting numbers. t is an array of size numstates of nfa state numbers.
241 * Upon return, t holds the epsilon closure and *numstates_addr is updated.
242 * accset holds a list of the accepting numbers, and the size of accset is
243 * given by *nacc_addr. t may be subjected to reallocation if it is not
244 * large enough to hold the epsilon closure.
245 *
246 * hashval is the hash value for the dfa corresponding to the state set.
247 */
248
epsclosure(t,ns_addr,accset,nacc_addr,hv_addr)249 int *epsclosure( t, ns_addr, accset, nacc_addr, hv_addr )
250 int *t, *ns_addr, accset[], *nacc_addr, *hv_addr;
251 {
252 int stkpos, ns, tsp;
253 int numstates = *ns_addr, nacc, hashval, transsym, nfaccnum;
254 int stkend, nstate;
255 static int did_stk_init = false, *stk;
256
257 #define MARK_STATE(state) \
258 trans1[state] = trans1[state] - MARKER_DIFFERENCE;
259
260 #define IS_MARKED(state) (trans1[state] < 0)
261
262 #define UNMARK_STATE(state) \
263 trans1[state] = trans1[state] + MARKER_DIFFERENCE;
264
265 #define CHECK_ACCEPT(state) \
266 { \
267 nfaccnum = accptnum[state]; \
268 if ( nfaccnum != NIL ) \
269 accset[++nacc] = nfaccnum; \
270 }
271
272 #define DO_REALLOCATION \
273 { \
274 current_max_dfa_size += MAX_DFA_SIZE_INCREMENT; \
275 ++num_reallocs; \
276 t = reallocate_integer_array( t, current_max_dfa_size ); \
277 stk = reallocate_integer_array( stk, current_max_dfa_size ); \
278 } \
279
280 #define PUT_ON_STACK(state) \
281 { \
282 if ( ++stkend >= current_max_dfa_size ) \
283 DO_REALLOCATION \
284 stk[stkend] = state; \
285 MARK_STATE(state) \
286 }
287
288 #define ADD_STATE(state) \
289 { \
290 if ( ++numstates >= current_max_dfa_size ) \
291 DO_REALLOCATION \
292 t[numstates] = state; \
293 hashval += state; \
294 }
295
296 #define STACK_STATE(state) \
297 { \
298 PUT_ON_STACK(state) \
299 CHECK_ACCEPT(state) \
300 if ( nfaccnum != NIL || transchar[state] != SYM_EPSILON ) \
301 ADD_STATE(state) \
302 }
303
304
305 if ( ! did_stk_init )
306 {
307 stk = allocate_integer_array( current_max_dfa_size );
308 did_stk_init = true;
309 }
310
311 nacc = stkend = hashval = 0;
312
313 for ( nstate = 1; nstate <= numstates; ++nstate )
314 {
315 ns = t[nstate];
316
317 /* The state could be marked if we've already pushed it onto
318 * the stack.
319 */
320 if ( ! IS_MARKED(ns) )
321 {
322 PUT_ON_STACK(ns)
323 CHECK_ACCEPT(ns)
324 hashval += ns;
325 }
326 }
327
328 for ( stkpos = 1; stkpos <= stkend; ++stkpos )
329 {
330 ns = stk[stkpos];
331 transsym = transchar[ns];
332
333 if ( transsym == SYM_EPSILON )
334 {
335 tsp = trans1[ns] + MARKER_DIFFERENCE;
336
337 if ( tsp != NO_TRANSITION )
338 {
339 if ( ! IS_MARKED(tsp) )
340 STACK_STATE(tsp)
341
342 tsp = trans2[ns];
343
344 if ( tsp != NO_TRANSITION && ! IS_MARKED(tsp) )
345 STACK_STATE(tsp)
346 }
347 }
348 }
349
350 /* Clear out "visit" markers. */
351
352 for ( stkpos = 1; stkpos <= stkend; ++stkpos )
353 {
354 if ( IS_MARKED(stk[stkpos]) )
355 UNMARK_STATE(stk[stkpos])
356 else
357 flexfatal(
358 _( "consistency check failed in epsclosure()" ) );
359 }
360
361 *ns_addr = numstates;
362 *hv_addr = hashval;
363 *nacc_addr = nacc;
364
365 return t;
366 }
367
368
369 /* increase_max_dfas - increase the maximum number of DFAs */
370
increase_max_dfas()371 void increase_max_dfas()
372 {
373 current_max_dfas += MAX_DFAS_INCREMENT;
374
375 ++num_reallocs;
376
377 base = reallocate_integer_array( base, current_max_dfas );
378 def = reallocate_integer_array( def, current_max_dfas );
379 dfasiz = reallocate_integer_array( dfasiz, current_max_dfas );
380 accsiz = reallocate_integer_array( accsiz, current_max_dfas );
381 dhash = reallocate_integer_array( dhash, current_max_dfas );
382 dss = reallocate_int_ptr_array( dss, current_max_dfas );
383 dfaacc = reallocate_dfaacc_union( dfaacc, current_max_dfas );
384
385 if ( nultrans )
386 nultrans =
387 reallocate_integer_array( nultrans, current_max_dfas );
388 }
389
390
391 /* ntod - convert an ndfa to a dfa
392 *
393 * Creates the dfa corresponding to the ndfa we've constructed. The
394 * dfa starts out in state #1.
395 */
396
ntod()397 void ntod()
398 {
399 int *accset, ds, nacc, newds;
400 int sym, hashval, numstates, dsize;
401 int num_full_table_rows; /* used only for -f */
402 int *nset, *dset;
403 int targptr, totaltrans, i, comstate, comfreq, targ;
404 int symlist[CSIZE + 1];
405 int num_start_states;
406 int todo_head, todo_next;
407
408 /* Note that the following are indexed by *equivalence classes*
409 * and not by characters. Since equivalence classes are indexed
410 * beginning with 1, even if the scanner accepts NUL's, this
411 * means that (since every character is potentially in its own
412 * equivalence class) these arrays must have room for indices
413 * from 1 to CSIZE, so their size must be CSIZE + 1.
414 */
415 int duplist[CSIZE + 1], state[CSIZE + 1];
416 int targfreq[CSIZE + 1], targstate[CSIZE + 1];
417
418 accset = allocate_integer_array( num_rules + 1 );
419 nset = allocate_integer_array( current_max_dfa_size );
420
421 /* The "todo" queue is represented by the head, which is the DFA
422 * state currently being processed, and the "next", which is the
423 * next DFA state number available (not in use). We depend on the
424 * fact that snstods() returns DFA's \in increasing order/, and thus
425 * need only know the bounds of the dfas to be processed.
426 */
427 todo_head = todo_next = 0;
428
429 for ( i = 0; i <= csize; ++i )
430 {
431 duplist[i] = NIL;
432 symlist[i] = false;
433 }
434
435 for ( i = 0; i <= num_rules; ++i )
436 accset[i] = NIL;
437
438 if ( trace )
439 {
440 dumpnfa( scset[1] );
441 fputs( _( "\n\nDFA Dump:\n\n" ), stderr );
442 }
443
444 inittbl();
445
446 /* Check to see whether we should build a separate table for
447 * transitions on NUL characters. We don't do this for full-speed
448 * (-F) scanners, since for them we don't have a simple state
449 * number lying around with which to index the table. We also
450 * don't bother doing it for scanners unless (1) NUL is in its own
451 * equivalence class (indicated by a positive value of
452 * ecgroup[NUL]), (2) NUL's equivalence class is the last
453 * equivalence class, and (3) the number of equivalence classes is
454 * the same as the number of characters. This latter case comes
455 * about when useecs is false or when it's true but every character
456 * still manages to land in its own class (unlikely, but it's
457 * cheap to check for). If all these things are true then the
458 * character code needed to represent NUL's equivalence class for
459 * indexing the tables is going to take one more bit than the
460 * number of characters, and therefore we won't be assured of
461 * being able to fit it into a YY_CHAR variable. This rules out
462 * storing the transitions in a compressed table, since the code
463 * for interpreting them uses a YY_CHAR variable (perhaps it
464 * should just use an integer, though; this is worth pondering ...
465 * ###).
466 *
467 * Finally, for full tables, we want the number of entries in the
468 * table to be a power of two so the array references go fast (it
469 * will just take a shift to compute the major index). If
470 * encoding NUL's transitions in the table will spoil this, we
471 * give it its own table (note that this will be the case if we're
472 * not using equivalence classes).
473 */
474
475 /* Note that the test for ecgroup[0] == numecs below accomplishes
476 * both (1) and (2) above
477 */
478 if ( ! fullspd && ecgroup[0] == numecs )
479 {
480 /* NUL is alone in its equivalence class, which is the
481 * last one.
482 */
483 int use_NUL_table = (numecs == csize);
484
485 if ( fulltbl && ! use_NUL_table )
486 {
487 /* We still may want to use the table if numecs
488 * is a power of 2.
489 */
490 int power_of_two;
491
492 for ( power_of_two = 1; power_of_two <= csize;
493 power_of_two *= 2 )
494 if ( numecs == power_of_two )
495 {
496 use_NUL_table = true;
497 break;
498 }
499 }
500
501 if ( use_NUL_table )
502 nultrans = allocate_integer_array( current_max_dfas );
503
504 /* From now on, nultrans != nil indicates that we're
505 * saving null transitions for later, separate encoding.
506 */
507 }
508
509
510 if ( fullspd )
511 {
512 for ( i = 0; i <= numecs; ++i )
513 state[i] = 0;
514
515 place_state( state, 0, 0 );
516 dfaacc[0].dfaacc_state = 0;
517 }
518
519 else if ( fulltbl )
520 {
521 if ( nultrans )
522 /* We won't be including NUL's transitions in the
523 * table, so build it for entries from 0 .. numecs - 1.
524 */
525 num_full_table_rows = numecs;
526
527 else
528 /* Take into account the fact that we'll be including
529 * the NUL entries in the transition table. Build it
530 * from 0 .. numecs.
531 */
532 num_full_table_rows = numecs + 1;
533
534 /* Unless -Ca, declare it "short" because it's a real
535 * long-shot that that won't be large enough.
536 */
537 out_str_dec( "static yyconst %s yy_nxt[][%d] =\n {\n",
538 /* '}' so vi doesn't get too confused */
539 long_align ? "long" : "short", num_full_table_rows );
540
541 outn( " {" );
542
543 /* Generate 0 entries for state #0. */
544 for ( i = 0; i < num_full_table_rows; ++i )
545 mk2data( 0 );
546
547 dataflush();
548 outn( " },\n" );
549 }
550
551 /* Create the first states. */
552
553 num_start_states = lastsc * 2;
554
555 for ( i = 1; i <= num_start_states; ++i )
556 {
557 numstates = 1;
558
559 /* For each start condition, make one state for the case when
560 * we're at the beginning of the line (the '^' operator) and
561 * one for the case when we're not.
562 */
563 if ( i % 2 == 1 )
564 nset[numstates] = scset[(i / 2) + 1];
565 else
566 nset[numstates] =
567 mkbranch( scbol[i / 2], scset[i / 2] );
568
569 nset = epsclosure( nset, &numstates, accset, &nacc, &hashval );
570
571 if ( snstods( nset, numstates, accset, nacc, hashval, &ds ) )
572 {
573 numas += nacc;
574 totnst += numstates;
575 ++todo_next;
576
577 if ( variable_trailing_context_rules && nacc > 0 )
578 check_trailing_context( nset, numstates,
579 accset, nacc );
580 }
581 }
582
583 if ( ! fullspd )
584 {
585 if ( ! snstods( nset, 0, accset, 0, 0, &end_of_buffer_state ) )
586 flexfatal(
587 _( "could not create unique end-of-buffer state" ) );
588
589 ++numas;
590 ++num_start_states;
591 ++todo_next;
592 }
593
594 while ( todo_head < todo_next )
595 {
596 targptr = 0;
597 totaltrans = 0;
598
599 for ( i = 1; i <= numecs; ++i )
600 state[i] = 0;
601
602 ds = ++todo_head;
603
604 dset = dss[ds];
605 dsize = dfasiz[ds];
606
607 if ( trace )
608 fprintf( stderr, _( "state # %d:\n" ), ds );
609
610 sympartition( dset, dsize, symlist, duplist );
611
612 for ( sym = 1; sym <= numecs; ++sym )
613 {
614 if ( symlist[sym] )
615 {
616 symlist[sym] = 0;
617
618 if ( duplist[sym] == NIL )
619 {
620 /* Symbol has unique out-transitions. */
621 numstates = symfollowset( dset, dsize,
622 sym, nset );
623 nset = epsclosure( nset, &numstates,
624 accset, &nacc, &hashval );
625
626 if ( snstods( nset, numstates, accset,
627 nacc, hashval, &newds ) )
628 {
629 totnst = totnst + numstates;
630 ++todo_next;
631 numas += nacc;
632
633 if (
634 variable_trailing_context_rules &&
635 nacc > 0 )
636 check_trailing_context(
637 nset, numstates,
638 accset, nacc );
639 }
640
641 state[sym] = newds;
642
643 if ( trace )
644 fprintf( stderr, "\t%d\t%d\n",
645 sym, newds );
646
647 targfreq[++targptr] = 1;
648 targstate[targptr] = newds;
649 ++numuniq;
650 }
651
652 else
653 {
654 /* sym's equivalence class has the same
655 * transitions as duplist(sym)'s
656 * equivalence class.
657 */
658 targ = state[duplist[sym]];
659 state[sym] = targ;
660
661 if ( trace )
662 fprintf( stderr, "\t%d\t%d\n",
663 sym, targ );
664
665 /* Update frequency count for
666 * destination state.
667 */
668
669 i = 0;
670 while ( targstate[++i] != targ )
671 ;
672
673 ++targfreq[i];
674 ++numdup;
675 }
676
677 ++totaltrans;
678 duplist[sym] = NIL;
679 }
680 }
681
682 if ( caseins && ! useecs )
683 {
684 int j;
685
686 for ( i = 'A', j = 'a'; i <= 'Z'; ++i, ++j )
687 {
688 if ( state[i] == 0 && state[j] != 0 )
689 /* We're adding a transition. */
690 ++totaltrans;
691
692 else if ( state[i] != 0 && state[j] == 0 )
693 /* We're taking away a transition. */
694 --totaltrans;
695
696 state[i] = state[j];
697 }
698 }
699
700 numsnpairs += totaltrans;
701
702 if ( ds > num_start_states )
703 check_for_backing_up( ds, state );
704
705 if ( nultrans )
706 {
707 nultrans[ds] = state[NUL_ec];
708 state[NUL_ec] = 0; /* remove transition */
709 }
710
711 if ( fulltbl )
712 {
713 outn( " {" );
714
715 /* Supply array's 0-element. */
716 if ( ds == end_of_buffer_state )
717 mk2data( -end_of_buffer_state );
718 else
719 mk2data( end_of_buffer_state );
720
721 for ( i = 1; i < num_full_table_rows; ++i )
722 /* Jams are marked by negative of state
723 * number.
724 */
725 mk2data( state[i] ? state[i] : -ds );
726
727 dataflush();
728 outn( " },\n" );
729 }
730
731 else if ( fullspd )
732 place_state( state, ds, totaltrans );
733
734 else if ( ds == end_of_buffer_state )
735 /* Special case this state to make sure it does what
736 * it's supposed to, i.e., jam on end-of-buffer.
737 */
738 stack1( ds, 0, 0, JAMSTATE );
739
740 else /* normal, compressed state */
741 {
742 /* Determine which destination state is the most
743 * common, and how many transitions to it there are.
744 */
745
746 comfreq = 0;
747 comstate = 0;
748
749 for ( i = 1; i <= targptr; ++i )
750 if ( targfreq[i] > comfreq )
751 {
752 comfreq = targfreq[i];
753 comstate = targstate[i];
754 }
755
756 bldtbl( state, ds, totaltrans, comstate, comfreq );
757 }
758 }
759
760 if ( fulltbl )
761 dataend();
762
763 else if ( ! fullspd )
764 {
765 cmptmps(); /* create compressed template entries */
766
767 /* Create tables for all the states with only one
768 * out-transition.
769 */
770 while ( onesp > 0 )
771 {
772 mk1tbl( onestate[onesp], onesym[onesp], onenext[onesp],
773 onedef[onesp] );
774 --onesp;
775 }
776
777 mkdeftbl();
778 }
779
780 flex_free( (void *) accset );
781 flex_free( (void *) nset );
782 }
783
784
785 /* snstods - converts a set of ndfa states into a dfa state
786 *
787 * synopsis
788 * is_new_state = snstods( int sns[numstates], int numstates,
789 * int accset[num_rules+1], int nacc,
790 * int hashval, int *newds_addr );
791 *
792 * On return, the dfa state number is in newds.
793 */
794
snstods(sns,numstates,accset,nacc,hashval,newds_addr)795 int snstods( sns, numstates, accset, nacc, hashval, newds_addr )
796 int sns[], numstates, accset[], nacc, hashval, *newds_addr;
797 {
798 int didsort = 0;
799 int i, j;
800 int newds, *oldsns;
801
802 for ( i = 1; i <= lastdfa; ++i )
803 if ( hashval == dhash[i] )
804 {
805 if ( numstates == dfasiz[i] )
806 {
807 oldsns = dss[i];
808
809 if ( ! didsort )
810 {
811 /* We sort the states in sns so we
812 * can compare it to oldsns quickly.
813 * We use bubble because there probably
814 * aren't very many states.
815 */
816 bubble( sns, numstates );
817 didsort = 1;
818 }
819
820 for ( j = 1; j <= numstates; ++j )
821 if ( sns[j] != oldsns[j] )
822 break;
823
824 if ( j > numstates )
825 {
826 ++dfaeql;
827 *newds_addr = i;
828 return 0;
829 }
830
831 ++hshcol;
832 }
833
834 else
835 ++hshsave;
836 }
837
838 /* Make a new dfa. */
839
840 if ( ++lastdfa >= current_max_dfas )
841 increase_max_dfas();
842
843 newds = lastdfa;
844
845 dss[newds] = allocate_integer_array( numstates + 1 );
846
847 /* If we haven't already sorted the states in sns, we do so now,
848 * so that future comparisons with it can be made quickly.
849 */
850
851 if ( ! didsort )
852 bubble( sns, numstates );
853
854 for ( i = 1; i <= numstates; ++i )
855 dss[newds][i] = sns[i];
856
857 dfasiz[newds] = numstates;
858 dhash[newds] = hashval;
859
860 if ( nacc == 0 )
861 {
862 if ( reject )
863 dfaacc[newds].dfaacc_set = (int *) 0;
864 else
865 dfaacc[newds].dfaacc_state = 0;
866
867 accsiz[newds] = 0;
868 }
869
870 else if ( reject )
871 {
872 /* We sort the accepting set in increasing order so the
873 * disambiguating rule that the first rule listed is considered
874 * match in the event of ties will work. We use a bubble
875 * sort since the list is probably quite small.
876 */
877
878 bubble( accset, nacc );
879
880 dfaacc[newds].dfaacc_set = allocate_integer_array( nacc + 1 );
881
882 /* Save the accepting set for later */
883 for ( i = 1; i <= nacc; ++i )
884 {
885 dfaacc[newds].dfaacc_set[i] = accset[i];
886
887 if ( accset[i] <= num_rules )
888 /* Who knows, perhaps a REJECT can yield
889 * this rule.
890 */
891 rule_useful[accset[i]] = true;
892 }
893
894 accsiz[newds] = nacc;
895 }
896
897 else
898 {
899 /* Find lowest numbered rule so the disambiguating rule
900 * will work.
901 */
902 j = num_rules + 1;
903
904 for ( i = 1; i <= nacc; ++i )
905 if ( accset[i] < j )
906 j = accset[i];
907
908 dfaacc[newds].dfaacc_state = j;
909
910 if ( j <= num_rules )
911 rule_useful[j] = true;
912 }
913
914 *newds_addr = newds;
915
916 return 1;
917 }
918
919
920 /* symfollowset - follow the symbol transitions one step
921 *
922 * synopsis
923 * numstates = symfollowset( int ds[current_max_dfa_size], int dsize,
924 * int transsym, int nset[current_max_dfa_size] );
925 */
926
symfollowset(ds,dsize,transsym,nset)927 int symfollowset( ds, dsize, transsym, nset )
928 int ds[], dsize, transsym, nset[];
929 {
930 int ns, tsp, sym, i, j, lenccl, ch, numstates, ccllist;
931
932 numstates = 0;
933
934 for ( i = 1; i <= dsize; ++i )
935 { /* for each nfa state ns in the state set of ds */
936 ns = ds[i];
937 sym = transchar[ns];
938 tsp = trans1[ns];
939
940 if ( sym < 0 )
941 { /* it's a character class */
942 sym = -sym;
943 ccllist = cclmap[sym];
944 lenccl = ccllen[sym];
945
946 if ( cclng[sym] )
947 {
948 for ( j = 0; j < lenccl; ++j )
949 {
950 /* Loop through negated character
951 * class.
952 */
953 ch = ccltbl[ccllist + j];
954
955 if ( ch == 0 )
956 ch = NUL_ec;
957
958 if ( ch > transsym )
959 /* Transsym isn't in negated
960 * ccl.
961 */
962 break;
963
964 else if ( ch == transsym )
965 /* next 2 */ goto bottom;
966 }
967
968 /* Didn't find transsym in ccl. */
969 nset[++numstates] = tsp;
970 }
971
972 else
973 for ( j = 0; j < lenccl; ++j )
974 {
975 ch = ccltbl[ccllist + j];
976
977 if ( ch == 0 )
978 ch = NUL_ec;
979
980 if ( ch > transsym )
981 break;
982 else if ( ch == transsym )
983 {
984 nset[++numstates] = tsp;
985 break;
986 }
987 }
988 }
989
990 else if ( sym >= 'A' && sym <= 'Z' && caseins )
991 flexfatal(
992 _( "consistency check failed in symfollowset" ) );
993
994 else if ( sym == SYM_EPSILON )
995 { /* do nothing */
996 }
997
998 else if ( ABS( ecgroup[sym] ) == transsym )
999 nset[++numstates] = tsp;
1000
1001 bottom: ;
1002 }
1003
1004 return numstates;
1005 }
1006
1007
1008 /* sympartition - partition characters with same out-transitions
1009 *
1010 * synopsis
1011 * sympartition( int ds[current_max_dfa_size], int numstates,
1012 * int symlist[numecs], int duplist[numecs] );
1013 */
1014
sympartition(ds,numstates,symlist,duplist)1015 void sympartition( ds, numstates, symlist, duplist )
1016 int ds[], numstates;
1017 int symlist[], duplist[];
1018 {
1019 int tch, i, j, k, ns, dupfwd[CSIZE + 1], lenccl, cclp, ich;
1020
1021 /* Partitioning is done by creating equivalence classes for those
1022 * characters which have out-transitions from the given state. Thus
1023 * we are really creating equivalence classes of equivalence classes.
1024 */
1025
1026 for ( i = 1; i <= numecs; ++i )
1027 { /* initialize equivalence class list */
1028 duplist[i] = i - 1;
1029 dupfwd[i] = i + 1;
1030 }
1031
1032 duplist[1] = NIL;
1033 dupfwd[numecs] = NIL;
1034
1035 for ( i = 1; i <= numstates; ++i )
1036 {
1037 ns = ds[i];
1038 tch = transchar[ns];
1039
1040 if ( tch != SYM_EPSILON )
1041 {
1042 if ( tch < -lastccl || tch >= csize )
1043 {
1044 flexfatal(
1045 _( "bad transition character detected in sympartition()" ) );
1046 }
1047
1048 if ( tch >= 0 )
1049 { /* character transition */
1050 int ec = ecgroup[tch];
1051
1052 mkechar( ec, dupfwd, duplist );
1053 symlist[ec] = 1;
1054 }
1055
1056 else
1057 { /* character class */
1058 tch = -tch;
1059
1060 lenccl = ccllen[tch];
1061 cclp = cclmap[tch];
1062 mkeccl( ccltbl + cclp, lenccl, dupfwd,
1063 duplist, numecs, NUL_ec );
1064
1065 if ( cclng[tch] )
1066 {
1067 j = 0;
1068
1069 for ( k = 0; k < lenccl; ++k )
1070 {
1071 ich = ccltbl[cclp + k];
1072
1073 if ( ich == 0 )
1074 ich = NUL_ec;
1075
1076 for ( ++j; j < ich; ++j )
1077 symlist[j] = 1;
1078 }
1079
1080 for ( ++j; j <= numecs; ++j )
1081 symlist[j] = 1;
1082 }
1083
1084 else
1085 for ( k = 0; k < lenccl; ++k )
1086 {
1087 ich = ccltbl[cclp + k];
1088
1089 if ( ich == 0 )
1090 ich = NUL_ec;
1091
1092 symlist[ich] = 1;
1093 }
1094 }
1095 }
1096 }
1097 }
1098