/*
* fa.h: finite automata
*
* Copyright (C) 2007-2016 David Lutterkort
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
* Author: David Lutterkort <dlutter@redhat.com>
*/
#ifndef FA_H_
#define FA_H_
#include <stdio.h>
#include <regex.h>
#include <stdbool.h>
#include <stdint.h>
/* The type for a finite automaton. */
struct fa;
/* The type of a state of a finite automaton. The fa_state functions return
* pointers to this struct. Those pointers are only valid as long as the
* only fa_* functions that are called are fa_state_* functions. For
* example, the following code will almost certainly result in a crash (or
* worse):
*
* struct state *s = fa_state_initial(fa);
* fa_minimize(fa);
* // Crashes as S will likely have been freed
* s = fa_state_next(s)
*/
struct state;
/* Denote some basic automata, used by fa_is_basic and fa_make_basic */
enum fa_basic {
FA_EMPTY, /* Accepts the empty language, i.e. no strings */
FA_EPSILON, /* Accepts only the empty word */
FA_TOTAL /* Accepts all words */
};
/* Choice of minimization algorithm to use; either Hopcroft's O(n log(n))
* algorithm or Brzozowski's reverse-determinize-reverse-determinize
* algorithm. While the latter has exponential complexity in theory, it
* works quite well for some cases.
*/
enum fa_minimization_algorithms {
FA_MIN_HOPCROFT,
FA_MIN_BRZOZOWSKI
};
/* Which minimization algorithm to use in FA_MINIMIZE. The library
* minimizes internally at certain points, too.
*
* Defaults to FA_MIN_HOPCROFT
*/
extern int fa_minimization_algorithm;
/* Unless otherwise mentioned, automata passed into routines are never
* modified. It is the responsibility of the caller to free automata
* returned by any of these routines when they are no longer needed.
*/
/*
* Compile the regular expression RE of length SIZE into an automaton. The
* return value is the same as the return value for the POSIX function
* regcomp. The syntax for regular expressions is extended POSIX syntax,
* with the difference that '.' does not match newlines.
*
* On success, FA points to the newly allocated automaton constructed for
* RE, and the function returns REG_NOERROR. Otherwise, FA is NULL, and the
* return value indicates the error.
*
* The FA is case sensitive. Call FA_NOCASE to switch it to
* case-insensitive.
*/
int fa_compile(const char *re, size_t size, struct fa **fa);
/* Make a new automaton that accepts one of the basic languages defined in
* the enum FA_BASIC.
*/
struct fa *fa_make_basic(unsigned int basic);
/* Return 1 if FA accepts the basic language BASIC, which must be one of
* the constants from enum FA_BASIC.
*/
int fa_is_basic(struct fa *fa, unsigned int basic);
/* Minimize FA using the currently-set fa_minimization_algorithm.
* As a side effect, the automaton will also be deterministic after being
* minimized. Modifies the automaton in place.
*/
int fa_minimize(struct fa *fa);
/* Return a finite automaton that accepts the concatenation of the
* languages for FA1 and FA2, i.e. L(FA1).L(FA2)
*/
struct fa *fa_concat(struct fa *fa1, struct fa *fa2);
/* Return a finite automaton that accepts the union of the languages that
* FA1 and FA2 accept (the '|' operator in regular expressions).
*/
struct fa *fa_union(struct fa *fa1, struct fa *fa2);
/* Return a finite automaton that accepts the intersection of the languages
* of FA1 and FA2.
*/
struct fa *fa_intersect(struct fa *fa1, struct fa *fa2);
/* Return a finite automaton that accepts the complement of the language of
* FA, i.e. the set of all words not accepted by FA
*/
struct fa *fa_complement(struct fa *fa);
/* Return a finite automaton that accepts the set difference of the
* languages of FA1 and FA2, i.e. L(FA1)\L(FA2)
*/
struct fa *fa_minus(struct fa *fa1, struct fa *fa2);
/* Return a finite automaton that accepts a repetition of the language that
* FA accepts. If MAX == -1, the returned automaton accepts arbitrarily
* long repetitions. MIN must be 0 or bigger, and unless MAX == -1, MIN
* must be less or equal to MAX. If MIN is greater than 0, the returned
* automaton accepts only words that have at least MIN repetitions of words
* from L(FA).
*
* The following common regexp repetitios are achieved by the following
* calls (using a lose notation equating automata and their languages):
*
* - FA* = FA_ITER(FA, 0, -1)
* - FA+ = FA_ITER(FA, 1, -1)
* - FA? = FA_ITER(FA, 0, 1)
* - FA{n,m} = FA_ITER(FA, n, m) with 0 <= n and m = -1 or n <= m
*/
struct fa *fa_iter(struct fa *fa, int min, int max);
/* If successful, returns 1 if the language of FA1 is contained in the language
* of FA2, 0 otherwise. Returns a negative number if an error occurred.
*/
int fa_contains(struct fa *fa1, struct fa *fa2);
/* If successful, returns 1 if the language of FA1 equals the language of FA2,
* 0 otherwise. Returns a negative number if an error occurred.
*/
int fa_equals(struct fa *fa1, struct fa *fa2);
/* Free all memory used by FA */
void fa_free(struct fa *fa);
/* Print FA to OUT as a graphviz dot file */
void fa_dot(FILE *out, struct fa *fa);
/* Return a finite automaton that accepts the overlap of the languages of
* FA1 and FA2. The overlap of two languages is the set of strings that can
* be split in more than one way into a left part accepted by FA1 and a
* right part accepted by FA2.
*/
struct fa *fa_overlap(struct fa *fa1, struct fa *fa2);
/* Produce an example for the language of FA. The example is not
* necessarily the shortest possible. The implementation works very hard to
* have printable characters (preferably alphanumeric) in the example, and
* to avoid just an empty word.
*
* *EXAMPLE will be the example, which may be NULL. If it is non-NULL,
* EXAMPLE_LEN will hold the length of the example.
*
* Return 0 on success, and a negative numer on error. On error, *EXAMPLE
* will be NULL.
*
* If *EXAMPLE is set, it is the caller's responsibility to free the string
* by calling free().
*/
int fa_example(struct fa *fa, char **example, size_t *example_len);
/* Produce an example of an ambiguous word for the concatenation of the
* languages of FA1 and FA2. The return value is such a word (which must be
* freed by the caller) if it exists. If none exists, NULL is returned.
*
* The returned word is of the form UPV and PV and V are set to the first
* character of P and V in the returned word. The word UPV has the property
* that U and UP are accepted by FA1 and that PV and V are accepted by FA2.
*
* Neither the language of FA1 or of FA2 may contain words with the
* characters '\001' and '\002', as they are used during construction of
* the ambiguous word.
*
* UPV_LEN will be set to the length of the entire string UPV
*
* Returns 0 on success, and a negative number on failure. On failure, UPV,
* PV, and V will be NULL
*/
int fa_ambig_example(struct fa *fa1, struct fa *fa2,
char **upv, size_t *upv_len,
char **pv, char **v);
/* Convert the finite automaton FA into a regular expression and set REGEXP
* to point to that. When REGEXP is compiled into another automaton, it is
* guaranteed that that automaton and FA accept the same language.
*
* The code tries to be semi-clever about keeping the generated regular
* expression short; to guarantee reasonably short regexps, the automaton
* should be minimized before passing it to this routine.
*
* On success, REGEXP_LEN is set to the length of REGEXP
*
* Return 0 on success, and a negative number on failure. The only reason
* for FA_AS_REGEXP to fail is running out of memory.
*/
int fa_as_regexp(struct fa *fa, char **regexp, size_t *regexp_len);
/* Given the regular expression REGEXP construct a new regular expression
* NEWREGEXP that does not match strings containing any of the characters
* in the range FROM to TO, with the endpoints included.
*
* The new regular expression is constructed by removing the range FROM to
* TO from all character sets in REGEXP; if any of the characters [FROM,
* TO] appear outside a character set in REGEXP, return -2.
*
* Return 0 if NEWREGEXP was constructed successfully, -1 if an internal
* error happened (e.g., an allocation failed) and -2 if NEWREGEXP can not
* be constructed because any character in the range [FROM, TO] appears
* outside of a character set.
*
* Return a positive value if REGEXP is not syntactically valid; the value
* returned is one of the REG_ERRCODE_T POSIX error codes. Return 0 on
* success and -1 if an allocation fails.
*/
int fa_restrict_alphabet(const char *regexp, size_t regexp_len,
char **newregexp, size_t *newregexp_len,
char from, char to);
/* Convert REGEXP into one that does not use ranges inside character
* classes.
*
* Return a positive value if REGEXP is not syntactically valid; the value
* returned is one of the REG_ERRCODE_T POSIX error codes. Return 0 on
* success and -1 if an allocation fails.
*/
int fa_expand_char_ranges(const char *regexp, size_t regexp_len,
char **newregexp, size_t *newregexp_len);
/* Modify FA so that it matches ignoring case.
*
* Returns 0 on success, and -1 if an allocation fails. On failure, the
* automaton is not guaranteed to represent anything sensible.
*/
int fa_nocase(struct fa *fa);
/* Return 1 if FA matches ignoring case, 0 if matches are case sensitive */
int fa_is_nocase(struct fa *fa);
/* Assume REGEXP is a case-insensitive regular expression, and convert it
* to one that matches the same strings when used case sensitively. All
* occurrences of individual letters c in the regular expression will be
* replaced by character sets [cC], and lower/upper case characters are
* added to character sets as needed.
*
* Return a positive value if REGEXP is not syntactically valid; the value
* returned is one of the REG_ERRCODE_T POSIX error codes. Return 0 on
* success and -1 if an allocation fails.
*/
int fa_expand_nocase(const char *regexp, size_t regexp_len,
char **newregexp, size_t *newregexp_len);
/* Generate up to LIMIT words from the language of FA, which is assumed to
* be finite. The words are returned in WORDS, which is allocated by this
* function and must be freed by the caller.
*
* If FA accepts the empty word, the empty string will be included in
* WORDS.
*
* Return the number of generated words on success, -1 if we run out of
* memory, and -2 if FA has more than LIMIT words.
*/
int fa_enumerate(struct fa *fa, int limit, char ***words);
/* Print FA to OUT as a JSON file. State 0 is always the initial one.
* Returns 0 on success, and -1 on failure.
*/
int fa_json(FILE *out, struct fa *fa);
/* Returns true if the FA is deterministic and 0 otherwise */
bool fa_is_deterministic(struct fa *fa);
/* Return the initial state */
struct state *fa_state_initial(struct fa *fa);
/* Return true if this is an accepting state */
bool fa_state_is_accepting(struct state *st);
/* Return the next state; return NULL if there are no more states */
struct state* fa_state_next(struct state *st);
/* Return the number of transitions for a state */
size_t fa_state_num_trans(struct state *st);
/* Produce details about the i-th transition.
*
* On success, *to points to the destination state of the transition and
* the interval [min-max] is the label of the transition.
*
* On failure, *to, min and max are not modified.
*
* Return 0 on success and -1 when I is larger than the number of
* transitions of ST.
*/
int fa_state_trans(struct state *st, size_t i,
struct state **to, unsigned char *min, unsigned char *max);
#endif
/*
* Local variables:
* indent-tabs-mode: nil
* c-indent-level: 4
* c-basic-offset: 4
* tab-width: 4
* End:
*/