]> git.saurik.com Git - bison.git/blame - tests/reduce.at
xml: match DOT output and xml2dot.xsl processing
[bison.git] / tests / reduce.at
CommitLineData
cb4956ee 1# Exercising Bison Grammar Reduction. -*- Autotest -*-
6e30ede8 2
c932d613 3# Copyright (C) 2001-2002, 2007-2012 Free Software Foundation, Inc.
cb4956ee 4
f16b0819 5# This program is free software: you can redistribute it and/or modify
cb4956ee 6# it under the terms of the GNU General Public License as published by
f16b0819
PE
7# the Free Software Foundation, either version 3 of the License, or
8# (at your option) any later version.
9#
cb4956ee
AD
10# This program is distributed in the hope that it will be useful,
11# but WITHOUT ANY WARRANTY; without even the implied warranty of
12# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
13# GNU General Public License for more details.
f16b0819 14#
cb4956ee 15# You should have received a copy of the GNU General Public License
f16b0819 16# along with this program. If not, see <http://www.gnu.org/licenses/>.
cb4956ee
AD
17
18AT_BANNER([[Grammar Reduction.]])
19
20
21## ------------------- ##
22## Useless Terminals. ##
23## ------------------- ##
24
25AT_SETUP([Useless Terminals])
26
27AT_DATA([[input.y]],
28[[%verbose
02975b9a 29%output "input.c"
cb4956ee
AD
30
31%token useless1
32%token useless2
33%token useless3
34%token useless4
35%token useless5
36%token useless6
37%token useless7
38%token useless8
39%token useless9
40
41%token useful
42%%
43exp: useful;
44]])
45
da730230 46AT_BISON_CHECK([[input.y]])
cb4956ee
AD
47
48AT_CHECK([[sed -n '/^Grammar/q;/^$/!p' input.output]], 0,
d80fb37a 49[[Terminals unused in grammar
cb4956ee
AD
50 useless1
51 useless2
52 useless3
53 useless4
54 useless5
55 useless6
56 useless7
57 useless8
58 useless9
59]])
60
61AT_CLEANUP
62
63
64
65## ---------------------- ##
66## Useless Nonterminals. ##
67## ---------------------- ##
68
69AT_SETUP([Useless Nonterminals])
70
71AT_DATA([[input.y]],
72[[%verbose
02975b9a 73%output "input.c"
cb4956ee
AD
74
75%nterm useless1
76%nterm useless2
77%nterm useless3
78%nterm useless4
79%nterm useless5
80%nterm useless6
81%nterm useless7
82%nterm useless8
83%nterm useless9
84
85%token useful
86%%
87exp: useful;
88]])
89
da730230 90AT_BISON_CHECK([[input.y]], 0, [],
cff03fb2
JD
91[[input.y: warning: 9 nonterminals useless in grammar
92input.y:4.8-15: warning: nonterminal useless in grammar: useless1
93input.y:5.8-15: warning: nonterminal useless in grammar: useless2
94input.y:6.8-15: warning: nonterminal useless in grammar: useless3
95input.y:7.8-15: warning: nonterminal useless in grammar: useless4
96input.y:8.8-15: warning: nonterminal useless in grammar: useless5
97input.y:9.8-15: warning: nonterminal useless in grammar: useless6
98input.y:10.8-15: warning: nonterminal useless in grammar: useless7
99input.y:11.8-15: warning: nonterminal useless in grammar: useless8
100input.y:12.8-15: warning: nonterminal useless in grammar: useless9
760b53a8 101]])
cb4956ee
AD
102
103AT_CHECK([[sed -n '/^Grammar/q;/^$/!p' input.output]], 0,
cff03fb2 104[[Nonterminals useless in grammar
cb4956ee
AD
105 useless1
106 useless2
107 useless3
108 useless4
109 useless5
110 useless6
111 useless7
112 useless8
113 useless9
114]])
115
116AT_CLEANUP
68f1e3ed
AD
117
118
119
120## --------------- ##
121## Useless Rules. ##
122## --------------- ##
123
124AT_SETUP([Useless Rules])
125
9757c359
AD
126AT_KEYWORDS([report])
127
68f1e3ed
AD
128AT_DATA([[input.y]],
129[[%verbose
02975b9a 130%output "input.c"
68f1e3ed
AD
131%token useful
132%%
133exp: useful;
134useless1: '1';
135useless2: '2';
136useless3: '3';
137useless4: '4';
138useless5: '5';
139useless6: '6';
140useless7: '7';
141useless8: '8';
142useless9: '9';
143]])
144
da730230 145AT_BISON_CHECK([[input.y]], 0, [],
bcf07cb7
JD
146[[input.y: warning: 9 nonterminals useless in grammar
147input.y: warning: 9 rules useless in grammar
cff03fb2
JD
148input.y:6.1-8: warning: nonterminal useless in grammar: useless1
149input.y:7.1-8: warning: nonterminal useless in grammar: useless2
150input.y:8.1-8: warning: nonterminal useless in grammar: useless3
151input.y:9.1-8: warning: nonterminal useless in grammar: useless4
152input.y:10.1-8: warning: nonterminal useless in grammar: useless5
153input.y:11.1-8: warning: nonterminal useless in grammar: useless6
154input.y:12.1-8: warning: nonterminal useless in grammar: useless7
155input.y:13.1-8: warning: nonterminal useless in grammar: useless8
156input.y:14.1-8: warning: nonterminal useless in grammar: useless9
157input.y:6.11-13: warning: rule useless in grammar: useless1: '1'
158input.y:7.11-13: warning: rule useless in grammar: useless2: '2'
159input.y:8.11-13: warning: rule useless in grammar: useless3: '3'
160input.y:9.11-13: warning: rule useless in grammar: useless4: '4'
161input.y:10.11-13: warning: rule useless in grammar: useless5: '5'
162input.y:11.11-13: warning: rule useless in grammar: useless6: '6'
163input.y:12.11-13: warning: rule useless in grammar: useless7: '7'
164input.y:13.11-13: warning: rule useless in grammar: useless8: '8'
165input.y:14.11-13: warning: rule useless in grammar: useless9: '9'
68f1e3ed
AD
166]])
167
168AT_CHECK([[sed -n '/^Grammar/q;/^$/!p' input.output]], 0,
cff03fb2 169[[Nonterminals useless in grammar
68f1e3ed
AD
170 useless1
171 useless2
172 useless3
173 useless4
174 useless5
175 useless6
176 useless7
177 useless8
178 useless9
d80fb37a 179Terminals unused in grammar
68f1e3ed
AD
180 '1'
181 '2'
182 '3'
183 '4'
184 '5'
185 '6'
186 '7'
187 '8'
188 '9'
cff03fb2 189Rules useless in grammar
9757c359
AD
190 2 useless1: '1'
191 3 useless2: '2'
192 4 useless3: '3'
193 5 useless4: '4'
194 6 useless5: '5'
195 7 useless6: '6'
196 8 useless7: '7'
197 9 useless8: '8'
198 10 useless9: '9'
68f1e3ed
AD
199]])
200
201AT_CLEANUP
202
203
204
c3b407f4
AD
205## ------------------- ##
206## Reduced Automaton. ##
207## ------------------- ##
208
209# Check that the automaton is that as the for the grammar reduced by
210# hand.
211
212AT_SETUP([Reduced Automaton])
213
9757c359
AD
214AT_KEYWORDS([report])
215
c3b407f4
AD
216# The non reduced grammar.
217# ------------------------
218AT_DATA([[not-reduced.y]],
219[[/* A useless token. */
220%token useless_token
221/* A useful one. */
222%token useful
223%verbose
02975b9a 224%output "not-reduced.c"
c3b407f4
AD
225
226%%
227
228exp: useful { /* A useful action. */ }
229 | non_productive { /* A non productive action. */ }
230 ;
231
232not_reachable: useful { /* A not reachable action. */ }
233 ;
234
235non_productive: non_productive useless_token
236 { /* Another non productive action. */ }
237 ;
e9955c83 238%%
c3b407f4
AD
239]])
240
da730230 241AT_BISON_CHECK([[not-reduced.y]], 0, [],
bcf07cb7
JD
242[[not-reduced.y: warning: 2 nonterminals useless in grammar
243not-reduced.y: warning: 3 rules useless in grammar
cff03fb2
JD
244not-reduced.y:14.1-13: warning: nonterminal useless in grammar: not_reachable
245not-reduced.y:11.6-19: warning: nonterminal useless in grammar: non_productive
246not-reduced.y:11.6-57: warning: rule useless in grammar: exp: non_productive
247not-reduced.y:14.16-56: warning: rule useless in grammar: not_reachable: useful
248not-reduced.y:17.17-18.63: warning: rule useless in grammar: non_productive: non_productive useless_token
c3b407f4
AD
249]])
250
251AT_CHECK([[sed -n '/^Grammar/q;/^$/!p' not-reduced.output]], 0,
cff03fb2 252[[Nonterminals useless in grammar
c3b407f4
AD
253 not_reachable
254 non_productive
d80fb37a 255Terminals unused in grammar
c3b407f4 256 useless_token
cff03fb2 257Rules useless in grammar
9757c359
AD
258 2 exp: non_productive
259 3 not_reachable: useful
260 4 non_productive: non_productive useless_token
c3b407f4
AD
261]])
262
263# The reduced grammar.
264# --------------------
265AT_DATA([[reduced.y]],
266[[/* A useless token. */
267%token useless_token
268/* A useful one. */
269%token useful
270%verbose
02975b9a 271%output "reduced.c"
c3b407f4
AD
272
273%%
274
275exp: useful { /* A useful action. */ }
276// | non_productive { /* A non productive action. */ } */
277 ;
278
279//not_reachable: useful { /* A not reachable action. */ }
280// ;
281
282//non_productive: non_productive useless_token
283// { /* Another non productive action. */ }
284// ;
e9955c83 285%%
c3b407f4
AD
286]])
287
da730230 288AT_BISON_CHECK([[reduced.y]])
c3b407f4
AD
289
290# Comparing the parsers.
291cp reduced.c expout
292AT_CHECK([sed 's/not-reduced/reduced/g' not-reduced.c], 0, [expout])
293
294AT_CLEANUP
295
296
297
68f1e3ed
AD
298## ------------------- ##
299## Underivable Rules. ##
300## ------------------- ##
301
302AT_SETUP([Underivable Rules])
303
9757c359
AD
304AT_KEYWORDS([report])
305
68f1e3ed
AD
306AT_DATA([[input.y]],
307[[%verbose
02975b9a 308%output "input.c"
68f1e3ed
AD
309%token useful
310%%
311exp: useful | underivable;
312underivable: indirection;
313indirection: underivable;
314]])
315
da730230 316AT_BISON_CHECK([[input.y]], 0, [],
bcf07cb7
JD
317[[input.y: warning: 2 nonterminals useless in grammar
318input.y: warning: 3 rules useless in grammar
cff03fb2
JD
319input.y:5.15-25: warning: nonterminal useless in grammar: underivable
320input.y:6.14-24: warning: nonterminal useless in grammar: indirection
321input.y:5.15-25: warning: rule useless in grammar: exp: underivable
322input.y:6.14-24: warning: rule useless in grammar: underivable: indirection
323input.y:7.14-24: warning: rule useless in grammar: indirection: underivable
68f1e3ed
AD
324]])
325
326AT_CHECK([[sed -n '/^Grammar/q;/^$/!p' input.output]], 0,
cff03fb2 327[[Nonterminals useless in grammar
68f1e3ed
AD
328 underivable
329 indirection
cff03fb2 330Rules useless in grammar
9757c359
AD
331 2 exp: underivable
332 3 underivable: indirection
333 4 indirection: underivable
68f1e3ed
AD
334]])
335
336AT_CLEANUP
1bfb97db
AD
337
338
339
340## ---------------- ##
341## Empty Language. ##
342## ---------------- ##
343
344AT_SETUP([Empty Language])
345
346AT_DATA([[input.y]],
02975b9a 347[[%output "input.c"
1bfb97db
AD
348%%
349exp: exp;
350]])
351
da730230 352AT_BISON_CHECK([[input.y]], 1, [],
bcf07cb7
JD
353[[input.y: warning: 2 nonterminals useless in grammar
354input.y: warning: 2 rules useless in grammar
1bfb97db
AD
355input.y:3.1-3: fatal error: start symbol exp does not derive any sentence
356]])
357
358AT_CLEANUP
03c07b03
JD
359
360
361
f805dfcb
JD
362## ----------------- ##
363## %define lr.type. ##
364## ----------------- ##
365
366# AT_TEST_LR_TYPE(DESCRIPTION,
367# DECLS, GRAMMAR, INPUT,
368# BISON-STDERR, TABLES,
369# [OTHER-CHECKS],
370# [PARSER-EXIT-VALUE],
371# [PARSER-STDOUT], [PARSER-STDERR])
372# -------------------------------------------------
373m4_define([AT_TEST_LR_TYPE],
374[
375AT_TEST_TABLES_AND_PARSE([[no %define lr.type: ]$1],
376 [[LALR]], [[]],
377 [$2], m4_shiftn(2, $@))
f37495f6 378AT_TEST_TABLES_AND_PARSE([[%define lr.type lalr: ]$1],
f805dfcb 379 [[LALR]], [[]],
f37495f6 380 [[%define lr.type lalr
f805dfcb
JD
381]$2],
382 m4_shiftn(2, $@))
f37495f6 383AT_TEST_TABLES_AND_PARSE([[%define lr.type ielr: ]$1],
f805dfcb 384 [[IELR]], [[]],
f37495f6 385 [[%define lr.type ielr
f805dfcb
JD
386]$2],
387 m4_shiftn(2, $@))
f37495f6 388AT_TEST_TABLES_AND_PARSE([[%define lr.type canonical-lr: ]$1],
f805dfcb 389 [[canonical LR]], [[]],
f37495f6 390 [[%define lr.type canonical-lr
f805dfcb
JD
391]$2],
392 m4_shiftn(2, $@))
393])
394
395AT_TEST_LR_TYPE([[Single State Split]],
396[[%left 'a'
397// Conflict resolution renders state 12 unreachable for canonical LR(1). We
398// keep it so that the paser table diff is easier to code.
812775a0 399%define lr.keep-unreachable-states]],
f805dfcb
JD
400[[
401S: 'a' A 'a' /* rule 1 */
402 | 'b' A 'b' /* rule 2 */
403 | 'c' c /* rule 3 */
404 ;
405
406/* A conflict should appear after the first 'a' in rules 4 and 5 but only after
407 having shifted the first 'a' in rule 1. However, when LALR(1) merging is
408 chosen, the state containing that conflict is reused after having seen the
409 first 'b' in rule 2 and then the first 'a' in rules 4 and 5. In both cases,
410 because of the merged state, if the next token is an 'a', the %left forces a
411 reduction action with rule 5. In the latter case, only a shift is actually
412 grammatically correct. Thus, the parser would report a syntax error for the
413 grammatically correct sentence "baab" because it would encounter a syntax
414 error after that incorrect reduction.
415
416 Despite not being LALR(1), Menhir version 20070322 suffers from this problem
417 as well. It uses David Pager's weak compatibility test for merging states.
418 Bison and Menhir accept non-LR(1) grammars with conflict resolution. Pager
419 designed his algorithm only for LR(1) grammars. */
420A: 'a' 'a' /* rule 4 */
421 | 'a' /* rule 5 */
422 ;
423
424/* Rule 3, rule 6, and rule 7 ensure that Bison does not report rule 4 as
425 useless after conflict resolution. This proves that, even though LALR(1)
426 generates incorrect parser tables sometimes, Bison will not necessarily
427 produce any warning to help the user realize it. */
428c: 'a' 'b' /* rule 6 */
429 | A /* rule 7 */
430 ;
431]],
432
433dnl INPUT
434[['b', 'a', 'a', 'b']],
435
436dnl BISON-STDERR
437[],
438
439dnl TABLES
d42fe46e 440[[State 0
f805dfcb
JD
441
442 0 $accept: . S $end
443 1 S: . 'a' A 'a'
444 2 | . 'b' A 'b'
445 3 | . 'c' c
446
447 'a' shift, and go to state 1
448 'b' shift, and go to state 2
449 'c' shift, and go to state 3
450
451 S go to state 4
452
453
d42fe46e 454State 1
f805dfcb
JD
455
456 1 S: 'a' . A 'a'
457 4 A: . 'a' 'a'
458 5 | . 'a'
459
460 'a' shift, and go to state 5
461
462 A go to state 6
463
464
d42fe46e 465State 2
f805dfcb
JD
466
467 2 S: 'b' . A 'b'
468 4 A: . 'a' 'a'
469 5 | . 'a'
470
471 'a' shift, and go to state ]AT_COND_CASE([[LALR]], [[5]], [[16]])[
472
473 A go to state 7
474
475
d42fe46e 476State 3
f805dfcb
JD
477
478 3 S: 'c' . c
479 4 A: . 'a' 'a'
480 5 | . 'a'
481 6 c: . 'a' 'b'
482 7 | . A
483
484 'a' shift, and go to state 8
485
486 A go to state 9
487 c go to state 10
488
489
d42fe46e 490State 4
f805dfcb
JD
491
492 0 $accept: S . $end
493
494 $end shift, and go to state 11
495
496
d42fe46e 497State 5
f805dfcb
JD
498
499 4 A: 'a' . 'a'
500 5 | 'a' . ]AT_COND_CASE([[LALR]], [[['a', 'b']]], [[['a']]])[
501
502 ]AT_COND_CASE([[canonical LR]], [['a']],
503 [[$default]])[ reduce using rule 5 (A)
504
505 Conflict between rule 5 and token 'a' resolved as reduce (%left 'a').
506
507
d42fe46e 508State 6
f805dfcb
JD
509
510 1 S: 'a' A . 'a'
511
512 'a' shift, and go to state 13
513
514
d42fe46e 515State 7
f805dfcb
JD
516
517 2 S: 'b' A . 'b'
518
519 'b' shift, and go to state 14
520
521
d42fe46e 522State 8
f805dfcb
JD
523
524 4 A: 'a' . 'a'
525 5 | 'a' . [$end]
526 6 c: 'a' . 'b'
527
528 'a' shift, and go to state ]AT_COND_CASE([[canonical LR]], [[17]],
529 [[12]])[
530 'b' shift, and go to state 15
531
532 ]AT_COND_CASE([[canonical LR]], [[$end]],
533 [[$default]])[ reduce using rule 5 (A)
534
535
d42fe46e 536State 9
f805dfcb
JD
537
538 7 c: A .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
539
540 ]AT_COND_CASE([[canonical LR]], [[$end]],
541 [[$default]])[ reduce using rule 7 (c)
542
543
d42fe46e 544State 10
f805dfcb
JD
545
546 3 S: 'c' c .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
547
548 ]AT_COND_CASE([[canonical LR]], [[$end]],
549 [[$default]])[ reduce using rule 3 (S)
550
551
d42fe46e 552State 11
f805dfcb
JD
553
554 0 $accept: S $end .
555
556 $default accept
557
558
d42fe46e 559State 12
f805dfcb
JD
560
561 4 A: 'a' 'a' .]AT_COND_CASE([[canonical LR]], [[ ['a']]])[
562
563 ]AT_COND_CASE([[canonical LR]], [['a']],
564 [[$default]])[ reduce using rule 4 (A)
565
566
d42fe46e 567State 13
f805dfcb
JD
568
569 1 S: 'a' A 'a' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
570
571 ]AT_COND_CASE([[canonical LR]], [[$end]],
572 [[$default]])[ reduce using rule 1 (S)
573
574
d42fe46e 575State 14
f805dfcb
JD
576
577 2 S: 'b' A 'b' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
578
579 ]AT_COND_CASE([[canonical LR]], [[$end]],
580 [[$default]])[ reduce using rule 2 (S)
581
582
d42fe46e 583State 15
f805dfcb
JD
584
585 6 c: 'a' 'b' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
586
587 ]AT_COND_CASE([[canonical LR]], [[$end]],
588 [[$default]])[ reduce using rule 6 (c)]AT_COND_CASE([[LALR]],
589 [[]], [[
590
591
d42fe46e 592State 16
f805dfcb
JD
593
594 4 A: 'a' . 'a'
595 5 | 'a' . ['b']
596
597 'a' shift, and go to state ]AT_COND_CASE([[canonical LR]], [[18]],
598 [[12]])[
599
600 ]AT_COND_CASE([[canonical LR]], [['b']],
601 [[$default]])[ reduce using rule 5 (A)]AT_COND_CASE([[canonical LR]], [[
602
603
d42fe46e 604State 17
f805dfcb
JD
605
606 4 A: 'a' 'a' . [$end]
607
608 $end reduce using rule 4 (A)
609
610
d42fe46e 611State 18
f805dfcb
JD
612
613 4 A: 'a' 'a' . ['b']
614
615 'b' reduce using rule 4 (A)]])])[
616]],
617
618dnl OTHER-CHECKS
619[],
620
621dnl PARSER-EXIT-VALUE, PARSER-STDOUT, PARSER-STDERR
622[AT_COND_CASE([[LALR]], [[1]], [[0]])],
623[],
624[AT_COND_CASE([[LALR]],
625[[syntax error
626]])])
627
628AT_TEST_LR_TYPE([[Lane Split]],
629[[%left 'a'
630// Conflict resolution renders state 16 unreachable for canonical LR(1). We
631// keep it so that the paser table diff is easier to code.
812775a0 632%define lr.keep-unreachable-states]],
f805dfcb
JD
633[[
634/* Similar to the last test case set but two states must be split. */
635S: 'a' A 'a' /* rule 1 */
636 | 'b' A 'b' /* rule 2 */
637 | 'c' c /* rule 3 */
638 ;
639
640A: 'a' 'a' 'a' /* rule 4 */
641 | 'a' 'a' /* rule 5 */
642 ;
643
644c: 'a' 'a' 'b' /* rule 6 */
645 | A /* rule 7 */
646 ;
647]],
648
649dnl INPUT
650[['b', 'a', 'a', 'a', 'b']],
651
652dnl BISON-STDERR
653[],
654
655dnl TABLES
d42fe46e 656[[State 0
f805dfcb
JD
657
658 0 $accept: . S $end
659 1 S: . 'a' A 'a'
660 2 | . 'b' A 'b'
661 3 | . 'c' c
662
663 'a' shift, and go to state 1
664 'b' shift, and go to state 2
665 'c' shift, and go to state 3
666
667 S go to state 4
668
669
d42fe46e 670State 1
f805dfcb
JD
671
672 1 S: 'a' . A 'a'
673 4 A: . 'a' 'a' 'a'
674 5 | . 'a' 'a'
675
676 'a' shift, and go to state 5
677
678 A go to state 6
679
680
d42fe46e 681State 2
f805dfcb
JD
682
683 2 S: 'b' . A 'b'
684 4 A: . 'a' 'a' 'a'
685 5 | . 'a' 'a'
686
687 'a' shift, and go to state ]AT_COND_CASE([[LALR]], [[5]], [[18]])[
688
689 A go to state 7
690
691
d42fe46e 692State 3
f805dfcb
JD
693
694 3 S: 'c' . c
695 4 A: . 'a' 'a' 'a'
696 5 | . 'a' 'a'
697 6 c: . 'a' 'a' 'b'
698 7 | . A
699
700 'a' shift, and go to state 8
701
702 A go to state 9
703 c go to state 10
704
705
d42fe46e 706State 4
f805dfcb
JD
707
708 0 $accept: S . $end
709
710 $end shift, and go to state 11
711
712
d42fe46e 713State 5
f805dfcb
JD
714
715 4 A: 'a' . 'a' 'a'
716 5 | 'a' . 'a'
717
718 'a' shift, and go to state 12
719
720
d42fe46e 721State 6
f805dfcb
JD
722
723 1 S: 'a' A . 'a'
724
725 'a' shift, and go to state 13
726
727
d42fe46e 728State 7
f805dfcb
JD
729
730 2 S: 'b' A . 'b'
731
732 'b' shift, and go to state 14
733
734
d42fe46e 735State 8
f805dfcb
JD
736
737 4 A: 'a' . 'a' 'a'
738 5 | 'a' . 'a'
739 6 c: 'a' . 'a' 'b'
740
741 'a' shift, and go to state 15
742
743
d42fe46e 744State 9
f805dfcb
JD
745
746 7 c: A .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
747
748 ]AT_COND_CASE([[canonical LR]], [[$end]],
749 [[$default]])[ reduce using rule 7 (c)
750
751
d42fe46e 752State 10
f805dfcb
JD
753
754 3 S: 'c' c .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
755
756 ]AT_COND_CASE([[canonical LR]], [[$end]],
757 [[$default]])[ reduce using rule 3 (S)
758
759
d42fe46e 760State 11
f805dfcb
JD
761
762 0 $accept: S $end .
763
764 $default accept
765
766
d42fe46e 767State 12
f805dfcb
JD
768
769 4 A: 'a' 'a' . 'a'
770 5 | 'a' 'a' . ]AT_COND_CASE([[LALR]], [[['a', 'b']]], [[['a']]])[
771
772 ]AT_COND_CASE([[canonical LR]], [['a']],
773 [[$default]])[ reduce using rule 5 (A)
774
775 Conflict between rule 5 and token 'a' resolved as reduce (%left 'a').
776
777
d42fe46e 778State 13
f805dfcb
JD
779
780 1 S: 'a' A 'a' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
781
782 ]AT_COND_CASE([[canonical LR]], [[$end]],
783 [[$default]])[ reduce using rule 1 (S)
784
785
d42fe46e 786State 14
f805dfcb
JD
787
788 2 S: 'b' A 'b' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
789
790 ]AT_COND_CASE([[canonical LR]], [[$end]],
791 [[$default]])[ reduce using rule 2 (S)
792
793
d42fe46e 794State 15
f805dfcb
JD
795
796 4 A: 'a' 'a' . 'a'
797 5 | 'a' 'a' . [$end]
798 6 c: 'a' 'a' . 'b'
799
800 'a' shift, and go to state ]AT_COND_CASE([[canonical LR]], [[19]],
801 [[16]])[
802 'b' shift, and go to state 17
803
804 ]AT_COND_CASE([[canonical LR]], [[$end]],
805 [[$default]])[ reduce using rule 5 (A)
806
807
d42fe46e 808State 16
f805dfcb
JD
809
810 4 A: 'a' 'a' 'a' .]AT_COND_CASE([[canonical LR]], [[ ['a']]])[
811
812 ]AT_COND_CASE([[canonical LR]], [['a']],
813 [[$default]])[ reduce using rule 4 (A)
814
815
d42fe46e 816State 17
f805dfcb
JD
817
818 6 c: 'a' 'a' 'b' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
819
820 ]AT_COND_CASE([[canonical LR]], [[$end]],
821 [[$default]])[ reduce using rule 6 (c)]AT_COND_CASE([[LALR]],
822 [[]], [[
823
824
d42fe46e 825State 18
f805dfcb
JD
826
827 4 A: 'a' . 'a' 'a'
828 5 | 'a' . 'a'
829
830 'a' shift, and go to state ]AT_COND_CASE([[canonical LR]], [[20]],
831 [[19]])[
832
833
d42fe46e 834State 19]AT_COND_CASE([[canonical LR]], [[
f805dfcb
JD
835
836 4 A: 'a' 'a' 'a' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
837
838 ]AT_COND_CASE([[canonical LR]], [[$end]],
839 [[$default]])[ reduce using rule 4 (A)
840
841
d42fe46e 842State 20]])[
f805dfcb
JD
843
844 4 A: 'a' 'a' . 'a'
845 5 | 'a' 'a' . ['b']
846
847 'a' shift, and go to state ]AT_COND_CASE([[canonical LR]], [[21]],
848 [[16]])[
849
850 ]AT_COND_CASE([[canonical LR]], [['b']],
851 [[$default]])[ reduce using rule 5 (A)]AT_COND_CASE([[canonical LR]], [[
852
853
d42fe46e 854State 21
f805dfcb
JD
855
856 4 A: 'a' 'a' 'a' .]AT_COND_CASE([[canonical LR]], [[ ['b']]])[
857
858 ]AT_COND_CASE([[canonical LR]], [['b']],
859 [[$default]])[ reduce using rule 4 (A)]])])[
860]],
861
862dnl OTHER-CHECKS
863[],
864
865dnl PARSER-EXIT-VALUE, PARSER-STDOUT, PARSER-STDERR
866[AT_COND_CASE([[LALR]], [[1]], [[0]])],
867[],
868[AT_COND_CASE([[LALR]],
869[[syntax error
870]])])
871
872AT_TEST_LR_TYPE([[Complex Lane Split]],
873[[%left 'a'
874// Conflict resolution renders state 16 unreachable for canonical LR(1). We
875// keep it so that the paser table diff is easier to code.
812775a0 876%define lr.keep-unreachable-states]],
f805dfcb
JD
877[[
878/* Similar to the last test case set but forseeing the S/R conflict from the
879 first state that must be split is becoming difficult. Imagine if B were
880 even more complex. Imagine if A had other RHS's ending in other
881 nonterminals. */
882S: 'a' A 'a'
883 | 'b' A 'b'
884 | 'c' c
885 ;
886A: 'a' 'a' B
887 ;
888B: 'a'
889 | %prec 'a'
890 ;
891c: 'a' 'a' 'b'
892 | A
893 ;
894]],
895
896dnl INPUT
897[['b', 'a', 'a', 'a', 'b']],
898
899dnl BISON-STDERR
900[],
901
902dnl TABLES
d42fe46e 903[[State 0
f805dfcb
JD
904
905 0 $accept: . S $end
906 1 S: . 'a' A 'a'
907 2 | . 'b' A 'b'
908 3 | . 'c' c
909
910 'a' shift, and go to state 1
911 'b' shift, and go to state 2
912 'c' shift, and go to state 3
913
914 S go to state 4
915
916
d42fe46e 917State 1
f805dfcb
JD
918
919 1 S: 'a' . A 'a'
920 4 A: . 'a' 'a' B
921
922 'a' shift, and go to state 5
923
924 A go to state 6
925
926
d42fe46e 927State 2
f805dfcb
JD
928
929 2 S: 'b' . A 'b'
930 4 A: . 'a' 'a' B
931
932 'a' shift, and go to state ]AT_COND_CASE([[LALR]], [[5]], [[19]])[
933
934 A go to state 7
935
936
d42fe46e 937State 3
f805dfcb
JD
938
939 3 S: 'c' . c
940 4 A: . 'a' 'a' B
941 7 c: . 'a' 'a' 'b'
942 8 | . A
943
944 'a' shift, and go to state 8
945
946 A go to state 9
947 c go to state 10
948
949
d42fe46e 950State 4
f805dfcb
JD
951
952 0 $accept: S . $end
953
954 $end shift, and go to state 11
955
956
d42fe46e 957State 5
f805dfcb
JD
958
959 4 A: 'a' . 'a' B
960
961 'a' shift, and go to state 12
962
963
d42fe46e 964State 6
f805dfcb
JD
965
966 1 S: 'a' A . 'a'
967
968 'a' shift, and go to state 13
969
970
d42fe46e 971State 7
f805dfcb
JD
972
973 2 S: 'b' A . 'b'
974
975 'b' shift, and go to state 14
976
977
d42fe46e 978State 8
f805dfcb
JD
979
980 4 A: 'a' . 'a' B
981 7 c: 'a' . 'a' 'b'
982
983 'a' shift, and go to state 15
984
985
d42fe46e 986State 9
f805dfcb
JD
987
988 8 c: A .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
989
990 ]AT_COND_CASE([[canonical LR]], [[$end]],
991 [[$default]])[ reduce using rule 8 (c)
992
993
d42fe46e 994State 10
f805dfcb
JD
995
996 3 S: 'c' c .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
997
998 ]AT_COND_CASE([[canonical LR]], [[$end]],
999 [[$default]])[ reduce using rule 3 (S)
1000
1001
d42fe46e 1002State 11
f805dfcb
JD
1003
1004 0 $accept: S $end .
1005
1006 $default accept
1007
1008
d42fe46e 1009State 12
f805dfcb
JD
1010
1011 4 A: 'a' 'a' . B
1012 5 B: . 'a'
1013 6 | . ]AT_COND_CASE([[LALR]], [[['a', 'b']]], [[['a']]])[
1014
1015 ]AT_COND_CASE([[canonical LR]], [['a']],
1016 [[$default]])[ reduce using rule 6 (B)
1017
1018 B go to state 17
1019
1020 Conflict between rule 6 and token 'a' resolved as reduce (%left 'a').
1021
1022
d42fe46e 1023State 13
f805dfcb
JD
1024
1025 1 S: 'a' A 'a' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
1026
1027 ]AT_COND_CASE([[canonical LR]], [[$end]],
1028 [[$default]])[ reduce using rule 1 (S)
1029
1030
d42fe46e 1031State 14
f805dfcb
JD
1032
1033 2 S: 'b' A 'b' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
1034
1035 ]AT_COND_CASE([[canonical LR]], [[$end]],
1036 [[$default]])[ reduce using rule 2 (S)
1037
1038
d42fe46e 1039State 15
f805dfcb
JD
1040
1041 4 A: 'a' 'a' . B
1042 5 B: . 'a'
1043 6 | . [$end]
1044 7 c: 'a' 'a' . 'b'
1045
1046 'a' shift, and go to state ]AT_COND_CASE([[canonical LR]], [[20]],
1047 [[16]])[
1048 'b' shift, and go to state 18
1049
1050 ]AT_COND_CASE([[canonical LR]], [[$end]],
1051 [[$default]])[ reduce using rule 6 (B)
1052
1053 B go to state ]AT_COND_CASE([[canonical LR]], [[21]], [[17]])[
1054
1055
d42fe46e 1056State 16
f805dfcb
JD
1057
1058 5 B: 'a' .]AT_COND_CASE([[canonical LR]], [[ ['a']]])[
1059
1060 ]AT_COND_CASE([[canonical LR]], [['a']],
1061 [[$default]])[ reduce using rule 5 (B)
1062
1063
d42fe46e 1064State 17
f805dfcb
JD
1065
1066 4 A: 'a' 'a' B .]AT_COND_CASE([[canonical LR]], [[ ['a']]])[
1067
1068 ]AT_COND_CASE([[canonical LR]], [['a']],
1069 [[$default]])[ reduce using rule 4 (A)
1070
1071
d42fe46e 1072State 18
f805dfcb
JD
1073
1074 7 c: 'a' 'a' 'b' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
1075
1076 ]AT_COND_CASE([[canonical LR]], [[$end]],
1077 [[$default]])[ reduce using rule 7 (c)]AT_COND_CASE([[LALR]], [], [[
1078
1079
d42fe46e 1080State 19
f805dfcb
JD
1081
1082 4 A: 'a' . 'a' B
1083
1084 'a' shift, and go to state ]AT_COND_CASE([[canonical LR]], [[22]],
1085 [[20]])[
1086
1087
d42fe46e 1088State 20]AT_COND_CASE([[canonical LR]], [[
f805dfcb
JD
1089
1090 5 B: 'a' . [$end]
1091
1092 $end reduce using rule 5 (B)
1093
1094
d42fe46e 1095State 21
f805dfcb
JD
1096
1097 4 A: 'a' 'a' B . [$end]
1098
1099 $end reduce using rule 4 (A)
1100
1101
d42fe46e 1102State 22]])[
f805dfcb
JD
1103
1104 4 A: 'a' 'a' . B
1105 5 B: . 'a'
1106 6 | . ['b']
1107
1108 'a' shift, and go to state ]AT_COND_CASE([[canonical LR]], [[23]],
1109 [[16]])[
1110
1111 ]AT_COND_CASE([[canonical LR]], [['b']],
1112 [[$default]])[ reduce using rule 6 (B)
1113
1114 B go to state ]AT_COND_CASE([[canonical LR]], [[24
1115
1116
d42fe46e 1117State 23
f805dfcb
JD
1118
1119 5 B: 'a' . ['b']
1120
1121 'b' reduce using rule 5 (B)
1122
1123
d42fe46e 1124State 24
f805dfcb
JD
1125
1126 4 A: 'a' 'a' B . ['b']
1127
1128 'b' reduce using rule 4 (A)]], [[17]])])[
1129]],
1130
1131dnl OTHER-CHECKS
1132[],
1133
1134dnl PARSER-EXIT-VALUE, PARSER-STDOUT, PARSER-STDERR
1135[AT_COND_CASE([[LALR]], [[1]], [[0]])],
1136[],
1137[AT_COND_CASE([[LALR]],
1138[[syntax error
1139]])])
1140
1141AT_TEST_LR_TYPE([[Split During Added Lookahead Propagation]],
812775a0 1142[[%define lr.keep-unreachable-states]],
f805dfcb
JD
1143[[
1144/* The partial state chart diagram below is for LALR(1). State 0 is the start
1145 state. States are iterated for successor construction in numerical order.
1146 Transitions are downwards.
1147
1148 State 13 has a R/R conflict that cannot be predicted by Bison's LR(1)
1149 algorithm using annotations alone. That is, when state 11's successor on
1150 'd' is merged with state 5 (which is originally just state 1's successor on
1151 'd'), state 5's successor on 'e' must then be changed because the resulting
1152 lookaheads that propagate to it now make it incompatible with state 8's
1153 successor on 'e'. In other words, state 13 must be split to avoid the
1154 conflict.
1155
1156 0
1157 / | \
1158 a / c| \ b
1159 1 3 2
1160 | | |
1161 d| |c | d
1162 | 11 |
1163 | | |
1164 \ /d |
1165 5 8
1166 \ |
1167 e \ / e
1168 13
1169 R/R
1170
1171 This grammar is designed carefully to make sure that, despite Bison's LR(1)
1172 algorithm's bread-first iteration of transitions to reconstruct states,
1173 state 11's successors are constructed after state 5's and state 8's.
1174 Otherwise (for example, if you remove the first 'c' in each of rules 6 and
1175 7), state 5's successor on 'e' would never be merged with state 8's, so the
1176 split of the resulting state 13 would never need to be performed. */
1177S: 'a' A 'f'
1178 | 'a' B
1179 | 'b' A 'f'
1180 | 'b' B 'g'
1181 | 'b' 'd'
1182 | 'c' 'c' A 'g'
1183 | 'c' 'c' B
1184 ;
1185A: 'd' 'e' ;
1186B: 'd' 'e' ;
1187]],
1188
1189dnl INPUT
1190[['b', 'd', 'e', 'g']],
1191
1192dnl BISON-STDERR
1193[AT_COND_CASE([[LALR]],
1194[[input.y: conflicts: 1 reduce/reduce
1195]], [])],
1196
1197dnl TABLES
d42fe46e 1198[[State 0
f805dfcb
JD
1199
1200 0 $accept: . S $end
1201 1 S: . 'a' A 'f'
1202 2 | . 'a' B
1203 3 | . 'b' A 'f'
1204 4 | . 'b' B 'g'
1205 5 | . 'b' 'd'
1206 6 | . 'c' 'c' A 'g'
1207 7 | . 'c' 'c' B
1208
1209 'a' shift, and go to state 1
1210 'b' shift, and go to state 2
1211 'c' shift, and go to state 3
1212
1213 S go to state 4
1214
1215
d42fe46e 1216State 1
f805dfcb
JD
1217
1218 1 S: 'a' . A 'f'
1219 2 | 'a' . B
1220 8 A: . 'd' 'e'
1221 9 B: . 'd' 'e'
1222
1223 'd' shift, and go to state 5
1224
1225 A go to state 6
1226 B go to state 7
1227
1228
d42fe46e 1229State 2
f805dfcb
JD
1230
1231 3 S: 'b' . A 'f'
1232 4 | 'b' . B 'g'
1233 5 | 'b' . 'd'
1234 8 A: . 'd' 'e'
1235 9 B: . 'd' 'e'
1236
1237 'd' shift, and go to state 8
1238
1239 A go to state 9
1240 B go to state 10
1241
1242
d42fe46e 1243State 3
f805dfcb
JD
1244
1245 6 S: 'c' . 'c' A 'g'
1246 7 | 'c' . 'c' B
1247
1248 'c' shift, and go to state 11
1249
1250
d42fe46e 1251State 4
f805dfcb
JD
1252
1253 0 $accept: S . $end
1254
1255 $end shift, and go to state 12
1256
1257
d42fe46e 1258State 5
f805dfcb
JD
1259
1260 8 A: 'd' . 'e'
1261 9 B: 'd' . 'e'
1262
1263 'e' shift, and go to state ]AT_COND_CASE([[LALR]], [[13]],
1264 [[canonical LR]], [[13]],
1265 [[20]])[
1266
1267
d42fe46e 1268State 6
f805dfcb
JD
1269
1270 1 S: 'a' A . 'f'
1271
1272 'f' shift, and go to state 14
1273
1274
d42fe46e 1275State 7
f805dfcb
JD
1276
1277 2 S: 'a' B .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
1278
1279 ]AT_COND_CASE([[canonical LR]], [[$end]],
1280 [[$default]])[ reduce using rule 2 (S)
1281
1282
d42fe46e 1283State 8
f805dfcb
JD
1284
1285 5 S: 'b' 'd' . [$end]
1286 8 A: 'd' . 'e'
1287 9 B: 'd' . 'e'
1288
1289 'e' shift, and go to state ]AT_COND_CASE([[canonical LR]], [[20]],
1290 [[13]])[
1291
1292 ]AT_COND_CASE([[canonical LR]], [[$end]],
1293 [[$default]])[ reduce using rule 5 (S)
1294
1295
d42fe46e 1296State 9
f805dfcb
JD
1297
1298 3 S: 'b' A . 'f'
1299
1300 'f' shift, and go to state 15
1301
1302
d42fe46e 1303State 10
f805dfcb
JD
1304
1305 4 S: 'b' B . 'g'
1306
1307 'g' shift, and go to state 16
1308
1309
d42fe46e 1310State 11
f805dfcb
JD
1311
1312 6 S: 'c' 'c' . A 'g'
1313 7 | 'c' 'c' . B
1314 8 A: . 'd' 'e'
1315 9 B: . 'd' 'e'
1316
1317 'd' shift, and go to state ]AT_COND_CASE([[canonical LR]], [[21]],
1318 [[5]])[
1319
1320 A go to state 17
1321 B go to state 18
1322
1323
d42fe46e 1324State 12
f805dfcb
JD
1325
1326 0 $accept: S $end .
1327
1328 $default accept]AT_COND_CASE([[LALR]], [[
1329
1330
d42fe46e 1331State 13
f805dfcb
JD
1332
1333 8 A: 'd' 'e' . ['f', 'g']
1334 9 B: 'd' 'e' . [$end, 'g']
1335
1336 $end reduce using rule 9 (B)
1337 'g' reduce using rule 8 (A)
1338 'g' [reduce using rule 9 (B)]
1339 $default reduce using rule 8 (A)]], [[
1340
1341
d42fe46e 1342State 13
f805dfcb
JD
1343
1344 8 A: 'd' 'e' . ['f']
1345 9 B: 'd' 'e' . ]AT_COND_CASE([[canonical LR]], [[[$end]]], [[['g']]])[
1346
1347 ]AT_COND_CASE([[canonical LR]], [[$end]],
1348 [['g' ]])[ reduce using rule 9 (B)
1349 ]AT_COND_CASE([[canonical LR]], [['f' ]],
1350 [[$default]])[ reduce using rule 8 (A)]])[
1351
1352
d42fe46e 1353State 14
f805dfcb
JD
1354
1355 1 S: 'a' A 'f' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
1356
1357 ]AT_COND_CASE([[canonical LR]], [[$end]],
1358 [[$default]])[ reduce using rule 1 (S)
1359
1360
d42fe46e 1361State 15
f805dfcb
JD
1362
1363 3 S: 'b' A 'f' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
1364
1365 ]AT_COND_CASE([[canonical LR]], [[$end]],
1366 [[$default]])[ reduce using rule 3 (S)
1367
1368
d42fe46e 1369State 16
f805dfcb
JD
1370
1371 4 S: 'b' B 'g' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
1372
1373 ]AT_COND_CASE([[canonical LR]], [[$end]],
1374 [[$default]])[ reduce using rule 4 (S)
1375
1376
d42fe46e 1377State 17
f805dfcb
JD
1378
1379 6 S: 'c' 'c' A . 'g'
1380
1381 'g' shift, and go to state 19
1382
1383
d42fe46e 1384State 18
f805dfcb
JD
1385
1386 7 S: 'c' 'c' B .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
1387
1388 ]AT_COND_CASE([[canonical LR]], [[$end]],
1389 [[$default]])[ reduce using rule 7 (S)
1390
1391
d42fe46e 1392State 19
f805dfcb
JD
1393
1394 6 S: 'c' 'c' A 'g' .]AT_COND_CASE([[canonical LR]], [[ [$end]]])[
1395
1396 ]AT_COND_CASE([[canonical LR]], [[$end]],
1397 [[$default]])[ reduce using rule 6 (S)]AT_COND_CASE([[LALR]],
1398 [[]], [[
1399
1400
d42fe46e 1401State 20]AT_COND_CASE([[canonical LR]], [[
f805dfcb
JD
1402
1403 8 A: 'd' 'e' . ['f']
1404 9 B: 'd' 'e' . ['g']
1405
1406 'f' reduce using rule 8 (A)
1407 'g' reduce using rule 9 (B)
1408
1409
d42fe46e 1410State 21
f805dfcb
JD
1411
1412 8 A: 'd' . 'e'
1413 9 B: 'd' . 'e'
1414
1415 'e' shift, and go to state 22
1416
1417
d42fe46e 1418State 22
f805dfcb
JD
1419
1420 8 A: 'd' 'e' . ['g']
1421 9 B: 'd' 'e' . [$end]
1422
1423 $end reduce using rule 9 (B)
1424 'g' reduce using rule 8 (A)]], [[
1425
1426 8 A: 'd' 'e' . ['f', 'g']
1427 9 B: 'd' 'e' . [$end]
1428
1429 $end reduce using rule 9 (B)
1430 $default reduce using rule 8 (A)]])])[
1431]],
1432
1433dnl OTHER-CHECKS
1434[],
1435
1436dnl PARSER-EXIT-VALUE, PARSER-STDOUT, PARSER-STDERR
1437[AT_COND_CASE([[LALR]], [[1]], [[0]])],
1438[],
1439[AT_COND_CASE([[LALR]],
1440[[syntax error
1441]])])
1442
1443
1444
620b5727 1445## ------------------------------- ##
1d0f55cc 1446## %define lr.default-reductions. ##
620b5727 1447## ------------------------------- ##
03c07b03 1448
620b5727
JD
1449# AT_TEST_LR_DEFAULT_REDUCTIONS(GRAMMAR, INPUT, TABLES)
1450# -----------------------------------------------------
1451m4_define([AT_TEST_LR_DEFAULT_REDUCTIONS],
03c07b03 1452[
1d0f55cc 1453AT_TEST_TABLES_AND_PARSE([[no %define lr.default-reductions]],
a6e5a280 1454 [[most]], [[]],
03c07b03
JD
1455 [[]],
1456 [$1], [$2], [[]], [$3])
a6e5a280
JD
1457AT_TEST_TABLES_AND_PARSE([[%define lr.default-reductions most]],
1458 [[most]], [[]],
1459 [[%define lr.default-reductions most]],
03c07b03 1460 [$1], [$2], [[]], [$3])
f37495f6 1461AT_TEST_TABLES_AND_PARSE([[%define lr.default-reductions consistent]],
03c07b03 1462 [[consistent]], [[]],
f37495f6 1463 [[%define lr.default-reductions consistent]],
03c07b03 1464 [$1], [$2], [[]], [$3])
f37495f6 1465AT_TEST_TABLES_AND_PARSE([[%define lr.default-reductions accepting]],
03c07b03 1466 [[accepting]], [[]],
f37495f6 1467 [[%define lr.default-reductions accepting]],
03c07b03
JD
1468 [$1], [$2], [[]], [$3])
1469])
1470
620b5727 1471AT_TEST_LR_DEFAULT_REDUCTIONS([[
03c07b03
JD
1472/* The start state is consistent and has a shift on 'a' and no reductions.
1473 After pushing the b below, enter an inconsistent state that has a shift and
1474 one reduction with one lookahead. */
1475start:
1476 a b
1477 | a b 'a'
1478 | a c 'b'
1479 ;
1480
1481/* After shifting this 'a', enter a consistent state that has no shift and 1
1482 reduction with multiple lookaheads. */
1483a: 'a' ;
1484
1485/* After the previous reduction, enter an inconsistent state that has no shift
1486 and multiple reductions. The first reduction has more lookaheads than the
620b5727 1487 second, so the first should always be preferred as the default reduction if
03c07b03
JD
1488 enabled. The second reduction has one lookahead. */
1489b: ;
1490c: ;
1491]],
1492dnl Visit each state mentioned above.
1493[['a', 'a']],
d42fe46e 1494[[State 0
03c07b03
JD
1495
1496 0 $accept: . start $end
1497 1 start: . a b
1498 2 | . a b 'a'
1499 3 | . a c 'b'
1500 4 a: . 'a'
1501
1502 'a' shift, and go to state 1
1503
1504 start go to state 2
1505 a go to state 3
1506
1507
d42fe46e 1508State 1
03c07b03
JD
1509
1510 4 a: 'a' .]AT_COND_CASE([[accepting]], [[ [$end, 'a', 'b']
1511
1512 $end reduce using rule 4 (a)
1513 'a' reduce using rule 4 (a)
1514 'b' reduce using rule 4 (a)]], [[
1515
1516 $default reduce using rule 4 (a)]])[
1517
1518
d42fe46e 1519State 2
03c07b03
JD
1520
1521 0 $accept: start . $end
1522
1523 $end shift, and go to state 4
1524
1525
d42fe46e 1526State 3
03c07b03
JD
1527
1528 1 start: a . b
1529 2 | a . b 'a'
1530 3 | a . c 'b'
1531 5 b: . [$end, 'a']
a6e5a280 1532 6 c: . ['b']]AT_COND_CASE([[most]], [[
03c07b03
JD
1533
1534 'b' reduce using rule 6 (c)
1535 $default reduce using rule 5 (b)]], [[
1536
1537 $end reduce using rule 5 (b)
1538 'a' reduce using rule 5 (b)
1539 'b' reduce using rule 6 (c)]])[
1540
1541 b go to state 5
1542 c go to state 6
1543
1544
d42fe46e 1545State 4
03c07b03
JD
1546
1547 0 $accept: start $end .
1548
1549 $default accept
1550
1551
d42fe46e 1552State 5
03c07b03
JD
1553
1554 1 start: a b . [$end]
1555 2 | a b . 'a'
1556
1557 'a' shift, and go to state 7
1558
a6e5a280 1559 ]AT_COND_CASE([[most]], [[$default]],
d815ec4a 1560 [[$end]])[ reduce using rule 1 (start)
03c07b03
JD
1561
1562
d42fe46e 1563State 6
03c07b03
JD
1564
1565 3 start: a c . 'b'
1566
1567 'b' shift, and go to state 8
1568
1569
d42fe46e 1570State 7
03c07b03
JD
1571
1572 2 start: a b 'a' .]AT_COND_CASE([[accepting]], [[ [$end]
1573
1574 $end reduce using rule 2 (start)]], [[
1575
1576 $default reduce using rule 2 (start)]])[
1577
1578
d42fe46e 1579State 8
03c07b03
JD
1580
1581 3 start: a c 'b' .]AT_COND_CASE([[accepting]], [[ [$end]
1582
1583 $end reduce using rule 3 (start)]], [[
1584
1585 $default reduce using rule 3 (start)]])[
1586]])