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1/*
2 * regexp.c: generic and extensible Regular Expression engine
3 *
4 * Basically designed with the purpose of compiling regexps for
5 * the variety of validation/shemas mechanisms now available in
6 * XML related specifications these include:
7 * - XML-1.0 DTD validation
8 * - XML Schemas structure part 1
9 * - XML Schemas Datatypes part 2 especially Appendix F
10 * - RELAX-NG/TREX i.e. the counter proposal
11 *
12 * See Copyright for the status of this software.
13 *
14 * Daniel Veillard <[email protected]>
15 */
16
17#define IN_LIBXML
18#include "libxml.h"
19
20#ifdef LIBXML_REGEXP_ENABLED
21
22/* #define DEBUG_ERR */
23
24#include <stdio.h>
25#include <string.h>
26#ifdef HAVE_LIMITS_H
27#include <limits.h>
28#endif
29
30#include <libxml/tree.h>
31#include <libxml/parserInternals.h>
32#include <libxml/xmlregexp.h>
33#include <libxml/xmlautomata.h>
34#include <libxml/xmlunicode.h>
35
36#ifndef INT_MAX
37#define INT_MAX 123456789 /* easy to flag and big enough for our needs */
38#endif
39
40/* #define DEBUG_REGEXP_GRAPH */
41/* #define DEBUG_REGEXP_EXEC */
42/* #define DEBUG_PUSH */
43/* #define DEBUG_COMPACTION */
44
45#define MAX_PUSH 10000000
46
47#ifdef ERROR
48#undef ERROR
49#endif
50#define ERROR(str) \
51 ctxt->error = XML_REGEXP_COMPILE_ERROR; \
52 xmlRegexpErrCompile(ctxt, str);
53#define NEXT ctxt->cur++
54#define CUR (*(ctxt->cur))
55#define NXT(index) (ctxt->cur[index])
56
57#define CUR_SCHAR(s, l) xmlStringCurrentChar(NULL, s, &l)
58#define NEXTL(l) ctxt->cur += l;
59#define XML_REG_STRING_SEPARATOR '|'
60/*
61 * Need PREV to check on a '-' within a Character Group. May only be used
62 * when it's guaranteed that cur is not at the beginning of ctxt->string!
63 */
64#define PREV (ctxt->cur[-1])
65
66/**
67 * TODO:
68 *
69 * macro to flag unimplemented blocks
70 */
71#define TODO \
72 xmlGenericError(xmlGenericErrorContext, \
73 "Unimplemented block at %s:%d\n", \
74 __FILE__, __LINE__);
75
76/************************************************************************
77 * *
78 * Datatypes and structures *
79 * *
80 ************************************************************************/
81
82/*
83 * Note: the order of the enums below is significant, do not shuffle
84 */
85typedef enum {
86 XML_REGEXP_EPSILON = 1,
87 XML_REGEXP_CHARVAL,
88 XML_REGEXP_RANGES,
89 XML_REGEXP_SUBREG, /* used for () sub regexps */
90 XML_REGEXP_STRING,
91 XML_REGEXP_ANYCHAR, /* . */
92 XML_REGEXP_ANYSPACE, /* \s */
93 XML_REGEXP_NOTSPACE, /* \S */
94 XML_REGEXP_INITNAME, /* \l */
95 XML_REGEXP_NOTINITNAME, /* \L */
96 XML_REGEXP_NAMECHAR, /* \c */
97 XML_REGEXP_NOTNAMECHAR, /* \C */
98 XML_REGEXP_DECIMAL, /* \d */
99 XML_REGEXP_NOTDECIMAL, /* \D */
100 XML_REGEXP_REALCHAR, /* \w */
101 XML_REGEXP_NOTREALCHAR, /* \W */
102 XML_REGEXP_LETTER = 100,
103 XML_REGEXP_LETTER_UPPERCASE,
104 XML_REGEXP_LETTER_LOWERCASE,
105 XML_REGEXP_LETTER_TITLECASE,
106 XML_REGEXP_LETTER_MODIFIER,
107 XML_REGEXP_LETTER_OTHERS,
108 XML_REGEXP_MARK,
109 XML_REGEXP_MARK_NONSPACING,
110 XML_REGEXP_MARK_SPACECOMBINING,
111 XML_REGEXP_MARK_ENCLOSING,
112 XML_REGEXP_NUMBER,
113 XML_REGEXP_NUMBER_DECIMAL,
114 XML_REGEXP_NUMBER_LETTER,
115 XML_REGEXP_NUMBER_OTHERS,
116 XML_REGEXP_PUNCT,
117 XML_REGEXP_PUNCT_CONNECTOR,
118 XML_REGEXP_PUNCT_DASH,
119 XML_REGEXP_PUNCT_OPEN,
120 XML_REGEXP_PUNCT_CLOSE,
121 XML_REGEXP_PUNCT_INITQUOTE,
122 XML_REGEXP_PUNCT_FINQUOTE,
123 XML_REGEXP_PUNCT_OTHERS,
124 XML_REGEXP_SEPAR,
125 XML_REGEXP_SEPAR_SPACE,
126 XML_REGEXP_SEPAR_LINE,
127 XML_REGEXP_SEPAR_PARA,
128 XML_REGEXP_SYMBOL,
129 XML_REGEXP_SYMBOL_MATH,
130 XML_REGEXP_SYMBOL_CURRENCY,
131 XML_REGEXP_SYMBOL_MODIFIER,
132 XML_REGEXP_SYMBOL_OTHERS,
133 XML_REGEXP_OTHER,
134 XML_REGEXP_OTHER_CONTROL,
135 XML_REGEXP_OTHER_FORMAT,
136 XML_REGEXP_OTHER_PRIVATE,
137 XML_REGEXP_OTHER_NA,
138 XML_REGEXP_BLOCK_NAME
139} xmlRegAtomType;
140
141typedef enum {
142 XML_REGEXP_QUANT_EPSILON = 1,
143 XML_REGEXP_QUANT_ONCE,
144 XML_REGEXP_QUANT_OPT,
145 XML_REGEXP_QUANT_MULT,
146 XML_REGEXP_QUANT_PLUS,
147 XML_REGEXP_QUANT_ONCEONLY,
148 XML_REGEXP_QUANT_ALL,
149 XML_REGEXP_QUANT_RANGE
150} xmlRegQuantType;
151
152typedef enum {
153 XML_REGEXP_START_STATE = 1,
154 XML_REGEXP_FINAL_STATE,
155 XML_REGEXP_TRANS_STATE,
156 XML_REGEXP_SINK_STATE,
157 XML_REGEXP_UNREACH_STATE
158} xmlRegStateType;
159
160typedef enum {
161 XML_REGEXP_MARK_NORMAL = 0,
162 XML_REGEXP_MARK_START,
163 XML_REGEXP_MARK_VISITED
164} xmlRegMarkedType;
165
166typedef struct _xmlRegRange xmlRegRange;
167typedef xmlRegRange *xmlRegRangePtr;
168
169struct _xmlRegRange {
170 int neg; /* 0 normal, 1 not, 2 exclude */
171 xmlRegAtomType type;
172 int start;
173 int end;
174 xmlChar *blockName;
175};
176
177typedef struct _xmlRegAtom xmlRegAtom;
178typedef xmlRegAtom *xmlRegAtomPtr;
179
180typedef struct _xmlAutomataState xmlRegState;
181typedef xmlRegState *xmlRegStatePtr;
182
183struct _xmlRegAtom {
184 int no;
185 xmlRegAtomType type;
186 xmlRegQuantType quant;
187 int min;
188 int max;
189
190 void *valuep;
191 void *valuep2;
192 int neg;
193 int codepoint;
194 xmlRegStatePtr start;
195 xmlRegStatePtr start0;
196 xmlRegStatePtr stop;
197 int maxRanges;
198 int nbRanges;
199 xmlRegRangePtr *ranges;
200 void *data;
201};
202
203typedef struct _xmlRegCounter xmlRegCounter;
204typedef xmlRegCounter *xmlRegCounterPtr;
205
206struct _xmlRegCounter {
207 int min;
208 int max;
209};
210
211typedef struct _xmlRegTrans xmlRegTrans;
212typedef xmlRegTrans *xmlRegTransPtr;
213
214struct _xmlRegTrans {
215 xmlRegAtomPtr atom;
216 int to;
217 int counter;
218 int count;
219 int nd;
220};
221
222struct _xmlAutomataState {
223 xmlRegStateType type;
224 xmlRegMarkedType mark;
225 xmlRegMarkedType markd;
226 xmlRegMarkedType reached;
227 int no;
228 int maxTrans;
229 int nbTrans;
230 xmlRegTrans *trans;
231 /* knowing states ponting to us can speed things up */
232 int maxTransTo;
233 int nbTransTo;
234 int *transTo;
235};
236
237typedef struct _xmlAutomata xmlRegParserCtxt;
238typedef xmlRegParserCtxt *xmlRegParserCtxtPtr;
239
240#define AM_AUTOMATA_RNG 1
241
242struct _xmlAutomata {
243 xmlChar *string;
244 xmlChar *cur;
245
246 int error;
247 int neg;
248
249 xmlRegStatePtr start;
250 xmlRegStatePtr end;
251 xmlRegStatePtr state;
252
253 xmlRegAtomPtr atom;
254
255 int maxAtoms;
256 int nbAtoms;
257 xmlRegAtomPtr *atoms;
258
259 int maxStates;
260 int nbStates;
261 xmlRegStatePtr *states;
262
263 int maxCounters;
264 int nbCounters;
265 xmlRegCounter *counters;
266
267 int determinist;
268 int negs;
269 int flags;
270};
271
272struct _xmlRegexp {
273 xmlChar *string;
274 int nbStates;
275 xmlRegStatePtr *states;
276 int nbAtoms;
277 xmlRegAtomPtr *atoms;
278 int nbCounters;
279 xmlRegCounter *counters;
280 int determinist;
281 int flags;
282 /*
283 * That's the compact form for determinists automatas
284 */
285 int nbstates;
286 int *compact;
287 void **transdata;
288 int nbstrings;
289 xmlChar **stringMap;
290};
291
292typedef struct _xmlRegExecRollback xmlRegExecRollback;
293typedef xmlRegExecRollback *xmlRegExecRollbackPtr;
294
295struct _xmlRegExecRollback {
296 xmlRegStatePtr state;/* the current state */
297 int index; /* the index in the input stack */
298 int nextbranch; /* the next transition to explore in that state */
299 int *counts; /* save the automata state if it has some */
300};
301
302typedef struct _xmlRegInputToken xmlRegInputToken;
303typedef xmlRegInputToken *xmlRegInputTokenPtr;
304
305struct _xmlRegInputToken {
306 xmlChar *value;
307 void *data;
308};
309
310struct _xmlRegExecCtxt {
311 int status; /* execution status != 0 indicate an error */
312 int determinist; /* did we find an indeterministic behaviour */
313 xmlRegexpPtr comp; /* the compiled regexp */
314 xmlRegExecCallbacks callback;
315 void *data;
316
317 xmlRegStatePtr state;/* the current state */
318 int transno; /* the current transition on that state */
319 int transcount; /* the number of chars in char counted transitions */
320
321 /*
322 * A stack of rollback states
323 */
324 int maxRollbacks;
325 int nbRollbacks;
326 xmlRegExecRollback *rollbacks;
327
328 /*
329 * The state of the automata if any
330 */
331 int *counts;
332
333 /*
334 * The input stack
335 */
336 int inputStackMax;
337 int inputStackNr;
338 int index;
339 int *charStack;
340 const xmlChar *inputString; /* when operating on characters */
341 xmlRegInputTokenPtr inputStack;/* when operating on strings */
342
343 /*
344 * error handling
345 */
346 int errStateNo; /* the error state number */
347 xmlRegStatePtr errState; /* the error state */
348 xmlChar *errString; /* the string raising the error */
349 int *errCounts; /* counters at the error state */
350 int nbPush;
351};
352
353#define REGEXP_ALL_COUNTER 0x123456
354#define REGEXP_ALL_LAX_COUNTER 0x123457
355
356static void xmlFAParseRegExp(xmlRegParserCtxtPtr ctxt, int top);
357static void xmlRegFreeState(xmlRegStatePtr state);
358static void xmlRegFreeAtom(xmlRegAtomPtr atom);
359static int xmlRegStrEqualWildcard(const xmlChar *expStr, const xmlChar *valStr);
360static int xmlRegCheckCharacter(xmlRegAtomPtr atom, int codepoint);
361static int xmlRegCheckCharacterRange(xmlRegAtomType type, int codepoint,
362 int neg, int start, int end, const xmlChar *blockName);
363
364void xmlAutomataSetFlags(xmlAutomataPtr am, int flags);
365
366/************************************************************************
367 * *
368 * Regexp memory error handler *
369 * *
370 ************************************************************************/
371/**
372 * xmlRegexpErrMemory:
373 * @extra: extra information
374 *
375 * Handle an out of memory condition
376 */
377static void
378xmlRegexpErrMemory(xmlRegParserCtxtPtr ctxt, const char *extra)
379{
380 const char *regexp = NULL;
381 if (ctxt != NULL) {
382 regexp = (const char *) ctxt->string;
383 ctxt->error = XML_ERR_NO_MEMORY;
384 }
385 __xmlRaiseError(NULL, NULL, NULL, NULL, NULL, XML_FROM_REGEXP,
386 XML_ERR_NO_MEMORY, XML_ERR_FATAL, NULL, 0, extra,
387 regexp, NULL, 0, 0,
388 "Memory allocation failed : %s\n", extra);
389}
390
391/**
392 * xmlRegexpErrCompile:
393 * @extra: extra information
394 *
395 * Handle a compilation failure
396 */
397static void
398xmlRegexpErrCompile(xmlRegParserCtxtPtr ctxt, const char *extra)
399{
400 const char *regexp = NULL;
401 int idx = 0;
402
403 if (ctxt != NULL) {
404 regexp = (const char *) ctxt->string;
405 idx = ctxt->cur - ctxt->string;
406 ctxt->error = XML_REGEXP_COMPILE_ERROR;
407 }
408 __xmlRaiseError(NULL, NULL, NULL, NULL, NULL, XML_FROM_REGEXP,
409 XML_REGEXP_COMPILE_ERROR, XML_ERR_FATAL, NULL, 0, extra,
410 regexp, NULL, idx, 0,
411 "failed to compile: %s\n", extra);
412}
413
414/************************************************************************
415 * *
416 * Allocation/Deallocation *
417 * *
418 ************************************************************************/
419
420static int xmlFAComputesDeterminism(xmlRegParserCtxtPtr ctxt);
421/**
422 * xmlRegEpxFromParse:
423 * @ctxt: the parser context used to build it
424 *
425 * Allocate a new regexp and fill it with the result from the parser
426 *
427 * Returns the new regexp or NULL in case of error
428 */
429static xmlRegexpPtr
430xmlRegEpxFromParse(xmlRegParserCtxtPtr ctxt) {
431 xmlRegexpPtr ret;
432
433 ret = (xmlRegexpPtr) xmlMalloc(sizeof(xmlRegexp));
434 if (ret == NULL) {
435 xmlRegexpErrMemory(ctxt, "compiling regexp");
436 return(NULL);
437 }
438 memset(ret, 0, sizeof(xmlRegexp));
439 ret->string = ctxt->string;
440 ret->nbStates = ctxt->nbStates;
441 ret->states = ctxt->states;
442 ret->nbAtoms = ctxt->nbAtoms;
443 ret->atoms = ctxt->atoms;
444 ret->nbCounters = ctxt->nbCounters;
445 ret->counters = ctxt->counters;
446 ret->determinist = ctxt->determinist;
447 ret->flags = ctxt->flags;
448 if (ret->determinist == -1) {
449 xmlRegexpIsDeterminist(ret);
450 }
451
452 if ((ret->determinist != 0) &&
453 (ret->nbCounters == 0) &&
454 (ctxt->negs == 0) &&
455 (ret->atoms != NULL) &&
456 (ret->atoms[0] != NULL) &&
457 (ret->atoms[0]->type == XML_REGEXP_STRING)) {
458 int i, j, nbstates = 0, nbatoms = 0;
459 int *stateRemap;
460 int *stringRemap;
461 int *transitions;
462 void **transdata;
463 xmlChar **stringMap;
464 xmlChar *value;
465
466 /*
467 * Switch to a compact representation
468 * 1/ counting the effective number of states left
469 * 2/ counting the unique number of atoms, and check that
470 * they are all of the string type
471 * 3/ build a table state x atom for the transitions
472 */
473
474 stateRemap = xmlMalloc(ret->nbStates * sizeof(int));
475 if (stateRemap == NULL) {
476 xmlRegexpErrMemory(ctxt, "compiling regexp");
477 xmlFree(ret);
478 return(NULL);
479 }
480 for (i = 0;i < ret->nbStates;i++) {
481 if (ret->states[i] != NULL) {
482 stateRemap[i] = nbstates;
483 nbstates++;
484 } else {
485 stateRemap[i] = -1;
486 }
487 }
488#ifdef DEBUG_COMPACTION
489 printf("Final: %d states\n", nbstates);
490#endif
491 stringMap = xmlMalloc(ret->nbAtoms * sizeof(char *));
492 if (stringMap == NULL) {
493 xmlRegexpErrMemory(ctxt, "compiling regexp");
494 xmlFree(stateRemap);
495 xmlFree(ret);
496 return(NULL);
497 }
498 stringRemap = xmlMalloc(ret->nbAtoms * sizeof(int));
499 if (stringRemap == NULL) {
500 xmlRegexpErrMemory(ctxt, "compiling regexp");
501 xmlFree(stringMap);
502 xmlFree(stateRemap);
503 xmlFree(ret);
504 return(NULL);
505 }
506 for (i = 0;i < ret->nbAtoms;i++) {
507 if ((ret->atoms[i]->type == XML_REGEXP_STRING) &&
508 (ret->atoms[i]->quant == XML_REGEXP_QUANT_ONCE)) {
509 value = ret->atoms[i]->valuep;
510 for (j = 0;j < nbatoms;j++) {
511 if (xmlStrEqual(stringMap[j], value)) {
512 stringRemap[i] = j;
513 break;
514 }
515 }
516 if (j >= nbatoms) {
517 stringRemap[i] = nbatoms;
518 stringMap[nbatoms] = xmlStrdup(value);
519 if (stringMap[nbatoms] == NULL) {
520 for (i = 0;i < nbatoms;i++)
521 xmlFree(stringMap[i]);
522 xmlFree(stringRemap);
523 xmlFree(stringMap);
524 xmlFree(stateRemap);
525 xmlFree(ret);
526 return(NULL);
527 }
528 nbatoms++;
529 }
530 } else {
531 xmlFree(stateRemap);
532 xmlFree(stringRemap);
533 for (i = 0;i < nbatoms;i++)
534 xmlFree(stringMap[i]);
535 xmlFree(stringMap);
536 xmlFree(ret);
537 return(NULL);
538 }
539 }
540#ifdef DEBUG_COMPACTION
541 printf("Final: %d atoms\n", nbatoms);
542#endif
543 transitions = (int *) xmlMalloc((nbstates + 1) *
544 (nbatoms + 1) * sizeof(int));
545 if (transitions == NULL) {
546 xmlFree(stateRemap);
547 xmlFree(stringRemap);
548 xmlFree(stringMap);
549 xmlFree(ret);
550 return(NULL);
551 }
552 memset(transitions, 0, (nbstates + 1) * (nbatoms + 1) * sizeof(int));
553
554 /*
555 * Allocate the transition table. The first entry for each
556 * state corresponds to the state type.
557 */
558 transdata = NULL;
559
560 for (i = 0;i < ret->nbStates;i++) {
561 int stateno, atomno, targetno, prev;
562 xmlRegStatePtr state;
563 xmlRegTransPtr trans;
564
565 stateno = stateRemap[i];
566 if (stateno == -1)
567 continue;
568 state = ret->states[i];
569
570 transitions[stateno * (nbatoms + 1)] = state->type;
571
572 for (j = 0;j < state->nbTrans;j++) {
573 trans = &(state->trans[j]);
574 if ((trans->to == -1) || (trans->atom == NULL))
575 continue;
576 atomno = stringRemap[trans->atom->no];
577 if ((trans->atom->data != NULL) && (transdata == NULL)) {
578 transdata = (void **) xmlMalloc(nbstates * nbatoms *
579 sizeof(void *));
580 if (transdata != NULL)
581 memset(transdata, 0,
582 nbstates * nbatoms * sizeof(void *));
583 else {
584 xmlRegexpErrMemory(ctxt, "compiling regexp");
585 break;
586 }
587 }
588 targetno = stateRemap[trans->to];
589 /*
590 * if the same atom can generate transitions to 2 different
591 * states then it means the automata is not determinist and
592 * the compact form can't be used !
593 */
594 prev = transitions[stateno * (nbatoms + 1) + atomno + 1];
595 if (prev != 0) {
596 if (prev != targetno + 1) {
597 ret->determinist = 0;
598#ifdef DEBUG_COMPACTION
599 printf("Indet: state %d trans %d, atom %d to %d : %d to %d\n",
600 i, j, trans->atom->no, trans->to, atomno, targetno);
601 printf(" previous to is %d\n", prev);
602#endif
603 if (transdata != NULL)
604 xmlFree(transdata);
605 xmlFree(transitions);
606 xmlFree(stateRemap);
607 xmlFree(stringRemap);
608 for (i = 0;i < nbatoms;i++)
609 xmlFree(stringMap[i]);
610 xmlFree(stringMap);
611 goto not_determ;
612 }
613 } else {
614#if 0
615 printf("State %d trans %d: atom %d to %d : %d to %d\n",
616 i, j, trans->atom->no, trans->to, atomno, targetno);
617#endif
618 transitions[stateno * (nbatoms + 1) + atomno + 1] =
619 targetno + 1; /* to avoid 0 */
620 if (transdata != NULL)
621 transdata[stateno * nbatoms + atomno] =
622 trans->atom->data;
623 }
624 }
625 }
626 ret->determinist = 1;
627#ifdef DEBUG_COMPACTION
628 /*
629 * Debug
630 */
631 for (i = 0;i < nbstates;i++) {
632 for (j = 0;j < nbatoms + 1;j++) {
633 printf("%02d ", transitions[i * (nbatoms + 1) + j]);
634 }
635 printf("\n");
636 }
637 printf("\n");
638#endif
639 /*
640 * Cleanup of the old data
641 */
642 if (ret->states != NULL) {
643 for (i = 0;i < ret->nbStates;i++)
644 xmlRegFreeState(ret->states[i]);
645 xmlFree(ret->states);
646 }
647 ret->states = NULL;
648 ret->nbStates = 0;
649 if (ret->atoms != NULL) {
650 for (i = 0;i < ret->nbAtoms;i++)
651 xmlRegFreeAtom(ret->atoms[i]);
652 xmlFree(ret->atoms);
653 }
654 ret->atoms = NULL;
655 ret->nbAtoms = 0;
656
657 ret->compact = transitions;
658 ret->transdata = transdata;
659 ret->stringMap = stringMap;
660 ret->nbstrings = nbatoms;
661 ret->nbstates = nbstates;
662 xmlFree(stateRemap);
663 xmlFree(stringRemap);
664 }
665not_determ:
666 ctxt->string = NULL;
667 ctxt->nbStates = 0;
668 ctxt->states = NULL;
669 ctxt->nbAtoms = 0;
670 ctxt->atoms = NULL;
671 ctxt->nbCounters = 0;
672 ctxt->counters = NULL;
673 return(ret);
674}
675
676/**
677 * xmlRegNewParserCtxt:
678 * @string: the string to parse
679 *
680 * Allocate a new regexp parser context
681 *
682 * Returns the new context or NULL in case of error
683 */
684static xmlRegParserCtxtPtr
685xmlRegNewParserCtxt(const xmlChar *string) {
686 xmlRegParserCtxtPtr ret;
687
688 ret = (xmlRegParserCtxtPtr) xmlMalloc(sizeof(xmlRegParserCtxt));
689 if (ret == NULL)
690 return(NULL);
691 memset(ret, 0, sizeof(xmlRegParserCtxt));
692 if (string != NULL)
693 ret->string = xmlStrdup(string);
694 ret->cur = ret->string;
695 ret->neg = 0;
696 ret->negs = 0;
697 ret->error = 0;
698 ret->determinist = -1;
699 return(ret);
700}
701
702/**
703 * xmlRegNewRange:
704 * @ctxt: the regexp parser context
705 * @neg: is that negative
706 * @type: the type of range
707 * @start: the start codepoint
708 * @end: the end codepoint
709 *
710 * Allocate a new regexp range
711 *
712 * Returns the new range or NULL in case of error
713 */
714static xmlRegRangePtr
715xmlRegNewRange(xmlRegParserCtxtPtr ctxt,
716 int neg, xmlRegAtomType type, int start, int end) {
717 xmlRegRangePtr ret;
718
719 ret = (xmlRegRangePtr) xmlMalloc(sizeof(xmlRegRange));
720 if (ret == NULL) {
721 xmlRegexpErrMemory(ctxt, "allocating range");
722 return(NULL);
723 }
724 ret->neg = neg;
725 ret->type = type;
726 ret->start = start;
727 ret->end = end;
728 return(ret);
729}
730
731/**
732 * xmlRegFreeRange:
733 * @range: the regexp range
734 *
735 * Free a regexp range
736 */
737static void
738xmlRegFreeRange(xmlRegRangePtr range) {
739 if (range == NULL)
740 return;
741
742 if (range->blockName != NULL)
743 xmlFree(range->blockName);
744 xmlFree(range);
745}
746
747/**
748 * xmlRegCopyRange:
749 * @range: the regexp range
750 *
751 * Copy a regexp range
752 *
753 * Returns the new copy or NULL in case of error.
754 */
755static xmlRegRangePtr
756xmlRegCopyRange(xmlRegParserCtxtPtr ctxt, xmlRegRangePtr range) {
757 xmlRegRangePtr ret;
758
759 if (range == NULL)
760 return(NULL);
761
762 ret = xmlRegNewRange(ctxt, range->neg, range->type, range->start,
763 range->end);
764 if (ret == NULL)
765 return(NULL);
766 if (range->blockName != NULL) {
767 ret->blockName = xmlStrdup(range->blockName);
768 if (ret->blockName == NULL) {
769 xmlRegexpErrMemory(ctxt, "allocating range");
770 xmlRegFreeRange(ret);
771 return(NULL);
772 }
773 }
774 return(ret);
775}
776
777/**
778 * xmlRegNewAtom:
779 * @ctxt: the regexp parser context
780 * @type: the type of atom
781 *
782 * Allocate a new atom
783 *
784 * Returns the new atom or NULL in case of error
785 */
786static xmlRegAtomPtr
787xmlRegNewAtom(xmlRegParserCtxtPtr ctxt, xmlRegAtomType type) {
788 xmlRegAtomPtr ret;
789
790 ret = (xmlRegAtomPtr) xmlMalloc(sizeof(xmlRegAtom));
791 if (ret == NULL) {
792 xmlRegexpErrMemory(ctxt, "allocating atom");
793 return(NULL);
794 }
795 memset(ret, 0, sizeof(xmlRegAtom));
796 ret->type = type;
797 ret->quant = XML_REGEXP_QUANT_ONCE;
798 ret->min = 0;
799 ret->max = 0;
800 return(ret);
801}
802
803/**
804 * xmlRegFreeAtom:
805 * @atom: the regexp atom
806 *
807 * Free a regexp atom
808 */
809static void
810xmlRegFreeAtom(xmlRegAtomPtr atom) {
811 int i;
812
813 if (atom == NULL)
814 return;
815
816 for (i = 0;i < atom->nbRanges;i++)
817 xmlRegFreeRange(atom->ranges[i]);
818 if (atom->ranges != NULL)
819 xmlFree(atom->ranges);
820 if ((atom->type == XML_REGEXP_STRING) && (atom->valuep != NULL))
821 xmlFree(atom->valuep);
822 if ((atom->type == XML_REGEXP_STRING) && (atom->valuep2 != NULL))
823 xmlFree(atom->valuep2);
824 if ((atom->type == XML_REGEXP_BLOCK_NAME) && (atom->valuep != NULL))
825 xmlFree(atom->valuep);
826 xmlFree(atom);
827}
828
829/**
830 * xmlRegCopyAtom:
831 * @ctxt: the regexp parser context
832 * @atom: the oiginal atom
833 *
834 * Allocate a new regexp range
835 *
836 * Returns the new atom or NULL in case of error
837 */
838static xmlRegAtomPtr
839xmlRegCopyAtom(xmlRegParserCtxtPtr ctxt, xmlRegAtomPtr atom) {
840 xmlRegAtomPtr ret;
841
842 ret = (xmlRegAtomPtr) xmlMalloc(sizeof(xmlRegAtom));
843 if (ret == NULL) {
844 xmlRegexpErrMemory(ctxt, "copying atom");
845 return(NULL);
846 }
847 memset(ret, 0, sizeof(xmlRegAtom));
848 ret->type = atom->type;
849 ret->quant = atom->quant;
850 ret->min = atom->min;
851 ret->max = atom->max;
852 if (atom->nbRanges > 0) {
853 int i;
854
855 ret->ranges = (xmlRegRangePtr *) xmlMalloc(sizeof(xmlRegRangePtr) *
856 atom->nbRanges);
857 if (ret->ranges == NULL) {
858 xmlRegexpErrMemory(ctxt, "copying atom");
859 goto error;
860 }
861 for (i = 0;i < atom->nbRanges;i++) {
862 ret->ranges[i] = xmlRegCopyRange(ctxt, atom->ranges[i]);
863 if (ret->ranges[i] == NULL)
864 goto error;
865 ret->nbRanges = i + 1;
866 }
867 }
868 return(ret);
869
870error:
871 xmlRegFreeAtom(ret);
872 return(NULL);
873}
874
875static xmlRegStatePtr
876xmlRegNewState(xmlRegParserCtxtPtr ctxt) {
877 xmlRegStatePtr ret;
878
879 ret = (xmlRegStatePtr) xmlMalloc(sizeof(xmlRegState));
880 if (ret == NULL) {
881 xmlRegexpErrMemory(ctxt, "allocating state");
882 return(NULL);
883 }
884 memset(ret, 0, sizeof(xmlRegState));
885 ret->type = XML_REGEXP_TRANS_STATE;
886 ret->mark = XML_REGEXP_MARK_NORMAL;
887 return(ret);
888}
889
890/**
891 * xmlRegFreeState:
892 * @state: the regexp state
893 *
894 * Free a regexp state
895 */
896static void
897xmlRegFreeState(xmlRegStatePtr state) {
898 if (state == NULL)
899 return;
900
901 if (state->trans != NULL)
902 xmlFree(state->trans);
903 if (state->transTo != NULL)
904 xmlFree(state->transTo);
905 xmlFree(state);
906}
907
908/**
909 * xmlRegFreeParserCtxt:
910 * @ctxt: the regexp parser context
911 *
912 * Free a regexp parser context
913 */
914static void
915xmlRegFreeParserCtxt(xmlRegParserCtxtPtr ctxt) {
916 int i;
917 if (ctxt == NULL)
918 return;
919
920 if (ctxt->string != NULL)
921 xmlFree(ctxt->string);
922 if (ctxt->states != NULL) {
923 for (i = 0;i < ctxt->nbStates;i++)
924 xmlRegFreeState(ctxt->states[i]);
925 xmlFree(ctxt->states);
926 }
927 if (ctxt->atoms != NULL) {
928 for (i = 0;i < ctxt->nbAtoms;i++)
929 xmlRegFreeAtom(ctxt->atoms[i]);
930 xmlFree(ctxt->atoms);
931 }
932 if (ctxt->counters != NULL)
933 xmlFree(ctxt->counters);
934 xmlFree(ctxt);
935}
936
937/************************************************************************
938 * *
939 * Display of Data structures *
940 * *
941 ************************************************************************/
942
943static void
944xmlRegPrintAtomType(FILE *output, xmlRegAtomType type) {
945 switch (type) {
946 case XML_REGEXP_EPSILON:
947 fprintf(output, "epsilon "); break;
948 case XML_REGEXP_CHARVAL:
949 fprintf(output, "charval "); break;
950 case XML_REGEXP_RANGES:
951 fprintf(output, "ranges "); break;
952 case XML_REGEXP_SUBREG:
953 fprintf(output, "subexpr "); break;
954 case XML_REGEXP_STRING:
955 fprintf(output, "string "); break;
956 case XML_REGEXP_ANYCHAR:
957 fprintf(output, "anychar "); break;
958 case XML_REGEXP_ANYSPACE:
959 fprintf(output, "anyspace "); break;
960 case XML_REGEXP_NOTSPACE:
961 fprintf(output, "notspace "); break;
962 case XML_REGEXP_INITNAME:
963 fprintf(output, "initname "); break;
964 case XML_REGEXP_NOTINITNAME:
965 fprintf(output, "notinitname "); break;
966 case XML_REGEXP_NAMECHAR:
967 fprintf(output, "namechar "); break;
968 case XML_REGEXP_NOTNAMECHAR:
969 fprintf(output, "notnamechar "); break;
970 case XML_REGEXP_DECIMAL:
971 fprintf(output, "decimal "); break;
972 case XML_REGEXP_NOTDECIMAL:
973 fprintf(output, "notdecimal "); break;
974 case XML_REGEXP_REALCHAR:
975 fprintf(output, "realchar "); break;
976 case XML_REGEXP_NOTREALCHAR:
977 fprintf(output, "notrealchar "); break;
978 case XML_REGEXP_LETTER:
979 fprintf(output, "LETTER "); break;
980 case XML_REGEXP_LETTER_UPPERCASE:
981 fprintf(output, "LETTER_UPPERCASE "); break;
982 case XML_REGEXP_LETTER_LOWERCASE:
983 fprintf(output, "LETTER_LOWERCASE "); break;
984 case XML_REGEXP_LETTER_TITLECASE:
985 fprintf(output, "LETTER_TITLECASE "); break;
986 case XML_REGEXP_LETTER_MODIFIER:
987 fprintf(output, "LETTER_MODIFIER "); break;
988 case XML_REGEXP_LETTER_OTHERS:
989 fprintf(output, "LETTER_OTHERS "); break;
990 case XML_REGEXP_MARK:
991 fprintf(output, "MARK "); break;
992 case XML_REGEXP_MARK_NONSPACING:
993 fprintf(output, "MARK_NONSPACING "); break;
994 case XML_REGEXP_MARK_SPACECOMBINING:
995 fprintf(output, "MARK_SPACECOMBINING "); break;
996 case XML_REGEXP_MARK_ENCLOSING:
997 fprintf(output, "MARK_ENCLOSING "); break;
998 case XML_REGEXP_NUMBER:
999 fprintf(output, "NUMBER "); break;
1000 case XML_REGEXP_NUMBER_DECIMAL:
1001 fprintf(output, "NUMBER_DECIMAL "); break;
1002 case XML_REGEXP_NUMBER_LETTER:
1003 fprintf(output, "NUMBER_LETTER "); break;
1004 case XML_REGEXP_NUMBER_OTHERS:
1005 fprintf(output, "NUMBER_OTHERS "); break;
1006 case XML_REGEXP_PUNCT:
1007 fprintf(output, "PUNCT "); break;
1008 case XML_REGEXP_PUNCT_CONNECTOR:
1009 fprintf(output, "PUNCT_CONNECTOR "); break;
1010 case XML_REGEXP_PUNCT_DASH:
1011 fprintf(output, "PUNCT_DASH "); break;
1012 case XML_REGEXP_PUNCT_OPEN:
1013 fprintf(output, "PUNCT_OPEN "); break;
1014 case XML_REGEXP_PUNCT_CLOSE:
1015 fprintf(output, "PUNCT_CLOSE "); break;
1016 case XML_REGEXP_PUNCT_INITQUOTE:
1017 fprintf(output, "PUNCT_INITQUOTE "); break;
1018 case XML_REGEXP_PUNCT_FINQUOTE:
1019 fprintf(output, "PUNCT_FINQUOTE "); break;
1020 case XML_REGEXP_PUNCT_OTHERS:
1021 fprintf(output, "PUNCT_OTHERS "); break;
1022 case XML_REGEXP_SEPAR:
1023 fprintf(output, "SEPAR "); break;
1024 case XML_REGEXP_SEPAR_SPACE:
1025 fprintf(output, "SEPAR_SPACE "); break;
1026 case XML_REGEXP_SEPAR_LINE:
1027 fprintf(output, "SEPAR_LINE "); break;
1028 case XML_REGEXP_SEPAR_PARA:
1029 fprintf(output, "SEPAR_PARA "); break;
1030 case XML_REGEXP_SYMBOL:
1031 fprintf(output, "SYMBOL "); break;
1032 case XML_REGEXP_SYMBOL_MATH:
1033 fprintf(output, "SYMBOL_MATH "); break;
1034 case XML_REGEXP_SYMBOL_CURRENCY:
1035 fprintf(output, "SYMBOL_CURRENCY "); break;
1036 case XML_REGEXP_SYMBOL_MODIFIER:
1037 fprintf(output, "SYMBOL_MODIFIER "); break;
1038 case XML_REGEXP_SYMBOL_OTHERS:
1039 fprintf(output, "SYMBOL_OTHERS "); break;
1040 case XML_REGEXP_OTHER:
1041 fprintf(output, "OTHER "); break;
1042 case XML_REGEXP_OTHER_CONTROL:
1043 fprintf(output, "OTHER_CONTROL "); break;
1044 case XML_REGEXP_OTHER_FORMAT:
1045 fprintf(output, "OTHER_FORMAT "); break;
1046 case XML_REGEXP_OTHER_PRIVATE:
1047 fprintf(output, "OTHER_PRIVATE "); break;
1048 case XML_REGEXP_OTHER_NA:
1049 fprintf(output, "OTHER_NA "); break;
1050 case XML_REGEXP_BLOCK_NAME:
1051 fprintf(output, "BLOCK "); break;
1052 }
1053}
1054
1055static void
1056xmlRegPrintQuantType(FILE *output, xmlRegQuantType type) {
1057 switch (type) {
1058 case XML_REGEXP_QUANT_EPSILON:
1059 fprintf(output, "epsilon "); break;
1060 case XML_REGEXP_QUANT_ONCE:
1061 fprintf(output, "once "); break;
1062 case XML_REGEXP_QUANT_OPT:
1063 fprintf(output, "? "); break;
1064 case XML_REGEXP_QUANT_MULT:
1065 fprintf(output, "* "); break;
1066 case XML_REGEXP_QUANT_PLUS:
1067 fprintf(output, "+ "); break;
1068 case XML_REGEXP_QUANT_RANGE:
1069 fprintf(output, "range "); break;
1070 case XML_REGEXP_QUANT_ONCEONLY:
1071 fprintf(output, "onceonly "); break;
1072 case XML_REGEXP_QUANT_ALL:
1073 fprintf(output, "all "); break;
1074 }
1075}
1076static void
1077xmlRegPrintRange(FILE *output, xmlRegRangePtr range) {
1078 fprintf(output, " range: ");
1079 if (range->neg)
1080 fprintf(output, "negative ");
1081 xmlRegPrintAtomType(output, range->type);
1082 fprintf(output, "%c - %c\n", range->start, range->end);
1083}
1084
1085static void
1086xmlRegPrintAtom(FILE *output, xmlRegAtomPtr atom) {
1087 fprintf(output, " atom: ");
1088 if (atom == NULL) {
1089 fprintf(output, "NULL\n");
1090 return;
1091 }
1092 if (atom->neg)
1093 fprintf(output, "not ");
1094 xmlRegPrintAtomType(output, atom->type);
1095 xmlRegPrintQuantType(output, atom->quant);
1096 if (atom->quant == XML_REGEXP_QUANT_RANGE)
1097 fprintf(output, "%d-%d ", atom->min, atom->max);
1098 if (atom->type == XML_REGEXP_STRING)
1099 fprintf(output, "'%s' ", (char *) atom->valuep);
1100 if (atom->type == XML_REGEXP_CHARVAL)
1101 fprintf(output, "char %c\n", atom->codepoint);
1102 else if (atom->type == XML_REGEXP_RANGES) {
1103 int i;
1104 fprintf(output, "%d entries\n", atom->nbRanges);
1105 for (i = 0; i < atom->nbRanges;i++)
1106 xmlRegPrintRange(output, atom->ranges[i]);
1107 } else if (atom->type == XML_REGEXP_SUBREG) {
1108 fprintf(output, "start %d end %d\n", atom->start->no, atom->stop->no);
1109 } else {
1110 fprintf(output, "\n");
1111 }
1112}
1113
1114static void
1115xmlRegPrintTrans(FILE *output, xmlRegTransPtr trans) {
1116 fprintf(output, " trans: ");
1117 if (trans == NULL) {
1118 fprintf(output, "NULL\n");
1119 return;
1120 }
1121 if (trans->to < 0) {
1122 fprintf(output, "removed\n");
1123 return;
1124 }
1125 if (trans->nd != 0) {
1126 if (trans->nd == 2)
1127 fprintf(output, "last not determinist, ");
1128 else
1129 fprintf(output, "not determinist, ");
1130 }
1131 if (trans->counter >= 0) {
1132 fprintf(output, "counted %d, ", trans->counter);
1133 }
1134 if (trans->count == REGEXP_ALL_COUNTER) {
1135 fprintf(output, "all transition, ");
1136 } else if (trans->count >= 0) {
1137 fprintf(output, "count based %d, ", trans->count);
1138 }
1139 if (trans->atom == NULL) {
1140 fprintf(output, "epsilon to %d\n", trans->to);
1141 return;
1142 }
1143 if (trans->atom->type == XML_REGEXP_CHARVAL)
1144 fprintf(output, "char %c ", trans->atom->codepoint);
1145 fprintf(output, "atom %d, to %d\n", trans->atom->no, trans->to);
1146}
1147
1148static void
1149xmlRegPrintState(FILE *output, xmlRegStatePtr state) {
1150 int i;
1151
1152 fprintf(output, " state: ");
1153 if (state == NULL) {
1154 fprintf(output, "NULL\n");
1155 return;
1156 }
1157 if (state->type == XML_REGEXP_START_STATE)
1158 fprintf(output, "START ");
1159 if (state->type == XML_REGEXP_FINAL_STATE)
1160 fprintf(output, "FINAL ");
1161
1162 fprintf(output, "%d, %d transitions:\n", state->no, state->nbTrans);
1163 for (i = 0;i < state->nbTrans; i++) {
1164 xmlRegPrintTrans(output, &(state->trans[i]));
1165 }
1166}
1167
1168#ifdef DEBUG_REGEXP_GRAPH
1169static void
1170xmlRegPrintCtxt(FILE *output, xmlRegParserCtxtPtr ctxt) {
1171 int i;
1172
1173 fprintf(output, " ctxt: ");
1174 if (ctxt == NULL) {
1175 fprintf(output, "NULL\n");
1176 return;
1177 }
1178 fprintf(output, "'%s' ", ctxt->string);
1179 if (ctxt->error)
1180 fprintf(output, "error ");
1181 if (ctxt->neg)
1182 fprintf(output, "neg ");
1183 fprintf(output, "\n");
1184 fprintf(output, "%d atoms:\n", ctxt->nbAtoms);
1185 for (i = 0;i < ctxt->nbAtoms; i++) {
1186 fprintf(output, " %02d ", i);
1187 xmlRegPrintAtom(output, ctxt->atoms[i]);
1188 }
1189 if (ctxt->atom != NULL) {
1190 fprintf(output, "current atom:\n");
1191 xmlRegPrintAtom(output, ctxt->atom);
1192 }
1193 fprintf(output, "%d states:", ctxt->nbStates);
1194 if (ctxt->start != NULL)
1195 fprintf(output, " start: %d", ctxt->start->no);
1196 if (ctxt->end != NULL)
1197 fprintf(output, " end: %d", ctxt->end->no);
1198 fprintf(output, "\n");
1199 for (i = 0;i < ctxt->nbStates; i++) {
1200 xmlRegPrintState(output, ctxt->states[i]);
1201 }
1202 fprintf(output, "%d counters:\n", ctxt->nbCounters);
1203 for (i = 0;i < ctxt->nbCounters; i++) {
1204 fprintf(output, " %d: min %d max %d\n", i, ctxt->counters[i].min,
1205 ctxt->counters[i].max);
1206 }
1207}
1208#endif
1209
1210/************************************************************************
1211 * *
1212 * Finite Automata structures manipulations *
1213 * *
1214 ************************************************************************/
1215
1216static void
1217xmlRegAtomAddRange(xmlRegParserCtxtPtr ctxt, xmlRegAtomPtr atom,
1218 int neg, xmlRegAtomType type, int start, int end,
1219 xmlChar *blockName) {
1220 xmlRegRangePtr range;
1221
1222 if (atom == NULL) {
1223 ERROR("add range: atom is NULL");
1224 return;
1225 }
1226 if (atom->type != XML_REGEXP_RANGES) {
1227 ERROR("add range: atom is not ranges");
1228 return;
1229 }
1230 if (atom->maxRanges == 0) {
1231 atom->maxRanges = 4;
1232 atom->ranges = (xmlRegRangePtr *) xmlMalloc(atom->maxRanges *
1233 sizeof(xmlRegRangePtr));
1234 if (atom->ranges == NULL) {
1235 xmlRegexpErrMemory(ctxt, "adding ranges");
1236 atom->maxRanges = 0;
1237 return;
1238 }
1239 } else if (atom->nbRanges >= atom->maxRanges) {
1240 xmlRegRangePtr *tmp;
1241 atom->maxRanges *= 2;
1242 tmp = (xmlRegRangePtr *) xmlRealloc(atom->ranges, atom->maxRanges *
1243 sizeof(xmlRegRangePtr));
1244 if (tmp == NULL) {
1245 xmlRegexpErrMemory(ctxt, "adding ranges");
1246 atom->maxRanges /= 2;
1247 return;
1248 }
1249 atom->ranges = tmp;
1250 }
1251 range = xmlRegNewRange(ctxt, neg, type, start, end);
1252 if (range == NULL)
1253 return;
1254 range->blockName = blockName;
1255 atom->ranges[atom->nbRanges++] = range;
1256
1257}
1258
1259static int
1260xmlRegGetCounter(xmlRegParserCtxtPtr ctxt) {
1261 if (ctxt->maxCounters == 0) {
1262 ctxt->maxCounters = 4;
1263 ctxt->counters = (xmlRegCounter *) xmlMalloc(ctxt->maxCounters *
1264 sizeof(xmlRegCounter));
1265 if (ctxt->counters == NULL) {
1266 xmlRegexpErrMemory(ctxt, "allocating counter");
1267 ctxt->maxCounters = 0;
1268 return(-1);
1269 }
1270 } else if (ctxt->nbCounters >= ctxt->maxCounters) {
1271 xmlRegCounter *tmp;
1272 ctxt->maxCounters *= 2;
1273 tmp = (xmlRegCounter *) xmlRealloc(ctxt->counters, ctxt->maxCounters *
1274 sizeof(xmlRegCounter));
1275 if (tmp == NULL) {
1276 xmlRegexpErrMemory(ctxt, "allocating counter");
1277 ctxt->maxCounters /= 2;
1278 return(-1);
1279 }
1280 ctxt->counters = tmp;
1281 }
1282 ctxt->counters[ctxt->nbCounters].min = -1;
1283 ctxt->counters[ctxt->nbCounters].max = -1;
1284 return(ctxt->nbCounters++);
1285}
1286
1287static int
1288xmlRegAtomPush(xmlRegParserCtxtPtr ctxt, xmlRegAtomPtr atom) {
1289 if (atom == NULL) {
1290 ERROR("atom push: atom is NULL");
1291 return(-1);
1292 }
1293 if (ctxt->maxAtoms == 0) {
1294 ctxt->maxAtoms = 4;
1295 ctxt->atoms = (xmlRegAtomPtr *) xmlMalloc(ctxt->maxAtoms *
1296 sizeof(xmlRegAtomPtr));
1297 if (ctxt->atoms == NULL) {
1298 xmlRegexpErrMemory(ctxt, "pushing atom");
1299 ctxt->maxAtoms = 0;
1300 return(-1);
1301 }
1302 } else if (ctxt->nbAtoms >= ctxt->maxAtoms) {
1303 xmlRegAtomPtr *tmp;
1304 ctxt->maxAtoms *= 2;
1305 tmp = (xmlRegAtomPtr *) xmlRealloc(ctxt->atoms, ctxt->maxAtoms *
1306 sizeof(xmlRegAtomPtr));
1307 if (tmp == NULL) {
1308 xmlRegexpErrMemory(ctxt, "allocating counter");
1309 ctxt->maxAtoms /= 2;
1310 return(-1);
1311 }
1312 ctxt->atoms = tmp;
1313 }
1314 atom->no = ctxt->nbAtoms;
1315 ctxt->atoms[ctxt->nbAtoms++] = atom;
1316 return(0);
1317}
1318
1319static void
1320xmlRegStateAddTransTo(xmlRegParserCtxtPtr ctxt, xmlRegStatePtr target,
1321 int from) {
1322 if (target->maxTransTo == 0) {
1323 target->maxTransTo = 8;
1324 target->transTo = (int *) xmlMalloc(target->maxTransTo *
1325 sizeof(int));
1326 if (target->transTo == NULL) {
1327 xmlRegexpErrMemory(ctxt, "adding transition");
1328 target->maxTransTo = 0;
1329 return;
1330 }
1331 } else if (target->nbTransTo >= target->maxTransTo) {
1332 int *tmp;
1333 target->maxTransTo *= 2;
1334 tmp = (int *) xmlRealloc(target->transTo, target->maxTransTo *
1335 sizeof(int));
1336 if (tmp == NULL) {
1337 xmlRegexpErrMemory(ctxt, "adding transition");
1338 target->maxTransTo /= 2;
1339 return;
1340 }
1341 target->transTo = tmp;
1342 }
1343 target->transTo[target->nbTransTo] = from;
1344 target->nbTransTo++;
1345}
1346
1347static void
1348xmlRegStateAddTrans(xmlRegParserCtxtPtr ctxt, xmlRegStatePtr state,
1349 xmlRegAtomPtr atom, xmlRegStatePtr target,
1350 int counter, int count) {
1351
1352 int nrtrans;
1353
1354 if (state == NULL) {
1355 ERROR("add state: state is NULL");
1356 return;
1357 }
1358 if (target == NULL) {
1359 ERROR("add state: target is NULL");
1360 return;
1361 }
1362 /*
1363 * Other routines follow the philosophy 'When in doubt, add a transition'
1364 * so we check here whether such a transition is already present and, if
1365 * so, silently ignore this request.
1366 */
1367
1368 for (nrtrans = state->nbTrans - 1; nrtrans >= 0; nrtrans--) {
1369 xmlRegTransPtr trans = &(state->trans[nrtrans]);
1370 if ((trans->atom == atom) &&
1371 (trans->to == target->no) &&
1372 (trans->counter == counter) &&
1373 (trans->count == count)) {
1374#ifdef DEBUG_REGEXP_GRAPH
1375 printf("Ignoring duplicate transition from %d to %d\n",
1376 state->no, target->no);
1377#endif
1378 return;
1379 }
1380 }
1381
1382 if (state->maxTrans == 0) {
1383 state->maxTrans = 8;
1384 state->trans = (xmlRegTrans *) xmlMalloc(state->maxTrans *
1385 sizeof(xmlRegTrans));
1386 if (state->trans == NULL) {
1387 xmlRegexpErrMemory(ctxt, "adding transition");
1388 state->maxTrans = 0;
1389 return;
1390 }
1391 } else if (state->nbTrans >= state->maxTrans) {
1392 xmlRegTrans *tmp;
1393 state->maxTrans *= 2;
1394 tmp = (xmlRegTrans *) xmlRealloc(state->trans, state->maxTrans *
1395 sizeof(xmlRegTrans));
1396 if (tmp == NULL) {
1397 xmlRegexpErrMemory(ctxt, "adding transition");
1398 state->maxTrans /= 2;
1399 return;
1400 }
1401 state->trans = tmp;
1402 }
1403#ifdef DEBUG_REGEXP_GRAPH
1404 printf("Add trans from %d to %d ", state->no, target->no);
1405 if (count == REGEXP_ALL_COUNTER)
1406 printf("all transition\n");
1407 else if (count >= 0)
1408 printf("count based %d\n", count);
1409 else if (counter >= 0)
1410 printf("counted %d\n", counter);
1411 else if (atom == NULL)
1412 printf("epsilon transition\n");
1413 else if (atom != NULL)
1414 xmlRegPrintAtom(stdout, atom);
1415#endif
1416
1417 state->trans[state->nbTrans].atom = atom;
1418 state->trans[state->nbTrans].to = target->no;
1419 state->trans[state->nbTrans].counter = counter;
1420 state->trans[state->nbTrans].count = count;
1421 state->trans[state->nbTrans].nd = 0;
1422 state->nbTrans++;
1423 xmlRegStateAddTransTo(ctxt, target, state->no);
1424}
1425
1426static int
1427xmlRegStatePush(xmlRegParserCtxtPtr ctxt, xmlRegStatePtr state) {
1428 if (state == NULL) return(-1);
1429 if (ctxt->maxStates == 0) {
1430 ctxt->maxStates = 4;
1431 ctxt->states = (xmlRegStatePtr *) xmlMalloc(ctxt->maxStates *
1432 sizeof(xmlRegStatePtr));
1433 if (ctxt->states == NULL) {
1434 xmlRegexpErrMemory(ctxt, "adding state");
1435 ctxt->maxStates = 0;
1436 return(-1);
1437 }
1438 } else if (ctxt->nbStates >= ctxt->maxStates) {
1439 xmlRegStatePtr *tmp;
1440 ctxt->maxStates *= 2;
1441 tmp = (xmlRegStatePtr *) xmlRealloc(ctxt->states, ctxt->maxStates *
1442 sizeof(xmlRegStatePtr));
1443 if (tmp == NULL) {
1444 xmlRegexpErrMemory(ctxt, "adding state");
1445 ctxt->maxStates /= 2;
1446 return(-1);
1447 }
1448 ctxt->states = tmp;
1449 }
1450 state->no = ctxt->nbStates;
1451 ctxt->states[ctxt->nbStates++] = state;
1452 return(0);
1453}
1454
1455/**
1456 * xmlFAGenerateAllTransition:
1457 * @ctxt: a regexp parser context
1458 * @from: the from state
1459 * @to: the target state or NULL for building a new one
1460 * @lax:
1461 *
1462 */
1463static void
1464xmlFAGenerateAllTransition(xmlRegParserCtxtPtr ctxt,
1465 xmlRegStatePtr from, xmlRegStatePtr to,
1466 int lax) {
1467 if (to == NULL) {
1468 to = xmlRegNewState(ctxt);
1469 xmlRegStatePush(ctxt, to);
1470 ctxt->state = to;
1471 }
1472 if (lax)
1473 xmlRegStateAddTrans(ctxt, from, NULL, to, -1, REGEXP_ALL_LAX_COUNTER);
1474 else
1475 xmlRegStateAddTrans(ctxt, from, NULL, to, -1, REGEXP_ALL_COUNTER);
1476}
1477
1478/**
1479 * xmlFAGenerateEpsilonTransition:
1480 * @ctxt: a regexp parser context
1481 * @from: the from state
1482 * @to: the target state or NULL for building a new one
1483 *
1484 */
1485static void
1486xmlFAGenerateEpsilonTransition(xmlRegParserCtxtPtr ctxt,
1487 xmlRegStatePtr from, xmlRegStatePtr to) {
1488 if (to == NULL) {
1489 to = xmlRegNewState(ctxt);
1490 xmlRegStatePush(ctxt, to);
1491 ctxt->state = to;
1492 }
1493 xmlRegStateAddTrans(ctxt, from, NULL, to, -1, -1);
1494}
1495
1496/**
1497 * xmlFAGenerateCountedEpsilonTransition:
1498 * @ctxt: a regexp parser context
1499 * @from: the from state
1500 * @to: the target state or NULL for building a new one
1501 * counter: the counter for that transition
1502 *
1503 */
1504static void
1505xmlFAGenerateCountedEpsilonTransition(xmlRegParserCtxtPtr ctxt,
1506 xmlRegStatePtr from, xmlRegStatePtr to, int counter) {
1507 if (to == NULL) {
1508 to = xmlRegNewState(ctxt);
1509 xmlRegStatePush(ctxt, to);
1510 ctxt->state = to;
1511 }
1512 xmlRegStateAddTrans(ctxt, from, NULL, to, counter, -1);
1513}
1514
1515/**
1516 * xmlFAGenerateCountedTransition:
1517 * @ctxt: a regexp parser context
1518 * @from: the from state
1519 * @to: the target state or NULL for building a new one
1520 * counter: the counter for that transition
1521 *
1522 */
1523static void
1524xmlFAGenerateCountedTransition(xmlRegParserCtxtPtr ctxt,
1525 xmlRegStatePtr from, xmlRegStatePtr to, int counter) {
1526 if (to == NULL) {
1527 to = xmlRegNewState(ctxt);
1528 xmlRegStatePush(ctxt, to);
1529 ctxt->state = to;
1530 }
1531 xmlRegStateAddTrans(ctxt, from, NULL, to, -1, counter);
1532}
1533
1534/**
1535 * xmlFAGenerateTransitions:
1536 * @ctxt: a regexp parser context
1537 * @from: the from state
1538 * @to: the target state or NULL for building a new one
1539 * @atom: the atom generating the transition
1540 *
1541 * Returns 0 if success and -1 in case of error.
1542 */
1543static int
1544xmlFAGenerateTransitions(xmlRegParserCtxtPtr ctxt, xmlRegStatePtr from,
1545 xmlRegStatePtr to, xmlRegAtomPtr atom) {
1546 xmlRegStatePtr end;
1547
1548 if (atom == NULL) {
1549 ERROR("genrate transition: atom == NULL");
1550 return(-1);
1551 }
1552 if (atom->type == XML_REGEXP_SUBREG) {
1553 /*
1554 * this is a subexpression handling one should not need to
1555 * create a new node except for XML_REGEXP_QUANT_RANGE.
1556 */
1557 if (xmlRegAtomPush(ctxt, atom) < 0) {
1558 return(-1);
1559 }
1560 if ((to != NULL) && (atom->stop != to) &&
1561 (atom->quant != XML_REGEXP_QUANT_RANGE)) {
1562 /*
1563 * Generate an epsilon transition to link to the target
1564 */
1565 xmlFAGenerateEpsilonTransition(ctxt, atom->stop, to);
1566#ifdef DV
1567 } else if ((to == NULL) && (atom->quant != XML_REGEXP_QUANT_RANGE) &&
1568 (atom->quant != XML_REGEXP_QUANT_ONCE)) {
1569 to = xmlRegNewState(ctxt);
1570 xmlRegStatePush(ctxt, to);
1571 ctxt->state = to;
1572 xmlFAGenerateEpsilonTransition(ctxt, atom->stop, to);
1573#endif
1574 }
1575 switch (atom->quant) {
1576 case XML_REGEXP_QUANT_OPT:
1577 atom->quant = XML_REGEXP_QUANT_ONCE;
1578 /*
1579 * transition done to the state after end of atom.
1580 * 1. set transition from atom start to new state
1581 * 2. set transition from atom end to this state.
1582 */
1583 if (to == NULL) {
1584 xmlFAGenerateEpsilonTransition(ctxt, atom->start, 0);
1585 xmlFAGenerateEpsilonTransition(ctxt, atom->stop,
1586 ctxt->state);
1587 } else {
1588 xmlFAGenerateEpsilonTransition(ctxt, atom->start, to);
1589 }
1590 break;
1591 case XML_REGEXP_QUANT_MULT:
1592 atom->quant = XML_REGEXP_QUANT_ONCE;
1593 xmlFAGenerateEpsilonTransition(ctxt, atom->start, atom->stop);
1594 xmlFAGenerateEpsilonTransition(ctxt, atom->stop, atom->start);
1595 break;
1596 case XML_REGEXP_QUANT_PLUS:
1597 atom->quant = XML_REGEXP_QUANT_ONCE;
1598 xmlFAGenerateEpsilonTransition(ctxt, atom->stop, atom->start);
1599 break;
1600 case XML_REGEXP_QUANT_RANGE: {
1601 int counter;
1602 xmlRegStatePtr inter, newstate;
1603
1604 /*
1605 * create the final state now if needed
1606 */
1607 if (to != NULL) {
1608 newstate = to;
1609 } else {
1610 newstate = xmlRegNewState(ctxt);
1611 xmlRegStatePush(ctxt, newstate);
1612 }
1613
1614 /*
1615 * The principle here is to use counted transition
1616 * to avoid explosion in the number of states in the
1617 * graph. This is clearly more complex but should not
1618 * be exploitable at runtime.
1619 */
1620 if ((atom->min == 0) && (atom->start0 == NULL)) {
1621 xmlRegAtomPtr copy;
1622 /*
1623 * duplicate a transition based on atom to count next
1624 * occurences after 1. We cannot loop to atom->start
1625 * directly because we need an epsilon transition to
1626 * newstate.
1627 */
1628 /* ???? For some reason it seems we never reach that
1629 case, I suppose this got optimized out before when
1630 building the automata */
1631 copy = xmlRegCopyAtom(ctxt, atom);
1632 if (copy == NULL)
1633 return(-1);
1634 copy->quant = XML_REGEXP_QUANT_ONCE;
1635 copy->min = 0;
1636 copy->max = 0;
1637
1638 if (xmlFAGenerateTransitions(ctxt, atom->start, NULL, copy)
1639 < 0)
1640 return(-1);
1641 inter = ctxt->state;
1642 counter = xmlRegGetCounter(ctxt);
1643 ctxt->counters[counter].min = atom->min - 1;
1644 ctxt->counters[counter].max = atom->max - 1;
1645 /* count the number of times we see it again */
1646 xmlFAGenerateCountedEpsilonTransition(ctxt, inter,
1647 atom->stop, counter);
1648 /* allow a way out based on the count */
1649 xmlFAGenerateCountedTransition(ctxt, inter,
1650 newstate, counter);
1651 /* and also allow a direct exit for 0 */
1652 xmlFAGenerateEpsilonTransition(ctxt, atom->start,
1653 newstate);
1654 } else {
1655 /*
1656 * either we need the atom at least once or there
1657 * is an atom->start0 allowing to easilly plug the
1658 * epsilon transition.
1659 */
1660 counter = xmlRegGetCounter(ctxt);
1661 ctxt->counters[counter].min = atom->min - 1;
1662 ctxt->counters[counter].max = atom->max - 1;
1663 /* count the number of times we see it again */
1664 xmlFAGenerateCountedEpsilonTransition(ctxt, atom->stop,
1665 atom->start, counter);
1666 /* allow a way out based on the count */
1667 xmlFAGenerateCountedTransition(ctxt, atom->stop,
1668 newstate, counter);
1669 /* and if needed allow a direct exit for 0 */
1670 if (atom->min == 0)
1671 xmlFAGenerateEpsilonTransition(ctxt, atom->start0,
1672 newstate);
1673
1674 }
1675 atom->min = 0;
1676 atom->max = 0;
1677 atom->quant = XML_REGEXP_QUANT_ONCE;
1678 ctxt->state = newstate;
1679 }
1680 default:
1681 break;
1682 }
1683 return(0);
1684 }
1685 if ((atom->min == 0) && (atom->max == 0) &&
1686 (atom->quant == XML_REGEXP_QUANT_RANGE)) {
1687 /*
1688 * we can discard the atom and generate an epsilon transition instead
1689 */
1690 if (to == NULL) {
1691 to = xmlRegNewState(ctxt);
1692 if (to != NULL)
1693 xmlRegStatePush(ctxt, to);
1694 else {
1695 return(-1);
1696 }
1697 }
1698 xmlFAGenerateEpsilonTransition(ctxt, from, to);
1699 ctxt->state = to;
1700 xmlRegFreeAtom(atom);
1701 return(0);
1702 }
1703 if (to == NULL) {
1704 to = xmlRegNewState(ctxt);
1705 if (to != NULL)
1706 xmlRegStatePush(ctxt, to);
1707 else {
1708 return(-1);
1709 }
1710 }
1711 end = to;
1712 if ((atom->quant == XML_REGEXP_QUANT_MULT) ||
1713 (atom->quant == XML_REGEXP_QUANT_PLUS)) {
1714 /*
1715 * Do not pollute the target state by adding transitions from
1716 * it as it is likely to be the shared target of multiple branches.
1717 * So isolate with an epsilon transition.
1718 */
1719 xmlRegStatePtr tmp;
1720
1721 tmp = xmlRegNewState(ctxt);
1722 if (tmp != NULL)
1723 xmlRegStatePush(ctxt, tmp);
1724 else {
1725 return(-1);
1726 }
1727 xmlFAGenerateEpsilonTransition(ctxt, tmp, to);
1728 to = tmp;
1729 }
1730 if (xmlRegAtomPush(ctxt, atom) < 0) {
1731 return(-1);
1732 }
1733 xmlRegStateAddTrans(ctxt, from, atom, to, -1, -1);
1734 ctxt->state = end;
1735 switch (atom->quant) {
1736 case XML_REGEXP_QUANT_OPT:
1737 atom->quant = XML_REGEXP_QUANT_ONCE;
1738 xmlFAGenerateEpsilonTransition(ctxt, from, to);
1739 break;
1740 case XML_REGEXP_QUANT_MULT:
1741 atom->quant = XML_REGEXP_QUANT_ONCE;
1742 xmlFAGenerateEpsilonTransition(ctxt, from, to);
1743 xmlRegStateAddTrans(ctxt, to, atom, to, -1, -1);
1744 break;
1745 case XML_REGEXP_QUANT_PLUS:
1746 atom->quant = XML_REGEXP_QUANT_ONCE;
1747 xmlRegStateAddTrans(ctxt, to, atom, to, -1, -1);
1748 break;
1749 case XML_REGEXP_QUANT_RANGE:
1750#if DV_test
1751 if (atom->min == 0) {
1752 xmlFAGenerateEpsilonTransition(ctxt, from, to);
1753 }
1754#endif
1755 break;
1756 default:
1757 break;
1758 }
1759 return(0);
1760}
1761
1762/**
1763 * xmlFAReduceEpsilonTransitions:
1764 * @ctxt: a regexp parser context
1765 * @fromnr: the from state
1766 * @tonr: the to state
1767 * @counter: should that transition be associated to a counted
1768 *
1769 */
1770static void
1771xmlFAReduceEpsilonTransitions(xmlRegParserCtxtPtr ctxt, int fromnr,
1772 int tonr, int counter) {
1773 int transnr;
1774 xmlRegStatePtr from;
1775 xmlRegStatePtr to;
1776
1777#ifdef DEBUG_REGEXP_GRAPH
1778 printf("xmlFAReduceEpsilonTransitions(%d, %d)\n", fromnr, tonr);
1779#endif
1780 from = ctxt->states[fromnr];
1781 if (from == NULL)
1782 return;
1783 to = ctxt->states[tonr];
1784 if (to == NULL)
1785 return;
1786 if ((to->mark == XML_REGEXP_MARK_START) ||
1787 (to->mark == XML_REGEXP_MARK_VISITED))
1788 return;
1789
1790 to->mark = XML_REGEXP_MARK_VISITED;
1791 if (to->type == XML_REGEXP_FINAL_STATE) {
1792#ifdef DEBUG_REGEXP_GRAPH
1793 printf("State %d is final, so %d becomes final\n", tonr, fromnr);
1794#endif
1795 from->type = XML_REGEXP_FINAL_STATE;
1796 }
1797 for (transnr = 0;transnr < to->nbTrans;transnr++) {
1798 if (to->trans[transnr].to < 0)
1799 continue;
1800 if (to->trans[transnr].atom == NULL) {
1801 /*
1802 * Don't remove counted transitions
1803 * Don't loop either
1804 */
1805 if (to->trans[transnr].to != fromnr) {
1806 if (to->trans[transnr].count >= 0) {
1807 int newto = to->trans[transnr].to;
1808
1809 xmlRegStateAddTrans(ctxt, from, NULL,
1810 ctxt->states[newto],
1811 -1, to->trans[transnr].count);
1812 } else {
1813#ifdef DEBUG_REGEXP_GRAPH
1814 printf("Found epsilon trans %d from %d to %d\n",
1815 transnr, tonr, to->trans[transnr].to);
1816#endif
1817 if (to->trans[transnr].counter >= 0) {
1818 xmlFAReduceEpsilonTransitions(ctxt, fromnr,
1819 to->trans[transnr].to,
1820 to->trans[transnr].counter);
1821 } else {
1822 xmlFAReduceEpsilonTransitions(ctxt, fromnr,
1823 to->trans[transnr].to,
1824 counter);
1825 }
1826 }
1827 }
1828 } else {
1829 int newto = to->trans[transnr].to;
1830
1831 if (to->trans[transnr].counter >= 0) {
1832 xmlRegStateAddTrans(ctxt, from, to->trans[transnr].atom,
1833 ctxt->states[newto],
1834 to->trans[transnr].counter, -1);
1835 } else {
1836 xmlRegStateAddTrans(ctxt, from, to->trans[transnr].atom,
1837 ctxt->states[newto], counter, -1);
1838 }
1839 }
1840 }
1841 to->mark = XML_REGEXP_MARK_NORMAL;
1842}
1843
1844/**
1845 * xmlFAEliminateSimpleEpsilonTransitions:
1846 * @ctxt: a regexp parser context
1847 *
1848 * Eliminating general epsilon transitions can get costly in the general
1849 * algorithm due to the large amount of generated new transitions and
1850 * associated comparisons. However for simple epsilon transition used just
1851 * to separate building blocks when generating the automata this can be
1852 * reduced to state elimination:
1853 * - if there exists an epsilon from X to Y
1854 * - if there is no other transition from X
1855 * then X and Y are semantically equivalent and X can be eliminated
1856 * If X is the start state then make Y the start state, else replace the
1857 * target of all transitions to X by transitions to Y.
1858 */
1859static void
1860xmlFAEliminateSimpleEpsilonTransitions(xmlRegParserCtxtPtr ctxt) {
1861 int statenr, i, j, newto;
1862 xmlRegStatePtr state, tmp;
1863
1864 for (statenr = 0;statenr < ctxt->nbStates;statenr++) {
1865 state = ctxt->states[statenr];
1866 if (state == NULL)
1867 continue;
1868 if (state->nbTrans != 1)
1869 continue;
1870 if (state->type == XML_REGEXP_UNREACH_STATE)
1871 continue;
1872 /* is the only transition out a basic transition */
1873 if ((state->trans[0].atom == NULL) &&
1874 (state->trans[0].to >= 0) &&
1875 (state->trans[0].to != statenr) &&
1876 (state->trans[0].counter < 0) &&
1877 (state->trans[0].count < 0)) {
1878 newto = state->trans[0].to;
1879
1880 if (state->type == XML_REGEXP_START_STATE) {
1881#ifdef DEBUG_REGEXP_GRAPH
1882 printf("Found simple epsilon trans from start %d to %d\n",
1883 statenr, newto);
1884#endif
1885 } else {
1886#ifdef DEBUG_REGEXP_GRAPH
1887 printf("Found simple epsilon trans from %d to %d\n",
1888 statenr, newto);
1889#endif
1890 for (i = 0;i < state->nbTransTo;i++) {
1891 tmp = ctxt->states[state->transTo[i]];
1892 for (j = 0;j < tmp->nbTrans;j++) {
1893 if (tmp->trans[j].to == statenr) {
1894#ifdef DEBUG_REGEXP_GRAPH
1895 printf("Changed transition %d on %d to go to %d\n",
1896 j, tmp->no, newto);
1897#endif
1898 tmp->trans[j].to = -1;
1899 xmlRegStateAddTrans(ctxt, tmp, tmp->trans[j].atom,
1900 ctxt->states[newto],
1901 tmp->trans[j].counter,
1902 tmp->trans[j].count);
1903 }
1904 }
1905 }
1906 if (state->type == XML_REGEXP_FINAL_STATE)
1907 ctxt->states[newto]->type = XML_REGEXP_FINAL_STATE;
1908 /* eliminate the transition completely */
1909 state->nbTrans = 0;
1910
1911 state->type = XML_REGEXP_UNREACH_STATE;
1912
1913 }
1914
1915 }
1916 }
1917}
1918/**
1919 * xmlFAEliminateEpsilonTransitions:
1920 * @ctxt: a regexp parser context
1921 *
1922 */
1923static void
1924xmlFAEliminateEpsilonTransitions(xmlRegParserCtxtPtr ctxt) {
1925 int statenr, transnr;
1926 xmlRegStatePtr state;
1927 int has_epsilon;
1928
1929 if (ctxt->states == NULL) return;
1930
1931 /*
1932 * Eliminate simple epsilon transition and the associated unreachable
1933 * states.
1934 */
1935 xmlFAEliminateSimpleEpsilonTransitions(ctxt);
1936 for (statenr = 0;statenr < ctxt->nbStates;statenr++) {
1937 state = ctxt->states[statenr];
1938 if ((state != NULL) && (state->type == XML_REGEXP_UNREACH_STATE)) {
1939#ifdef DEBUG_REGEXP_GRAPH
1940 printf("Removed unreachable state %d\n", statenr);
1941#endif
1942 xmlRegFreeState(state);
1943 ctxt->states[statenr] = NULL;
1944 }
1945 }
1946
1947 has_epsilon = 0;
1948
1949 /*
1950 * Build the completed transitions bypassing the epsilons
1951 * Use a marking algorithm to avoid loops
1952 * Mark sink states too.
1953 * Process from the latests states backward to the start when
1954 * there is long cascading epsilon chains this minimize the
1955 * recursions and transition compares when adding the new ones
1956 */
1957 for (statenr = ctxt->nbStates - 1;statenr >= 0;statenr--) {
1958 state = ctxt->states[statenr];
1959 if (state == NULL)
1960 continue;
1961 if ((state->nbTrans == 0) &&
1962 (state->type != XML_REGEXP_FINAL_STATE)) {
1963 state->type = XML_REGEXP_SINK_STATE;
1964 }
1965 for (transnr = 0;transnr < state->nbTrans;transnr++) {
1966 if ((state->trans[transnr].atom == NULL) &&
1967 (state->trans[transnr].to >= 0)) {
1968 if (state->trans[transnr].to == statenr) {
1969 state->trans[transnr].to = -1;
1970#ifdef DEBUG_REGEXP_GRAPH
1971 printf("Removed loopback epsilon trans %d on %d\n",
1972 transnr, statenr);
1973#endif
1974 } else if (state->trans[transnr].count < 0) {
1975 int newto = state->trans[transnr].to;
1976
1977#ifdef DEBUG_REGEXP_GRAPH
1978 printf("Found epsilon trans %d from %d to %d\n",
1979 transnr, statenr, newto);
1980#endif
1981 has_epsilon = 1;
1982 state->trans[transnr].to = -2;
1983 state->mark = XML_REGEXP_MARK_START;
1984 xmlFAReduceEpsilonTransitions(ctxt, statenr,
1985 newto, state->trans[transnr].counter);
1986 state->mark = XML_REGEXP_MARK_NORMAL;
1987#ifdef DEBUG_REGEXP_GRAPH
1988 } else {
1989 printf("Found counted transition %d on %d\n",
1990 transnr, statenr);
1991#endif
1992 }
1993 }
1994 }
1995 }
1996 /*
1997 * Eliminate the epsilon transitions
1998 */
1999 if (has_epsilon) {
2000 for (statenr = 0;statenr < ctxt->nbStates;statenr++) {
2001 state = ctxt->states[statenr];
2002 if (state == NULL)
2003 continue;
2004 for (transnr = 0;transnr < state->nbTrans;transnr++) {
2005 xmlRegTransPtr trans = &(state->trans[transnr]);
2006 if ((trans->atom == NULL) &&
2007 (trans->count < 0) &&
2008 (trans->to >= 0)) {
2009 trans->to = -1;
2010 }
2011 }
2012 }
2013 }
2014
2015 /*
2016 * Use this pass to detect unreachable states too
2017 */
2018 for (statenr = 0;statenr < ctxt->nbStates;statenr++) {
2019 state = ctxt->states[statenr];
2020 if (state != NULL)
2021 state->reached = XML_REGEXP_MARK_NORMAL;
2022 }
2023 state = ctxt->states[0];
2024 if (state != NULL)
2025 state->reached = XML_REGEXP_MARK_START;
2026 while (state != NULL) {
2027 xmlRegStatePtr target = NULL;
2028 state->reached = XML_REGEXP_MARK_VISITED;
2029 /*
2030 * Mark all states reachable from the current reachable state
2031 */
2032 for (transnr = 0;transnr < state->nbTrans;transnr++) {
2033 if ((state->trans[transnr].to >= 0) &&
2034 ((state->trans[transnr].atom != NULL) ||
2035 (state->trans[transnr].count >= 0))) {
2036 int newto = state->trans[transnr].to;
2037
2038 if (ctxt->states[newto] == NULL)
2039 continue;
2040 if (ctxt->states[newto]->reached == XML_REGEXP_MARK_NORMAL) {
2041 ctxt->states[newto]->reached = XML_REGEXP_MARK_START;
2042 target = ctxt->states[newto];
2043 }
2044 }
2045 }
2046
2047 /*
2048 * find the next accessible state not explored
2049 */
2050 if (target == NULL) {
2051 for (statenr = 1;statenr < ctxt->nbStates;statenr++) {
2052 state = ctxt->states[statenr];
2053 if ((state != NULL) && (state->reached ==
2054 XML_REGEXP_MARK_START)) {
2055 target = state;
2056 break;
2057 }
2058 }
2059 }
2060 state = target;
2061 }
2062 for (statenr = 0;statenr < ctxt->nbStates;statenr++) {
2063 state = ctxt->states[statenr];
2064 if ((state != NULL) && (state->reached == XML_REGEXP_MARK_NORMAL)) {
2065#ifdef DEBUG_REGEXP_GRAPH
2066 printf("Removed unreachable state %d\n", statenr);
2067#endif
2068 xmlRegFreeState(state);
2069 ctxt->states[statenr] = NULL;
2070 }
2071 }
2072
2073}
2074
2075static int
2076xmlFACompareRanges(xmlRegRangePtr range1, xmlRegRangePtr range2) {
2077 int ret = 0;
2078
2079 if ((range1->type == XML_REGEXP_RANGES) ||
2080 (range2->type == XML_REGEXP_RANGES) ||
2081 (range2->type == XML_REGEXP_SUBREG) ||
2082 (range1->type == XML_REGEXP_SUBREG) ||
2083 (range1->type == XML_REGEXP_STRING) ||
2084 (range2->type == XML_REGEXP_STRING))
2085 return(-1);
2086
2087 /* put them in order */
2088 if (range1->type > range2->type) {
2089 xmlRegRangePtr tmp;
2090
2091 tmp = range1;
2092 range1 = range2;
2093 range2 = tmp;
2094 }
2095 if ((range1->type == XML_REGEXP_ANYCHAR) ||
2096 (range2->type == XML_REGEXP_ANYCHAR)) {
2097 ret = 1;
2098 } else if ((range1->type == XML_REGEXP_EPSILON) ||
2099 (range2->type == XML_REGEXP_EPSILON)) {
2100 return(0);
2101 } else if (range1->type == range2->type) {
2102 if (range1->type != XML_REGEXP_CHARVAL)
2103 ret = 1;
2104 else if ((range1->end < range2->start) ||
2105 (range2->end < range1->start))
2106 ret = 0;
2107 else
2108 ret = 1;
2109 } else if (range1->type == XML_REGEXP_CHARVAL) {
2110 int codepoint;
2111 int neg = 0;
2112
2113 /*
2114 * just check all codepoints in the range for acceptance,
2115 * this is usually way cheaper since done only once at
2116 * compilation than testing over and over at runtime or
2117 * pushing too many states when evaluating.
2118 */
2119 if (((range1->neg == 0) && (range2->neg != 0)) ||
2120 ((range1->neg != 0) && (range2->neg == 0)))
2121 neg = 1;
2122
2123 for (codepoint = range1->start;codepoint <= range1->end ;codepoint++) {
2124 ret = xmlRegCheckCharacterRange(range2->type, codepoint,
2125 0, range2->start, range2->end,
2126 range2->blockName);
2127 if (ret < 0)
2128 return(-1);
2129 if (((neg == 1) && (ret == 0)) ||
2130 ((neg == 0) && (ret == 1)))
2131 return(1);
2132 }
2133 return(0);
2134 } else if ((range1->type == XML_REGEXP_BLOCK_NAME) ||
2135 (range2->type == XML_REGEXP_BLOCK_NAME)) {
2136 if (range1->type == range2->type) {
2137 ret = xmlStrEqual(range1->blockName, range2->blockName);
2138 } else {
2139 /*
2140 * comparing a block range with anything else is way
2141 * too costly, and maintining the table is like too much
2142 * memory too, so let's force the automata to save state
2143 * here.
2144 */
2145 return(1);
2146 }
2147 } else if ((range1->type < XML_REGEXP_LETTER) ||
2148 (range2->type < XML_REGEXP_LETTER)) {
2149 if ((range1->type == XML_REGEXP_ANYSPACE) &&
2150 (range2->type == XML_REGEXP_NOTSPACE))
2151 ret = 0;
2152 else if ((range1->type == XML_REGEXP_INITNAME) &&
2153 (range2->type == XML_REGEXP_NOTINITNAME))
2154 ret = 0;
2155 else if ((range1->type == XML_REGEXP_NAMECHAR) &&
2156 (range2->type == XML_REGEXP_NOTNAMECHAR))
2157 ret = 0;
2158 else if ((range1->type == XML_REGEXP_DECIMAL) &&
2159 (range2->type == XML_REGEXP_NOTDECIMAL))
2160 ret = 0;
2161 else if ((range1->type == XML_REGEXP_REALCHAR) &&
2162 (range2->type == XML_REGEXP_NOTREALCHAR))
2163 ret = 0;
2164 else {
2165 /* same thing to limit complexity */
2166 return(1);
2167 }
2168 } else {
2169 ret = 0;
2170 /* range1->type < range2->type here */
2171 switch (range1->type) {
2172 case XML_REGEXP_LETTER:
2173 /* all disjoint except in the subgroups */
2174 if ((range2->type == XML_REGEXP_LETTER_UPPERCASE) ||
2175 (range2->type == XML_REGEXP_LETTER_LOWERCASE) ||
2176 (range2->type == XML_REGEXP_LETTER_TITLECASE) ||
2177 (range2->type == XML_REGEXP_LETTER_MODIFIER) ||
2178 (range2->type == XML_REGEXP_LETTER_OTHERS))
2179 ret = 1;
2180 break;
2181 case XML_REGEXP_MARK:
2182 if ((range2->type == XML_REGEXP_MARK_NONSPACING) ||
2183 (range2->type == XML_REGEXP_MARK_SPACECOMBINING) ||
2184 (range2->type == XML_REGEXP_MARK_ENCLOSING))
2185 ret = 1;
2186 break;
2187 case XML_REGEXP_NUMBER:
2188 if ((range2->type == XML_REGEXP_NUMBER_DECIMAL) ||
2189 (range2->type == XML_REGEXP_NUMBER_LETTER) ||
2190 (range2->type == XML_REGEXP_NUMBER_OTHERS))
2191 ret = 1;
2192 break;
2193 case XML_REGEXP_PUNCT:
2194 if ((range2->type == XML_REGEXP_PUNCT_CONNECTOR) ||
2195 (range2->type == XML_REGEXP_PUNCT_DASH) ||
2196 (range2->type == XML_REGEXP_PUNCT_OPEN) ||
2197 (range2->type == XML_REGEXP_PUNCT_CLOSE) ||
2198 (range2->type == XML_REGEXP_PUNCT_INITQUOTE) ||
2199 (range2->type == XML_REGEXP_PUNCT_FINQUOTE) ||
2200 (range2->type == XML_REGEXP_PUNCT_OTHERS))
2201 ret = 1;
2202 break;
2203 case XML_REGEXP_SEPAR:
2204 if ((range2->type == XML_REGEXP_SEPAR_SPACE) ||
2205 (range2->type == XML_REGEXP_SEPAR_LINE) ||
2206 (range2->type == XML_REGEXP_SEPAR_PARA))
2207 ret = 1;
2208 break;
2209 case XML_REGEXP_SYMBOL:
2210 if ((range2->type == XML_REGEXP_SYMBOL_MATH) ||
2211 (range2->type == XML_REGEXP_SYMBOL_CURRENCY) ||
2212 (range2->type == XML_REGEXP_SYMBOL_MODIFIER) ||
2213 (range2->type == XML_REGEXP_SYMBOL_OTHERS))
2214 ret = 1;
2215 break;
2216 case XML_REGEXP_OTHER:
2217 if ((range2->type == XML_REGEXP_OTHER_CONTROL) ||
2218 (range2->type == XML_REGEXP_OTHER_FORMAT) ||
2219 (range2->type == XML_REGEXP_OTHER_PRIVATE))
2220 ret = 1;
2221 break;
2222 default:
2223 if ((range2->type >= XML_REGEXP_LETTER) &&
2224 (range2->type < XML_REGEXP_BLOCK_NAME))
2225 ret = 0;
2226 else {
2227 /* safety net ! */
2228 return(1);
2229 }
2230 }
2231 }
2232 if (((range1->neg == 0) && (range2->neg != 0)) ||
2233 ((range1->neg != 0) && (range2->neg == 0)))
2234 ret = !ret;
2235 return(ret);
2236}
2237
2238/**
2239 * xmlFACompareAtomTypes:
2240 * @type1: an atom type
2241 * @type2: an atom type
2242 *
2243 * Compares two atoms type to check whether they intersect in some ways,
2244 * this is used by xmlFACompareAtoms only
2245 *
2246 * Returns 1 if they may intersect and 0 otherwise
2247 */
2248static int
2249xmlFACompareAtomTypes(xmlRegAtomType type1, xmlRegAtomType type2) {
2250 if ((type1 == XML_REGEXP_EPSILON) ||
2251 (type1 == XML_REGEXP_CHARVAL) ||
2252 (type1 == XML_REGEXP_RANGES) ||
2253 (type1 == XML_REGEXP_SUBREG) ||
2254 (type1 == XML_REGEXP_STRING) ||
2255 (type1 == XML_REGEXP_ANYCHAR))
2256 return(1);
2257 if ((type2 == XML_REGEXP_EPSILON) ||
2258 (type2 == XML_REGEXP_CHARVAL) ||
2259 (type2 == XML_REGEXP_RANGES) ||
2260 (type2 == XML_REGEXP_SUBREG) ||
2261 (type2 == XML_REGEXP_STRING) ||
2262 (type2 == XML_REGEXP_ANYCHAR))
2263 return(1);
2264
2265 if (type1 == type2) return(1);
2266
2267 /* simplify subsequent compares by making sure type1 < type2 */
2268 if (type1 > type2) {
2269 xmlRegAtomType tmp = type1;
2270 type1 = type2;
2271 type2 = tmp;
2272 }
2273 switch (type1) {
2274 case XML_REGEXP_ANYSPACE: /* \s */
2275 /* can't be a letter, number, mark, pontuation, symbol */
2276 if ((type2 == XML_REGEXP_NOTSPACE) ||
2277 ((type2 >= XML_REGEXP_LETTER) &&
2278 (type2 <= XML_REGEXP_LETTER_OTHERS)) ||
2279 ((type2 >= XML_REGEXP_NUMBER) &&
2280 (type2 <= XML_REGEXP_NUMBER_OTHERS)) ||
2281 ((type2 >= XML_REGEXP_MARK) &&
2282 (type2 <= XML_REGEXP_MARK_ENCLOSING)) ||
2283 ((type2 >= XML_REGEXP_PUNCT) &&
2284 (type2 <= XML_REGEXP_PUNCT_OTHERS)) ||
2285 ((type2 >= XML_REGEXP_SYMBOL) &&
2286 (type2 <= XML_REGEXP_SYMBOL_OTHERS))
2287 ) return(0);
2288 break;
2289 case XML_REGEXP_NOTSPACE: /* \S */
2290 break;
2291 case XML_REGEXP_INITNAME: /* \l */
2292 /* can't be a number, mark, separator, pontuation, symbol or other */
2293 if ((type2 == XML_REGEXP_NOTINITNAME) ||
2294 ((type2 >= XML_REGEXP_NUMBER) &&
2295 (type2 <= XML_REGEXP_NUMBER_OTHERS)) ||
2296 ((type2 >= XML_REGEXP_MARK) &&
2297 (type2 <= XML_REGEXP_MARK_ENCLOSING)) ||
2298 ((type2 >= XML_REGEXP_SEPAR) &&
2299 (type2 <= XML_REGEXP_SEPAR_PARA)) ||
2300 ((type2 >= XML_REGEXP_PUNCT) &&
2301 (type2 <= XML_REGEXP_PUNCT_OTHERS)) ||
2302 ((type2 >= XML_REGEXP_SYMBOL) &&
2303 (type2 <= XML_REGEXP_SYMBOL_OTHERS)) ||
2304 ((type2 >= XML_REGEXP_OTHER) &&
2305 (type2 <= XML_REGEXP_OTHER_NA))
2306 ) return(0);
2307 break;
2308 case XML_REGEXP_NOTINITNAME: /* \L */
2309 break;
2310 case XML_REGEXP_NAMECHAR: /* \c */
2311 /* can't be a mark, separator, pontuation, symbol or other */
2312 if ((type2 == XML_REGEXP_NOTNAMECHAR) ||
2313 ((type2 >= XML_REGEXP_MARK) &&
2314 (type2 <= XML_REGEXP_MARK_ENCLOSING)) ||
2315 ((type2 >= XML_REGEXP_PUNCT) &&
2316 (type2 <= XML_REGEXP_PUNCT_OTHERS)) ||
2317 ((type2 >= XML_REGEXP_SEPAR) &&
2318 (type2 <= XML_REGEXP_SEPAR_PARA)) ||
2319 ((type2 >= XML_REGEXP_SYMBOL) &&
2320 (type2 <= XML_REGEXP_SYMBOL_OTHERS)) ||
2321 ((type2 >= XML_REGEXP_OTHER) &&
2322 (type2 <= XML_REGEXP_OTHER_NA))
2323 ) return(0);
2324 break;
2325 case XML_REGEXP_NOTNAMECHAR: /* \C */
2326 break;
2327 case XML_REGEXP_DECIMAL: /* \d */
2328 /* can't be a letter, mark, separator, pontuation, symbol or other */
2329 if ((type2 == XML_REGEXP_NOTDECIMAL) ||
2330 (type2 == XML_REGEXP_REALCHAR) ||
2331 ((type2 >= XML_REGEXP_LETTER) &&
2332 (type2 <= XML_REGEXP_LETTER_OTHERS)) ||
2333 ((type2 >= XML_REGEXP_MARK) &&
2334 (type2 <= XML_REGEXP_MARK_ENCLOSING)) ||
2335 ((type2 >= XML_REGEXP_PUNCT) &&
2336 (type2 <= XML_REGEXP_PUNCT_OTHERS)) ||
2337 ((type2 >= XML_REGEXP_SEPAR) &&
2338 (type2 <= XML_REGEXP_SEPAR_PARA)) ||
2339 ((type2 >= XML_REGEXP_SYMBOL) &&
2340 (type2 <= XML_REGEXP_SYMBOL_OTHERS)) ||
2341 ((type2 >= XML_REGEXP_OTHER) &&
2342 (type2 <= XML_REGEXP_OTHER_NA))
2343 )return(0);
2344 break;
2345 case XML_REGEXP_NOTDECIMAL: /* \D */
2346 break;
2347 case XML_REGEXP_REALCHAR: /* \w */
2348 /* can't be a mark, separator, pontuation, symbol or other */
2349 if ((type2 == XML_REGEXP_NOTDECIMAL) ||
2350 ((type2 >= XML_REGEXP_MARK) &&
2351 (type2 <= XML_REGEXP_MARK_ENCLOSING)) ||
2352 ((type2 >= XML_REGEXP_PUNCT) &&
2353 (type2 <= XML_REGEXP_PUNCT_OTHERS)) ||
2354 ((type2 >= XML_REGEXP_SEPAR) &&
2355 (type2 <= XML_REGEXP_SEPAR_PARA)) ||
2356 ((type2 >= XML_REGEXP_SYMBOL) &&
2357 (type2 <= XML_REGEXP_SYMBOL_OTHERS)) ||
2358 ((type2 >= XML_REGEXP_OTHER) &&
2359 (type2 <= XML_REGEXP_OTHER_NA))
2360 )return(0);
2361 break;
2362 case XML_REGEXP_NOTREALCHAR: /* \W */
2363 break;
2364 /*
2365 * at that point we know both type 1 and type2 are from
2366 * character categories are ordered and are different,
2367 * it becomes simple because this is a partition
2368 */
2369 case XML_REGEXP_LETTER:
2370 if (type2 <= XML_REGEXP_LETTER_OTHERS)
2371 return(1);
2372 return(0);
2373 case XML_REGEXP_LETTER_UPPERCASE:
2374 case XML_REGEXP_LETTER_LOWERCASE:
2375 case XML_REGEXP_LETTER_TITLECASE:
2376 case XML_REGEXP_LETTER_MODIFIER:
2377 case XML_REGEXP_LETTER_OTHERS:
2378 return(0);
2379 case XML_REGEXP_MARK:
2380 if (type2 <= XML_REGEXP_MARK_ENCLOSING)
2381 return(1);
2382 return(0);
2383 case XML_REGEXP_MARK_NONSPACING:
2384 case XML_REGEXP_MARK_SPACECOMBINING:
2385 case XML_REGEXP_MARK_ENCLOSING:
2386 return(0);
2387 case XML_REGEXP_NUMBER:
2388 if (type2 <= XML_REGEXP_NUMBER_OTHERS)
2389 return(1);
2390 return(0);
2391 case XML_REGEXP_NUMBER_DECIMAL:
2392 case XML_REGEXP_NUMBER_LETTER:
2393 case XML_REGEXP_NUMBER_OTHERS:
2394 return(0);
2395 case XML_REGEXP_PUNCT:
2396 if (type2 <= XML_REGEXP_PUNCT_OTHERS)
2397 return(1);
2398 return(0);
2399 case XML_REGEXP_PUNCT_CONNECTOR:
2400 case XML_REGEXP_PUNCT_DASH:
2401 case XML_REGEXP_PUNCT_OPEN:
2402 case XML_REGEXP_PUNCT_CLOSE:
2403 case XML_REGEXP_PUNCT_INITQUOTE:
2404 case XML_REGEXP_PUNCT_FINQUOTE:
2405 case XML_REGEXP_PUNCT_OTHERS:
2406 return(0);
2407 case XML_REGEXP_SEPAR:
2408 if (type2 <= XML_REGEXP_SEPAR_PARA)
2409 return(1);
2410 return(0);
2411 case XML_REGEXP_SEPAR_SPACE:
2412 case XML_REGEXP_SEPAR_LINE:
2413 case XML_REGEXP_SEPAR_PARA:
2414 return(0);
2415 case XML_REGEXP_SYMBOL:
2416 if (type2 <= XML_REGEXP_SYMBOL_OTHERS)
2417 return(1);
2418 return(0);
2419 case XML_REGEXP_SYMBOL_MATH:
2420 case XML_REGEXP_SYMBOL_CURRENCY:
2421 case XML_REGEXP_SYMBOL_MODIFIER:
2422 case XML_REGEXP_SYMBOL_OTHERS:
2423 return(0);
2424 case XML_REGEXP_OTHER:
2425 if (type2 <= XML_REGEXP_OTHER_NA)
2426 return(1);
2427 return(0);
2428 case XML_REGEXP_OTHER_CONTROL:
2429 case XML_REGEXP_OTHER_FORMAT:
2430 case XML_REGEXP_OTHER_PRIVATE:
2431 case XML_REGEXP_OTHER_NA:
2432 return(0);
2433 default:
2434 break;
2435 }
2436 return(1);
2437}
2438
2439/**
2440 * xmlFAEqualAtoms:
2441 * @atom1: an atom
2442 * @atom2: an atom
2443 * @deep: if not set only compare string pointers
2444 *
2445 * Compares two atoms to check whether they are the same exactly
2446 * this is used to remove equivalent transitions
2447 *
2448 * Returns 1 if same and 0 otherwise
2449 */
2450static int
2451xmlFAEqualAtoms(xmlRegAtomPtr atom1, xmlRegAtomPtr atom2, int deep) {
2452 int ret = 0;
2453
2454 if (atom1 == atom2)
2455 return(1);
2456 if ((atom1 == NULL) || (atom2 == NULL))
2457 return(0);
2458
2459 if (atom1->type != atom2->type)
2460 return(0);
2461 switch (atom1->type) {
2462 case XML_REGEXP_EPSILON:
2463 ret = 0;
2464 break;
2465 case XML_REGEXP_STRING:
2466 if (!deep)
2467 ret = (atom1->valuep == atom2->valuep);
2468 else
2469 ret = xmlStrEqual((xmlChar *)atom1->valuep,
2470 (xmlChar *)atom2->valuep);
2471 break;
2472 case XML_REGEXP_CHARVAL:
2473 ret = (atom1->codepoint == atom2->codepoint);
2474 break;
2475 case XML_REGEXP_RANGES:
2476 /* too hard to do in the general case */
2477 ret = 0;
2478 default:
2479 break;
2480 }
2481 return(ret);
2482}
2483
2484/**
2485 * xmlFACompareAtoms:
2486 * @atom1: an atom
2487 * @atom2: an atom
2488 * @deep: if not set only compare string pointers
2489 *
2490 * Compares two atoms to check whether they intersect in some ways,
2491 * this is used by xmlFAComputesDeterminism and xmlFARecurseDeterminism only
2492 *
2493 * Returns 1 if yes and 0 otherwise
2494 */
2495static int
2496xmlFACompareAtoms(xmlRegAtomPtr atom1, xmlRegAtomPtr atom2, int deep) {
2497 int ret = 1;
2498
2499 if (atom1 == atom2)
2500 return(1);
2501 if ((atom1 == NULL) || (atom2 == NULL))
2502 return(0);
2503
2504 if ((atom1->type == XML_REGEXP_ANYCHAR) ||
2505 (atom2->type == XML_REGEXP_ANYCHAR))
2506 return(1);
2507
2508 if (atom1->type > atom2->type) {
2509 xmlRegAtomPtr tmp;
2510 tmp = atom1;
2511 atom1 = atom2;
2512 atom2 = tmp;
2513 }
2514 if (atom1->type != atom2->type) {
2515 ret = xmlFACompareAtomTypes(atom1->type, atom2->type);
2516 /* if they can't intersect at the type level break now */
2517 if (ret == 0)
2518 return(0);
2519 }
2520 switch (atom1->type) {
2521 case XML_REGEXP_STRING:
2522 if (!deep)
2523 ret = (atom1->valuep != atom2->valuep);
2524 else
2525 ret = xmlRegStrEqualWildcard((xmlChar *)atom1->valuep,
2526 (xmlChar *)atom2->valuep);
2527 break;
2528 case XML_REGEXP_EPSILON:
2529 goto not_determinist;
2530 case XML_REGEXP_CHARVAL:
2531 if (atom2->type == XML_REGEXP_CHARVAL) {
2532 ret = (atom1->codepoint == atom2->codepoint);
2533 } else {
2534 ret = xmlRegCheckCharacter(atom2, atom1->codepoint);
2535 if (ret < 0)
2536 ret = 1;
2537 }
2538 break;
2539 case XML_REGEXP_RANGES:
2540 if (atom2->type == XML_REGEXP_RANGES) {
2541 int i, j, res;
2542 xmlRegRangePtr r1, r2;
2543
2544 /*
2545 * need to check that none of the ranges eventually matches
2546 */
2547 for (i = 0;i < atom1->nbRanges;i++) {
2548 for (j = 0;j < atom2->nbRanges;j++) {
2549 r1 = atom1->ranges[i];
2550 r2 = atom2->ranges[j];
2551 res = xmlFACompareRanges(r1, r2);
2552 if (res == 1) {
2553 ret = 1;
2554 goto done;
2555 }
2556 }
2557 }
2558 ret = 0;
2559 }
2560 break;
2561 default:
2562 goto not_determinist;
2563 }
2564done:
2565 if (atom1->neg != atom2->neg) {
2566 ret = !ret;
2567 }
2568 if (ret == 0)
2569 return(0);
2570not_determinist:
2571 return(1);
2572}
2573
2574/**
2575 * xmlFARecurseDeterminism:
2576 * @ctxt: a regexp parser context
2577 *
2578 * Check whether the associated regexp is determinist,
2579 * should be called after xmlFAEliminateEpsilonTransitions()
2580 *
2581 */
2582static int
2583xmlFARecurseDeterminism(xmlRegParserCtxtPtr ctxt, xmlRegStatePtr state,
2584 int to, xmlRegAtomPtr atom) {
2585 int ret = 1;
2586 int res;
2587 int transnr, nbTrans;
2588 xmlRegTransPtr t1;
2589 int deep = 1;
2590
2591 if (state == NULL)
2592 return(ret);
2593 if (state->markd == XML_REGEXP_MARK_VISITED)
2594 return(ret);
2595
2596 if (ctxt->flags & AM_AUTOMATA_RNG)
2597 deep = 0;
2598
2599 /*
2600 * don't recurse on transitions potentially added in the course of
2601 * the elimination.
2602 */
2603 nbTrans = state->nbTrans;
2604 for (transnr = 0;transnr < nbTrans;transnr++) {
2605 t1 = &(state->trans[transnr]);
2606 /*
2607 * check transitions conflicting with the one looked at
2608 */
2609 if (t1->atom == NULL) {
2610 if (t1->to < 0)
2611 continue;
2612 state->markd = XML_REGEXP_MARK_VISITED;
2613 res = xmlFARecurseDeterminism(ctxt, ctxt->states[t1->to],
2614 to, atom);
2615 state->markd = 0;
2616 if (res == 0) {
2617 ret = 0;
2618 /* t1->nd = 1; */
2619 }
2620 continue;
2621 }
2622 if (t1->to != to)
2623 continue;
2624 if (xmlFACompareAtoms(t1->atom, atom, deep)) {
2625 ret = 0;
2626 /* mark the transition as non-deterministic */
2627 t1->nd = 1;
2628 }
2629 }
2630 return(ret);
2631}
2632
2633/**
2634 * xmlFAComputesDeterminism:
2635 * @ctxt: a regexp parser context
2636 *
2637 * Check whether the associated regexp is determinist,
2638 * should be called after xmlFAEliminateEpsilonTransitions()
2639 *
2640 */
2641static int
2642xmlFAComputesDeterminism(xmlRegParserCtxtPtr ctxt) {
2643 int statenr, transnr;
2644 xmlRegStatePtr state;
2645 xmlRegTransPtr t1, t2, last;
2646 int i;
2647 int ret = 1;
2648 int deep = 1;
2649
2650#ifdef DEBUG_REGEXP_GRAPH
2651 printf("xmlFAComputesDeterminism\n");
2652 xmlRegPrintCtxt(stdout, ctxt);
2653#endif
2654 if (ctxt->determinist != -1)
2655 return(ctxt->determinist);
2656
2657 if (ctxt->flags & AM_AUTOMATA_RNG)
2658 deep = 0;
2659
2660 /*
2661 * First cleanup the automata removing cancelled transitions
2662 */
2663 for (statenr = 0;statenr < ctxt->nbStates;statenr++) {
2664 state = ctxt->states[statenr];
2665 if (state == NULL)
2666 continue;
2667 if (state->nbTrans < 2)
2668 continue;
2669 for (transnr = 0;transnr < state->nbTrans;transnr++) {
2670 t1 = &(state->trans[transnr]);
2671 /*
2672 * Determinism checks in case of counted or all transitions
2673 * will have to be handled separately
2674 */
2675 if (t1->atom == NULL) {
2676 /* t1->nd = 1; */
2677 continue;
2678 }
2679 if (t1->to == -1) /* eliminated */
2680 continue;
2681 for (i = 0;i < transnr;i++) {
2682 t2 = &(state->trans[i]);
2683 if (t2->to == -1) /* eliminated */
2684 continue;
2685 if (t2->atom != NULL) {
2686 if (t1->to == t2->to) {
2687 /*
2688 * Here we use deep because we want to keep the
2689 * transitions which indicate a conflict
2690 */
2691 if (xmlFAEqualAtoms(t1->atom, t2->atom, deep) &&
2692 (t1->counter == t2->counter) &&
2693 (t1->count == t2->count))
2694 t2->to = -1; /* eliminated */
2695 }
2696 }
2697 }
2698 }
2699 }
2700
2701 /*
2702 * Check for all states that there aren't 2 transitions
2703 * with the same atom and a different target.
2704 */
2705 for (statenr = 0;statenr < ctxt->nbStates;statenr++) {
2706 state = ctxt->states[statenr];
2707 if (state == NULL)
2708 continue;
2709 if (state->nbTrans < 2)
2710 continue;
2711 last = NULL;
2712 for (transnr = 0;transnr < state->nbTrans;transnr++) {
2713 t1 = &(state->trans[transnr]);
2714 /*
2715 * Determinism checks in case of counted or all transitions
2716 * will have to be handled separately
2717 */
2718 if (t1->atom == NULL) {
2719 continue;
2720 }
2721 if (t1->to == -1) /* eliminated */
2722 continue;
2723 for (i = 0;i < transnr;i++) {
2724 t2 = &(state->trans[i]);
2725 if (t2->to == -1) /* eliminated */
2726 continue;
2727 if (t2->atom != NULL) {
2728 /*
2729 * But here we don't use deep because we want to
2730 * find transitions which indicate a conflict
2731 */
2732 if (xmlFACompareAtoms(t1->atom, t2->atom, 1)) {
2733 ret = 0;
2734 /* mark the transitions as non-deterministic ones */
2735 t1->nd = 1;
2736 t2->nd = 1;
2737 last = t1;
2738 }
2739 } else if (t1->to != -1) {
2740 /*
2741 * do the closure in case of remaining specific
2742 * epsilon transitions like choices or all
2743 */
2744 ret = xmlFARecurseDeterminism(ctxt, ctxt->states[t1->to],
2745 t2->to, t2->atom);
2746 /* don't shortcut the computation so all non deterministic
2747 transition get marked down
2748 if (ret == 0)
2749 return(0);
2750 */
2751 if (ret == 0) {
2752 t1->nd = 1;
2753 /* t2->nd = 1; */
2754 last = t1;
2755 }
2756 }
2757 }
2758 /* don't shortcut the computation so all non deterministic
2759 transition get marked down
2760 if (ret == 0)
2761 break; */
2762 }
2763
2764 /*
2765 * mark specifically the last non-deterministic transition
2766 * from a state since there is no need to set-up rollback
2767 * from it
2768 */
2769 if (last != NULL) {
2770 last->nd = 2;
2771 }
2772
2773 /* don't shortcut the computation so all non deterministic
2774 transition get marked down
2775 if (ret == 0)
2776 break; */
2777 }
2778
2779 ctxt->determinist = ret;
2780 return(ret);
2781}
2782
2783/************************************************************************
2784 * *
2785 * Routines to check input against transition atoms *
2786 * *
2787 ************************************************************************/
2788
2789static int
2790xmlRegCheckCharacterRange(xmlRegAtomType type, int codepoint, int neg,
2791 int start, int end, const xmlChar *blockName) {
2792 int ret = 0;
2793
2794 switch (type) {
2795 case XML_REGEXP_STRING:
2796 case XML_REGEXP_SUBREG:
2797 case XML_REGEXP_RANGES:
2798 case XML_REGEXP_EPSILON:
2799 return(-1);
2800 case XML_REGEXP_ANYCHAR:
2801 ret = ((codepoint != '\n') && (codepoint != '\r'));
2802 break;
2803 case XML_REGEXP_CHARVAL:
2804 ret = ((codepoint >= start) && (codepoint <= end));
2805 break;
2806 case XML_REGEXP_NOTSPACE:
2807 neg = !neg;
2808 case XML_REGEXP_ANYSPACE:
2809 ret = ((codepoint == '\n') || (codepoint == '\r') ||
2810 (codepoint == '\t') || (codepoint == ' '));
2811 break;
2812 case XML_REGEXP_NOTINITNAME:
2813 neg = !neg;
2814 case XML_REGEXP_INITNAME:
2815 ret = (IS_LETTER(codepoint) ||
2816 (codepoint == '_') || (codepoint == ':'));
2817 break;
2818 case XML_REGEXP_NOTNAMECHAR:
2819 neg = !neg;
2820 case XML_REGEXP_NAMECHAR:
2821 ret = (IS_LETTER(codepoint) || IS_DIGIT(codepoint) ||
2822 (codepoint == '.') || (codepoint == '-') ||
2823 (codepoint == '_') || (codepoint == ':') ||
2824 IS_COMBINING(codepoint) || IS_EXTENDER(codepoint));
2825 break;
2826 case XML_REGEXP_NOTDECIMAL:
2827 neg = !neg;
2828 case XML_REGEXP_DECIMAL:
2829 ret = xmlUCSIsCatNd(codepoint);
2830 break;
2831 case XML_REGEXP_REALCHAR:
2832 neg = !neg;
2833 case XML_REGEXP_NOTREALCHAR:
2834 ret = xmlUCSIsCatP(codepoint);
2835 if (ret == 0)
2836 ret = xmlUCSIsCatZ(codepoint);
2837 if (ret == 0)
2838 ret = xmlUCSIsCatC(codepoint);
2839 break;
2840 case XML_REGEXP_LETTER:
2841 ret = xmlUCSIsCatL(codepoint);
2842 break;
2843 case XML_REGEXP_LETTER_UPPERCASE:
2844 ret = xmlUCSIsCatLu(codepoint);
2845 break;
2846 case XML_REGEXP_LETTER_LOWERCASE:
2847 ret = xmlUCSIsCatLl(codepoint);
2848 break;
2849 case XML_REGEXP_LETTER_TITLECASE:
2850 ret = xmlUCSIsCatLt(codepoint);
2851 break;
2852 case XML_REGEXP_LETTER_MODIFIER:
2853 ret = xmlUCSIsCatLm(codepoint);
2854 break;
2855 case XML_REGEXP_LETTER_OTHERS:
2856 ret = xmlUCSIsCatLo(codepoint);
2857 break;
2858 case XML_REGEXP_MARK:
2859 ret = xmlUCSIsCatM(codepoint);
2860 break;
2861 case XML_REGEXP_MARK_NONSPACING:
2862 ret = xmlUCSIsCatMn(codepoint);
2863 break;
2864 case XML_REGEXP_MARK_SPACECOMBINING:
2865 ret = xmlUCSIsCatMc(codepoint);
2866 break;
2867 case XML_REGEXP_MARK_ENCLOSING:
2868 ret = xmlUCSIsCatMe(codepoint);
2869 break;
2870 case XML_REGEXP_NUMBER:
2871 ret = xmlUCSIsCatN(codepoint);
2872 break;
2873 case XML_REGEXP_NUMBER_DECIMAL:
2874 ret = xmlUCSIsCatNd(codepoint);
2875 break;
2876 case XML_REGEXP_NUMBER_LETTER:
2877 ret = xmlUCSIsCatNl(codepoint);
2878 break;
2879 case XML_REGEXP_NUMBER_OTHERS:
2880 ret = xmlUCSIsCatNo(codepoint);
2881 break;
2882 case XML_REGEXP_PUNCT:
2883 ret = xmlUCSIsCatP(codepoint);
2884 break;
2885 case XML_REGEXP_PUNCT_CONNECTOR:
2886 ret = xmlUCSIsCatPc(codepoint);
2887 break;
2888 case XML_REGEXP_PUNCT_DASH:
2889 ret = xmlUCSIsCatPd(codepoint);
2890 break;
2891 case XML_REGEXP_PUNCT_OPEN:
2892 ret = xmlUCSIsCatPs(codepoint);
2893 break;
2894 case XML_REGEXP_PUNCT_CLOSE:
2895 ret = xmlUCSIsCatPe(codepoint);
2896 break;
2897 case XML_REGEXP_PUNCT_INITQUOTE:
2898 ret = xmlUCSIsCatPi(codepoint);
2899 break;
2900 case XML_REGEXP_PUNCT_FINQUOTE:
2901 ret = xmlUCSIsCatPf(codepoint);
2902 break;
2903 case XML_REGEXP_PUNCT_OTHERS:
2904 ret = xmlUCSIsCatPo(codepoint);
2905 break;
2906 case XML_REGEXP_SEPAR:
2907 ret = xmlUCSIsCatZ(codepoint);
2908 break;
2909 case XML_REGEXP_SEPAR_SPACE:
2910 ret = xmlUCSIsCatZs(codepoint);
2911 break;
2912 case XML_REGEXP_SEPAR_LINE:
2913 ret = xmlUCSIsCatZl(codepoint);
2914 break;
2915 case XML_REGEXP_SEPAR_PARA:
2916 ret = xmlUCSIsCatZp(codepoint);
2917 break;
2918 case XML_REGEXP_SYMBOL:
2919 ret = xmlUCSIsCatS(codepoint);
2920 break;
2921 case XML_REGEXP_SYMBOL_MATH:
2922 ret = xmlUCSIsCatSm(codepoint);
2923 break;
2924 case XML_REGEXP_SYMBOL_CURRENCY:
2925 ret = xmlUCSIsCatSc(codepoint);
2926 break;
2927 case XML_REGEXP_SYMBOL_MODIFIER:
2928 ret = xmlUCSIsCatSk(codepoint);
2929 break;
2930 case XML_REGEXP_SYMBOL_OTHERS:
2931 ret = xmlUCSIsCatSo(codepoint);
2932 break;
2933 case XML_REGEXP_OTHER:
2934 ret = xmlUCSIsCatC(codepoint);
2935 break;
2936 case XML_REGEXP_OTHER_CONTROL:
2937 ret = xmlUCSIsCatCc(codepoint);
2938 break;
2939 case XML_REGEXP_OTHER_FORMAT:
2940 ret = xmlUCSIsCatCf(codepoint);
2941 break;
2942 case XML_REGEXP_OTHER_PRIVATE:
2943 ret = xmlUCSIsCatCo(codepoint);
2944 break;
2945 case XML_REGEXP_OTHER_NA:
2946 /* ret = xmlUCSIsCatCn(codepoint); */
2947 /* Seems it doesn't exist anymore in recent Unicode releases */
2948 ret = 0;
2949 break;
2950 case XML_REGEXP_BLOCK_NAME:
2951 ret = xmlUCSIsBlock(codepoint, (const char *) blockName);
2952 break;
2953 }
2954 if (neg)
2955 return(!ret);
2956 return(ret);
2957}
2958
2959static int
2960xmlRegCheckCharacter(xmlRegAtomPtr atom, int codepoint) {
2961 int i, ret = 0;
2962 xmlRegRangePtr range;
2963
2964 if ((atom == NULL) || (!IS_CHAR(codepoint)))
2965 return(-1);
2966
2967 switch (atom->type) {
2968 case XML_REGEXP_SUBREG:
2969 case XML_REGEXP_EPSILON:
2970 return(-1);
2971 case XML_REGEXP_CHARVAL:
2972 return(codepoint == atom->codepoint);
2973 case XML_REGEXP_RANGES: {
2974 int accept = 0;
2975
2976 for (i = 0;i < atom->nbRanges;i++) {
2977 range = atom->ranges[i];
2978 if (range->neg == 2) {
2979 ret = xmlRegCheckCharacterRange(range->type, codepoint,
2980 0, range->start, range->end,
2981 range->blockName);
2982 if (ret != 0)
2983 return(0); /* excluded char */
2984 } else if (range->neg) {
2985 ret = xmlRegCheckCharacterRange(range->type, codepoint,
2986 0, range->start, range->end,
2987 range->blockName);
2988 if (ret == 0)
2989 accept = 1;
2990 else
2991 return(0);
2992 } else {
2993 ret = xmlRegCheckCharacterRange(range->type, codepoint,
2994 0, range->start, range->end,
2995 range->blockName);
2996 if (ret != 0)
2997 accept = 1; /* might still be excluded */
2998 }
2999 }
3000 return(accept);
3001 }
3002 case XML_REGEXP_STRING:
3003 printf("TODO: XML_REGEXP_STRING\n");
3004 return(-1);
3005 case XML_REGEXP_ANYCHAR:
3006 case XML_REGEXP_ANYSPACE:
3007 case XML_REGEXP_NOTSPACE:
3008 case XML_REGEXP_INITNAME:
3009 case XML_REGEXP_NOTINITNAME:
3010 case XML_REGEXP_NAMECHAR:
3011 case XML_REGEXP_NOTNAMECHAR:
3012 case XML_REGEXP_DECIMAL:
3013 case XML_REGEXP_NOTDECIMAL:
3014 case XML_REGEXP_REALCHAR:
3015 case XML_REGEXP_NOTREALCHAR:
3016 case XML_REGEXP_LETTER:
3017 case XML_REGEXP_LETTER_UPPERCASE:
3018 case XML_REGEXP_LETTER_LOWERCASE:
3019 case XML_REGEXP_LETTER_TITLECASE:
3020 case XML_REGEXP_LETTER_MODIFIER:
3021 case XML_REGEXP_LETTER_OTHERS:
3022 case XML_REGEXP_MARK:
3023 case XML_REGEXP_MARK_NONSPACING:
3024 case XML_REGEXP_MARK_SPACECOMBINING:
3025 case XML_REGEXP_MARK_ENCLOSING:
3026 case XML_REGEXP_NUMBER:
3027 case XML_REGEXP_NUMBER_DECIMAL:
3028 case XML_REGEXP_NUMBER_LETTER:
3029 case XML_REGEXP_NUMBER_OTHERS:
3030 case XML_REGEXP_PUNCT:
3031 case XML_REGEXP_PUNCT_CONNECTOR:
3032 case XML_REGEXP_PUNCT_DASH:
3033 case XML_REGEXP_PUNCT_OPEN:
3034 case XML_REGEXP_PUNCT_CLOSE:
3035 case XML_REGEXP_PUNCT_INITQUOTE:
3036 case XML_REGEXP_PUNCT_FINQUOTE:
3037 case XML_REGEXP_PUNCT_OTHERS:
3038 case XML_REGEXP_SEPAR:
3039 case XML_REGEXP_SEPAR_SPACE:
3040 case XML_REGEXP_SEPAR_LINE:
3041 case XML_REGEXP_SEPAR_PARA:
3042 case XML_REGEXP_SYMBOL:
3043 case XML_REGEXP_SYMBOL_MATH:
3044 case XML_REGEXP_SYMBOL_CURRENCY:
3045 case XML_REGEXP_SYMBOL_MODIFIER:
3046 case XML_REGEXP_SYMBOL_OTHERS:
3047 case XML_REGEXP_OTHER:
3048 case XML_REGEXP_OTHER_CONTROL:
3049 case XML_REGEXP_OTHER_FORMAT:
3050 case XML_REGEXP_OTHER_PRIVATE:
3051 case XML_REGEXP_OTHER_NA:
3052 case XML_REGEXP_BLOCK_NAME:
3053 ret = xmlRegCheckCharacterRange(atom->type, codepoint, 0, 0, 0,
3054 (const xmlChar *)atom->valuep);
3055 if (atom->neg)
3056 ret = !ret;
3057 break;
3058 }
3059 return(ret);
3060}
3061
3062/************************************************************************
3063 * *
3064 * Saving and restoring state of an execution context *
3065 * *
3066 ************************************************************************/
3067
3068#ifdef DEBUG_REGEXP_EXEC
3069static void
3070xmlFARegDebugExec(xmlRegExecCtxtPtr exec) {
3071 printf("state: %d:%d:idx %d", exec->state->no, exec->transno, exec->index);
3072 if (exec->inputStack != NULL) {
3073 int i;
3074 printf(": ");
3075 for (i = 0;(i < 3) && (i < exec->inputStackNr);i++)
3076 printf("%s ", (const char *)
3077 exec->inputStack[exec->inputStackNr - (i + 1)].value);
3078 } else {
3079 printf(": %s", &(exec->inputString[exec->index]));
3080 }
3081 printf("\n");
3082}
3083#endif
3084
3085static void
3086xmlFARegExecSave(xmlRegExecCtxtPtr exec) {
3087#ifdef DEBUG_REGEXP_EXEC
3088 printf("saving ");
3089 exec->transno++;
3090 xmlFARegDebugExec(exec);
3091 exec->transno--;
3092#endif
3093#ifdef MAX_PUSH
3094 if (exec->nbPush > MAX_PUSH) {
3095 return;
3096 }
3097 exec->nbPush++;
3098#endif
3099
3100 if (exec->maxRollbacks == 0) {
3101 exec->maxRollbacks = 4;
3102 exec->rollbacks = (xmlRegExecRollback *) xmlMalloc(exec->maxRollbacks *
3103 sizeof(xmlRegExecRollback));
3104 if (exec->rollbacks == NULL) {
3105 xmlRegexpErrMemory(NULL, "saving regexp");
3106 exec->maxRollbacks = 0;
3107 return;
3108 }
3109 memset(exec->rollbacks, 0,
3110 exec->maxRollbacks * sizeof(xmlRegExecRollback));
3111 } else if (exec->nbRollbacks >= exec->maxRollbacks) {
3112 xmlRegExecRollback *tmp;
3113 int len = exec->maxRollbacks;
3114
3115 exec->maxRollbacks *= 2;
3116 tmp = (xmlRegExecRollback *) xmlRealloc(exec->rollbacks,
3117 exec->maxRollbacks * sizeof(xmlRegExecRollback));
3118 if (tmp == NULL) {
3119 xmlRegexpErrMemory(NULL, "saving regexp");
3120 exec->maxRollbacks /= 2;
3121 return;
3122 }
3123 exec->rollbacks = tmp;
3124 tmp = &exec->rollbacks[len];
3125 memset(tmp, 0, (exec->maxRollbacks - len) * sizeof(xmlRegExecRollback));
3126 }
3127 exec->rollbacks[exec->nbRollbacks].state = exec->state;
3128 exec->rollbacks[exec->nbRollbacks].index = exec->index;
3129 exec->rollbacks[exec->nbRollbacks].nextbranch = exec->transno + 1;
3130 if (exec->comp->nbCounters > 0) {
3131 if (exec->rollbacks[exec->nbRollbacks].counts == NULL) {
3132 exec->rollbacks[exec->nbRollbacks].counts = (int *)
3133 xmlMalloc(exec->comp->nbCounters * sizeof(int));
3134 if (exec->rollbacks[exec->nbRollbacks].counts == NULL) {
3135 xmlRegexpErrMemory(NULL, "saving regexp");
3136 exec->status = -5;
3137 return;
3138 }
3139 }
3140 memcpy(exec->rollbacks[exec->nbRollbacks].counts, exec->counts,
3141 exec->comp->nbCounters * sizeof(int));
3142 }
3143 exec->nbRollbacks++;
3144}
3145
3146static void
3147xmlFARegExecRollBack(xmlRegExecCtxtPtr exec) {
3148 if (exec->nbRollbacks <= 0) {
3149 exec->status = -1;
3150#ifdef DEBUG_REGEXP_EXEC
3151 printf("rollback failed on empty stack\n");
3152#endif
3153 return;
3154 }
3155 exec->nbRollbacks--;
3156 exec->state = exec->rollbacks[exec->nbRollbacks].state;
3157 exec->index = exec->rollbacks[exec->nbRollbacks].index;
3158 exec->transno = exec->rollbacks[exec->nbRollbacks].nextbranch;
3159 if (exec->comp->nbCounters > 0) {
3160 if (exec->rollbacks[exec->nbRollbacks].counts == NULL) {
3161 fprintf(stderr, "exec save: allocation failed");
3162 exec->status = -6;
3163 return;
3164 }
3165 if (exec->counts) {
3166 memcpy(exec->counts, exec->rollbacks[exec->nbRollbacks].counts,
3167 exec->comp->nbCounters * sizeof(int));
3168 }
3169 }
3170
3171#ifdef DEBUG_REGEXP_EXEC
3172 printf("restored ");
3173 xmlFARegDebugExec(exec);
3174#endif
3175}
3176
3177/************************************************************************
3178 * *
3179 * Verifier, running an input against a compiled regexp *
3180 * *
3181 ************************************************************************/
3182
3183static int
3184xmlFARegExec(xmlRegexpPtr comp, const xmlChar *content) {
3185 xmlRegExecCtxt execval;
3186 xmlRegExecCtxtPtr exec = &execval;
3187 int ret, codepoint = 0, len, deter;
3188
3189 exec->inputString = content;
3190 exec->index = 0;
3191 exec->nbPush = 0;
3192 exec->determinist = 1;
3193 exec->maxRollbacks = 0;
3194 exec->nbRollbacks = 0;
3195 exec->rollbacks = NULL;
3196 exec->status = 0;
3197 exec->comp = comp;
3198 exec->state = comp->states[0];
3199 exec->transno = 0;
3200 exec->transcount = 0;
3201 exec->inputStack = NULL;
3202 exec->inputStackMax = 0;
3203 if (comp->nbCounters > 0) {
3204 exec->counts = (int *) xmlMalloc(comp->nbCounters * sizeof(int));
3205 if (exec->counts == NULL) {
3206 xmlRegexpErrMemory(NULL, "running regexp");
3207 return(-1);
3208 }
3209 memset(exec->counts, 0, comp->nbCounters * sizeof(int));
3210 } else
3211 exec->counts = NULL;
3212 while ((exec->status == 0) && (exec->state != NULL) &&
3213 ((exec->inputString[exec->index] != 0) ||
3214 ((exec->state != NULL) &&
3215 (exec->state->type != XML_REGEXP_FINAL_STATE)))) {
3216 xmlRegTransPtr trans;
3217 xmlRegAtomPtr atom;
3218
3219 /*
3220 * If end of input on non-terminal state, rollback, however we may
3221 * still have epsilon like transition for counted transitions
3222 * on counters, in that case don't break too early. Additionally,
3223 * if we are working on a range like "AB{0,2}", where B is not present,
3224 * we don't want to break.
3225 */
3226 len = 1;
3227 if ((exec->inputString[exec->index] == 0) && (exec->counts == NULL)) {
3228 /*
3229 * if there is a transition, we must check if
3230 * atom allows minOccurs of 0
3231 */
3232 if (exec->transno < exec->state->nbTrans) {
3233 trans = &exec->state->trans[exec->transno];
3234 if (trans->to >=0) {
3235 atom = trans->atom;
3236 if (!((atom->min == 0) && (atom->max > 0)))
3237 goto rollback;
3238 }
3239 } else
3240 goto rollback;
3241 }
3242
3243 exec->transcount = 0;
3244 for (;exec->transno < exec->state->nbTrans;exec->transno++) {
3245 trans = &exec->state->trans[exec->transno];
3246 if (trans->to < 0)
3247 continue;
3248 atom = trans->atom;
3249 ret = 0;
3250 deter = 1;
3251 if (trans->count >= 0) {
3252 int count;
3253 xmlRegCounterPtr counter;
3254
3255 if (exec->counts == NULL) {
3256 exec->status = -1;
3257 goto error;
3258 }
3259 /*
3260 * A counted transition.
3261 */
3262
3263 count = exec->counts[trans->count];
3264 counter = &exec->comp->counters[trans->count];
3265#ifdef DEBUG_REGEXP_EXEC
3266 printf("testing count %d: val %d, min %d, max %d\n",
3267 trans->count, count, counter->min, counter->max);
3268#endif
3269 ret = ((count >= counter->min) && (count <= counter->max));
3270 if ((ret) && (counter->min != counter->max))
3271 deter = 0;
3272 } else if (atom == NULL) {
3273 fprintf(stderr, "epsilon transition left at runtime\n");
3274 exec->status = -2;
3275 break;
3276 } else if (exec->inputString[exec->index] != 0) {
3277 codepoint = CUR_SCHAR(&(exec->inputString[exec->index]), len);
3278 ret = xmlRegCheckCharacter(atom, codepoint);
3279 if ((ret == 1) && (atom->min >= 0) && (atom->max > 0)) {
3280 xmlRegStatePtr to = comp->states[trans->to];
3281
3282 /*
3283 * this is a multiple input sequence
3284 * If there is a counter associated increment it now.
3285 * before potentially saving and rollback
3286 * do not increment if the counter is already over the
3287 * maximum limit in which case get to next transition
3288 */
3289 if (trans->counter >= 0) {
3290 xmlRegCounterPtr counter;
3291
3292 if ((exec->counts == NULL) ||
3293 (exec->comp == NULL) ||
3294 (exec->comp->counters == NULL)) {
3295 exec->status = -1;
3296 goto error;
3297 }
3298 counter = &exec->comp->counters[trans->counter];
3299 if (exec->counts[trans->counter] >= counter->max)
3300 continue; /* for loop on transitions */
3301
3302#ifdef DEBUG_REGEXP_EXEC
3303 printf("Increasing count %d\n", trans->counter);
3304#endif
3305 exec->counts[trans->counter]++;
3306 }
3307 if (exec->state->nbTrans > exec->transno + 1) {
3308 xmlFARegExecSave(exec);
3309 }
3310 exec->transcount = 1;
3311 do {
3312 /*
3313 * Try to progress as much as possible on the input
3314 */
3315 if (exec->transcount == atom->max) {
3316 break;
3317 }
3318 exec->index += len;
3319 /*
3320 * End of input: stop here
3321 */
3322 if (exec->inputString[exec->index] == 0) {
3323 exec->index -= len;
3324 break;
3325 }
3326 if (exec->transcount >= atom->min) {
3327 int transno = exec->transno;
3328 xmlRegStatePtr state = exec->state;
3329
3330 /*
3331 * The transition is acceptable save it
3332 */
3333 exec->transno = -1; /* trick */
3334 exec->state = to;
3335 xmlFARegExecSave(exec);
3336 exec->transno = transno;
3337 exec->state = state;
3338 }
3339 codepoint = CUR_SCHAR(&(exec->inputString[exec->index]),
3340 len);
3341 ret = xmlRegCheckCharacter(atom, codepoint);
3342 exec->transcount++;
3343 } while (ret == 1);
3344 if (exec->transcount < atom->min)
3345 ret = 0;
3346
3347 /*
3348 * If the last check failed but one transition was found
3349 * possible, rollback
3350 */
3351 if (ret < 0)
3352 ret = 0;
3353 if (ret == 0) {
3354 goto rollback;
3355 }
3356 if (trans->counter >= 0) {
3357 if (exec->counts == NULL) {
3358 exec->status = -1;
3359 goto error;
3360 }
3361#ifdef DEBUG_REGEXP_EXEC
3362 printf("Decreasing count %d\n", trans->counter);
3363#endif
3364 exec->counts[trans->counter]--;
3365 }
3366 } else if ((ret == 0) && (atom->min == 0) && (atom->max > 0)) {
3367 /*
3368 * we don't match on the codepoint, but minOccurs of 0
3369 * says that's ok. Setting len to 0 inhibits stepping
3370 * over the codepoint.
3371 */
3372 exec->transcount = 1;
3373 len = 0;
3374 ret = 1;
3375 }
3376 } else if ((atom->min == 0) && (atom->max > 0)) {
3377 /* another spot to match when minOccurs is 0 */
3378 exec->transcount = 1;
3379 len = 0;
3380 ret = 1;
3381 }
3382 if (ret == 1) {
3383 if ((trans->nd == 1) ||
3384 ((trans->count >= 0) && (deter == 0) &&
3385 (exec->state->nbTrans > exec->transno + 1))) {
3386#ifdef DEBUG_REGEXP_EXEC
3387 if (trans->nd == 1)
3388 printf("Saving on nd transition atom %d for %c at %d\n",
3389 trans->atom->no, codepoint, exec->index);
3390 else
3391 printf("Saving on counted transition count %d for %c at %d\n",
3392 trans->count, codepoint, exec->index);
3393#endif
3394 xmlFARegExecSave(exec);
3395 }
3396 if (trans->counter >= 0) {
3397 xmlRegCounterPtr counter;
3398
3399 /* make sure we don't go over the counter maximum value */
3400 if ((exec->counts == NULL) ||
3401 (exec->comp == NULL) ||
3402 (exec->comp->counters == NULL)) {
3403 exec->status = -1;
3404 goto error;
3405 }
3406 counter = &exec->comp->counters[trans->counter];
3407 if (exec->counts[trans->counter] >= counter->max)
3408 continue; /* for loop on transitions */
3409#ifdef DEBUG_REGEXP_EXEC
3410 printf("Increasing count %d\n", trans->counter);
3411#endif
3412 exec->counts[trans->counter]++;
3413 }
3414 if ((trans->count >= 0) &&
3415 (trans->count < REGEXP_ALL_COUNTER)) {
3416 if (exec->counts == NULL) {
3417 exec->status = -1;
3418 goto error;
3419 }
3420#ifdef DEBUG_REGEXP_EXEC
3421 printf("resetting count %d on transition\n",
3422 trans->count);
3423#endif
3424 exec->counts[trans->count] = 0;
3425 }
3426#ifdef DEBUG_REGEXP_EXEC
3427 printf("entering state %d\n", trans->to);
3428#endif
3429 exec->state = comp->states[trans->to];
3430 exec->transno = 0;
3431 if (trans->atom != NULL) {
3432 exec->index += len;
3433 }
3434 goto progress;
3435 } else if (ret < 0) {
3436 exec->status = -4;
3437 break;
3438 }
3439 }
3440 if ((exec->transno != 0) || (exec->state->nbTrans == 0)) {
3441rollback:
3442 /*
3443 * Failed to find a way out
3444 */
3445 exec->determinist = 0;
3446#ifdef DEBUG_REGEXP_EXEC
3447 printf("rollback from state %d on %d:%c\n", exec->state->no,
3448 codepoint,codepoint);
3449#endif
3450 xmlFARegExecRollBack(exec);
3451 }
3452progress:
3453 continue;
3454 }
3455error:
3456 if (exec->rollbacks != NULL) {
3457 if (exec->counts != NULL) {
3458 int i;
3459
3460 for (i = 0;i < exec->maxRollbacks;i++)
3461 if (exec->rollbacks[i].counts != NULL)
3462 xmlFree(exec->rollbacks[i].counts);
3463 }
3464 xmlFree(exec->rollbacks);
3465 }
3466 if (exec->state == NULL)
3467 return(-1);
3468 if (exec->counts != NULL)
3469 xmlFree(exec->counts);
3470 if (exec->status == 0)
3471 return(1);
3472 if (exec->status == -1) {
3473 if (exec->nbPush > MAX_PUSH)
3474 return(-1);
3475 return(0);
3476 }
3477 return(exec->status);
3478}
3479
3480/************************************************************************
3481 * *
3482 * Progressive interface to the verifier one atom at a time *
3483 * *
3484 ************************************************************************/
3485#ifdef DEBUG_ERR
3486static void testerr(xmlRegExecCtxtPtr exec);
3487#endif
3488
3489/**
3490 * xmlRegNewExecCtxt:
3491 * @comp: a precompiled regular expression
3492 * @callback: a callback function used for handling progresses in the
3493 * automata matching phase
3494 * @data: the context data associated to the callback in this context
3495 *
3496 * Build a context used for progressive evaluation of a regexp.
3497 *
3498 * Returns the new context
3499 */
3500xmlRegExecCtxtPtr
3501xmlRegNewExecCtxt(xmlRegexpPtr comp, xmlRegExecCallbacks callback, void *data) {
3502 xmlRegExecCtxtPtr exec;
3503
3504 if (comp == NULL)
3505 return(NULL);
3506 if ((comp->compact == NULL) && (comp->states == NULL))
3507 return(NULL);
3508 exec = (xmlRegExecCtxtPtr) xmlMalloc(sizeof(xmlRegExecCtxt));
3509 if (exec == NULL) {
3510 xmlRegexpErrMemory(NULL, "creating execution context");
3511 return(NULL);
3512 }
3513 memset(exec, 0, sizeof(xmlRegExecCtxt));
3514 exec->inputString = NULL;
3515 exec->index = 0;
3516 exec->determinist = 1;
3517 exec->maxRollbacks = 0;
3518 exec->nbRollbacks = 0;
3519 exec->rollbacks = NULL;
3520 exec->status = 0;
3521 exec->comp = comp;
3522 if (comp->compact == NULL)
3523 exec->state = comp->states[0];
3524 exec->transno = 0;
3525 exec->transcount = 0;
3526 exec->callback = callback;
3527 exec->data = data;
3528 if (comp->nbCounters > 0) {
3529 /*
3530 * For error handling, exec->counts is allocated twice the size
3531 * the second half is used to store the data in case of rollback
3532 */
3533 exec->counts = (int *) xmlMalloc(comp->nbCounters * sizeof(int)
3534 * 2);
3535 if (exec->counts == NULL) {
3536 xmlRegexpErrMemory(NULL, "creating execution context");
3537 xmlFree(exec);
3538 return(NULL);
3539 }
3540 memset(exec->counts, 0, comp->nbCounters * sizeof(int) * 2);
3541 exec->errCounts = &exec->counts[comp->nbCounters];
3542 } else {
3543 exec->counts = NULL;
3544 exec->errCounts = NULL;
3545 }
3546 exec->inputStackMax = 0;
3547 exec->inputStackNr = 0;
3548 exec->inputStack = NULL;
3549 exec->errStateNo = -1;
3550 exec->errString = NULL;
3551 exec->nbPush = 0;
3552 return(exec);
3553}
3554
3555/**
3556 * xmlRegFreeExecCtxt:
3557 * @exec: a regular expression evaulation context
3558 *
3559 * Free the structures associated to a regular expression evaulation context.
3560 */
3561void
3562xmlRegFreeExecCtxt(xmlRegExecCtxtPtr exec) {
3563 if (exec == NULL)
3564 return;
3565
3566 if (exec->rollbacks != NULL) {
3567 if (exec->counts != NULL) {
3568 int i;
3569
3570 for (i = 0;i < exec->maxRollbacks;i++)
3571 if (exec->rollbacks[i].counts != NULL)
3572 xmlFree(exec->rollbacks[i].counts);
3573 }
3574 xmlFree(exec->rollbacks);
3575 }
3576 if (exec->counts != NULL)
3577 xmlFree(exec->counts);
3578 if (exec->inputStack != NULL) {
3579 int i;
3580
3581 for (i = 0;i < exec->inputStackNr;i++) {
3582 if (exec->inputStack[i].value != NULL)
3583 xmlFree(exec->inputStack[i].value);
3584 }
3585 xmlFree(exec->inputStack);
3586 }
3587 if (exec->errString != NULL)
3588 xmlFree(exec->errString);
3589 xmlFree(exec);
3590}
3591
3592static void
3593xmlFARegExecSaveInputString(xmlRegExecCtxtPtr exec, const xmlChar *value,
3594 void *data) {
3595#ifdef DEBUG_PUSH
3596 printf("saving value: %d:%s\n", exec->inputStackNr, value);
3597#endif
3598 if (exec->inputStackMax == 0) {
3599 exec->inputStackMax = 4;
3600 exec->inputStack = (xmlRegInputTokenPtr)
3601 xmlMalloc(exec->inputStackMax * sizeof(xmlRegInputToken));
3602 if (exec->inputStack == NULL) {
3603 xmlRegexpErrMemory(NULL, "pushing input string");
3604 exec->inputStackMax = 0;
3605 return;
3606 }
3607 } else if (exec->inputStackNr + 1 >= exec->inputStackMax) {
3608 xmlRegInputTokenPtr tmp;
3609
3610 exec->inputStackMax *= 2;
3611 tmp = (xmlRegInputTokenPtr) xmlRealloc(exec->inputStack,
3612 exec->inputStackMax * sizeof(xmlRegInputToken));
3613 if (tmp == NULL) {
3614 xmlRegexpErrMemory(NULL, "pushing input string");
3615 exec->inputStackMax /= 2;
3616 return;
3617 }
3618 exec->inputStack = tmp;
3619 }
3620 exec->inputStack[exec->inputStackNr].value = xmlStrdup(value);
3621 exec->inputStack[exec->inputStackNr].data = data;
3622 exec->inputStackNr++;
3623 exec->inputStack[exec->inputStackNr].value = NULL;
3624 exec->inputStack[exec->inputStackNr].data = NULL;
3625}
3626
3627/**
3628 * xmlRegStrEqualWildcard:
3629 * @expStr: the string to be evaluated
3630 * @valStr: the validation string
3631 *
3632 * Checks if both strings are equal or have the same content. "*"
3633 * can be used as a wildcard in @valStr; "|" is used as a seperator of
3634 * substrings in both @expStr and @valStr.
3635 *
3636 * Returns 1 if the comparison is satisfied and the number of substrings
3637 * is equal, 0 otherwise.
3638 */
3639
3640static int
3641xmlRegStrEqualWildcard(const xmlChar *expStr, const xmlChar *valStr) {
3642 if (expStr == valStr) return(1);
3643 if (expStr == NULL) return(0);
3644 if (valStr == NULL) return(0);
3645 do {
3646 /*
3647 * Eval if we have a wildcard for the current item.
3648 */
3649 if (*expStr != *valStr) {
3650 /* if one of them starts with a wildcard make valStr be it */
3651 if (*valStr == '*') {
3652 const xmlChar *tmp;
3653
3654 tmp = valStr;
3655 valStr = expStr;
3656 expStr = tmp;
3657 }
3658 if ((*valStr != 0) && (*expStr != 0) && (*expStr++ == '*')) {
3659 do {
3660 if (*valStr == XML_REG_STRING_SEPARATOR)
3661 break;
3662 valStr++;
3663 } while (*valStr != 0);
3664 continue;
3665 } else
3666 return(0);
3667 }
3668 expStr++;
3669 valStr++;
3670 } while (*valStr != 0);
3671 if (*expStr != 0)
3672 return (0);
3673 else
3674 return (1);
3675}
3676
3677/**
3678 * xmlRegCompactPushString:
3679 * @exec: a regexp execution context
3680 * @comp: the precompiled exec with a compact table
3681 * @value: a string token input
3682 * @data: data associated to the token to reuse in callbacks
3683 *
3684 * Push one input token in the execution context
3685 *
3686 * Returns: 1 if the regexp reached a final state, 0 if non-final, and
3687 * a negative value in case of error.
3688 */
3689static int
3690xmlRegCompactPushString(xmlRegExecCtxtPtr exec,
3691 xmlRegexpPtr comp,
3692 const xmlChar *value,
3693 void *data) {
3694 int state = exec->index;
3695 int i, target;
3696
3697 if ((comp == NULL) || (comp->compact == NULL) || (comp->stringMap == NULL))
3698 return(-1);
3699
3700 if (value == NULL) {
3701 /*
3702 * are we at a final state ?
3703 */
3704 if (comp->compact[state * (comp->nbstrings + 1)] ==
3705 XML_REGEXP_FINAL_STATE)
3706 return(1);
3707 return(0);
3708 }
3709
3710#ifdef DEBUG_PUSH
3711 printf("value pushed: %s\n", value);
3712#endif
3713
3714 /*
3715 * Examine all outside transitions from current state
3716 */
3717 for (i = 0;i < comp->nbstrings;i++) {
3718 target = comp->compact[state * (comp->nbstrings + 1) + i + 1];
3719 if ((target > 0) && (target <= comp->nbstates)) {
3720 target--; /* to avoid 0 */
3721 if (xmlRegStrEqualWildcard(comp->stringMap[i], value)) {
3722 exec->index = target;
3723 if ((exec->callback != NULL) && (comp->transdata != NULL)) {
3724 exec->callback(exec->data, value,
3725 comp->transdata[state * comp->nbstrings + i], data);
3726 }
3727#ifdef DEBUG_PUSH
3728 printf("entering state %d\n", target);
3729#endif
3730 if (comp->compact[target * (comp->nbstrings + 1)] ==
3731 XML_REGEXP_SINK_STATE)
3732 goto error;
3733
3734 if (comp->compact[target * (comp->nbstrings + 1)] ==
3735 XML_REGEXP_FINAL_STATE)
3736 return(1);
3737 return(0);
3738 }
3739 }
3740 }
3741 /*
3742 * Failed to find an exit transition out from current state for the
3743 * current token
3744 */
3745#ifdef DEBUG_PUSH
3746 printf("failed to find a transition for %s on state %d\n", value, state);
3747#endif
3748error:
3749 if (exec->errString != NULL)
3750 xmlFree(exec->errString);
3751 exec->errString = xmlStrdup(value);
3752 exec->errStateNo = state;
3753 exec->status = -1;
3754#ifdef DEBUG_ERR
3755 testerr(exec);
3756#endif
3757 return(-1);
3758}
3759
3760/**
3761 * xmlRegExecPushStringInternal:
3762 * @exec: a regexp execution context or NULL to indicate the end
3763 * @value: a string token input
3764 * @data: data associated to the token to reuse in callbacks
3765 * @compound: value was assembled from 2 strings
3766 *
3767 * Push one input token in the execution context
3768 *
3769 * Returns: 1 if the regexp reached a final state, 0 if non-final, and
3770 * a negative value in case of error.
3771 */
3772static int
3773xmlRegExecPushStringInternal(xmlRegExecCtxtPtr exec, const xmlChar *value,
3774 void *data, int compound) {
3775 xmlRegTransPtr trans;
3776 xmlRegAtomPtr atom;
3777 int ret;
3778 int final = 0;
3779 int progress = 1;
3780
3781 if (exec == NULL)
3782 return(-1);
3783 if (exec->comp == NULL)
3784 return(-1);
3785 if (exec->status != 0)
3786 return(exec->status);
3787
3788 if (exec->comp->compact != NULL)
3789 return(xmlRegCompactPushString(exec, exec->comp, value, data));
3790
3791 if (value == NULL) {
3792 if (exec->state->type == XML_REGEXP_FINAL_STATE)
3793 return(1);
3794 final = 1;
3795 }
3796
3797#ifdef DEBUG_PUSH
3798 printf("value pushed: %s\n", value);
3799#endif
3800 /*
3801 * If we have an active rollback stack push the new value there
3802 * and get back to where we were left
3803 */
3804 if ((value != NULL) && (exec->inputStackNr > 0)) {
3805 xmlFARegExecSaveInputString(exec, value, data);
3806 value = exec->inputStack[exec->index].value;
3807 data = exec->inputStack[exec->index].data;
3808#ifdef DEBUG_PUSH
3809 printf("value loaded: %s\n", value);
3810#endif
3811 }
3812
3813 while ((exec->status == 0) &&
3814 ((value != NULL) ||
3815 ((final == 1) &&
3816 (exec->state->type != XML_REGEXP_FINAL_STATE)))) {
3817
3818 /*
3819 * End of input on non-terminal state, rollback, however we may
3820 * still have epsilon like transition for counted transitions
3821 * on counters, in that case don't break too early.
3822 */
3823 if ((value == NULL) && (exec->counts == NULL))
3824 goto rollback;
3825
3826 exec->transcount = 0;
3827 for (;exec->transno < exec->state->nbTrans;exec->transno++) {
3828 trans = &exec->state->trans[exec->transno];
3829 if (trans->to < 0)
3830 continue;
3831 atom = trans->atom;
3832 ret = 0;
3833 if (trans->count == REGEXP_ALL_LAX_COUNTER) {
3834 int i;
3835 int count;
3836 xmlRegTransPtr t;
3837 xmlRegCounterPtr counter;
3838
3839 ret = 0;
3840
3841#ifdef DEBUG_PUSH
3842 printf("testing all lax %d\n", trans->count);
3843#endif
3844 /*
3845 * Check all counted transitions from the current state
3846 */
3847 if ((value == NULL) && (final)) {
3848 ret = 1;
3849 } else if (value != NULL) {
3850 for (i = 0;i < exec->state->nbTrans;i++) {
3851 t = &exec->state->trans[i];
3852 if ((t->counter < 0) || (t == trans))
3853 continue;
3854 counter = &exec->comp->counters[t->counter];
3855 count = exec->counts[t->counter];
3856 if ((count < counter->max) &&
3857 (t->atom != NULL) &&
3858 (xmlStrEqual(value, t->atom->valuep))) {
3859 ret = 0;
3860 break;
3861 }
3862 if ((count >= counter->min) &&
3863 (count < counter->max) &&
3864 (t->atom != NULL) &&
3865 (xmlStrEqual(value, t->atom->valuep))) {
3866 ret = 1;
3867 break;
3868 }
3869 }
3870 }
3871 } else if (trans->count == REGEXP_ALL_COUNTER) {
3872 int i;
3873 int count;
3874 xmlRegTransPtr t;
3875 xmlRegCounterPtr counter;
3876
3877 ret = 1;
3878
3879#ifdef DEBUG_PUSH
3880 printf("testing all %d\n", trans->count);
3881#endif
3882 /*
3883 * Check all counted transitions from the current state
3884 */
3885 for (i = 0;i < exec->state->nbTrans;i++) {
3886 t = &exec->state->trans[i];
3887 if ((t->counter < 0) || (t == trans))
3888 continue;
3889 counter = &exec->comp->counters[t->counter];
3890 count = exec->counts[t->counter];
3891 if ((count < counter->min) || (count > counter->max)) {
3892 ret = 0;
3893 break;
3894 }
3895 }
3896 } else if (trans->count >= 0) {
3897 int count;
3898 xmlRegCounterPtr counter;
3899
3900 /*
3901 * A counted transition.
3902 */
3903
3904 count = exec->counts[trans->count];
3905 counter = &exec->comp->counters[trans->count];
3906#ifdef DEBUG_PUSH
3907 printf("testing count %d: val %d, min %d, max %d\n",
3908 trans->count, count, counter->min, counter->max);
3909#endif
3910 ret = ((count >= counter->min) && (count <= counter->max));
3911 } else if (atom == NULL) {
3912 fprintf(stderr, "epsilon transition left at runtime\n");
3913 exec->status = -2;
3914 break;
3915 } else if (value != NULL) {
3916 ret = xmlRegStrEqualWildcard(atom->valuep, value);
3917 if (atom->neg) {
3918 ret = !ret;
3919 if (!compound)
3920 ret = 0;
3921 }
3922 if ((ret == 1) && (trans->counter >= 0)) {
3923 xmlRegCounterPtr counter;
3924 int count;
3925
3926 count = exec->counts[trans->counter];
3927 counter = &exec->comp->counters[trans->counter];
3928 if (count >= counter->max)
3929 ret = 0;
3930 }
3931
3932 if ((ret == 1) && (atom->min > 0) && (atom->max > 0)) {
3933 xmlRegStatePtr to = exec->comp->states[trans->to];
3934
3935 /*
3936 * this is a multiple input sequence
3937 */
3938 if (exec->state->nbTrans > exec->transno + 1) {
3939 if (exec->inputStackNr <= 0) {
3940 xmlFARegExecSaveInputString(exec, value, data);
3941 }
3942 xmlFARegExecSave(exec);
3943 }
3944 exec->transcount = 1;
3945 do {
3946 /*
3947 * Try to progress as much as possible on the input
3948 */
3949 if (exec->transcount == atom->max) {
3950 break;
3951 }
3952 exec->index++;
3953 value = exec->inputStack[exec->index].value;
3954 data = exec->inputStack[exec->index].data;
3955#ifdef DEBUG_PUSH
3956 printf("value loaded: %s\n", value);
3957#endif
3958
3959 /*
3960 * End of input: stop here
3961 */
3962 if (value == NULL) {
3963 exec->index --;
3964 break;
3965 }
3966 if (exec->transcount >= atom->min) {
3967 int transno = exec->transno;
3968 xmlRegStatePtr state = exec->state;
3969
3970 /*
3971 * The transition is acceptable save it
3972 */
3973 exec->transno = -1; /* trick */
3974 exec->state = to;
3975 if (exec->inputStackNr <= 0) {
3976 xmlFARegExecSaveInputString(exec, value, data);
3977 }
3978 xmlFARegExecSave(exec);
3979 exec->transno = transno;
3980 exec->state = state;
3981 }
3982 ret = xmlStrEqual(value, atom->valuep);
3983 exec->transcount++;
3984 } while (ret == 1);
3985 if (exec->transcount < atom->min)
3986 ret = 0;
3987
3988 /*
3989 * If the last check failed but one transition was found
3990 * possible, rollback
3991 */
3992 if (ret < 0)
3993 ret = 0;
3994 if (ret == 0) {
3995 goto rollback;
3996 }
3997 }
3998 }
3999 if (ret == 1) {
4000 if ((exec->callback != NULL) && (atom != NULL) &&
4001 (data != NULL)) {
4002 exec->callback(exec->data, atom->valuep,
4003 atom->data, data);
4004 }
4005 if (exec->state->nbTrans > exec->transno + 1) {
4006 if (exec->inputStackNr <= 0) {
4007 xmlFARegExecSaveInputString(exec, value, data);
4008 }
4009 xmlFARegExecSave(exec);
4010 }
4011 if (trans->counter >= 0) {
4012#ifdef DEBUG_PUSH
4013 printf("Increasing count %d\n", trans->counter);
4014#endif
4015 exec->counts[trans->counter]++;
4016 }
4017 if ((trans->count >= 0) &&
4018 (trans->count < REGEXP_ALL_COUNTER)) {
4019#ifdef DEBUG_REGEXP_EXEC
4020 printf("resetting count %d on transition\n",
4021 trans->count);
4022#endif
4023 exec->counts[trans->count] = 0;
4024 }
4025#ifdef DEBUG_PUSH
4026 printf("entering state %d\n", trans->to);
4027#endif
4028 if ((exec->comp->states[trans->to] != NULL) &&
4029 (exec->comp->states[trans->to]->type ==
4030 XML_REGEXP_SINK_STATE)) {
4031 /*
4032 * entering a sink state, save the current state as error
4033 * state.
4034 */
4035 if (exec->errString != NULL)
4036 xmlFree(exec->errString);
4037 exec->errString = xmlStrdup(value);
4038 exec->errState = exec->state;
4039 memcpy(exec->errCounts, exec->counts,
4040 exec->comp->nbCounters * sizeof(int));
4041 }
4042 exec->state = exec->comp->states[trans->to];
4043 exec->transno = 0;
4044 if (trans->atom != NULL) {
4045 if (exec->inputStack != NULL) {
4046 exec->index++;
4047 if (exec->index < exec->inputStackNr) {
4048 value = exec->inputStack[exec->index].value;
4049 data = exec->inputStack[exec->index].data;
4050#ifdef DEBUG_PUSH
4051 printf("value loaded: %s\n", value);
4052#endif
4053 } else {
4054 value = NULL;
4055 data = NULL;
4056#ifdef DEBUG_PUSH
4057 printf("end of input\n");
4058#endif
4059 }
4060 } else {
4061 value = NULL;
4062 data = NULL;
4063#ifdef DEBUG_PUSH
4064 printf("end of input\n");
4065#endif
4066 }
4067 }
4068 goto progress;
4069 } else if (ret < 0) {
4070 exec->status = -4;
4071 break;
4072 }
4073 }
4074 if ((exec->transno != 0) || (exec->state->nbTrans == 0)) {
4075rollback:
4076 /*
4077 * if we didn't yet rollback on the current input
4078 * store the current state as the error state.
4079 */
4080 if ((progress) && (exec->state != NULL) &&
4081 (exec->state->type != XML_REGEXP_SINK_STATE)) {
4082 progress = 0;
4083 if (exec->errString != NULL)
4084 xmlFree(exec->errString);
4085 exec->errString = xmlStrdup(value);
4086 exec->errState = exec->state;
4087 memcpy(exec->errCounts, exec->counts,
4088 exec->comp->nbCounters * sizeof(int));
4089 }
4090
4091 /*
4092 * Failed to find a way out
4093 */
4094 exec->determinist = 0;
4095 xmlFARegExecRollBack(exec);
4096 if ((exec->inputStack != NULL ) && (exec->status == 0)) {
4097 value = exec->inputStack[exec->index].value;
4098 data = exec->inputStack[exec->index].data;
4099#ifdef DEBUG_PUSH
4100 printf("value loaded: %s\n", value);
4101#endif
4102 }
4103 }
4104 continue;
4105progress:
4106 progress = 1;
4107 continue;
4108 }
4109 if (exec->status == 0) {
4110 return(exec->state->type == XML_REGEXP_FINAL_STATE);
4111 }
4112#ifdef DEBUG_ERR
4113 if (exec->status < 0) {
4114 testerr(exec);
4115 }
4116#endif
4117 return(exec->status);
4118}
4119
4120/**
4121 * xmlRegExecPushString:
4122 * @exec: a regexp execution context or NULL to indicate the end
4123 * @value: a string token input
4124 * @data: data associated to the token to reuse in callbacks
4125 *
4126 * Push one input token in the execution context
4127 *
4128 * Returns: 1 if the regexp reached a final state, 0 if non-final, and
4129 * a negative value in case of error.
4130 */
4131int
4132xmlRegExecPushString(xmlRegExecCtxtPtr exec, const xmlChar *value,
4133 void *data) {
4134 return(xmlRegExecPushStringInternal(exec, value, data, 0));
4135}
4136
4137/**
4138 * xmlRegExecPushString2:
4139 * @exec: a regexp execution context or NULL to indicate the end
4140 * @value: the first string token input
4141 * @value2: the second string token input
4142 * @data: data associated to the token to reuse in callbacks
4143 *
4144 * Push one input token in the execution context
4145 *
4146 * Returns: 1 if the regexp reached a final state, 0 if non-final, and
4147 * a negative value in case of error.
4148 */
4149int
4150xmlRegExecPushString2(xmlRegExecCtxtPtr exec, const xmlChar *value,
4151 const xmlChar *value2, void *data) {
4152 xmlChar buf[150];
4153 int lenn, lenp, ret;
4154 xmlChar *str;
4155
4156 if (exec == NULL)
4157 return(-1);
4158 if (exec->comp == NULL)
4159 return(-1);
4160 if (exec->status != 0)
4161 return(exec->status);
4162
4163 if (value2 == NULL)
4164 return(xmlRegExecPushString(exec, value, data));
4165
4166 lenn = strlen((char *) value2);
4167 lenp = strlen((char *) value);
4168
4169 if (150 < lenn + lenp + 2) {
4170 str = (xmlChar *) xmlMallocAtomic(lenn + lenp + 2);
4171 if (str == NULL) {
4172 exec->status = -1;
4173 return(-1);
4174 }
4175 } else {
4176 str = buf;
4177 }
4178 memcpy(&str[0], value, lenp);
4179 str[lenp] = XML_REG_STRING_SEPARATOR;
4180 memcpy(&str[lenp + 1], value2, lenn);
4181 str[lenn + lenp + 1] = 0;
4182
4183 if (exec->comp->compact != NULL)
4184 ret = xmlRegCompactPushString(exec, exec->comp, str, data);
4185 else
4186 ret = xmlRegExecPushStringInternal(exec, str, data, 1);
4187
4188 if (str != buf)
4189 xmlFree(str);
4190 return(ret);
4191}
4192
4193/**
4194 * xmlRegExecGetValues:
4195 * @exec: a regexp execution context
4196 * @err: error extraction or normal one
4197 * @nbval: pointer to the number of accepted values IN/OUT
4198 * @nbneg: return number of negative transitions
4199 * @values: pointer to the array of acceptable values
4200 * @terminal: return value if this was a terminal state
4201 *
4202 * Extract informations from the regexp execution, internal routine to
4203 * implement xmlRegExecNextValues() and xmlRegExecErrInfo()
4204 *
4205 * Returns: 0 in case of success or -1 in case of error.
4206 */
4207static int
4208xmlRegExecGetValues(xmlRegExecCtxtPtr exec, int err,
4209 int *nbval, int *nbneg,
4210 xmlChar **values, int *terminal) {
4211 int maxval;
4212 int nb = 0;
4213
4214 if ((exec == NULL) || (nbval == NULL) || (nbneg == NULL) ||
4215 (values == NULL) || (*nbval <= 0))
4216 return(-1);
4217
4218 maxval = *nbval;
4219 *nbval = 0;
4220 *nbneg = 0;
4221 if ((exec->comp != NULL) && (exec->comp->compact != NULL)) {
4222 xmlRegexpPtr comp;
4223 int target, i, state;
4224
4225 comp = exec->comp;
4226
4227 if (err) {
4228 if (exec->errStateNo == -1) return(-1);
4229 state = exec->errStateNo;
4230 } else {
4231 state = exec->index;
4232 }
4233 if (terminal != NULL) {
4234 if (comp->compact[state * (comp->nbstrings + 1)] ==
4235 XML_REGEXP_FINAL_STATE)
4236 *terminal = 1;
4237 else
4238 *terminal = 0;
4239 }
4240 for (i = 0;(i < comp->nbstrings) && (nb < maxval);i++) {
4241 target = comp->compact[state * (comp->nbstrings + 1) + i + 1];
4242 if ((target > 0) && (target <= comp->nbstates) &&
4243 (comp->compact[(target - 1) * (comp->nbstrings + 1)] !=
4244 XML_REGEXP_SINK_STATE)) {
4245 values[nb++] = comp->stringMap[i];
4246 (*nbval)++;
4247 }
4248 }
4249 for (i = 0;(i < comp->nbstrings) && (nb < maxval);i++) {
4250 target = comp->compact[state * (comp->nbstrings + 1) + i + 1];
4251 if ((target > 0) && (target <= comp->nbstates) &&
4252 (comp->compact[(target - 1) * (comp->nbstrings + 1)] ==
4253 XML_REGEXP_SINK_STATE)) {
4254 values[nb++] = comp->stringMap[i];
4255 (*nbneg)++;
4256 }
4257 }
4258 } else {
4259 int transno;
4260 xmlRegTransPtr trans;
4261 xmlRegAtomPtr atom;
4262 xmlRegStatePtr state;
4263
4264 if (terminal != NULL) {
4265 if (exec->state->type == XML_REGEXP_FINAL_STATE)
4266 *terminal = 1;
4267 else
4268 *terminal = 0;
4269 }
4270
4271 if (err) {
4272 if (exec->errState == NULL) return(-1);
4273 state = exec->errState;
4274 } else {
4275 if (exec->state == NULL) return(-1);
4276 state = exec->state;
4277 }
4278 for (transno = 0;
4279 (transno < state->nbTrans) && (nb < maxval);
4280 transno++) {
4281 trans = &state->trans[transno];
4282 if (trans->to < 0)
4283 continue;
4284 atom = trans->atom;
4285 if ((atom == NULL) || (atom->valuep == NULL))
4286 continue;
4287 if (trans->count == REGEXP_ALL_LAX_COUNTER) {
4288 /* this should not be reached but ... */
4289 TODO;
4290 } else if (trans->count == REGEXP_ALL_COUNTER) {
4291 /* this should not be reached but ... */
4292 TODO;
4293 } else if (trans->counter >= 0) {
4294 xmlRegCounterPtr counter = NULL;
4295 int count;
4296
4297 if (err)
4298 count = exec->errCounts[trans->counter];
4299 else
4300 count = exec->counts[trans->counter];
4301 if (exec->comp != NULL)
4302 counter = &exec->comp->counters[trans->counter];
4303 if ((counter == NULL) || (count < counter->max)) {
4304 if (atom->neg)
4305 values[nb++] = (xmlChar *) atom->valuep2;
4306 else
4307 values[nb++] = (xmlChar *) atom->valuep;
4308 (*nbval)++;
4309 }
4310 } else {
4311 if ((exec->comp != NULL) && (exec->comp->states[trans->to] != NULL) &&
4312 (exec->comp->states[trans->to]->type !=
4313 XML_REGEXP_SINK_STATE)) {
4314 if (atom->neg)
4315 values[nb++] = (xmlChar *) atom->valuep2;
4316 else
4317 values[nb++] = (xmlChar *) atom->valuep;
4318 (*nbval)++;
4319 }
4320 }
4321 }
4322 for (transno = 0;
4323 (transno < state->nbTrans) && (nb < maxval);
4324 transno++) {
4325 trans = &state->trans[transno];
4326 if (trans->to < 0)
4327 continue;
4328 atom = trans->atom;
4329 if ((atom == NULL) || (atom->valuep == NULL))
4330 continue;
4331 if (trans->count == REGEXP_ALL_LAX_COUNTER) {
4332 continue;
4333 } else if (trans->count == REGEXP_ALL_COUNTER) {
4334 continue;
4335 } else if (trans->counter >= 0) {
4336 continue;
4337 } else {
4338 if ((exec->comp->states[trans->to] != NULL) &&
4339 (exec->comp->states[trans->to]->type ==
4340 XML_REGEXP_SINK_STATE)) {
4341 if (atom->neg)
4342 values[nb++] = (xmlChar *) atom->valuep2;
4343 else
4344 values[nb++] = (xmlChar *) atom->valuep;
4345 (*nbneg)++;
4346 }
4347 }
4348 }
4349 }
4350 return(0);
4351}
4352
4353/**
4354 * xmlRegExecNextValues:
4355 * @exec: a regexp execution context
4356 * @nbval: pointer to the number of accepted values IN/OUT
4357 * @nbneg: return number of negative transitions
4358 * @values: pointer to the array of acceptable values
4359 * @terminal: return value if this was a terminal state
4360 *
4361 * Extract informations from the regexp execution,
4362 * the parameter @values must point to an array of @nbval string pointers
4363 * on return nbval will contain the number of possible strings in that
4364 * state and the @values array will be updated with them. The string values
4365 * returned will be freed with the @exec context and don't need to be
4366 * deallocated.
4367 *
4368 * Returns: 0 in case of success or -1 in case of error.
4369 */
4370int
4371xmlRegExecNextValues(xmlRegExecCtxtPtr exec, int *nbval, int *nbneg,
4372 xmlChar **values, int *terminal) {
4373 return(xmlRegExecGetValues(exec, 0, nbval, nbneg, values, terminal));
4374}
4375
4376/**
4377 * xmlRegExecErrInfo:
4378 * @exec: a regexp execution context generating an error
4379 * @string: return value for the error string
4380 * @nbval: pointer to the number of accepted values IN/OUT
4381 * @nbneg: return number of negative transitions
4382 * @values: pointer to the array of acceptable values
4383 * @terminal: return value if this was a terminal state
4384 *
4385 * Extract error informations from the regexp execution, the parameter
4386 * @string will be updated with the value pushed and not accepted,
4387 * the parameter @values must point to an array of @nbval string pointers
4388 * on return nbval will contain the number of possible strings in that
4389 * state and the @values array will be updated with them. The string values
4390 * returned will be freed with the @exec context and don't need to be
4391 * deallocated.
4392 *
4393 * Returns: 0 in case of success or -1 in case of error.
4394 */
4395int
4396xmlRegExecErrInfo(xmlRegExecCtxtPtr exec, const xmlChar **string,
4397 int *nbval, int *nbneg, xmlChar **values, int *terminal) {
4398 if (exec == NULL)
4399 return(-1);
4400 if (string != NULL) {
4401 if (exec->status != 0)
4402 *string = exec->errString;
4403 else
4404 *string = NULL;
4405 }
4406 return(xmlRegExecGetValues(exec, 1, nbval, nbneg, values, terminal));
4407}
4408
4409#ifdef DEBUG_ERR
4410static void testerr(xmlRegExecCtxtPtr exec) {
4411 const xmlChar *string;
4412 xmlChar *values[5];
4413 int nb = 5;
4414 int nbneg;
4415 int terminal;
4416 xmlRegExecErrInfo(exec, &string, &nb, &nbneg, &values[0], &terminal);
4417}
4418#endif
4419
4420#if 0
4421static int
4422xmlRegExecPushChar(xmlRegExecCtxtPtr exec, int UCS) {
4423 xmlRegTransPtr trans;
4424 xmlRegAtomPtr atom;
4425 int ret;
4426 int codepoint, len;
4427
4428 if (exec == NULL)
4429 return(-1);
4430 if (exec->status != 0)
4431 return(exec->status);
4432
4433 while ((exec->status == 0) &&
4434 ((exec->inputString[exec->index] != 0) ||
4435 (exec->state->type != XML_REGEXP_FINAL_STATE))) {
4436
4437 /*
4438 * End of input on non-terminal state, rollback, however we may
4439 * still have epsilon like transition for counted transitions
4440 * on counters, in that case don't break too early.
4441 */
4442 if ((exec->inputString[exec->index] == 0) && (exec->counts == NULL))
4443 goto rollback;
4444
4445 exec->transcount = 0;
4446 for (;exec->transno < exec->state->nbTrans;exec->transno++) {
4447 trans = &exec->state->trans[exec->transno];
4448 if (trans->to < 0)
4449 continue;
4450 atom = trans->atom;
4451 ret = 0;
4452 if (trans->count >= 0) {
4453 int count;
4454 xmlRegCounterPtr counter;
4455
4456 /*
4457 * A counted transition.
4458 */
4459
4460 count = exec->counts[trans->count];
4461 counter = &exec->comp->counters[trans->count];
4462#ifdef DEBUG_REGEXP_EXEC
4463 printf("testing count %d: val %d, min %d, max %d\n",
4464 trans->count, count, counter->min, counter->max);
4465#endif
4466 ret = ((count >= counter->min) && (count <= counter->max));
4467 } else if (atom == NULL) {
4468 fprintf(stderr, "epsilon transition left at runtime\n");
4469 exec->status = -2;
4470 break;
4471 } else if (exec->inputString[exec->index] != 0) {
4472 codepoint = CUR_SCHAR(&(exec->inputString[exec->index]), len);
4473 ret = xmlRegCheckCharacter(atom, codepoint);
4474 if ((ret == 1) && (atom->min > 0) && (atom->max > 0)) {
4475 xmlRegStatePtr to = exec->comp->states[trans->to];
4476
4477 /*
4478 * this is a multiple input sequence
4479 */
4480 if (exec->state->nbTrans > exec->transno + 1) {
4481 xmlFARegExecSave(exec);
4482 }
4483 exec->transcount = 1;
4484 do {
4485 /*
4486 * Try to progress as much as possible on the input
4487 */
4488 if (exec->transcount == atom->max) {
4489 break;
4490 }
4491 exec->index += len;
4492 /*
4493 * End of input: stop here
4494 */
4495 if (exec->inputString[exec->index] == 0) {
4496 exec->index -= len;
4497 break;
4498 }
4499 if (exec->transcount >= atom->min) {
4500 int transno = exec->transno;
4501 xmlRegStatePtr state = exec->state;
4502
4503 /*
4504 * The transition is acceptable save it
4505 */
4506 exec->transno = -1; /* trick */
4507 exec->state = to;
4508 xmlFARegExecSave(exec);
4509 exec->transno = transno;
4510 exec->state = state;
4511 }
4512 codepoint = CUR_SCHAR(&(exec->inputString[exec->index]),
4513 len);
4514 ret = xmlRegCheckCharacter(atom, codepoint);
4515 exec->transcount++;
4516 } while (ret == 1);
4517 if (exec->transcount < atom->min)
4518 ret = 0;
4519
4520 /*
4521 * If the last check failed but one transition was found
4522 * possible, rollback
4523 */
4524 if (ret < 0)
4525 ret = 0;
4526 if (ret == 0) {
4527 goto rollback;
4528 }
4529 }
4530 }
4531 if (ret == 1) {
4532 if (exec->state->nbTrans > exec->transno + 1) {
4533 xmlFARegExecSave(exec);
4534 }
4535 /*
4536 * restart count for expressions like this ((abc){2})*
4537 */
4538 if (trans->count >= 0) {
4539#ifdef DEBUG_REGEXP_EXEC
4540 printf("Reset count %d\n", trans->count);
4541#endif
4542 exec->counts[trans->count] = 0;
4543 }
4544 if (trans->counter >= 0) {
4545#ifdef DEBUG_REGEXP_EXEC
4546 printf("Increasing count %d\n", trans->counter);
4547#endif
4548 exec->counts[trans->counter]++;
4549 }
4550#ifdef DEBUG_REGEXP_EXEC
4551 printf("entering state %d\n", trans->to);
4552#endif
4553 exec->state = exec->comp->states[trans->to];
4554 exec->transno = 0;
4555 if (trans->atom != NULL) {
4556 exec->index += len;
4557 }
4558 goto progress;
4559 } else if (ret < 0) {
4560 exec->status = -4;
4561 break;
4562 }
4563 }
4564 if ((exec->transno != 0) || (exec->state->nbTrans == 0)) {
4565rollback:
4566 /*
4567 * Failed to find a way out
4568 */
4569 exec->determinist = 0;
4570 xmlFARegExecRollBack(exec);
4571 }
4572progress:
4573 continue;
4574 }
4575}
4576#endif
4577/************************************************************************
4578 * *
4579 * Parser for the Schemas Datatype Regular Expressions *
4580 * http://www.w3.org/TR/2001/REC-xmlschema-2-20010502/#regexs *
4581 * *
4582 ************************************************************************/
4583
4584/**
4585 * xmlFAIsChar:
4586 * @ctxt: a regexp parser context
4587 *
4588 * [10] Char ::= [^.\?*+()|#x5B#x5D]
4589 */
4590static int
4591xmlFAIsChar(xmlRegParserCtxtPtr ctxt) {
4592 int cur;
4593 int len;
4594
4595 cur = CUR_SCHAR(ctxt->cur, len);
4596 if ((cur == '.') || (cur == '\\') || (cur == '?') ||
4597 (cur == '*') || (cur == '+') || (cur == '(') ||
4598 (cur == ')') || (cur == '|') || (cur == 0x5B) ||
4599 (cur == 0x5D) || (cur == 0))
4600 return(-1);
4601 return(cur);
4602}
4603
4604/**
4605 * xmlFAParseCharProp:
4606 * @ctxt: a regexp parser context
4607 *
4608 * [27] charProp ::= IsCategory | IsBlock
4609 * [28] IsCategory ::= Letters | Marks | Numbers | Punctuation |
4610 * Separators | Symbols | Others
4611 * [29] Letters ::= 'L' [ultmo]?
4612 * [30] Marks ::= 'M' [nce]?
4613 * [31] Numbers ::= 'N' [dlo]?
4614 * [32] Punctuation ::= 'P' [cdseifo]?
4615 * [33] Separators ::= 'Z' [slp]?
4616 * [34] Symbols ::= 'S' [mcko]?
4617 * [35] Others ::= 'C' [cfon]?
4618 * [36] IsBlock ::= 'Is' [a-zA-Z0-9#x2D]+
4619 */
4620static void
4621xmlFAParseCharProp(xmlRegParserCtxtPtr ctxt) {
4622 int cur;
4623 xmlRegAtomType type = (xmlRegAtomType) 0;
4624 xmlChar *blockName = NULL;
4625
4626 cur = CUR;
4627 if (cur == 'L') {
4628 NEXT;
4629 cur = CUR;
4630 if (cur == 'u') {
4631 NEXT;
4632 type = XML_REGEXP_LETTER_UPPERCASE;
4633 } else if (cur == 'l') {
4634 NEXT;
4635 type = XML_REGEXP_LETTER_LOWERCASE;
4636 } else if (cur == 't') {
4637 NEXT;
4638 type = XML_REGEXP_LETTER_TITLECASE;
4639 } else if (cur == 'm') {
4640 NEXT;
4641 type = XML_REGEXP_LETTER_MODIFIER;
4642 } else if (cur == 'o') {
4643 NEXT;
4644 type = XML_REGEXP_LETTER_OTHERS;
4645 } else {
4646 type = XML_REGEXP_LETTER;
4647 }
4648 } else if (cur == 'M') {
4649 NEXT;
4650 cur = CUR;
4651 if (cur == 'n') {
4652 NEXT;
4653 /* nonspacing */
4654 type = XML_REGEXP_MARK_NONSPACING;
4655 } else if (cur == 'c') {
4656 NEXT;
4657 /* spacing combining */
4658 type = XML_REGEXP_MARK_SPACECOMBINING;
4659 } else if (cur == 'e') {
4660 NEXT;
4661 /* enclosing */
4662 type = XML_REGEXP_MARK_ENCLOSING;
4663 } else {
4664 /* all marks */
4665 type = XML_REGEXP_MARK;
4666 }
4667 } else if (cur == 'N') {
4668 NEXT;
4669 cur = CUR;
4670 if (cur == 'd') {
4671 NEXT;
4672 /* digital */
4673 type = XML_REGEXP_NUMBER_DECIMAL;
4674 } else if (cur == 'l') {
4675 NEXT;
4676 /* letter */
4677 type = XML_REGEXP_NUMBER_LETTER;
4678 } else if (cur == 'o') {
4679 NEXT;
4680 /* other */
4681 type = XML_REGEXP_NUMBER_OTHERS;
4682 } else {
4683 /* all numbers */
4684 type = XML_REGEXP_NUMBER;
4685 }
4686 } else if (cur == 'P') {
4687 NEXT;
4688 cur = CUR;
4689 if (cur == 'c') {
4690 NEXT;
4691 /* connector */
4692 type = XML_REGEXP_PUNCT_CONNECTOR;
4693 } else if (cur == 'd') {
4694 NEXT;
4695 /* dash */
4696 type = XML_REGEXP_PUNCT_DASH;
4697 } else if (cur == 's') {
4698 NEXT;
4699 /* open */
4700 type = XML_REGEXP_PUNCT_OPEN;
4701 } else if (cur == 'e') {
4702 NEXT;
4703 /* close */
4704 type = XML_REGEXP_PUNCT_CLOSE;
4705 } else if (cur == 'i') {
4706 NEXT;
4707 /* initial quote */
4708 type = XML_REGEXP_PUNCT_INITQUOTE;
4709 } else if (cur == 'f') {
4710 NEXT;
4711 /* final quote */
4712 type = XML_REGEXP_PUNCT_FINQUOTE;
4713 } else if (cur == 'o') {
4714 NEXT;
4715 /* other */
4716 type = XML_REGEXP_PUNCT_OTHERS;
4717 } else {
4718 /* all punctuation */
4719 type = XML_REGEXP_PUNCT;
4720 }
4721 } else if (cur == 'Z') {
4722 NEXT;
4723 cur = CUR;
4724 if (cur == 's') {
4725 NEXT;
4726 /* space */
4727 type = XML_REGEXP_SEPAR_SPACE;
4728 } else if (cur == 'l') {
4729 NEXT;
4730 /* line */
4731 type = XML_REGEXP_SEPAR_LINE;
4732 } else if (cur == 'p') {
4733 NEXT;
4734 /* paragraph */
4735 type = XML_REGEXP_SEPAR_PARA;
4736 } else {
4737 /* all separators */
4738 type = XML_REGEXP_SEPAR;
4739 }
4740 } else if (cur == 'S') {
4741 NEXT;
4742 cur = CUR;
4743 if (cur == 'm') {
4744 NEXT;
4745 type = XML_REGEXP_SYMBOL_MATH;
4746 /* math */
4747 } else if (cur == 'c') {
4748 NEXT;
4749 type = XML_REGEXP_SYMBOL_CURRENCY;
4750 /* currency */
4751 } else if (cur == 'k') {
4752 NEXT;
4753 type = XML_REGEXP_SYMBOL_MODIFIER;
4754 /* modifiers */
4755 } else if (cur == 'o') {
4756 NEXT;
4757 type = XML_REGEXP_SYMBOL_OTHERS;
4758 /* other */
4759 } else {
4760 /* all symbols */
4761 type = XML_REGEXP_SYMBOL;
4762 }
4763 } else if (cur == 'C') {
4764 NEXT;
4765 cur = CUR;
4766 if (cur == 'c') {
4767 NEXT;
4768 /* control */
4769 type = XML_REGEXP_OTHER_CONTROL;
4770 } else if (cur == 'f') {
4771 NEXT;
4772 /* format */
4773 type = XML_REGEXP_OTHER_FORMAT;
4774 } else if (cur == 'o') {
4775 NEXT;
4776 /* private use */
4777 type = XML_REGEXP_OTHER_PRIVATE;
4778 } else if (cur == 'n') {
4779 NEXT;
4780 /* not assigned */
4781 type = XML_REGEXP_OTHER_NA;
4782 } else {
4783 /* all others */
4784 type = XML_REGEXP_OTHER;
4785 }
4786 } else if (cur == 'I') {
4787 const xmlChar *start;
4788 NEXT;
4789 cur = CUR;
4790 if (cur != 's') {
4791 ERROR("IsXXXX expected");
4792 return;
4793 }
4794 NEXT;
4795 start = ctxt->cur;
4796 cur = CUR;
4797 if (((cur >= 'a') && (cur <= 'z')) ||
4798 ((cur >= 'A') && (cur <= 'Z')) ||
4799 ((cur >= '0') && (cur <= '9')) ||
4800 (cur == 0x2D)) {
4801 NEXT;
4802 cur = CUR;
4803 while (((cur >= 'a') && (cur <= 'z')) ||
4804 ((cur >= 'A') && (cur <= 'Z')) ||
4805 ((cur >= '0') && (cur <= '9')) ||
4806 (cur == 0x2D)) {
4807 NEXT;
4808 cur = CUR;
4809 }
4810 }
4811 type = XML_REGEXP_BLOCK_NAME;
4812 blockName = xmlStrndup(start, ctxt->cur - start);
4813 } else {
4814 ERROR("Unknown char property");
4815 return;
4816 }
4817 if (ctxt->atom == NULL) {
4818 ctxt->atom = xmlRegNewAtom(ctxt, type);
4819 if (ctxt->atom != NULL)
4820 ctxt->atom->valuep = blockName;
4821 } else if (ctxt->atom->type == XML_REGEXP_RANGES) {
4822 xmlRegAtomAddRange(ctxt, ctxt->atom, ctxt->neg,
4823 type, 0, 0, blockName);
4824 }
4825}
4826
4827/**
4828 * xmlFAParseCharClassEsc:
4829 * @ctxt: a regexp parser context
4830 *
4831 * [23] charClassEsc ::= ( SingleCharEsc | MultiCharEsc | catEsc | complEsc )
4832 * [24] SingleCharEsc ::= '\' [nrt\|.?*+(){}#x2D#x5B#x5D#x5E]
4833 * [25] catEsc ::= '\p{' charProp '}'
4834 * [26] complEsc ::= '\P{' charProp '}'
4835 * [37] MultiCharEsc ::= '.' | ('\' [sSiIcCdDwW])
4836 */
4837static void
4838xmlFAParseCharClassEsc(xmlRegParserCtxtPtr ctxt) {
4839 int cur;
4840
4841 if (CUR == '.') {
4842 if (ctxt->atom == NULL) {
4843 ctxt->atom = xmlRegNewAtom(ctxt, XML_REGEXP_ANYCHAR);
4844 } else if (ctxt->atom->type == XML_REGEXP_RANGES) {
4845 xmlRegAtomAddRange(ctxt, ctxt->atom, ctxt->neg,
4846 XML_REGEXP_ANYCHAR, 0, 0, NULL);
4847 }
4848 NEXT;
4849 return;
4850 }
4851 if (CUR != '\\') {
4852 ERROR("Escaped sequence: expecting \\");
4853 return;
4854 }
4855 NEXT;
4856 cur = CUR;
4857 if (cur == 'p') {
4858 NEXT;
4859 if (CUR != '{') {
4860 ERROR("Expecting '{'");
4861 return;
4862 }
4863 NEXT;
4864 xmlFAParseCharProp(ctxt);
4865 if (CUR != '}') {
4866 ERROR("Expecting '}'");
4867 return;
4868 }
4869 NEXT;
4870 } else if (cur == 'P') {
4871 NEXT;
4872 if (CUR != '{') {
4873 ERROR("Expecting '{'");
4874 return;
4875 }
4876 NEXT;
4877 xmlFAParseCharProp(ctxt);
4878 ctxt->atom->neg = 1;
4879 if (CUR != '}') {
4880 ERROR("Expecting '}'");
4881 return;
4882 }
4883 NEXT;
4884 } else if ((cur == 'n') || (cur == 'r') || (cur == 't') || (cur == '\\') ||
4885 (cur == '|') || (cur == '.') || (cur == '?') || (cur == '*') ||
4886 (cur == '+') || (cur == '(') || (cur == ')') || (cur == '{') ||
4887 (cur == '}') || (cur == 0x2D) || (cur == 0x5B) || (cur == 0x5D) ||
4888 (cur == 0x5E)) {
4889 if (ctxt->atom == NULL) {
4890 ctxt->atom = xmlRegNewAtom(ctxt, XML_REGEXP_CHARVAL);
4891 if (ctxt->atom != NULL) {
4892 switch (cur) {
4893 case 'n':
4894 ctxt->atom->codepoint = '\n';
4895 break;
4896 case 'r':
4897 ctxt->atom->codepoint = '\r';
4898 break;
4899 case 't':
4900 ctxt->atom->codepoint = '\t';
4901 break;
4902 default:
4903 ctxt->atom->codepoint = cur;
4904 }
4905 }
4906 } else if (ctxt->atom->type == XML_REGEXP_RANGES) {
4907 switch (cur) {
4908 case 'n':
4909 cur = '\n';
4910 break;
4911 case 'r':
4912 cur = '\r';
4913 break;
4914 case 't':
4915 cur = '\t';
4916 break;
4917 }
4918 xmlRegAtomAddRange(ctxt, ctxt->atom, ctxt->neg,
4919 XML_REGEXP_CHARVAL, cur, cur, NULL);
4920 }
4921 NEXT;
4922 } else if ((cur == 's') || (cur == 'S') || (cur == 'i') || (cur == 'I') ||
4923 (cur == 'c') || (cur == 'C') || (cur == 'd') || (cur == 'D') ||
4924 (cur == 'w') || (cur == 'W')) {
4925 xmlRegAtomType type = XML_REGEXP_ANYSPACE;
4926
4927 switch (cur) {
4928 case 's':
4929 type = XML_REGEXP_ANYSPACE;
4930 break;
4931 case 'S':
4932 type = XML_REGEXP_NOTSPACE;
4933 break;
4934 case 'i':
4935 type = XML_REGEXP_INITNAME;
4936 break;
4937 case 'I':
4938 type = XML_REGEXP_NOTINITNAME;
4939 break;
4940 case 'c':
4941 type = XML_REGEXP_NAMECHAR;
4942 break;
4943 case 'C':
4944 type = XML_REGEXP_NOTNAMECHAR;
4945 break;
4946 case 'd':
4947 type = XML_REGEXP_DECIMAL;
4948 break;
4949 case 'D':
4950 type = XML_REGEXP_NOTDECIMAL;
4951 break;
4952 case 'w':
4953 type = XML_REGEXP_REALCHAR;
4954 break;
4955 case 'W':
4956 type = XML_REGEXP_NOTREALCHAR;
4957 break;
4958 }
4959 NEXT;
4960 if (ctxt->atom == NULL) {
4961 ctxt->atom = xmlRegNewAtom(ctxt, type);
4962 } else if (ctxt->atom->type == XML_REGEXP_RANGES) {
4963 xmlRegAtomAddRange(ctxt, ctxt->atom, ctxt->neg,
4964 type, 0, 0, NULL);
4965 }
4966 } else {
4967 ERROR("Wrong escape sequence, misuse of character '\\'");
4968 }
4969}
4970
4971/**
4972 * xmlFAParseCharRange:
4973 * @ctxt: a regexp parser context
4974 *
4975 * [17] charRange ::= seRange | XmlCharRef | XmlCharIncDash
4976 * [18] seRange ::= charOrEsc '-' charOrEsc
4977 * [20] charOrEsc ::= XmlChar | SingleCharEsc
4978 * [21] XmlChar ::= [^\#x2D#x5B#x5D]
4979 * [22] XmlCharIncDash ::= [^\#x5B#x5D]
4980 */
4981static void
4982xmlFAParseCharRange(xmlRegParserCtxtPtr ctxt) {
4983 int cur, len;
4984 int start = -1;
4985 int end = -1;
4986
4987 if (CUR == '\0') {
4988 ERROR("Expecting ']'");
4989 return;
4990 }
4991
4992 cur = CUR;
4993 if (cur == '\\') {
4994 NEXT;
4995 cur = CUR;
4996 switch (cur) {
4997 case 'n': start = 0xA; break;
4998 case 'r': start = 0xD; break;
4999 case 't': start = 0x9; break;
5000 case '\\': case '|': case '.': case '-': case '^': case '?':
5001 case '*': case '+': case '{': case '}': case '(': case ')':
5002 case '[': case ']':
5003 start = cur; break;
5004 default:
5005 ERROR("Invalid escape value");
5006 return;
5007 }
5008 end = start;
5009 len = 1;
5010 } else if ((cur != 0x5B) && (cur != 0x5D)) {
5011 end = start = CUR_SCHAR(ctxt->cur, len);
5012 } else {
5013 ERROR("Expecting a char range");
5014 return;
5015 }
5016 /*
5017 * Since we are "inside" a range, we can assume ctxt->cur is past
5018 * the start of ctxt->string, and PREV should be safe
5019 */
5020 if ((start == '-') && (NXT(1) != ']') && (PREV != '[') && (PREV != '^')) {
5021 NEXTL(len);
5022 return;
5023 }
5024 NEXTL(len);
5025 cur = CUR;
5026 if ((cur != '-') || (NXT(1) == ']')) {
5027 xmlRegAtomAddRange(ctxt, ctxt->atom, ctxt->neg,
5028 XML_REGEXP_CHARVAL, start, end, NULL);
5029 return;
5030 }
5031 NEXT;
5032 cur = CUR;
5033 if (cur == '\\') {
5034 NEXT;
5035 cur = CUR;
5036 switch (cur) {
5037 case 'n': end = 0xA; break;
5038 case 'r': end = 0xD; break;
5039 case 't': end = 0x9; break;
5040 case '\\': case '|': case '.': case '-': case '^': case '?':
5041 case '*': case '+': case '{': case '}': case '(': case ')':
5042 case '[': case ']':
5043 end = cur; break;
5044 default:
5045 ERROR("Invalid escape value");
5046 return;
5047 }
5048 len = 1;
5049 } else if ((cur != 0x5B) && (cur != 0x5D)) {
5050 end = CUR_SCHAR(ctxt->cur, len);
5051 } else {
5052 ERROR("Expecting the end of a char range");
5053 return;
5054 }
5055 NEXTL(len);
5056 /* TODO check that the values are acceptable character ranges for XML */
5057 if (end < start) {
5058 ERROR("End of range is before start of range");
5059 } else {
5060 xmlRegAtomAddRange(ctxt, ctxt->atom, ctxt->neg,
5061 XML_REGEXP_CHARVAL, start, end, NULL);
5062 }
5063 return;
5064}
5065
5066/**
5067 * xmlFAParsePosCharGroup:
5068 * @ctxt: a regexp parser context
5069 *
5070 * [14] posCharGroup ::= ( charRange | charClassEsc )+
5071 */
5072static void
5073xmlFAParsePosCharGroup(xmlRegParserCtxtPtr ctxt) {
5074 do {
5075 if (CUR == '\\') {
5076 xmlFAParseCharClassEsc(ctxt);
5077 } else {
5078 xmlFAParseCharRange(ctxt);
5079 }
5080 } while ((CUR != ']') && (CUR != '^') && (CUR != '-') &&
5081 (CUR != 0) && (ctxt->error == 0));
5082}
5083
5084/**
5085 * xmlFAParseCharGroup:
5086 * @ctxt: a regexp parser context
5087 *
5088 * [13] charGroup ::= posCharGroup | negCharGroup | charClassSub
5089 * [15] negCharGroup ::= '^' posCharGroup
5090 * [16] charClassSub ::= ( posCharGroup | negCharGroup ) '-' charClassExpr
5091 * [12] charClassExpr ::= '[' charGroup ']'
5092 */
5093static void
5094xmlFAParseCharGroup(xmlRegParserCtxtPtr ctxt) {
5095 int n = ctxt->neg;
5096 while ((CUR != ']') && (ctxt->error == 0)) {
5097 if (CUR == '^') {
5098 int neg = ctxt->neg;
5099
5100 NEXT;
5101 ctxt->neg = !ctxt->neg;
5102 xmlFAParsePosCharGroup(ctxt);
5103 ctxt->neg = neg;
5104 } else if ((CUR == '-') && (NXT(1) == '[')) {
5105 int neg = ctxt->neg;
5106 ctxt->neg = 2;
5107 NEXT; /* eat the '-' */
5108 NEXT; /* eat the '[' */
5109 xmlFAParseCharGroup(ctxt);
5110 if (CUR == ']') {
5111 NEXT;
5112 } else {
5113 ERROR("charClassExpr: ']' expected");
5114 break;
5115 }
5116 ctxt->neg = neg;
5117 break;
5118 } else if (CUR != ']') {
5119 xmlFAParsePosCharGroup(ctxt);
5120 }
5121 }
5122 ctxt->neg = n;
5123}
5124
5125/**
5126 * xmlFAParseCharClass:
5127 * @ctxt: a regexp parser context
5128 *
5129 * [11] charClass ::= charClassEsc | charClassExpr
5130 * [12] charClassExpr ::= '[' charGroup ']'
5131 */
5132static void
5133xmlFAParseCharClass(xmlRegParserCtxtPtr ctxt) {
5134 if (CUR == '[') {
5135 NEXT;
5136 ctxt->atom = xmlRegNewAtom(ctxt, XML_REGEXP_RANGES);
5137 if (ctxt->atom == NULL)
5138 return;
5139 xmlFAParseCharGroup(ctxt);
5140 if (CUR == ']') {
5141 NEXT;
5142 } else {
5143 ERROR("xmlFAParseCharClass: ']' expected");
5144 }
5145 } else {
5146 xmlFAParseCharClassEsc(ctxt);
5147 }
5148}
5149
5150/**
5151 * xmlFAParseQuantExact:
5152 * @ctxt: a regexp parser context
5153 *
5154 * [8] QuantExact ::= [0-9]+
5155 *
5156 * Returns 0 if success or -1 in case of error
5157 */
5158static int
5159xmlFAParseQuantExact(xmlRegParserCtxtPtr ctxt) {
5160 int ret = 0;
5161 int ok = 0;
5162
5163 while ((CUR >= '0') && (CUR <= '9')) {
5164 ret = ret * 10 + (CUR - '0');
5165 ok = 1;
5166 NEXT;
5167 }
5168 if (ok != 1) {
5169 return(-1);
5170 }
5171 return(ret);
5172}
5173
5174/**
5175 * xmlFAParseQuantifier:
5176 * @ctxt: a regexp parser context
5177 *
5178 * [4] quantifier ::= [?*+] | ( '{' quantity '}' )
5179 * [5] quantity ::= quantRange | quantMin | QuantExact
5180 * [6] quantRange ::= QuantExact ',' QuantExact
5181 * [7] quantMin ::= QuantExact ','
5182 * [8] QuantExact ::= [0-9]+
5183 */
5184static int
5185xmlFAParseQuantifier(xmlRegParserCtxtPtr ctxt) {
5186 int cur;
5187
5188 cur = CUR;
5189 if ((cur == '?') || (cur == '*') || (cur == '+')) {
5190 if (ctxt->atom != NULL) {
5191 if (cur == '?')
5192 ctxt->atom->quant = XML_REGEXP_QUANT_OPT;
5193 else if (cur == '*')
5194 ctxt->atom->quant = XML_REGEXP_QUANT_MULT;
5195 else if (cur == '+')
5196 ctxt->atom->quant = XML_REGEXP_QUANT_PLUS;
5197 }
5198 NEXT;
5199 return(1);
5200 }
5201 if (cur == '{') {
5202 int min = 0, max = 0;
5203
5204 NEXT;
5205 cur = xmlFAParseQuantExact(ctxt);
5206 if (cur >= 0)
5207 min = cur;
5208 if (CUR == ',') {
5209 NEXT;
5210 if (CUR == '}')
5211 max = INT_MAX;
5212 else {
5213 cur = xmlFAParseQuantExact(ctxt);
5214 if (cur >= 0)
5215 max = cur;
5216 else {
5217 ERROR("Improper quantifier");
5218 }
5219 }
5220 }
5221 if (CUR == '}') {
5222 NEXT;
5223 } else {
5224 ERROR("Unterminated quantifier");
5225 }
5226 if (max == 0)
5227 max = min;
5228 if (ctxt->atom != NULL) {
5229 ctxt->atom->quant = XML_REGEXP_QUANT_RANGE;
5230 ctxt->atom->min = min;
5231 ctxt->atom->max = max;
5232 }
5233 return(1);
5234 }
5235 return(0);
5236}
5237
5238/**
5239 * xmlFAParseAtom:
5240 * @ctxt: a regexp parser context
5241 *
5242 * [9] atom ::= Char | charClass | ( '(' regExp ')' )
5243 */
5244static int
5245xmlFAParseAtom(xmlRegParserCtxtPtr ctxt) {
5246 int codepoint, len;
5247
5248 codepoint = xmlFAIsChar(ctxt);
5249 if (codepoint > 0) {
5250 ctxt->atom = xmlRegNewAtom(ctxt, XML_REGEXP_CHARVAL);
5251 if (ctxt->atom == NULL)
5252 return(-1);
5253 codepoint = CUR_SCHAR(ctxt->cur, len);
5254 ctxt->atom->codepoint = codepoint;
5255 NEXTL(len);
5256 return(1);
5257 } else if (CUR == '|') {
5258 return(0);
5259 } else if (CUR == 0) {
5260 return(0);
5261 } else if (CUR == ')') {
5262 return(0);
5263 } else if (CUR == '(') {
5264 xmlRegStatePtr start, oldend, start0;
5265
5266 NEXT;
5267 /*
5268 * this extra Epsilon transition is needed if we count with 0 allowed
5269 * unfortunately this can't be known at that point
5270 */
5271 xmlFAGenerateEpsilonTransition(ctxt, ctxt->state, NULL);
5272 start0 = ctxt->state;
5273 xmlFAGenerateEpsilonTransition(ctxt, ctxt->state, NULL);
5274 start = ctxt->state;
5275 oldend = ctxt->end;
5276 ctxt->end = NULL;
5277 ctxt->atom = NULL;
5278 xmlFAParseRegExp(ctxt, 0);
5279 if (CUR == ')') {
5280 NEXT;
5281 } else {
5282 ERROR("xmlFAParseAtom: expecting ')'");
5283 }
5284 ctxt->atom = xmlRegNewAtom(ctxt, XML_REGEXP_SUBREG);
5285 if (ctxt->atom == NULL)
5286 return(-1);
5287 ctxt->atom->start = start;
5288 ctxt->atom->start0 = start0;
5289 ctxt->atom->stop = ctxt->state;
5290 ctxt->end = oldend;
5291 return(1);
5292 } else if ((CUR == '[') || (CUR == '\\') || (CUR == '.')) {
5293 xmlFAParseCharClass(ctxt);
5294 return(1);
5295 }
5296 return(0);
5297}
5298
5299/**
5300 * xmlFAParsePiece:
5301 * @ctxt: a regexp parser context
5302 *
5303 * [3] piece ::= atom quantifier?
5304 */
5305static int
5306xmlFAParsePiece(xmlRegParserCtxtPtr ctxt) {
5307 int ret;
5308
5309 ctxt->atom = NULL;
5310 ret = xmlFAParseAtom(ctxt);
5311 if (ret == 0)
5312 return(0);
5313 if (ctxt->atom == NULL) {
5314 ERROR("internal: no atom generated");
5315 }
5316 xmlFAParseQuantifier(ctxt);
5317 return(1);
5318}
5319
5320/**
5321 * xmlFAParseBranch:
5322 * @ctxt: a regexp parser context
5323 * @to: optional target to the end of the branch
5324 *
5325 * @to is used to optimize by removing duplicate path in automata
5326 * in expressions like (a|b)(c|d)
5327 *
5328 * [2] branch ::= piece*
5329 */
5330static int
5331xmlFAParseBranch(xmlRegParserCtxtPtr ctxt, xmlRegStatePtr to) {
5332 xmlRegStatePtr previous;
5333 int ret;
5334
5335 previous = ctxt->state;
5336 ret = xmlFAParsePiece(ctxt);
5337 if (ret != 0) {
5338 if (xmlFAGenerateTransitions(ctxt, previous,
5339 (CUR=='|' || CUR==')') ? to : NULL, ctxt->atom) < 0)
5340 return(-1);
5341 previous = ctxt->state;
5342 ctxt->atom = NULL;
5343 }
5344 while ((ret != 0) && (ctxt->error == 0)) {
5345 ret = xmlFAParsePiece(ctxt);
5346 if (ret != 0) {
5347 if (xmlFAGenerateTransitions(ctxt, previous,
5348 (CUR=='|' || CUR==')') ? to : NULL, ctxt->atom) < 0)
5349 return(-1);
5350 previous = ctxt->state;
5351 ctxt->atom = NULL;
5352 }
5353 }
5354 return(0);
5355}
5356
5357/**
5358 * xmlFAParseRegExp:
5359 * @ctxt: a regexp parser context
5360 * @top: is this the top-level expression ?
5361 *
5362 * [1] regExp ::= branch ( '|' branch )*
5363 */
5364static void
5365xmlFAParseRegExp(xmlRegParserCtxtPtr ctxt, int top) {
5366 xmlRegStatePtr start, end;
5367
5368 /* if not top start should have been generated by an epsilon trans */
5369 start = ctxt->state;
5370 ctxt->end = NULL;
5371 xmlFAParseBranch(ctxt, NULL);
5372 if (top) {
5373#ifdef DEBUG_REGEXP_GRAPH
5374 printf("State %d is final\n", ctxt->state->no);
5375#endif
5376 ctxt->state->type = XML_REGEXP_FINAL_STATE;
5377 }
5378 if (CUR != '|') {
5379 ctxt->end = ctxt->state;
5380 return;
5381 }
5382 end = ctxt->state;
5383 while ((CUR == '|') && (ctxt->error == 0)) {
5384 NEXT;
5385 if (CUR == 0) {
5386 ERROR("expecting a branch after |")
5387 return;
5388 }
5389 ctxt->state = start;
5390 ctxt->end = NULL;
5391 xmlFAParseBranch(ctxt, end);
5392 }
5393 if (!top) {
5394 ctxt->state = end;
5395 ctxt->end = end;
5396 }
5397}
5398
5399/************************************************************************
5400 * *
5401 * The basic API *
5402 * *
5403 ************************************************************************/
5404
5405/**
5406 * xmlRegexpPrint:
5407 * @output: the file for the output debug
5408 * @regexp: the compiled regexp
5409 *
5410 * Print the content of the compiled regular expression
5411 */
5412void
5413xmlRegexpPrint(FILE *output, xmlRegexpPtr regexp) {
5414 int i;
5415
5416 if (output == NULL)
5417 return;
5418 fprintf(output, " regexp: ");
5419 if (regexp == NULL) {
5420 fprintf(output, "NULL\n");
5421 return;
5422 }
5423 fprintf(output, "'%s' ", regexp->string);
5424 fprintf(output, "\n");
5425 fprintf(output, "%d atoms:\n", regexp->nbAtoms);
5426 for (i = 0;i < regexp->nbAtoms; i++) {
5427 fprintf(output, " %02d ", i);
5428 xmlRegPrintAtom(output, regexp->atoms[i]);
5429 }
5430 fprintf(output, "%d states:", regexp->nbStates);
5431 fprintf(output, "\n");
5432 for (i = 0;i < regexp->nbStates; i++) {
5433 xmlRegPrintState(output, regexp->states[i]);
5434 }
5435 fprintf(output, "%d counters:\n", regexp->nbCounters);
5436 for (i = 0;i < regexp->nbCounters; i++) {
5437 fprintf(output, " %d: min %d max %d\n", i, regexp->counters[i].min,
5438 regexp->counters[i].max);
5439 }
5440}
5441
5442/**
5443 * xmlRegexpCompile:
5444 * @regexp: a regular expression string
5445 *
5446 * Parses a regular expression conforming to XML Schemas Part 2 Datatype
5447 * Appendix F and builds an automata suitable for testing strings against
5448 * that regular expression
5449 *
5450 * Returns the compiled expression or NULL in case of error
5451 */
5452xmlRegexpPtr
5453xmlRegexpCompile(const xmlChar *regexp) {
5454 xmlRegexpPtr ret;
5455 xmlRegParserCtxtPtr ctxt;
5456
5457 ctxt = xmlRegNewParserCtxt(regexp);
5458 if (ctxt == NULL)
5459 return(NULL);
5460
5461 /* initialize the parser */
5462 ctxt->end = NULL;
5463 ctxt->start = ctxt->state = xmlRegNewState(ctxt);
5464 xmlRegStatePush(ctxt, ctxt->start);
5465
5466 /* parse the expression building an automata */
5467 xmlFAParseRegExp(ctxt, 1);
5468 if (CUR != 0) {
5469 ERROR("xmlFAParseRegExp: extra characters");
5470 }
5471 if (ctxt->error != 0) {
5472 xmlRegFreeParserCtxt(ctxt);
5473 return(NULL);
5474 }
5475 ctxt->end = ctxt->state;
5476 ctxt->start->type = XML_REGEXP_START_STATE;
5477 ctxt->end->type = XML_REGEXP_FINAL_STATE;
5478
5479 /* remove the Epsilon except for counted transitions */
5480 xmlFAEliminateEpsilonTransitions(ctxt);
5481
5482
5483 if (ctxt->error != 0) {
5484 xmlRegFreeParserCtxt(ctxt);
5485 return(NULL);
5486 }
5487 ret = xmlRegEpxFromParse(ctxt);
5488 xmlRegFreeParserCtxt(ctxt);
5489 return(ret);
5490}
5491
5492/**
5493 * xmlRegexpExec:
5494 * @comp: the compiled regular expression
5495 * @content: the value to check against the regular expression
5496 *
5497 * Check if the regular expression generates the value
5498 *
5499 * Returns 1 if it matches, 0 if not and a negative value in case of error
5500 */
5501int
5502xmlRegexpExec(xmlRegexpPtr comp, const xmlChar *content) {
5503 if ((comp == NULL) || (content == NULL))
5504 return(-1);
5505 return(xmlFARegExec(comp, content));
5506}
5507
5508/**
5509 * xmlRegexpIsDeterminist:
5510 * @comp: the compiled regular expression
5511 *
5512 * Check if the regular expression is determinist
5513 *
5514 * Returns 1 if it yes, 0 if not and a negative value in case of error
5515 */
5516int
5517xmlRegexpIsDeterminist(xmlRegexpPtr comp) {
5518 xmlAutomataPtr am;
5519 int ret;
5520
5521 if (comp == NULL)
5522 return(-1);
5523 if (comp->determinist != -1)
5524 return(comp->determinist);
5525
5526 am = xmlNewAutomata();
5527 if (am->states != NULL) {
5528 int i;
5529
5530 for (i = 0;i < am->nbStates;i++)
5531 xmlRegFreeState(am->states[i]);
5532 xmlFree(am->states);
5533 }
5534 am->nbAtoms = comp->nbAtoms;
5535 am->atoms = comp->atoms;
5536 am->nbStates = comp->nbStates;
5537 am->states = comp->states;
5538 am->determinist = -1;
5539 am->flags = comp->flags;
5540 ret = xmlFAComputesDeterminism(am);
5541 am->atoms = NULL;
5542 am->states = NULL;
5543 xmlFreeAutomata(am);
5544 comp->determinist = ret;
5545 return(ret);
5546}
5547
5548/**
5549 * xmlRegFreeRegexp:
5550 * @regexp: the regexp
5551 *
5552 * Free a regexp
5553 */
5554void
5555xmlRegFreeRegexp(xmlRegexpPtr regexp) {
5556 int i;
5557 if (regexp == NULL)
5558 return;
5559
5560 if (regexp->string != NULL)
5561 xmlFree(regexp->string);
5562 if (regexp->states != NULL) {
5563 for (i = 0;i < regexp->nbStates;i++)
5564 xmlRegFreeState(regexp->states[i]);
5565 xmlFree(regexp->states);
5566 }
5567 if (regexp->atoms != NULL) {
5568 for (i = 0;i < regexp->nbAtoms;i++)
5569 xmlRegFreeAtom(regexp->atoms[i]);
5570 xmlFree(regexp->atoms);
5571 }
5572 if (regexp->counters != NULL)
5573 xmlFree(regexp->counters);
5574 if (regexp->compact != NULL)
5575 xmlFree(regexp->compact);
5576 if (regexp->transdata != NULL)
5577 xmlFree(regexp->transdata);
5578 if (regexp->stringMap != NULL) {
5579 for (i = 0; i < regexp->nbstrings;i++)
5580 xmlFree(regexp->stringMap[i]);
5581 xmlFree(regexp->stringMap);
5582 }
5583
5584 xmlFree(regexp);
5585}
5586
5587#ifdef LIBXML_AUTOMATA_ENABLED
5588/************************************************************************
5589 * *
5590 * The Automata interface *
5591 * *
5592 ************************************************************************/
5593
5594/**
5595 * xmlNewAutomata:
5596 *
5597 * Create a new automata
5598 *
5599 * Returns the new object or NULL in case of failure
5600 */
5601xmlAutomataPtr
5602xmlNewAutomata(void) {
5603 xmlAutomataPtr ctxt;
5604
5605 ctxt = xmlRegNewParserCtxt(NULL);
5606 if (ctxt == NULL)
5607 return(NULL);
5608
5609 /* initialize the parser */
5610 ctxt->end = NULL;
5611 ctxt->start = ctxt->state = xmlRegNewState(ctxt);
5612 if (ctxt->start == NULL) {
5613 xmlFreeAutomata(ctxt);
5614 return(NULL);
5615 }
5616 ctxt->start->type = XML_REGEXP_START_STATE;
5617 if (xmlRegStatePush(ctxt, ctxt->start) < 0) {
5618 xmlRegFreeState(ctxt->start);
5619 xmlFreeAutomata(ctxt);
5620 return(NULL);
5621 }
5622 ctxt->flags = 0;
5623
5624 return(ctxt);
5625}
5626
5627/**
5628 * xmlFreeAutomata:
5629 * @am: an automata
5630 *
5631 * Free an automata
5632 */
5633void
5634xmlFreeAutomata(xmlAutomataPtr am) {
5635 if (am == NULL)
5636 return;
5637 xmlRegFreeParserCtxt(am);
5638}
5639
5640/**
5641 * xmlAutomataSetFlags:
5642 * @am: an automata
5643 * @flags: a set of internal flags
5644 *
5645 * Set some flags on the automata
5646 */
5647void
5648xmlAutomataSetFlags(xmlAutomataPtr am, int flags) {
5649 if (am == NULL)
5650 return;
5651 am->flags |= flags;
5652}
5653
5654/**
5655 * xmlAutomataGetInitState:
5656 * @am: an automata
5657 *
5658 * Initial state lookup
5659 *
5660 * Returns the initial state of the automata
5661 */
5662xmlAutomataStatePtr
5663xmlAutomataGetInitState(xmlAutomataPtr am) {
5664 if (am == NULL)
5665 return(NULL);
5666 return(am->start);
5667}
5668
5669/**
5670 * xmlAutomataSetFinalState:
5671 * @am: an automata
5672 * @state: a state in this automata
5673 *
5674 * Makes that state a final state
5675 *
5676 * Returns 0 or -1 in case of error
5677 */
5678int
5679xmlAutomataSetFinalState(xmlAutomataPtr am, xmlAutomataStatePtr state) {
5680 if ((am == NULL) || (state == NULL))
5681 return(-1);
5682 state->type = XML_REGEXP_FINAL_STATE;
5683 return(0);
5684}
5685
5686/**
5687 * xmlAutomataNewTransition:
5688 * @am: an automata
5689 * @from: the starting point of the transition
5690 * @to: the target point of the transition or NULL
5691 * @token: the input string associated to that transition
5692 * @data: data passed to the callback function if the transition is activated
5693 *
5694 * If @to is NULL, this creates first a new target state in the automata
5695 * and then adds a transition from the @from state to the target state
5696 * activated by the value of @token
5697 *
5698 * Returns the target state or NULL in case of error
5699 */
5700xmlAutomataStatePtr
5701xmlAutomataNewTransition(xmlAutomataPtr am, xmlAutomataStatePtr from,
5702 xmlAutomataStatePtr to, const xmlChar *token,
5703 void *data) {
5704 xmlRegAtomPtr atom;
5705
5706 if ((am == NULL) || (from == NULL) || (token == NULL))
5707 return(NULL);
5708 atom = xmlRegNewAtom(am, XML_REGEXP_STRING);
5709 if (atom == NULL)
5710 return(NULL);
5711 atom->data = data;
5712 atom->valuep = xmlStrdup(token);
5713
5714 if (xmlFAGenerateTransitions(am, from, to, atom) < 0) {
5715 xmlRegFreeAtom(atom);
5716 return(NULL);
5717 }
5718 if (to == NULL)
5719 return(am->state);
5720 return(to);
5721}
5722
5723/**
5724 * xmlAutomataNewTransition2:
5725 * @am: an automata
5726 * @from: the starting point of the transition
5727 * @to: the target point of the transition or NULL
5728 * @token: the first input string associated to that transition
5729 * @token2: the second input string associated to that transition
5730 * @data: data passed to the callback function if the transition is activated
5731 *
5732 * If @to is NULL, this creates first a new target state in the automata
5733 * and then adds a transition from the @from state to the target state
5734 * activated by the value of @token
5735 *
5736 * Returns the target state or NULL in case of error
5737 */
5738xmlAutomataStatePtr
5739xmlAutomataNewTransition2(xmlAutomataPtr am, xmlAutomataStatePtr from,
5740 xmlAutomataStatePtr to, const xmlChar *token,
5741 const xmlChar *token2, void *data) {
5742 xmlRegAtomPtr atom;
5743
5744 if ((am == NULL) || (from == NULL) || (token == NULL))
5745 return(NULL);
5746 atom = xmlRegNewAtom(am, XML_REGEXP_STRING);
5747 if (atom == NULL)
5748 return(NULL);
5749 atom->data = data;
5750 if ((token2 == NULL) || (*token2 == 0)) {
5751 atom->valuep = xmlStrdup(token);
5752 } else {
5753 int lenn, lenp;
5754 xmlChar *str;
5755
5756 lenn = strlen((char *) token2);
5757 lenp = strlen((char *) token);
5758
5759 str = (xmlChar *) xmlMallocAtomic(lenn + lenp + 2);
5760 if (str == NULL) {
5761 xmlRegFreeAtom(atom);
5762 return(NULL);
5763 }
5764 memcpy(&str[0], token, lenp);
5765 str[lenp] = '|';
5766 memcpy(&str[lenp + 1], token2, lenn);
5767 str[lenn + lenp + 1] = 0;
5768
5769 atom->valuep = str;
5770 }
5771
5772 if (xmlFAGenerateTransitions(am, from, to, atom) < 0) {
5773 xmlRegFreeAtom(atom);
5774 return(NULL);
5775 }
5776 if (to == NULL)
5777 return(am->state);
5778 return(to);
5779}
5780
5781/**
5782 * xmlAutomataNewNegTrans:
5783 * @am: an automata
5784 * @from: the starting point of the transition
5785 * @to: the target point of the transition or NULL
5786 * @token: the first input string associated to that transition
5787 * @token2: the second input string associated to that transition
5788 * @data: data passed to the callback function if the transition is activated
5789 *
5790 * If @to is NULL, this creates first a new target state in the automata
5791 * and then adds a transition from the @from state to the target state
5792 * activated by any value except (@token,@token2)
5793 * Note that if @token2 is not NULL, then (X, NULL) won't match to follow
5794 # the semantic of XSD ##other
5795 *
5796 * Returns the target state or NULL in case of error
5797 */
5798xmlAutomataStatePtr
5799xmlAutomataNewNegTrans(xmlAutomataPtr am, xmlAutomataStatePtr from,
5800 xmlAutomataStatePtr to, const xmlChar *token,
5801 const xmlChar *token2, void *data) {
5802 xmlRegAtomPtr atom;
5803 xmlChar err_msg[200];
5804
5805 if ((am == NULL) || (from == NULL) || (token == NULL))
5806 return(NULL);
5807 atom = xmlRegNewAtom(am, XML_REGEXP_STRING);
5808 if (atom == NULL)
5809 return(NULL);
5810 atom->data = data;
5811 atom->neg = 1;
5812 if ((token2 == NULL) || (*token2 == 0)) {
5813 atom->valuep = xmlStrdup(token);
5814 } else {
5815 int lenn, lenp;
5816 xmlChar *str;
5817
5818 lenn = strlen((char *) token2);
5819 lenp = strlen((char *) token);
5820
5821 str = (xmlChar *) xmlMallocAtomic(lenn + lenp + 2);
5822 if (str == NULL) {
5823 xmlRegFreeAtom(atom);
5824 return(NULL);
5825 }
5826 memcpy(&str[0], token, lenp);
5827 str[lenp] = '|';
5828 memcpy(&str[lenp + 1], token2, lenn);
5829 str[lenn + lenp + 1] = 0;
5830
5831 atom->valuep = str;
5832 }
5833 snprintf((char *) err_msg, 199, "not %s", (const char *) atom->valuep);
5834 err_msg[199] = 0;
5835 atom->valuep2 = xmlStrdup(err_msg);
5836
5837 if (xmlFAGenerateTransitions(am, from, to, atom) < 0) {
5838 xmlRegFreeAtom(atom);
5839 return(NULL);
5840 }
5841 am->negs++;
5842 if (to == NULL)
5843 return(am->state);
5844 return(to);
5845}
5846
5847/**
5848 * xmlAutomataNewCountTrans2:
5849 * @am: an automata
5850 * @from: the starting point of the transition
5851 * @to: the target point of the transition or NULL
5852 * @token: the input string associated to that transition
5853 * @token2: the second input string associated to that transition
5854 * @min: the minimum successive occurences of token
5855 * @max: the maximum successive occurences of token
5856 * @data: data associated to the transition
5857 *
5858 * If @to is NULL, this creates first a new target state in the automata
5859 * and then adds a transition from the @from state to the target state
5860 * activated by a succession of input of value @token and @token2 and
5861 * whose number is between @min and @max
5862 *
5863 * Returns the target state or NULL in case of error
5864 */
5865xmlAutomataStatePtr
5866xmlAutomataNewCountTrans2(xmlAutomataPtr am, xmlAutomataStatePtr from,
5867 xmlAutomataStatePtr to, const xmlChar *token,
5868 const xmlChar *token2,
5869 int min, int max, void *data) {
5870 xmlRegAtomPtr atom;
5871 int counter;
5872
5873 if ((am == NULL) || (from == NULL) || (token == NULL))
5874 return(NULL);
5875 if (min < 0)
5876 return(NULL);
5877 if ((max < min) || (max < 1))
5878 return(NULL);
5879 atom = xmlRegNewAtom(am, XML_REGEXP_STRING);
5880 if (atom == NULL)
5881 return(NULL);
5882 if ((token2 == NULL) || (*token2 == 0)) {
5883 atom->valuep = xmlStrdup(token);
5884 } else {
5885 int lenn, lenp;
5886 xmlChar *str;
5887
5888 lenn = strlen((char *) token2);
5889 lenp = strlen((char *) token);
5890
5891 str = (xmlChar *) xmlMallocAtomic(lenn + lenp + 2);
5892 if (str == NULL) {
5893 xmlRegFreeAtom(atom);
5894 return(NULL);
5895 }
5896 memcpy(&str[0], token, lenp);
5897 str[lenp] = '|';
5898 memcpy(&str[lenp + 1], token2, lenn);
5899 str[lenn + lenp + 1] = 0;
5900
5901 atom->valuep = str;
5902 }
5903 atom->data = data;
5904 if (min == 0)
5905 atom->min = 1;
5906 else
5907 atom->min = min;
5908 atom->max = max;
5909
5910 /*
5911 * associate a counter to the transition.
5912 */
5913 counter = xmlRegGetCounter(am);
5914 am->counters[counter].min = min;
5915 am->counters[counter].max = max;
5916
5917 /* xmlFAGenerateTransitions(am, from, to, atom); */
5918 if (to == NULL) {
5919 to = xmlRegNewState(am);
5920 xmlRegStatePush(am, to);
5921 }
5922 xmlRegStateAddTrans(am, from, atom, to, counter, -1);
5923 xmlRegAtomPush(am, atom);
5924 am->state = to;
5925
5926 if (to == NULL)
5927 to = am->state;
5928 if (to == NULL)
5929 return(NULL);
5930 if (min == 0)
5931 xmlFAGenerateEpsilonTransition(am, from, to);
5932 return(to);
5933}
5934
5935/**
5936 * xmlAutomataNewCountTrans:
5937 * @am: an automata
5938 * @from: the starting point of the transition
5939 * @to: the target point of the transition or NULL
5940 * @token: the input string associated to that transition
5941 * @min: the minimum successive occurences of token
5942 * @max: the maximum successive occurences of token
5943 * @data: data associated to the transition
5944 *
5945 * If @to is NULL, this creates first a new target state in the automata
5946 * and then adds a transition from the @from state to the target state
5947 * activated by a succession of input of value @token and whose number
5948 * is between @min and @max
5949 *
5950 * Returns the target state or NULL in case of error
5951 */
5952xmlAutomataStatePtr
5953xmlAutomataNewCountTrans(xmlAutomataPtr am, xmlAutomataStatePtr from,
5954 xmlAutomataStatePtr to, const xmlChar *token,
5955 int min, int max, void *data) {
5956 xmlRegAtomPtr atom;
5957 int counter;
5958
5959 if ((am == NULL) || (from == NULL) || (token == NULL))
5960 return(NULL);
5961 if (min < 0)
5962 return(NULL);
5963 if ((max < min) || (max < 1))
5964 return(NULL);
5965 atom = xmlRegNewAtom(am, XML_REGEXP_STRING);
5966 if (atom == NULL)
5967 return(NULL);
5968 atom->valuep = xmlStrdup(token);
5969 atom->data = data;
5970 if (min == 0)
5971 atom->min = 1;
5972 else
5973 atom->min = min;
5974 atom->max = max;
5975
5976 /*
5977 * associate a counter to the transition.
5978 */
5979 counter = xmlRegGetCounter(am);
5980 am->counters[counter].min = min;
5981 am->counters[counter].max = max;
5982
5983 /* xmlFAGenerateTransitions(am, from, to, atom); */
5984 if (to == NULL) {
5985 to = xmlRegNewState(am);
5986 xmlRegStatePush(am, to);
5987 }
5988 xmlRegStateAddTrans(am, from, atom, to, counter, -1);
5989 xmlRegAtomPush(am, atom);
5990 am->state = to;
5991
5992 if (to == NULL)
5993 to = am->state;
5994 if (to == NULL)
5995 return(NULL);
5996 if (min == 0)
5997 xmlFAGenerateEpsilonTransition(am, from, to);
5998 return(to);
5999}
6000
6001/**
6002 * xmlAutomataNewOnceTrans2:
6003 * @am: an automata
6004 * @from: the starting point of the transition
6005 * @to: the target point of the transition or NULL
6006 * @token: the input string associated to that transition
6007 * @token2: the second input string associated to that transition
6008 * @min: the minimum successive occurences of token
6009 * @max: the maximum successive occurences of token
6010 * @data: data associated to the transition
6011 *
6012 * If @to is NULL, this creates first a new target state in the automata
6013 * and then adds a transition from the @from state to the target state
6014 * activated by a succession of input of value @token and @token2 and whose
6015 * number is between @min and @max, moreover that transition can only be
6016 * crossed once.
6017 *
6018 * Returns the target state or NULL in case of error
6019 */
6020xmlAutomataStatePtr
6021xmlAutomataNewOnceTrans2(xmlAutomataPtr am, xmlAutomataStatePtr from,
6022 xmlAutomataStatePtr to, const xmlChar *token,
6023 const xmlChar *token2,
6024 int min, int max, void *data) {
6025 xmlRegAtomPtr atom;
6026 int counter;
6027
6028 if ((am == NULL) || (from == NULL) || (token == NULL))
6029 return(NULL);
6030 if (min < 1)
6031 return(NULL);
6032 if ((max < min) || (max < 1))
6033 return(NULL);
6034 atom = xmlRegNewAtom(am, XML_REGEXP_STRING);
6035 if (atom == NULL)
6036 return(NULL);
6037 if ((token2 == NULL) || (*token2 == 0)) {
6038 atom->valuep = xmlStrdup(token);
6039 } else {
6040 int lenn, lenp;
6041 xmlChar *str;
6042
6043 lenn = strlen((char *) token2);
6044 lenp = strlen((char *) token);
6045
6046 str = (xmlChar *) xmlMallocAtomic(lenn + lenp + 2);
6047 if (str == NULL) {
6048 xmlRegFreeAtom(atom);
6049 return(NULL);
6050 }
6051 memcpy(&str[0], token, lenp);
6052 str[lenp] = '|';
6053 memcpy(&str[lenp + 1], token2, lenn);
6054 str[lenn + lenp + 1] = 0;
6055
6056 atom->valuep = str;
6057 }
6058 atom->data = data;
6059 atom->quant = XML_REGEXP_QUANT_ONCEONLY;
6060 atom->min = min;
6061 atom->max = max;
6062 /*
6063 * associate a counter to the transition.
6064 */
6065 counter = xmlRegGetCounter(am);
6066 am->counters[counter].min = 1;
6067 am->counters[counter].max = 1;
6068
6069 /* xmlFAGenerateTransitions(am, from, to, atom); */
6070 if (to == NULL) {
6071 to = xmlRegNewState(am);
6072 xmlRegStatePush(am, to);
6073 }
6074 xmlRegStateAddTrans(am, from, atom, to, counter, -1);
6075 xmlRegAtomPush(am, atom);
6076 am->state = to;
6077 return(to);
6078}
6079
6080
6081
6082/**
6083 * xmlAutomataNewOnceTrans:
6084 * @am: an automata
6085 * @from: the starting point of the transition
6086 * @to: the target point of the transition or NULL
6087 * @token: the input string associated to that transition
6088 * @min: the minimum successive occurences of token
6089 * @max: the maximum successive occurences of token
6090 * @data: data associated to the transition
6091 *
6092 * If @to is NULL, this creates first a new target state in the automata
6093 * and then adds a transition from the @from state to the target state
6094 * activated by a succession of input of value @token and whose number
6095 * is between @min and @max, moreover that transition can only be crossed
6096 * once.
6097 *
6098 * Returns the target state or NULL in case of error
6099 */
6100xmlAutomataStatePtr
6101xmlAutomataNewOnceTrans(xmlAutomataPtr am, xmlAutomataStatePtr from,
6102 xmlAutomataStatePtr to, const xmlChar *token,
6103 int min, int max, void *data) {
6104 xmlRegAtomPtr atom;
6105 int counter;
6106
6107 if ((am == NULL) || (from == NULL) || (token == NULL))
6108 return(NULL);
6109 if (min < 1)
6110 return(NULL);
6111 if ((max < min) || (max < 1))
6112 return(NULL);
6113 atom = xmlRegNewAtom(am, XML_REGEXP_STRING);
6114 if (atom == NULL)
6115 return(NULL);
6116 atom->valuep = xmlStrdup(token);
6117 atom->data = data;
6118 atom->quant = XML_REGEXP_QUANT_ONCEONLY;
6119 atom->min = min;
6120 atom->max = max;
6121 /*
6122 * associate a counter to the transition.
6123 */
6124 counter = xmlRegGetCounter(am);
6125 am->counters[counter].min = 1;
6126 am->counters[counter].max = 1;
6127
6128 /* xmlFAGenerateTransitions(am, from, to, atom); */
6129 if (to == NULL) {
6130 to = xmlRegNewState(am);
6131 xmlRegStatePush(am, to);
6132 }
6133 xmlRegStateAddTrans(am, from, atom, to, counter, -1);
6134 xmlRegAtomPush(am, atom);
6135 am->state = to;
6136 return(to);
6137}
6138
6139/**
6140 * xmlAutomataNewState:
6141 * @am: an automata
6142 *
6143 * Create a new disconnected state in the automata
6144 *
6145 * Returns the new state or NULL in case of error
6146 */
6147xmlAutomataStatePtr
6148xmlAutomataNewState(xmlAutomataPtr am) {
6149 xmlAutomataStatePtr to;
6150
6151 if (am == NULL)
6152 return(NULL);
6153 to = xmlRegNewState(am);
6154 xmlRegStatePush(am, to);
6155 return(to);
6156}
6157
6158/**
6159 * xmlAutomataNewEpsilon:
6160 * @am: an automata
6161 * @from: the starting point of the transition
6162 * @to: the target point of the transition or NULL
6163 *
6164 * If @to is NULL, this creates first a new target state in the automata
6165 * and then adds an epsilon transition from the @from state to the
6166 * target state
6167 *
6168 * Returns the target state or NULL in case of error
6169 */
6170xmlAutomataStatePtr
6171xmlAutomataNewEpsilon(xmlAutomataPtr am, xmlAutomataStatePtr from,
6172 xmlAutomataStatePtr to) {
6173 if ((am == NULL) || (from == NULL))
6174 return(NULL);
6175 xmlFAGenerateEpsilonTransition(am, from, to);
6176 if (to == NULL)
6177 return(am->state);
6178 return(to);
6179}
6180
6181/**
6182 * xmlAutomataNewAllTrans:
6183 * @am: an automata
6184 * @from: the starting point of the transition
6185 * @to: the target point of the transition or NULL
6186 * @lax: allow to transition if not all all transitions have been activated
6187 *
6188 * If @to is NULL, this creates first a new target state in the automata
6189 * and then adds a an ALL transition from the @from state to the
6190 * target state. That transition is an epsilon transition allowed only when
6191 * all transitions from the @from node have been activated.
6192 *
6193 * Returns the target state or NULL in case of error
6194 */
6195xmlAutomataStatePtr
6196xmlAutomataNewAllTrans(xmlAutomataPtr am, xmlAutomataStatePtr from,
6197 xmlAutomataStatePtr to, int lax) {
6198 if ((am == NULL) || (from == NULL))
6199 return(NULL);
6200 xmlFAGenerateAllTransition(am, from, to, lax);
6201 if (to == NULL)
6202 return(am->state);
6203 return(to);
6204}
6205
6206/**
6207 * xmlAutomataNewCounter:
6208 * @am: an automata
6209 * @min: the minimal value on the counter
6210 * @max: the maximal value on the counter
6211 *
6212 * Create a new counter
6213 *
6214 * Returns the counter number or -1 in case of error
6215 */
6216int
6217xmlAutomataNewCounter(xmlAutomataPtr am, int min, int max) {
6218 int ret;
6219
6220 if (am == NULL)
6221 return(-1);
6222
6223 ret = xmlRegGetCounter(am);
6224 if (ret < 0)
6225 return(-1);
6226 am->counters[ret].min = min;
6227 am->counters[ret].max = max;
6228 return(ret);
6229}
6230
6231/**
6232 * xmlAutomataNewCountedTrans:
6233 * @am: an automata
6234 * @from: the starting point of the transition
6235 * @to: the target point of the transition or NULL
6236 * @counter: the counter associated to that transition
6237 *
6238 * If @to is NULL, this creates first a new target state in the automata
6239 * and then adds an epsilon transition from the @from state to the target state
6240 * which will increment the counter provided
6241 *
6242 * Returns the target state or NULL in case of error
6243 */
6244xmlAutomataStatePtr
6245xmlAutomataNewCountedTrans(xmlAutomataPtr am, xmlAutomataStatePtr from,
6246 xmlAutomataStatePtr to, int counter) {
6247 if ((am == NULL) || (from == NULL) || (counter < 0))
6248 return(NULL);
6249 xmlFAGenerateCountedEpsilonTransition(am, from, to, counter);
6250 if (to == NULL)
6251 return(am->state);
6252 return(to);
6253}
6254
6255/**
6256 * xmlAutomataNewCounterTrans:
6257 * @am: an automata
6258 * @from: the starting point of the transition
6259 * @to: the target point of the transition or NULL
6260 * @counter: the counter associated to that transition
6261 *
6262 * If @to is NULL, this creates first a new target state in the automata
6263 * and then adds an epsilon transition from the @from state to the target state
6264 * which will be allowed only if the counter is within the right range.
6265 *
6266 * Returns the target state or NULL in case of error
6267 */
6268xmlAutomataStatePtr
6269xmlAutomataNewCounterTrans(xmlAutomataPtr am, xmlAutomataStatePtr from,
6270 xmlAutomataStatePtr to, int counter) {
6271 if ((am == NULL) || (from == NULL) || (counter < 0))
6272 return(NULL);
6273 xmlFAGenerateCountedTransition(am, from, to, counter);
6274 if (to == NULL)
6275 return(am->state);
6276 return(to);
6277}
6278
6279/**
6280 * xmlAutomataCompile:
6281 * @am: an automata
6282 *
6283 * Compile the automata into a Reg Exp ready for being executed.
6284 * The automata should be free after this point.
6285 *
6286 * Returns the compiled regexp or NULL in case of error
6287 */
6288xmlRegexpPtr
6289xmlAutomataCompile(xmlAutomataPtr am) {
6290 xmlRegexpPtr ret;
6291
6292 if ((am == NULL) || (am->error != 0)) return(NULL);
6293 xmlFAEliminateEpsilonTransitions(am);
6294 /* xmlFAComputesDeterminism(am); */
6295 ret = xmlRegEpxFromParse(am);
6296
6297 return(ret);
6298}
6299
6300/**
6301 * xmlAutomataIsDeterminist:
6302 * @am: an automata
6303 *
6304 * Checks if an automata is determinist.
6305 *
6306 * Returns 1 if true, 0 if not, and -1 in case of error
6307 */
6308int
6309xmlAutomataIsDeterminist(xmlAutomataPtr am) {
6310 int ret;
6311
6312 if (am == NULL)
6313 return(-1);
6314
6315 ret = xmlFAComputesDeterminism(am);
6316 return(ret);
6317}
6318#endif /* LIBXML_AUTOMATA_ENABLED */
6319
6320#ifdef LIBXML_EXPR_ENABLED
6321/************************************************************************
6322 * *
6323 * Formal Expression handling code *
6324 * *
6325 ************************************************************************/
6326/************************************************************************
6327 * *
6328 * Expression handling context *
6329 * *
6330 ************************************************************************/
6331
6332struct _xmlExpCtxt {
6333 xmlDictPtr dict;
6334 xmlExpNodePtr *table;
6335 int size;
6336 int nbElems;
6337 int nb_nodes;
6338 int maxNodes;
6339 const char *expr;
6340 const char *cur;
6341 int nb_cons;
6342 int tabSize;
6343};
6344
6345/**
6346 * xmlExpNewCtxt:
6347 * @maxNodes: the maximum number of nodes
6348 * @dict: optional dictionnary to use internally
6349 *
6350 * Creates a new context for manipulating expressions
6351 *
6352 * Returns the context or NULL in case of error
6353 */
6354xmlExpCtxtPtr
6355xmlExpNewCtxt(int maxNodes, xmlDictPtr dict) {
6356 xmlExpCtxtPtr ret;
6357 int size = 256;
6358
6359 if (maxNodes <= 4096)
6360 maxNodes = 4096;
6361
6362 ret = (xmlExpCtxtPtr) xmlMalloc(sizeof(xmlExpCtxt));
6363 if (ret == NULL)
6364 return(NULL);
6365 memset(ret, 0, sizeof(xmlExpCtxt));
6366 ret->size = size;
6367 ret->nbElems = 0;
6368 ret->maxNodes = maxNodes;
6369 ret->table = xmlMalloc(size * sizeof(xmlExpNodePtr));
6370 if (ret->table == NULL) {
6371 xmlFree(ret);
6372 return(NULL);
6373 }
6374 memset(ret->table, 0, size * sizeof(xmlExpNodePtr));
6375 if (dict == NULL) {
6376 ret->dict = xmlDictCreate();
6377 if (ret->dict == NULL) {
6378 xmlFree(ret->table);
6379 xmlFree(ret);
6380 return(NULL);
6381 }
6382 } else {
6383 ret->dict = dict;
6384 xmlDictReference(ret->dict);
6385 }
6386 return(ret);
6387}
6388
6389/**
6390 * xmlExpFreeCtxt:
6391 * @ctxt: an expression context
6392 *
6393 * Free an expression context
6394 */
6395void
6396xmlExpFreeCtxt(xmlExpCtxtPtr ctxt) {
6397 if (ctxt == NULL)
6398 return;
6399 xmlDictFree(ctxt->dict);
6400 if (ctxt->table != NULL)
6401 xmlFree(ctxt->table);
6402 xmlFree(ctxt);
6403}
6404
6405/************************************************************************
6406 * *
6407 * Structure associated to an expression node *
6408 * *
6409 ************************************************************************/
6410#define MAX_NODES 10000
6411
6412/* #define DEBUG_DERIV */
6413
6414/*
6415 * TODO:
6416 * - Wildcards
6417 * - public API for creation
6418 *
6419 * Started
6420 * - regression testing
6421 *
6422 * Done
6423 * - split into module and test tool
6424 * - memleaks
6425 */
6426
6427typedef enum {
6428 XML_EXP_NILABLE = (1 << 0)
6429} xmlExpNodeInfo;
6430
6431#define IS_NILLABLE(node) ((node)->info & XML_EXP_NILABLE)
6432
6433struct _xmlExpNode {
6434 unsigned char type;/* xmlExpNodeType */
6435 unsigned char info;/* OR of xmlExpNodeInfo */
6436 unsigned short key; /* the hash key */
6437 unsigned int ref; /* The number of references */
6438 int c_max; /* the maximum length it can consume */
6439 xmlExpNodePtr exp_left;
6440 xmlExpNodePtr next;/* the next node in the hash table or free list */
6441 union {
6442 struct {
6443 int f_min;
6444 int f_max;
6445 } count;
6446 struct {
6447 xmlExpNodePtr f_right;
6448 } children;
6449 const xmlChar *f_str;
6450 } field;
6451};
6452
6453#define exp_min field.count.f_min
6454#define exp_max field.count.f_max
6455/* #define exp_left field.children.f_left */
6456#define exp_right field.children.f_right
6457#define exp_str field.f_str
6458
6459static xmlExpNodePtr xmlExpNewNode(xmlExpCtxtPtr ctxt, xmlExpNodeType type);
6460static xmlExpNode forbiddenExpNode = {
6461 XML_EXP_FORBID, 0, 0, 0, 0, NULL, NULL, {{ 0, 0}}
6462};
6463xmlExpNodePtr forbiddenExp = &forbiddenExpNode;
6464static xmlExpNode emptyExpNode = {
6465 XML_EXP_EMPTY, 1, 0, 0, 0, NULL, NULL, {{ 0, 0}}
6466};
6467xmlExpNodePtr emptyExp = &emptyExpNode;
6468
6469/************************************************************************
6470 * *
6471 * The custom hash table for unicity and canonicalization *
6472 * of sub-expressions pointers *
6473 * *
6474 ************************************************************************/
6475/*
6476 * xmlExpHashNameComputeKey:
6477 * Calculate the hash key for a token
6478 */
6479static unsigned short
6480xmlExpHashNameComputeKey(const xmlChar *name) {
6481 unsigned short value = 0L;
6482 char ch;
6483
6484 if (name != NULL) {
6485 value += 30 * (*name);
6486 while ((ch = *name++) != 0) {
6487 value = value ^ ((value << 5) + (value >> 3) + (unsigned long)ch);
6488 }
6489 }
6490 return (value);
6491}
6492
6493/*
6494 * xmlExpHashComputeKey:
6495 * Calculate the hash key for a compound expression
6496 */
6497static unsigned short
6498xmlExpHashComputeKey(xmlExpNodeType type, xmlExpNodePtr left,
6499 xmlExpNodePtr right) {
6500 unsigned long value;
6501 unsigned short ret;
6502
6503 switch (type) {
6504 case XML_EXP_SEQ:
6505 value = left->key;
6506 value += right->key;
6507 value *= 3;
6508 ret = (unsigned short) value;
6509 break;
6510 case XML_EXP_OR:
6511 value = left->key;
6512 value += right->key;
6513 value *= 7;
6514 ret = (unsigned short) value;
6515 break;
6516 case XML_EXP_COUNT:
6517 value = left->key;
6518 value += right->key;
6519 ret = (unsigned short) value;
6520 break;
6521 default:
6522 ret = 0;
6523 }
6524 return(ret);
6525}
6526
6527
6528static xmlExpNodePtr
6529xmlExpNewNode(xmlExpCtxtPtr ctxt, xmlExpNodeType type) {
6530 xmlExpNodePtr ret;
6531
6532 if (ctxt->nb_nodes >= MAX_NODES)
6533 return(NULL);
6534 ret = (xmlExpNodePtr) xmlMalloc(sizeof(xmlExpNode));
6535 if (ret == NULL)
6536 return(NULL);
6537 memset(ret, 0, sizeof(xmlExpNode));
6538 ret->type = type;
6539 ret->next = NULL;
6540 ctxt->nb_nodes++;
6541 ctxt->nb_cons++;
6542 return(ret);
6543}
6544
6545/**
6546 * xmlExpHashGetEntry:
6547 * @table: the hash table
6548 *
6549 * Get the unique entry from the hash table. The entry is created if
6550 * needed. @left and @right are consumed, i.e. their ref count will
6551 * be decremented by the operation.
6552 *
6553 * Returns the pointer or NULL in case of error
6554 */
6555static xmlExpNodePtr
6556xmlExpHashGetEntry(xmlExpCtxtPtr ctxt, xmlExpNodeType type,
6557 xmlExpNodePtr left, xmlExpNodePtr right,
6558 const xmlChar *name, int min, int max) {
6559 unsigned short kbase, key;
6560 xmlExpNodePtr entry;
6561 xmlExpNodePtr insert;
6562
6563 if (ctxt == NULL)
6564 return(NULL);
6565
6566 /*
6567 * Check for duplicate and insertion location.
6568 */
6569 if (type == XML_EXP_ATOM) {
6570 kbase = xmlExpHashNameComputeKey(name);
6571 } else if (type == XML_EXP_COUNT) {
6572 /* COUNT reduction rule 1 */
6573 /* a{1} -> a */
6574 if (min == max) {
6575 if (min == 1) {
6576 return(left);
6577 }
6578 if (min == 0) {
6579 xmlExpFree(ctxt, left);
6580 return(emptyExp);
6581 }
6582 }
6583 if (min < 0) {
6584 xmlExpFree(ctxt, left);
6585 return(forbiddenExp);
6586 }
6587 if (max == -1)
6588 kbase = min + 79;
6589 else
6590 kbase = max - min;
6591 kbase += left->key;
6592 } else if (type == XML_EXP_OR) {
6593 /* Forbid reduction rules */
6594 if (left->type == XML_EXP_FORBID) {
6595 xmlExpFree(ctxt, left);
6596 return(right);
6597 }
6598 if (right->type == XML_EXP_FORBID) {
6599 xmlExpFree(ctxt, right);
6600 return(left);
6601 }
6602
6603 /* OR reduction rule 1 */
6604 /* a | a reduced to a */
6605 if (left == right) {
6606 left->ref--;
6607 return(left);
6608 }
6609 /* OR canonicalization rule 1 */
6610 /* linearize (a | b) | c into a | (b | c) */
6611 if ((left->type == XML_EXP_OR) && (right->type != XML_EXP_OR)) {
6612 xmlExpNodePtr tmp = left;
6613 left = right;
6614 right = tmp;
6615 }
6616 /* OR reduction rule 2 */
6617 /* a | (a | b) and b | (a | b) are reduced to a | b */
6618 if (right->type == XML_EXP_OR) {
6619 if ((left == right->exp_left) ||
6620 (left == right->exp_right)) {
6621 xmlExpFree(ctxt, left);
6622 return(right);
6623 }
6624 }
6625 /* OR canonicalization rule 2 */
6626 /* linearize (a | b) | c into a | (b | c) */
6627 if (left->type == XML_EXP_OR) {
6628 xmlExpNodePtr tmp;
6629
6630 /* OR canonicalization rule 2 */
6631 if ((left->exp_right->type != XML_EXP_OR) &&
6632 (left->exp_right->key < left->exp_left->key)) {
6633 tmp = left->exp_right;
6634 left->exp_right = left->exp_left;
6635 left->exp_left = tmp;
6636 }
6637 left->exp_right->ref++;
6638 tmp = xmlExpHashGetEntry(ctxt, XML_EXP_OR, left->exp_right, right,
6639 NULL, 0, 0);
6640 left->exp_left->ref++;
6641 tmp = xmlExpHashGetEntry(ctxt, XML_EXP_OR, left->exp_left, tmp,
6642 NULL, 0, 0);
6643
6644 xmlExpFree(ctxt, left);
6645 return(tmp);
6646 }
6647 if (right->type == XML_EXP_OR) {
6648 /* Ordering in the tree */
6649 /* C | (A | B) -> A | (B | C) */
6650 if (left->key > right->exp_right->key) {
6651 xmlExpNodePtr tmp;
6652 right->exp_right->ref++;
6653 tmp = xmlExpHashGetEntry(ctxt, XML_EXP_OR, right->exp_right,
6654 left, NULL, 0, 0);
6655 right->exp_left->ref++;
6656 tmp = xmlExpHashGetEntry(ctxt, XML_EXP_OR, right->exp_left,
6657 tmp, NULL, 0, 0);
6658 xmlExpFree(ctxt, right);
6659 return(tmp);
6660 }
6661 /* Ordering in the tree */
6662 /* B | (A | C) -> A | (B | C) */
6663 if (left->key > right->exp_left->key) {
6664 xmlExpNodePtr tmp;
6665 right->exp_right->ref++;
6666 tmp = xmlExpHashGetEntry(ctxt, XML_EXP_OR, left,
6667 right->exp_right, NULL, 0, 0);
6668 right->exp_left->ref++;
6669 tmp = xmlExpHashGetEntry(ctxt, XML_EXP_OR, right->exp_left,
6670 tmp, NULL, 0, 0);
6671 xmlExpFree(ctxt, right);
6672 return(tmp);
6673 }
6674 }
6675 /* we know both types are != XML_EXP_OR here */
6676 else if (left->key > right->key) {
6677 xmlExpNodePtr tmp = left;
6678 left = right;
6679 right = tmp;
6680 }
6681 kbase = xmlExpHashComputeKey(type, left, right);
6682 } else if (type == XML_EXP_SEQ) {
6683 /* Forbid reduction rules */
6684 if (left->type == XML_EXP_FORBID) {
6685 xmlExpFree(ctxt, right);
6686 return(left);
6687 }
6688 if (right->type == XML_EXP_FORBID) {
6689 xmlExpFree(ctxt, left);
6690 return(right);
6691 }
6692 /* Empty reduction rules */
6693 if (right->type == XML_EXP_EMPTY) {
6694 return(left);
6695 }
6696 if (left->type == XML_EXP_EMPTY) {
6697 return(right);
6698 }
6699 kbase = xmlExpHashComputeKey(type, left, right);
6700 } else
6701 return(NULL);
6702
6703 key = kbase % ctxt->size;
6704 if (ctxt->table[key] != NULL) {
6705 for (insert = ctxt->table[key]; insert != NULL;
6706 insert = insert->next) {
6707 if ((insert->key == kbase) &&
6708 (insert->type == type)) {
6709 if (type == XML_EXP_ATOM) {
6710 if (name == insert->exp_str) {
6711 insert->ref++;
6712 return(insert);
6713 }
6714 } else if (type == XML_EXP_COUNT) {
6715 if ((insert->exp_min == min) && (insert->exp_max == max) &&
6716 (insert->exp_left == left)) {
6717 insert->ref++;
6718 left->ref--;
6719 return(insert);
6720 }
6721 } else if ((insert->exp_left == left) &&
6722 (insert->exp_right == right)) {
6723 insert->ref++;
6724 left->ref--;
6725 right->ref--;
6726 return(insert);
6727 }
6728 }
6729 }
6730 }
6731
6732 entry = xmlExpNewNode(ctxt, type);
6733 if (entry == NULL)
6734 return(NULL);
6735 entry->key = kbase;
6736 if (type == XML_EXP_ATOM) {
6737 entry->exp_str = name;
6738 entry->c_max = 1;
6739 } else if (type == XML_EXP_COUNT) {
6740 entry->exp_min = min;
6741 entry->exp_max = max;
6742 entry->exp_left = left;
6743 if ((min == 0) || (IS_NILLABLE(left)))
6744 entry->info |= XML_EXP_NILABLE;
6745 if (max < 0)
6746 entry->c_max = -1;
6747 else
6748 entry->c_max = max * entry->exp_left->c_max;
6749 } else {
6750 entry->exp_left = left;
6751 entry->exp_right = right;
6752 if (type == XML_EXP_OR) {
6753 if ((IS_NILLABLE(left)) || (IS_NILLABLE(right)))
6754 entry->info |= XML_EXP_NILABLE;
6755 if ((entry->exp_left->c_max == -1) ||
6756 (entry->exp_right->c_max == -1))
6757 entry->c_max = -1;
6758 else if (entry->exp_left->c_max > entry->exp_right->c_max)
6759 entry->c_max = entry->exp_left->c_max;
6760 else
6761 entry->c_max = entry->exp_right->c_max;
6762 } else {
6763 if ((IS_NILLABLE(left)) && (IS_NILLABLE(right)))
6764 entry->info |= XML_EXP_NILABLE;
6765 if ((entry->exp_left->c_max == -1) ||
6766 (entry->exp_right->c_max == -1))
6767 entry->c_max = -1;
6768 else
6769 entry->c_max = entry->exp_left->c_max + entry->exp_right->c_max;
6770 }
6771 }
6772 entry->ref = 1;
6773 if (ctxt->table[key] != NULL)
6774 entry->next = ctxt->table[key];
6775
6776 ctxt->table[key] = entry;
6777 ctxt->nbElems++;
6778
6779 return(entry);
6780}
6781
6782/**
6783 * xmlExpFree:
6784 * @ctxt: the expression context
6785 * @exp: the expression
6786 *
6787 * Dereference the expression
6788 */
6789void
6790xmlExpFree(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp) {
6791 if ((exp == NULL) || (exp == forbiddenExp) || (exp == emptyExp))
6792 return;
6793 exp->ref--;
6794 if (exp->ref == 0) {
6795 unsigned short key;
6796
6797 /* Unlink it first from the hash table */
6798 key = exp->key % ctxt->size;
6799 if (ctxt->table[key] == exp) {
6800 ctxt->table[key] = exp->next;
6801 } else {
6802 xmlExpNodePtr tmp;
6803
6804 tmp = ctxt->table[key];
6805 while (tmp != NULL) {
6806 if (tmp->next == exp) {
6807 tmp->next = exp->next;
6808 break;
6809 }
6810 tmp = tmp->next;
6811 }
6812 }
6813
6814 if ((exp->type == XML_EXP_SEQ) || (exp->type == XML_EXP_OR)) {
6815 xmlExpFree(ctxt, exp->exp_left);
6816 xmlExpFree(ctxt, exp->exp_right);
6817 } else if (exp->type == XML_EXP_COUNT) {
6818 xmlExpFree(ctxt, exp->exp_left);
6819 }
6820 xmlFree(exp);
6821 ctxt->nb_nodes--;
6822 }
6823}
6824
6825/**
6826 * xmlExpRef:
6827 * @exp: the expression
6828 *
6829 * Increase the reference count of the expression
6830 */
6831void
6832xmlExpRef(xmlExpNodePtr exp) {
6833 if (exp != NULL)
6834 exp->ref++;
6835}
6836
6837/**
6838 * xmlExpNewAtom:
6839 * @ctxt: the expression context
6840 * @name: the atom name
6841 * @len: the atom name length in byte (or -1);
6842 *
6843 * Get the atom associated to this name from that context
6844 *
6845 * Returns the node or NULL in case of error
6846 */
6847xmlExpNodePtr
6848xmlExpNewAtom(xmlExpCtxtPtr ctxt, const xmlChar *name, int len) {
6849 if ((ctxt == NULL) || (name == NULL))
6850 return(NULL);
6851 name = xmlDictLookup(ctxt->dict, name, len);
6852 if (name == NULL)
6853 return(NULL);
6854 return(xmlExpHashGetEntry(ctxt, XML_EXP_ATOM, NULL, NULL, name, 0, 0));
6855}
6856
6857/**
6858 * xmlExpNewOr:
6859 * @ctxt: the expression context
6860 * @left: left expression
6861 * @right: right expression
6862 *
6863 * Get the atom associated to the choice @left | @right
6864 * Note that @left and @right are consumed in the operation, to keep
6865 * an handle on them use xmlExpRef() and use xmlExpFree() to release them,
6866 * this is true even in case of failure (unless ctxt == NULL).
6867 *
6868 * Returns the node or NULL in case of error
6869 */
6870xmlExpNodePtr
6871xmlExpNewOr(xmlExpCtxtPtr ctxt, xmlExpNodePtr left, xmlExpNodePtr right) {
6872 if (ctxt == NULL)
6873 return(NULL);
6874 if ((left == NULL) || (right == NULL)) {
6875 xmlExpFree(ctxt, left);
6876 xmlExpFree(ctxt, right);
6877 return(NULL);
6878 }
6879 return(xmlExpHashGetEntry(ctxt, XML_EXP_OR, left, right, NULL, 0, 0));
6880}
6881
6882/**
6883 * xmlExpNewSeq:
6884 * @ctxt: the expression context
6885 * @left: left expression
6886 * @right: right expression
6887 *
6888 * Get the atom associated to the sequence @left , @right
6889 * Note that @left and @right are consumed in the operation, to keep
6890 * an handle on them use xmlExpRef() and use xmlExpFree() to release them,
6891 * this is true even in case of failure (unless ctxt == NULL).
6892 *
6893 * Returns the node or NULL in case of error
6894 */
6895xmlExpNodePtr
6896xmlExpNewSeq(xmlExpCtxtPtr ctxt, xmlExpNodePtr left, xmlExpNodePtr right) {
6897 if (ctxt == NULL)
6898 return(NULL);
6899 if ((left == NULL) || (right == NULL)) {
6900 xmlExpFree(ctxt, left);
6901 xmlExpFree(ctxt, right);
6902 return(NULL);
6903 }
6904 return(xmlExpHashGetEntry(ctxt, XML_EXP_SEQ, left, right, NULL, 0, 0));
6905}
6906
6907/**
6908 * xmlExpNewRange:
6909 * @ctxt: the expression context
6910 * @subset: the expression to be repeated
6911 * @min: the lower bound for the repetition
6912 * @max: the upper bound for the repetition, -1 means infinite
6913 *
6914 * Get the atom associated to the range (@subset){@min, @max}
6915 * Note that @subset is consumed in the operation, to keep
6916 * an handle on it use xmlExpRef() and use xmlExpFree() to release it,
6917 * this is true even in case of failure (unless ctxt == NULL).
6918 *
6919 * Returns the node or NULL in case of error
6920 */
6921xmlExpNodePtr
6922xmlExpNewRange(xmlExpCtxtPtr ctxt, xmlExpNodePtr subset, int min, int max) {
6923 if (ctxt == NULL)
6924 return(NULL);
6925 if ((subset == NULL) || (min < 0) || (max < -1) ||
6926 ((max >= 0) && (min > max))) {
6927 xmlExpFree(ctxt, subset);
6928 return(NULL);
6929 }
6930 return(xmlExpHashGetEntry(ctxt, XML_EXP_COUNT, subset,
6931 NULL, NULL, min, max));
6932}
6933
6934/************************************************************************
6935 * *
6936 * Public API for operations on expressions *
6937 * *
6938 ************************************************************************/
6939
6940static int
6941xmlExpGetLanguageInt(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp,
6942 const xmlChar**list, int len, int nb) {
6943 int tmp, tmp2;
6944tail:
6945 switch (exp->type) {
6946 case XML_EXP_EMPTY:
6947 return(0);
6948 case XML_EXP_ATOM:
6949 for (tmp = 0;tmp < nb;tmp++)
6950 if (list[tmp] == exp->exp_str)
6951 return(0);
6952 if (nb >= len)
6953 return(-2);
6954 list[nb] = exp->exp_str;
6955 return(1);
6956 case XML_EXP_COUNT:
6957 exp = exp->exp_left;
6958 goto tail;
6959 case XML_EXP_SEQ:
6960 case XML_EXP_OR:
6961 tmp = xmlExpGetLanguageInt(ctxt, exp->exp_left, list, len, nb);
6962 if (tmp < 0)
6963 return(tmp);
6964 tmp2 = xmlExpGetLanguageInt(ctxt, exp->exp_right, list, len,
6965 nb + tmp);
6966 if (tmp2 < 0)
6967 return(tmp2);
6968 return(tmp + tmp2);
6969 }
6970 return(-1);
6971}
6972
6973/**
6974 * xmlExpGetLanguage:
6975 * @ctxt: the expression context
6976 * @exp: the expression
6977 * @langList: where to store the tokens
6978 * @len: the allocated length of @list
6979 *
6980 * Find all the strings used in @exp and store them in @list
6981 *
6982 * Returns the number of unique strings found, -1 in case of errors and
6983 * -2 if there is more than @len strings
6984 */
6985int
6986xmlExpGetLanguage(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp,
6987 const xmlChar**langList, int len) {
6988 if ((ctxt == NULL) || (exp == NULL) || (langList == NULL) || (len <= 0))
6989 return(-1);
6990 return(xmlExpGetLanguageInt(ctxt, exp, langList, len, 0));
6991}
6992
6993static int
6994xmlExpGetStartInt(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp,
6995 const xmlChar**list, int len, int nb) {
6996 int tmp, tmp2;
6997tail:
6998 switch (exp->type) {
6999 case XML_EXP_FORBID:
7000 return(0);
7001 case XML_EXP_EMPTY:
7002 return(0);
7003 case XML_EXP_ATOM:
7004 for (tmp = 0;tmp < nb;tmp++)
7005 if (list[tmp] == exp->exp_str)
7006 return(0);
7007 if (nb >= len)
7008 return(-2);
7009 list[nb] = exp->exp_str;
7010 return(1);
7011 case XML_EXP_COUNT:
7012 exp = exp->exp_left;
7013 goto tail;
7014 case XML_EXP_SEQ:
7015 tmp = xmlExpGetStartInt(ctxt, exp->exp_left, list, len, nb);
7016 if (tmp < 0)
7017 return(tmp);
7018 if (IS_NILLABLE(exp->exp_left)) {
7019 tmp2 = xmlExpGetStartInt(ctxt, exp->exp_right, list, len,
7020 nb + tmp);
7021 if (tmp2 < 0)
7022 return(tmp2);
7023 tmp += tmp2;
7024 }
7025 return(tmp);
7026 case XML_EXP_OR:
7027 tmp = xmlExpGetStartInt(ctxt, exp->exp_left, list, len, nb);
7028 if (tmp < 0)
7029 return(tmp);
7030 tmp2 = xmlExpGetStartInt(ctxt, exp->exp_right, list, len,
7031 nb + tmp);
7032 if (tmp2 < 0)
7033 return(tmp2);
7034 return(tmp + tmp2);
7035 }
7036 return(-1);
7037}
7038
7039/**
7040 * xmlExpGetStart:
7041 * @ctxt: the expression context
7042 * @exp: the expression
7043 * @tokList: where to store the tokens
7044 * @len: the allocated length of @list
7045 *
7046 * Find all the strings that appears at the start of the languages
7047 * accepted by @exp and store them in @list. E.g. for (a, b) | c
7048 * it will return the list [a, c]
7049 *
7050 * Returns the number of unique strings found, -1 in case of errors and
7051 * -2 if there is more than @len strings
7052 */
7053int
7054xmlExpGetStart(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp,
7055 const xmlChar**tokList, int len) {
7056 if ((ctxt == NULL) || (exp == NULL) || (tokList == NULL) || (len <= 0))
7057 return(-1);
7058 return(xmlExpGetStartInt(ctxt, exp, tokList, len, 0));
7059}
7060
7061/**
7062 * xmlExpIsNillable:
7063 * @exp: the expression
7064 *
7065 * Finds if the expression is nillable, i.e. if it accepts the empty sequqnce
7066 *
7067 * Returns 1 if nillable, 0 if not and -1 in case of error
7068 */
7069int
7070xmlExpIsNillable(xmlExpNodePtr exp) {
7071 if (exp == NULL)
7072 return(-1);
7073 return(IS_NILLABLE(exp) != 0);
7074}
7075
7076static xmlExpNodePtr
7077xmlExpStringDeriveInt(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp, const xmlChar *str)
7078{
7079 xmlExpNodePtr ret;
7080
7081 switch (exp->type) {
7082 case XML_EXP_EMPTY:
7083 return(forbiddenExp);
7084 case XML_EXP_FORBID:
7085 return(forbiddenExp);
7086 case XML_EXP_ATOM:
7087 if (exp->exp_str == str) {
7088#ifdef DEBUG_DERIV
7089 printf("deriv atom: equal => Empty\n");
7090#endif
7091 ret = emptyExp;
7092 } else {
7093#ifdef DEBUG_DERIV
7094 printf("deriv atom: mismatch => forbid\n");
7095#endif
7096 /* TODO wildcards here */
7097 ret = forbiddenExp;
7098 }
7099 return(ret);
7100 case XML_EXP_OR: {
7101 xmlExpNodePtr tmp;
7102
7103#ifdef DEBUG_DERIV
7104 printf("deriv or: => or(derivs)\n");
7105#endif
7106 tmp = xmlExpStringDeriveInt(ctxt, exp->exp_left, str);
7107 if (tmp == NULL) {
7108 return(NULL);
7109 }
7110 ret = xmlExpStringDeriveInt(ctxt, exp->exp_right, str);
7111 if (ret == NULL) {
7112 xmlExpFree(ctxt, tmp);
7113 return(NULL);
7114 }
7115 ret = xmlExpHashGetEntry(ctxt, XML_EXP_OR, tmp, ret,
7116 NULL, 0, 0);
7117 return(ret);
7118 }
7119 case XML_EXP_SEQ:
7120#ifdef DEBUG_DERIV
7121 printf("deriv seq: starting with left\n");
7122#endif
7123 ret = xmlExpStringDeriveInt(ctxt, exp->exp_left, str);
7124 if (ret == NULL) {
7125 return(NULL);
7126 } else if (ret == forbiddenExp) {
7127 if (IS_NILLABLE(exp->exp_left)) {
7128#ifdef DEBUG_DERIV
7129 printf("deriv seq: left failed but nillable\n");
7130#endif
7131 ret = xmlExpStringDeriveInt(ctxt, exp->exp_right, str);
7132 }
7133 } else {
7134#ifdef DEBUG_DERIV
7135 printf("deriv seq: left match => sequence\n");
7136#endif
7137 exp->exp_right->ref++;
7138 ret = xmlExpHashGetEntry(ctxt, XML_EXP_SEQ, ret, exp->exp_right,
7139 NULL, 0, 0);
7140 }
7141 return(ret);
7142 case XML_EXP_COUNT: {
7143 int min, max;
7144 xmlExpNodePtr tmp;
7145
7146 if (exp->exp_max == 0)
7147 return(forbiddenExp);
7148 ret = xmlExpStringDeriveInt(ctxt, exp->exp_left, str);
7149 if (ret == NULL)
7150 return(NULL);
7151 if (ret == forbiddenExp) {
7152#ifdef DEBUG_DERIV
7153 printf("deriv count: pattern mismatch => forbid\n");
7154#endif
7155 return(ret);
7156 }
7157 if (exp->exp_max == 1)
7158 return(ret);
7159 if (exp->exp_max < 0) /* unbounded */
7160 max = -1;
7161 else
7162 max = exp->exp_max - 1;
7163 if (exp->exp_min > 0)
7164 min = exp->exp_min - 1;
7165 else
7166 min = 0;
7167 exp->exp_left->ref++;
7168 tmp = xmlExpHashGetEntry(ctxt, XML_EXP_COUNT, exp->exp_left, NULL,
7169 NULL, min, max);
7170 if (ret == emptyExp) {
7171#ifdef DEBUG_DERIV
7172 printf("deriv count: match to empty => new count\n");
7173#endif
7174 return(tmp);
7175 }
7176#ifdef DEBUG_DERIV
7177 printf("deriv count: match => sequence with new count\n");
7178#endif
7179 return(xmlExpHashGetEntry(ctxt, XML_EXP_SEQ, ret, tmp,
7180 NULL, 0, 0));
7181 }
7182 }
7183 return(NULL);
7184}
7185
7186/**
7187 * xmlExpStringDerive:
7188 * @ctxt: the expression context
7189 * @exp: the expression
7190 * @str: the string
7191 * @len: the string len in bytes if available
7192 *
7193 * Do one step of Brzozowski derivation of the expression @exp with
7194 * respect to the input string
7195 *
7196 * Returns the resulting expression or NULL in case of internal error
7197 */
7198xmlExpNodePtr
7199xmlExpStringDerive(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp,
7200 const xmlChar *str, int len) {
7201 const xmlChar *input;
7202
7203 if ((exp == NULL) || (ctxt == NULL) || (str == NULL)) {
7204 return(NULL);
7205 }
7206 /*
7207 * check the string is in the dictionnary, if yes use an interned
7208 * copy, otherwise we know it's not an acceptable input
7209 */
7210 input = xmlDictExists(ctxt->dict, str, len);
7211 if (input == NULL) {
7212 return(forbiddenExp);
7213 }
7214 return(xmlExpStringDeriveInt(ctxt, exp, input));
7215}
7216
7217static int
7218xmlExpCheckCard(xmlExpNodePtr exp, xmlExpNodePtr sub) {
7219 int ret = 1;
7220
7221 if (sub->c_max == -1) {
7222 if (exp->c_max != -1)
7223 ret = 0;
7224 } else if ((exp->c_max >= 0) && (exp->c_max < sub->c_max)) {
7225 ret = 0;
7226 }
7227#if 0
7228 if ((IS_NILLABLE(sub)) && (!IS_NILLABLE(exp)))
7229 ret = 0;
7230#endif
7231 return(ret);
7232}
7233
7234static xmlExpNodePtr xmlExpExpDeriveInt(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp,
7235 xmlExpNodePtr sub);
7236/**
7237 * xmlExpDivide:
7238 * @ctxt: the expressions context
7239 * @exp: the englobing expression
7240 * @sub: the subexpression
7241 * @mult: the multiple expression
7242 * @remain: the remain from the derivation of the multiple
7243 *
7244 * Check if exp is a multiple of sub, i.e. if there is a finite number n
7245 * so that sub{n} subsume exp
7246 *
7247 * Returns the multiple value if successful, 0 if it is not a multiple
7248 * and -1 in case of internel error.
7249 */
7250
7251static int
7252xmlExpDivide(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp, xmlExpNodePtr sub,
7253 xmlExpNodePtr *mult, xmlExpNodePtr *remain) {
7254 int i;
7255 xmlExpNodePtr tmp, tmp2;
7256
7257 if (mult != NULL) *mult = NULL;
7258 if (remain != NULL) *remain = NULL;
7259 if (exp->c_max == -1) return(0);
7260 if (IS_NILLABLE(exp) && (!IS_NILLABLE(sub))) return(0);
7261
7262 for (i = 1;i <= exp->c_max;i++) {
7263 sub->ref++;
7264 tmp = xmlExpHashGetEntry(ctxt, XML_EXP_COUNT,
7265 sub, NULL, NULL, i, i);
7266 if (tmp == NULL) {
7267 return(-1);
7268 }
7269 if (!xmlExpCheckCard(tmp, exp)) {
7270 xmlExpFree(ctxt, tmp);
7271 continue;
7272 }
7273 tmp2 = xmlExpExpDeriveInt(ctxt, tmp, exp);
7274 if (tmp2 == NULL) {
7275 xmlExpFree(ctxt, tmp);
7276 return(-1);
7277 }
7278 if ((tmp2 != forbiddenExp) && (IS_NILLABLE(tmp2))) {
7279 if (remain != NULL)
7280 *remain = tmp2;
7281 else
7282 xmlExpFree(ctxt, tmp2);
7283 if (mult != NULL)
7284 *mult = tmp;
7285 else
7286 xmlExpFree(ctxt, tmp);
7287#ifdef DEBUG_DERIV
7288 printf("Divide succeeded %d\n", i);
7289#endif
7290 return(i);
7291 }
7292 xmlExpFree(ctxt, tmp);
7293 xmlExpFree(ctxt, tmp2);
7294 }
7295#ifdef DEBUG_DERIV
7296 printf("Divide failed\n");
7297#endif
7298 return(0);
7299}
7300
7301/**
7302 * xmlExpExpDeriveInt:
7303 * @ctxt: the expressions context
7304 * @exp: the englobing expression
7305 * @sub: the subexpression
7306 *
7307 * Try to do a step of Brzozowski derivation but at a higher level
7308 * the input being a subexpression.
7309 *
7310 * Returns the resulting expression or NULL in case of internal error
7311 */
7312static xmlExpNodePtr
7313xmlExpExpDeriveInt(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp, xmlExpNodePtr sub) {
7314 xmlExpNodePtr ret, tmp, tmp2, tmp3;
7315 const xmlChar **tab;
7316 int len, i;
7317
7318 /*
7319 * In case of equality and if the expression can only consume a finite
7320 * amount, then the derivation is empty
7321 */
7322 if ((exp == sub) && (exp->c_max >= 0)) {
7323#ifdef DEBUG_DERIV
7324 printf("Equal(exp, sub) and finite -> Empty\n");
7325#endif
7326 return(emptyExp);
7327 }
7328 /*
7329 * decompose sub sequence first
7330 */
7331 if (sub->type == XML_EXP_EMPTY) {
7332#ifdef DEBUG_DERIV
7333 printf("Empty(sub) -> Empty\n");
7334#endif
7335 exp->ref++;
7336 return(exp);
7337 }
7338 if (sub->type == XML_EXP_SEQ) {
7339#ifdef DEBUG_DERIV
7340 printf("Seq(sub) -> decompose\n");
7341#endif
7342 tmp = xmlExpExpDeriveInt(ctxt, exp, sub->exp_left);
7343 if (tmp == NULL)
7344 return(NULL);
7345 if (tmp == forbiddenExp)
7346 return(tmp);
7347 ret = xmlExpExpDeriveInt(ctxt, tmp, sub->exp_right);
7348 xmlExpFree(ctxt, tmp);
7349 return(ret);
7350 }
7351 if (sub->type == XML_EXP_OR) {
7352#ifdef DEBUG_DERIV
7353 printf("Or(sub) -> decompose\n");
7354#endif
7355 tmp = xmlExpExpDeriveInt(ctxt, exp, sub->exp_left);
7356 if (tmp == forbiddenExp)
7357 return(tmp);
7358 if (tmp == NULL)
7359 return(NULL);
7360 ret = xmlExpExpDeriveInt(ctxt, exp, sub->exp_right);
7361 if ((ret == NULL) || (ret == forbiddenExp)) {
7362 xmlExpFree(ctxt, tmp);
7363 return(ret);
7364 }
7365 return(xmlExpHashGetEntry(ctxt, XML_EXP_OR, tmp, ret, NULL, 0, 0));
7366 }
7367 if (!xmlExpCheckCard(exp, sub)) {
7368#ifdef DEBUG_DERIV
7369 printf("CheckCard(exp, sub) failed -> Forbid\n");
7370#endif
7371 return(forbiddenExp);
7372 }
7373 switch (exp->type) {
7374 case XML_EXP_EMPTY:
7375 if (sub == emptyExp)
7376 return(emptyExp);
7377#ifdef DEBUG_DERIV
7378 printf("Empty(exp) -> Forbid\n");
7379#endif
7380 return(forbiddenExp);
7381 case XML_EXP_FORBID:
7382#ifdef DEBUG_DERIV
7383 printf("Forbid(exp) -> Forbid\n");
7384#endif
7385 return(forbiddenExp);
7386 case XML_EXP_ATOM:
7387 if (sub->type == XML_EXP_ATOM) {
7388 /* TODO: handle wildcards */
7389 if (exp->exp_str == sub->exp_str) {
7390#ifdef DEBUG_DERIV
7391 printf("Atom match -> Empty\n");
7392#endif
7393 return(emptyExp);
7394 }
7395#ifdef DEBUG_DERIV
7396 printf("Atom mismatch -> Forbid\n");
7397#endif
7398 return(forbiddenExp);
7399 }
7400 if ((sub->type == XML_EXP_COUNT) &&
7401 (sub->exp_max == 1) &&
7402 (sub->exp_left->type == XML_EXP_ATOM)) {
7403 /* TODO: handle wildcards */
7404 if (exp->exp_str == sub->exp_left->exp_str) {
7405#ifdef DEBUG_DERIV
7406 printf("Atom match -> Empty\n");
7407#endif
7408 return(emptyExp);
7409 }
7410#ifdef DEBUG_DERIV
7411 printf("Atom mismatch -> Forbid\n");
7412#endif
7413 return(forbiddenExp);
7414 }
7415#ifdef DEBUG_DERIV
7416 printf("Compex exp vs Atom -> Forbid\n");
7417#endif
7418 return(forbiddenExp);
7419 case XML_EXP_SEQ:
7420 /* try to get the sequence consumed only if possible */
7421 if (xmlExpCheckCard(exp->exp_left, sub)) {
7422 /* See if the sequence can be consumed directly */
7423#ifdef DEBUG_DERIV
7424 printf("Seq trying left only\n");
7425#endif
7426 ret = xmlExpExpDeriveInt(ctxt, exp->exp_left, sub);
7427 if ((ret != forbiddenExp) && (ret != NULL)) {
7428#ifdef DEBUG_DERIV
7429 printf("Seq trying left only worked\n");
7430#endif
7431 /*
7432 * TODO: assumption here that we are determinist
7433 * i.e. we won't get to a nillable exp left
7434 * subset which could be matched by the right
7435 * part too.
7436 * e.g.: (a | b)+,(a | c) and 'a+,a'
7437 */
7438 exp->exp_right->ref++;
7439 return(xmlExpHashGetEntry(ctxt, XML_EXP_SEQ, ret,
7440 exp->exp_right, NULL, 0, 0));
7441 }
7442#ifdef DEBUG_DERIV
7443 } else {
7444 printf("Seq: left too short\n");
7445#endif
7446 }
7447 /* Try instead to decompose */
7448 if (sub->type == XML_EXP_COUNT) {
7449 int min, max;
7450
7451#ifdef DEBUG_DERIV
7452 printf("Seq: sub is a count\n");
7453#endif
7454 ret = xmlExpExpDeriveInt(ctxt, exp->exp_left, sub->exp_left);
7455 if (ret == NULL)
7456 return(NULL);
7457 if (ret != forbiddenExp) {
7458#ifdef DEBUG_DERIV
7459 printf("Seq , Count match on left\n");
7460#endif
7461 if (sub->exp_max < 0)
7462 max = -1;
7463 else
7464 max = sub->exp_max -1;
7465 if (sub->exp_min > 0)
7466 min = sub->exp_min -1;
7467 else
7468 min = 0;
7469 exp->exp_right->ref++;
7470 tmp = xmlExpHashGetEntry(ctxt, XML_EXP_SEQ, ret,
7471 exp->exp_right, NULL, 0, 0);
7472 if (tmp == NULL)
7473 return(NULL);
7474
7475 sub->exp_left->ref++;
7476 tmp2 = xmlExpHashGetEntry(ctxt, XML_EXP_COUNT,
7477 sub->exp_left, NULL, NULL, min, max);
7478 if (tmp2 == NULL) {
7479 xmlExpFree(ctxt, tmp);
7480 return(NULL);
7481 }
7482 ret = xmlExpExpDeriveInt(ctxt, tmp, tmp2);
7483 xmlExpFree(ctxt, tmp);
7484 xmlExpFree(ctxt, tmp2);
7485 return(ret);
7486 }
7487 }
7488 /* we made no progress on structured operations */
7489 break;
7490 case XML_EXP_OR:
7491#ifdef DEBUG_DERIV
7492 printf("Or , trying both side\n");
7493#endif
7494 ret = xmlExpExpDeriveInt(ctxt, exp->exp_left, sub);
7495 if (ret == NULL)
7496 return(NULL);
7497 tmp = xmlExpExpDeriveInt(ctxt, exp->exp_right, sub);
7498 if (tmp == NULL) {
7499 xmlExpFree(ctxt, ret);
7500 return(NULL);
7501 }
7502 return(xmlExpHashGetEntry(ctxt, XML_EXP_OR, ret, tmp, NULL, 0, 0));
7503 case XML_EXP_COUNT: {
7504 int min, max;
7505
7506 if (sub->type == XML_EXP_COUNT) {
7507 /*
7508 * Try to see if the loop is completely subsumed
7509 */
7510 tmp = xmlExpExpDeriveInt(ctxt, exp->exp_left, sub->exp_left);
7511 if (tmp == NULL)
7512 return(NULL);
7513 if (tmp == forbiddenExp) {
7514 int mult;
7515
7516#ifdef DEBUG_DERIV
7517 printf("Count, Count inner don't subsume\n");
7518#endif
7519 mult = xmlExpDivide(ctxt, sub->exp_left, exp->exp_left,
7520 NULL, &tmp);
7521 if (mult <= 0) {
7522#ifdef DEBUG_DERIV
7523 printf("Count, Count not multiple => forbidden\n");
7524#endif
7525 return(forbiddenExp);
7526 }
7527 if (sub->exp_max == -1) {
7528 max = -1;
7529 if (exp->exp_max == -1) {
7530 if (exp->exp_min <= sub->exp_min * mult)
7531 min = 0;
7532 else
7533 min = exp->exp_min - sub->exp_min * mult;
7534 } else {
7535#ifdef DEBUG_DERIV
7536 printf("Count, Count finite can't subsume infinite\n");
7537#endif
7538 xmlExpFree(ctxt, tmp);
7539 return(forbiddenExp);
7540 }
7541 } else {
7542 if (exp->exp_max == -1) {
7543#ifdef DEBUG_DERIV
7544 printf("Infinite loop consume mult finite loop\n");
7545#endif
7546 if (exp->exp_min > sub->exp_min * mult) {
7547 max = -1;
7548 min = exp->exp_min - sub->exp_min * mult;
7549 } else {
7550 max = -1;
7551 min = 0;
7552 }
7553 } else {
7554 if (exp->exp_max < sub->exp_max * mult) {
7555#ifdef DEBUG_DERIV
7556 printf("loops max mult mismatch => forbidden\n");
7557#endif
7558 xmlExpFree(ctxt, tmp);
7559 return(forbiddenExp);
7560 }
7561 if (sub->exp_max * mult > exp->exp_min)
7562 min = 0;
7563 else
7564 min = exp->exp_min - sub->exp_max * mult;
7565 max = exp->exp_max - sub->exp_max * mult;
7566 }
7567 }
7568 } else if (!IS_NILLABLE(tmp)) {
7569 /*
7570 * TODO: loop here to try to grow if working on finite
7571 * blocks.
7572 */
7573#ifdef DEBUG_DERIV
7574 printf("Count, Count remain not nillable => forbidden\n");
7575#endif
7576 xmlExpFree(ctxt, tmp);
7577 return(forbiddenExp);
7578 } else if (sub->exp_max == -1) {
7579 if (exp->exp_max == -1) {
7580 if (exp->exp_min <= sub->exp_min) {
7581#ifdef DEBUG_DERIV
7582 printf("Infinite loops Okay => COUNT(0,Inf)\n");
7583#endif
7584 max = -1;
7585 min = 0;
7586 } else {
7587#ifdef DEBUG_DERIV
7588 printf("Infinite loops min => Count(X,Inf)\n");
7589#endif
7590 max = -1;
7591 min = exp->exp_min - sub->exp_min;
7592 }
7593 } else if (exp->exp_min > sub->exp_min) {
7594#ifdef DEBUG_DERIV
7595 printf("loops min mismatch 1 => forbidden ???\n");
7596#endif
7597 xmlExpFree(ctxt, tmp);
7598 return(forbiddenExp);
7599 } else {
7600 max = -1;
7601 min = 0;
7602 }
7603 } else {
7604 if (exp->exp_max == -1) {
7605#ifdef DEBUG_DERIV
7606 printf("Infinite loop consume finite loop\n");
7607#endif
7608 if (exp->exp_min > sub->exp_min) {
7609 max = -1;
7610 min = exp->exp_min - sub->exp_min;
7611 } else {
7612 max = -1;
7613 min = 0;
7614 }
7615 } else {
7616 if (exp->exp_max < sub->exp_max) {
7617#ifdef DEBUG_DERIV
7618 printf("loops max mismatch => forbidden\n");
7619#endif
7620 xmlExpFree(ctxt, tmp);
7621 return(forbiddenExp);
7622 }
7623 if (sub->exp_max > exp->exp_min)
7624 min = 0;
7625 else
7626 min = exp->exp_min - sub->exp_max;
7627 max = exp->exp_max - sub->exp_max;
7628 }
7629 }
7630#ifdef DEBUG_DERIV
7631 printf("loops match => SEQ(COUNT())\n");
7632#endif
7633 exp->exp_left->ref++;
7634 tmp2 = xmlExpHashGetEntry(ctxt, XML_EXP_COUNT, exp->exp_left,
7635 NULL, NULL, min, max);
7636 if (tmp2 == NULL) {
7637 return(NULL);
7638 }
7639 ret = xmlExpHashGetEntry(ctxt, XML_EXP_SEQ, tmp, tmp2,
7640 NULL, 0, 0);
7641 return(ret);
7642 }
7643 tmp = xmlExpExpDeriveInt(ctxt, exp->exp_left, sub);
7644 if (tmp == NULL)
7645 return(NULL);
7646 if (tmp == forbiddenExp) {
7647#ifdef DEBUG_DERIV
7648 printf("loop mismatch => forbidden\n");
7649#endif
7650 return(forbiddenExp);
7651 }
7652 if (exp->exp_min > 0)
7653 min = exp->exp_min - 1;
7654 else
7655 min = 0;
7656 if (exp->exp_max < 0)
7657 max = -1;
7658 else
7659 max = exp->exp_max - 1;
7660
7661#ifdef DEBUG_DERIV
7662 printf("loop match => SEQ(COUNT())\n");
7663#endif
7664 exp->exp_left->ref++;
7665 tmp2 = xmlExpHashGetEntry(ctxt, XML_EXP_COUNT, exp->exp_left,
7666 NULL, NULL, min, max);
7667 if (tmp2 == NULL)
7668 return(NULL);
7669 ret = xmlExpHashGetEntry(ctxt, XML_EXP_SEQ, tmp, tmp2,
7670 NULL, 0, 0);
7671 return(ret);
7672 }
7673 }
7674
7675#ifdef DEBUG_DERIV
7676 printf("Fallback to derivative\n");
7677#endif
7678 if (IS_NILLABLE(sub)) {
7679 if (!(IS_NILLABLE(exp)))
7680 return(forbiddenExp);
7681 else
7682 ret = emptyExp;
7683 } else
7684 ret = NULL;
7685 /*
7686 * here the structured derivation made no progress so
7687 * we use the default token based derivation to force one more step
7688 */
7689 if (ctxt->tabSize == 0)
7690 ctxt->tabSize = 40;
7691
7692 tab = (const xmlChar **) xmlMalloc(ctxt->tabSize *
7693 sizeof(const xmlChar *));
7694 if (tab == NULL) {
7695 return(NULL);
7696 }
7697
7698 /*
7699 * collect all the strings accepted by the subexpression on input
7700 */
7701 len = xmlExpGetStartInt(ctxt, sub, tab, ctxt->tabSize, 0);
7702 while (len < 0) {
7703 const xmlChar **temp;
7704 temp = (const xmlChar **) xmlRealloc((xmlChar **) tab, ctxt->tabSize * 2 *
7705 sizeof(const xmlChar *));
7706 if (temp == NULL) {
7707 xmlFree((xmlChar **) tab);
7708 return(NULL);
7709 }
7710 tab = temp;
7711 ctxt->tabSize *= 2;
7712 len = xmlExpGetStartInt(ctxt, sub, tab, ctxt->tabSize, 0);
7713 }
7714 for (i = 0;i < len;i++) {
7715 tmp = xmlExpStringDeriveInt(ctxt, exp, tab[i]);
7716 if ((tmp == NULL) || (tmp == forbiddenExp)) {
7717 xmlExpFree(ctxt, ret);
7718 xmlFree((xmlChar **) tab);
7719 return(tmp);
7720 }
7721 tmp2 = xmlExpStringDeriveInt(ctxt, sub, tab[i]);
7722 if ((tmp2 == NULL) || (tmp2 == forbiddenExp)) {
7723 xmlExpFree(ctxt, tmp);
7724 xmlExpFree(ctxt, ret);
7725 xmlFree((xmlChar **) tab);
7726 return(tmp);
7727 }
7728 tmp3 = xmlExpExpDeriveInt(ctxt, tmp, tmp2);
7729 xmlExpFree(ctxt, tmp);
7730 xmlExpFree(ctxt, tmp2);
7731
7732 if ((tmp3 == NULL) || (tmp3 == forbiddenExp)) {
7733 xmlExpFree(ctxt, ret);
7734 xmlFree((xmlChar **) tab);
7735 return(tmp3);
7736 }
7737
7738 if (ret == NULL)
7739 ret = tmp3;
7740 else {
7741 ret = xmlExpHashGetEntry(ctxt, XML_EXP_OR, ret, tmp3, NULL, 0, 0);
7742 if (ret == NULL) {
7743 xmlFree((xmlChar **) tab);
7744 return(NULL);
7745 }
7746 }
7747 }
7748 xmlFree((xmlChar **) tab);
7749 return(ret);
7750}
7751
7752/**
7753 * xmlExpExpDerive:
7754 * @ctxt: the expressions context
7755 * @exp: the englobing expression
7756 * @sub: the subexpression
7757 *
7758 * Evaluates the expression resulting from @exp consuming a sub expression @sub
7759 * Based on algebraic derivation and sometimes direct Brzozowski derivation
7760 * it usually tatkes less than linear time and can handle expressions generating
7761 * infinite languages.
7762 *
7763 * Returns the resulting expression or NULL in case of internal error, the
7764 * result must be freed
7765 */
7766xmlExpNodePtr
7767xmlExpExpDerive(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp, xmlExpNodePtr sub) {
7768 if ((exp == NULL) || (ctxt == NULL) || (sub == NULL))
7769 return(NULL);
7770
7771 /*
7772 * O(1) speedups
7773 */
7774 if (IS_NILLABLE(sub) && (!IS_NILLABLE(exp))) {
7775#ifdef DEBUG_DERIV
7776 printf("Sub nillable and not exp : can't subsume\n");
7777#endif
7778 return(forbiddenExp);
7779 }
7780 if (xmlExpCheckCard(exp, sub) == 0) {
7781#ifdef DEBUG_DERIV
7782 printf("sub generate longuer sequances than exp : can't subsume\n");
7783#endif
7784 return(forbiddenExp);
7785 }
7786 return(xmlExpExpDeriveInt(ctxt, exp, sub));
7787}
7788
7789/**
7790 * xmlExpSubsume:
7791 * @ctxt: the expressions context
7792 * @exp: the englobing expression
7793 * @sub: the subexpression
7794 *
7795 * Check whether @exp accepts all the languages accexpted by @sub
7796 * the input being a subexpression.
7797 *
7798 * Returns 1 if true 0 if false and -1 in case of failure.
7799 */
7800int
7801xmlExpSubsume(xmlExpCtxtPtr ctxt, xmlExpNodePtr exp, xmlExpNodePtr sub) {
7802 xmlExpNodePtr tmp;
7803
7804 if ((exp == NULL) || (ctxt == NULL) || (sub == NULL))
7805 return(-1);
7806
7807 /*
7808 * TODO: speedup by checking the language of sub is a subset of the
7809 * language of exp
7810 */
7811 /*
7812 * O(1) speedups
7813 */
7814 if (IS_NILLABLE(sub) && (!IS_NILLABLE(exp))) {
7815#ifdef DEBUG_DERIV
7816 printf("Sub nillable and not exp : can't subsume\n");
7817#endif
7818 return(0);
7819 }
7820 if (xmlExpCheckCard(exp, sub) == 0) {
7821#ifdef DEBUG_DERIV
7822 printf("sub generate longuer sequances than exp : can't subsume\n");
7823#endif
7824 return(0);
7825 }
7826 tmp = xmlExpExpDeriveInt(ctxt, exp, sub);
7827#ifdef DEBUG_DERIV
7828 printf("Result derivation :\n");
7829 PRINT_EXP(tmp);
7830#endif
7831 if (tmp == NULL)
7832 return(-1);
7833 if (tmp == forbiddenExp)
7834 return(0);
7835 if (tmp == emptyExp)
7836 return(1);
7837 if ((tmp != NULL) && (IS_NILLABLE(tmp))) {
7838 xmlExpFree(ctxt, tmp);
7839 return(1);
7840 }
7841 xmlExpFree(ctxt, tmp);
7842 return(0);
7843}
7844
7845/************************************************************************
7846 * *
7847 * Parsing expression *
7848 * *
7849 ************************************************************************/
7850
7851static xmlExpNodePtr xmlExpParseExpr(xmlExpCtxtPtr ctxt);
7852
7853#undef CUR
7854#define CUR (*ctxt->cur)
7855#undef NEXT
7856#define NEXT ctxt->cur++;
7857#undef IS_BLANK
7858#define IS_BLANK(c) ((c == ' ') || (c == '\n') || (c == '\r') || (c == '\t'))
7859#define SKIP_BLANKS while (IS_BLANK(*ctxt->cur)) ctxt->cur++;
7860
7861static int
7862xmlExpParseNumber(xmlExpCtxtPtr ctxt) {
7863 int ret = 0;
7864
7865 SKIP_BLANKS
7866 if (CUR == '*') {
7867 NEXT
7868 return(-1);
7869 }
7870 if ((CUR < '0') || (CUR > '9'))
7871 return(-1);
7872 while ((CUR >= '0') && (CUR <= '9')) {
7873 ret = ret * 10 + (CUR - '0');
7874 NEXT
7875 }
7876 return(ret);
7877}
7878
7879static xmlExpNodePtr
7880xmlExpParseOr(xmlExpCtxtPtr ctxt) {
7881 const char *base;
7882 xmlExpNodePtr ret;
7883 const xmlChar *val;
7884
7885 SKIP_BLANKS
7886 base = ctxt->cur;
7887 if (*ctxt->cur == '(') {
7888 NEXT
7889 ret = xmlExpParseExpr(ctxt);
7890 SKIP_BLANKS
7891 if (*ctxt->cur != ')') {
7892 fprintf(stderr, "unbalanced '(' : %s\n", base);
7893 xmlExpFree(ctxt, ret);
7894 return(NULL);
7895 }
7896 NEXT;
7897 SKIP_BLANKS
7898 goto parse_quantifier;
7899 }
7900 while ((CUR != 0) && (!(IS_BLANK(CUR))) && (CUR != '(') &&
7901 (CUR != ')') && (CUR != '|') && (CUR != ',') && (CUR != '{') &&
7902 (CUR != '*') && (CUR != '+') && (CUR != '?') && (CUR != '}'))
7903 NEXT;
7904 val = xmlDictLookup(ctxt->dict, BAD_CAST base, ctxt->cur - base);
7905 if (val == NULL)
7906 return(NULL);
7907 ret = xmlExpHashGetEntry(ctxt, XML_EXP_ATOM, NULL, NULL, val, 0, 0);
7908 if (ret == NULL)
7909 return(NULL);
7910 SKIP_BLANKS
7911parse_quantifier:
7912 if (CUR == '{') {
7913 int min, max;
7914
7915 NEXT
7916 min = xmlExpParseNumber(ctxt);
7917 if (min < 0) {
7918 xmlExpFree(ctxt, ret);
7919 return(NULL);
7920 }
7921 SKIP_BLANKS
7922 if (CUR == ',') {
7923 NEXT
7924 max = xmlExpParseNumber(ctxt);
7925 SKIP_BLANKS
7926 } else
7927 max = min;
7928 if (CUR != '}') {
7929 xmlExpFree(ctxt, ret);
7930 return(NULL);
7931 }
7932 NEXT
7933 ret = xmlExpHashGetEntry(ctxt, XML_EXP_COUNT, ret, NULL, NULL,
7934 min, max);
7935 SKIP_BLANKS
7936 } else if (CUR == '?') {
7937 NEXT
7938 ret = xmlExpHashGetEntry(ctxt, XML_EXP_COUNT, ret, NULL, NULL,
7939 0, 1);
7940 SKIP_BLANKS
7941 } else if (CUR == '+') {
7942 NEXT
7943 ret = xmlExpHashGetEntry(ctxt, XML_EXP_COUNT, ret, NULL, NULL,
7944 1, -1);
7945 SKIP_BLANKS
7946 } else if (CUR == '*') {
7947 NEXT
7948 ret = xmlExpHashGetEntry(ctxt, XML_EXP_COUNT, ret, NULL, NULL,
7949 0, -1);
7950 SKIP_BLANKS
7951 }
7952 return(ret);
7953}
7954
7955
7956static xmlExpNodePtr
7957xmlExpParseSeq(xmlExpCtxtPtr ctxt) {
7958 xmlExpNodePtr ret, right;
7959
7960 ret = xmlExpParseOr(ctxt);
7961 SKIP_BLANKS
7962 while (CUR == '|') {
7963 NEXT
7964 right = xmlExpParseOr(ctxt);
7965 if (right == NULL) {
7966 xmlExpFree(ctxt, ret);
7967 return(NULL);
7968 }
7969 ret = xmlExpHashGetEntry(ctxt, XML_EXP_OR, ret, right, NULL, 0, 0);
7970 if (ret == NULL)
7971 return(NULL);
7972 }
7973 return(ret);
7974}
7975
7976static xmlExpNodePtr
7977xmlExpParseExpr(xmlExpCtxtPtr ctxt) {
7978 xmlExpNodePtr ret, right;
7979
7980 ret = xmlExpParseSeq(ctxt);
7981 SKIP_BLANKS
7982 while (CUR == ',') {
7983 NEXT
7984 right = xmlExpParseSeq(ctxt);
7985 if (right == NULL) {
7986 xmlExpFree(ctxt, ret);
7987 return(NULL);
7988 }
7989 ret = xmlExpHashGetEntry(ctxt, XML_EXP_SEQ, ret, right, NULL, 0, 0);
7990 if (ret == NULL)
7991 return(NULL);
7992 }
7993 return(ret);
7994}
7995
7996/**
7997 * xmlExpParse:
7998 * @ctxt: the expressions context
7999 * @expr: the 0 terminated string
8000 *
8001 * Minimal parser for regexps, it understand the following constructs
8002 * - string terminals
8003 * - choice operator |
8004 * - sequence operator ,
8005 * - subexpressions (...)
8006 * - usual cardinality operators + * and ?
8007 * - finite sequences { min, max }
8008 * - infinite sequences { min, * }
8009 * There is minimal checkings made especially no checking on strings values
8010 *
8011 * Returns a new expression or NULL in case of failure
8012 */
8013xmlExpNodePtr
8014xmlExpParse(xmlExpCtxtPtr ctxt, const char *expr) {
8015 xmlExpNodePtr ret;
8016
8017 ctxt->expr = expr;
8018 ctxt->cur = expr;
8019
8020 ret = xmlExpParseExpr(ctxt);
8021 SKIP_BLANKS
8022 if (*ctxt->cur != 0) {
8023 xmlExpFree(ctxt, ret);
8024 return(NULL);
8025 }
8026 return(ret);
8027}
8028
8029static void
8030xmlExpDumpInt(xmlBufferPtr buf, xmlExpNodePtr expr, int glob) {
8031 xmlExpNodePtr c;
8032
8033 if (expr == NULL) return;
8034 if (glob) xmlBufferWriteChar(buf, "(");
8035 switch (expr->type) {
8036 case XML_EXP_EMPTY:
8037 xmlBufferWriteChar(buf, "empty");
8038 break;
8039 case XML_EXP_FORBID:
8040 xmlBufferWriteChar(buf, "forbidden");
8041 break;
8042 case XML_EXP_ATOM:
8043 xmlBufferWriteCHAR(buf, expr->exp_str);
8044 break;
8045 case XML_EXP_SEQ:
8046 c = expr->exp_left;
8047 if ((c->type == XML_EXP_SEQ) || (c->type == XML_EXP_OR))
8048 xmlExpDumpInt(buf, c, 1);
8049 else
8050 xmlExpDumpInt(buf, c, 0);
8051 xmlBufferWriteChar(buf, " , ");
8052 c = expr->exp_right;
8053 if ((c->type == XML_EXP_SEQ) || (c->type == XML_EXP_OR))
8054 xmlExpDumpInt(buf, c, 1);
8055 else
8056 xmlExpDumpInt(buf, c, 0);
8057 break;
8058 case XML_EXP_OR:
8059 c = expr->exp_left;
8060 if ((c->type == XML_EXP_SEQ) || (c->type == XML_EXP_OR))
8061 xmlExpDumpInt(buf, c, 1);
8062 else
8063 xmlExpDumpInt(buf, c, 0);
8064 xmlBufferWriteChar(buf, " | ");
8065 c = expr->exp_right;
8066 if ((c->type == XML_EXP_SEQ) || (c->type == XML_EXP_OR))
8067 xmlExpDumpInt(buf, c, 1);
8068 else
8069 xmlExpDumpInt(buf, c, 0);
8070 break;
8071 case XML_EXP_COUNT: {
8072 char rep[40];
8073
8074 c = expr->exp_left;
8075 if ((c->type == XML_EXP_SEQ) || (c->type == XML_EXP_OR))
8076 xmlExpDumpInt(buf, c, 1);
8077 else
8078 xmlExpDumpInt(buf, c, 0);
8079 if ((expr->exp_min == 0) && (expr->exp_max == 1)) {
8080 rep[0] = '?';
8081 rep[1] = 0;
8082 } else if ((expr->exp_min == 0) && (expr->exp_max == -1)) {
8083 rep[0] = '*';
8084 rep[1] = 0;
8085 } else if ((expr->exp_min == 1) && (expr->exp_max == -1)) {
8086 rep[0] = '+';
8087 rep[1] = 0;
8088 } else if (expr->exp_max == expr->exp_min) {
8089 snprintf(rep, 39, "{%d}", expr->exp_min);
8090 } else if (expr->exp_max < 0) {
8091 snprintf(rep, 39, "{%d,inf}", expr->exp_min);
8092 } else {
8093 snprintf(rep, 39, "{%d,%d}", expr->exp_min, expr->exp_max);
8094 }
8095 rep[39] = 0;
8096 xmlBufferWriteChar(buf, rep);
8097 break;
8098 }
8099 default:
8100 fprintf(stderr, "Error in tree\n");
8101 }
8102 if (glob)
8103 xmlBufferWriteChar(buf, ")");
8104}
8105/**
8106 * xmlExpDump:
8107 * @buf: a buffer to receive the output
8108 * @expr: the compiled expression
8109 *
8110 * Serialize the expression as compiled to the buffer
8111 */
8112void
8113xmlExpDump(xmlBufferPtr buf, xmlExpNodePtr expr) {
8114 if ((buf == NULL) || (expr == NULL))
8115 return;
8116 xmlExpDumpInt(buf, expr, 0);
8117}
8118
8119/**
8120 * xmlExpMaxToken:
8121 * @expr: a compiled expression
8122 *
8123 * Indicate the maximum number of input a expression can accept
8124 *
8125 * Returns the maximum length or -1 in case of error
8126 */
8127int
8128xmlExpMaxToken(xmlExpNodePtr expr) {
8129 if (expr == NULL)
8130 return(-1);
8131 return(expr->c_max);
8132}
8133
8134/**
8135 * xmlExpCtxtNbNodes:
8136 * @ctxt: an expression context
8137 *
8138 * Debugging facility provides the number of allocated nodes at a that point
8139 *
8140 * Returns the number of nodes in use or -1 in case of error
8141 */
8142int
8143xmlExpCtxtNbNodes(xmlExpCtxtPtr ctxt) {
8144 if (ctxt == NULL)
8145 return(-1);
8146 return(ctxt->nb_nodes);
8147}
8148
8149/**
8150 * xmlExpCtxtNbCons:
8151 * @ctxt: an expression context
8152 *
8153 * Debugging facility provides the number of allocated nodes over lifetime
8154 *
8155 * Returns the number of nodes ever allocated or -1 in case of error
8156 */
8157int
8158xmlExpCtxtNbCons(xmlExpCtxtPtr ctxt) {
8159 if (ctxt == NULL)
8160 return(-1);
8161 return(ctxt->nb_cons);
8162}
8163
8164#endif /* LIBXML_EXPR_ENABLED */
8165#define bottom_xmlregexp
8166#include "elfgcchack.h"
8167#endif /* LIBXML_REGEXP_ENABLED */
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