1 #if !defined(RXH) || defined(RX_WANT_SE_DEFS)
4 /* Copyright (C) 1992, 1993 Free Software Foundation, Inc.
6 This file is part of the librx library.
8 Librx is free software; you can redistribute it and/or modify it under
9 the terms of the GNU Library General Public License as published by
10 the Free Software Foundation; either version 2, or (at your option)
13 Librx is distributed in the hope that it will be useful, but WITHOUT
14 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
15 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
18 You should have received a copy of the GNU Library General Public
19 License along with this software; see the file COPYING.LIB. If not,
20 write to the Free Software Foundation, 59 Temple Place - Suite 330,
21 Boston, MA 02111-1307, USA. */
22 /* t. lord Wed Sep 23 18:20:57 1992 */
31 #ifndef RX_WANT_SE_DEFS
33 /* This page: Bitsets */
36 typedef unsigned int RX_subset
;
37 #define RX_subset_bits (32)
38 #define RX_subset_mask (RX_subset_bits - 1)
41 typedef RX_subset
* rx_Bitset
;
44 typedef void (*rx_bitset_iterator
) (void *, int member_index
);
46 typedef void (*rx_bitset_iterator
) ();
49 #define rx_bitset_subset(N) ((N) / RX_subset_bits)
50 #define rx_bitset_subset_val(B,N) ((B)[rx_bitset_subset(N)])
51 #define RX_bitset_access(B,N,OP) \
52 ((B)[rx_bitset_subset(N)] OP rx_subset_singletons[(N) & RX_subset_mask])
53 #define RX_bitset_member(B,N) RX_bitset_access(B, N, &)
54 #define RX_bitset_enjoin(B,N) RX_bitset_access(B, N, |=)
55 #define RX_bitset_remove(B,N) RX_bitset_access(B, N, &= ~)
56 #define RX_bitset_toggle(B,N) RX_bitset_access(B, N, ^= )
57 #define rx_bitset_numb_subsets(N) (((N) + RX_subset_bits - 1) / RX_subset_bits)
58 #define rx_sizeof_bitset(N) (rx_bitset_numb_subsets(N) * sizeof(RX_subset))
62 /* This page: Splay trees. */
65 typedef int (*rx_sp_comparer
) (void * a
, void * b
);
67 typedef int (*rx_sp_comparer
) ();
74 struct rx_sp_node
* kids
[2];
78 typedef void (*rx_sp_key_data_freer
) (struct rx_sp_node
*);
80 typedef void (*rx_sp_key_data_freer
) ();
84 /* giant inflatable hash trees */
88 struct rx_hash_item
* next_same_hash
;
89 struct rx_hash
* table
;
97 struct rx_hash
* parent
;
99 struct rx_hash
* children
[13];
100 struct rx_hash_item
* buckets
[13];
101 int bucket_size
[13];
104 struct rx_hash_rules
;
107 /* should return like == */
108 typedef int (*rx_hash_eq
)(void *, void *);
109 typedef struct rx_hash
* (*rx_alloc_hash
)(struct rx_hash_rules
*);
110 typedef void (*rx_free_hash
)(struct rx_hash
*,
111 struct rx_hash_rules
*);
112 typedef struct rx_hash_item
* (*rx_alloc_hash_item
)(struct rx_hash_rules
*,
114 typedef void (*rx_free_hash_item
)(struct rx_hash_item
*,
115 struct rx_hash_rules
*);
117 typedef int (*rx_hash_eq
)();
118 typedef struct rx_hash
* (*rx_alloc_hash
)();
119 typedef void (*rx_free_hash
)();
120 typedef struct rx_hash_item
* (*rx_alloc_hash_item
)();
121 typedef void (*rx_free_hash_item
)();
127 rx_alloc_hash hash_alloc
;
128 rx_free_hash free_hash
;
129 rx_alloc_hash_item hash_item_alloc
;
130 rx_free_hash_item free_hash_item
;
134 /* Forward declarations */
149 * pattern - a `regular' expression. The expression
150 * need not be formally regular -- it can contain
151 * constructs that don't correspond to purely regular
155 * string - the string (or strings) being searched or matched.
157 * pattern buffer - a structure of type `struct re_pattern_buffer'
158 * This in turn contains a `struct rx', which holds the
159 * NFA compiled from a pattern, as well as some of the state
160 * of a matcher using the pattern.
162 * NFA - nondeterministic finite automata. Some people
163 * use this term to a member of the class of
164 * regular automata (those corresponding to a regular
165 * language). However, in this code, the meaning is
166 * more general. The automata used by Rx are comperable
167 * in power to what are usually called `push down automata'.
169 * Two NFA are built by rx for every pattern. One is built
170 * by the compiler. The other is built from the first, on
171 * the fly, by the matcher. The latter is called the `superstate
172 * NFA' because its states correspond to sets of states from
173 * the first NFA. (Joe Keane gets credit for the name
178 * side-effect edges - The NFA compiled from a pattern can have three
179 * kinds of edges. Epsilon edges can be taken freely anytime
180 * their source state is reached. Character set edges can be
181 * taken when their source state is reached and when the next
182 * character in the buffer is a member of the set. Side effect
183 * edges imply a transition that can only be taken after the
184 * indicated side effect has been successfully accomplished.
185 * Some examples of side effects are:
187 * Storing the current match position to record the
188 * location of a parentesized subexpression.
190 * Advancing the matcher over N characters if they
191 * match the N characters previously matched by a
192 * parentesized subexpression.
194 * Both of those kinds of edges occur in the NFA generated
195 * by the pattern: \(.\)\1
197 * Epsilon and side effect edges are similar. Unfortunately,
198 * some of the code uses the name `epsilon edge' to mean
199 * both epsilon and side effect edges. For example, the
200 * function has_non_idempotent_epsilon_path computes the existance
201 * of a non-trivial path containing only a mix of epsilon and
202 * side effect edges. In that case `nonidempotent epsilon' is being
203 * used to mean `side effect'.
210 /* LOW LEVEL PATTERN BUFFERS */
212 /* Suppose that from some NFA state, more than one path through
213 * side-effect edges is possible. In what order should the paths
214 * be tried? A function of type rx_se_list_order answers that
215 * question. It compares two lists of side effects, and says
216 * which list comes first.
220 typedef int (*rx_se_list_order
) (struct rx
*,
222 struct rx_se_list
*);
224 typedef int (*rx_se_list_order
) ();
229 /* Struct RX holds a compiled regular expression - that is, an nfa
230 * ready to be converted on demand to a more efficient superstate nfa.
231 * This is for the low level interface. The high-level interfaces enclose
232 * this in a `struct re_pattern_buffer'.
236 /* The compiler assigns a unique id to every pattern.
237 * Like sequence numbers in X, there is a subtle bug here
238 * if you use Rx in a system that runs for a long time.
239 * But, because of the way the caches work out, it is almost
240 * impossible to trigger the Rx version of this bug.
242 * The id is used to validate superstates found in a cache
243 * of superstates. It isn't sufficient to let a superstate
244 * point back to the rx for which it was compiled -- the caller
245 * may be re-using a `struct rx' in which case the superstate
246 * is not really valid. So instead, superstates are validated
247 * by checking the sequence number of the pattern for which
252 /* This is memory mgt. state for superstates. This may be
253 * shared by more than one struct rx.
255 struct rx_cache
* cache
;
257 /* Every regex defines the size of its own character set.
258 * A superstate has an array of this size, with each element
259 * a `struct rx_inx'. So, don't make this number too large.
260 * In particular, don't make it 2^16.
264 /* After the NFA is built, it is copied into a contiguous region
265 * of memory (mostly for compatability with GNU regex).
266 * Here is that region, and it's size:
269 unsigned long allocated
;
271 /* Clients of RX can ask for some extra storage in the space pointed
272 * to by BUFFER. The field RESERVED is an input parameter to the
273 * compiler. After compilation, this much space will be available
274 * at (buffer + allocated - reserved)
276 unsigned long reserved
;
278 /* --------- The remaining fields are for internal use only. --------- */
279 /* --------- But! they must be initialized to 0. --------- */
281 /* NODEC is the number of nodes in the NFA with non-epsilon
286 /* EPSNODEC is the number of nodes with only epsilon transitions. */
289 /* The sum (NODEC + EPSNODEC) is the total number of states in the
293 /* Lists of side effects as stored in the NFA are `hash consed'..meaning
294 * that lists with the same elements are ==. During compilation,
295 * this table facilitates hash-consing.
297 struct rx_hash se_list_memo
;
299 /* Lists of NFA states are also hashed.
301 struct rx_hash set_list_memo
;
306 /* The compiler and matcher must build a number of instruction frames.
307 * The format of these frames is fixed (c.f. struct rx_inx). The values
308 * of the instructions is not fixed.
310 * An enumerated type (enum rx_opcode) defines the set of instructions
311 * that the compiler or matcher might generate. When filling an instruction
312 * frame, the INX field is found by indexing this instruction table
315 void ** instruction_table
;
317 /* The list of all states in an NFA.
318 * During compilation, the NEXT field of NFA states links this list.
319 * After compilation, all the states are compacted into an array,
320 * ordered by state id numbers. At that time, this points to the base
323 struct rx_nfa_state
*nfa_states
;
325 /* Every nfa begins with one distinguished starting state:
327 struct rx_nfa_state
*start
;
329 /* This orders the search through super-nfa paths.
330 * See the comment near the typedef of rx_se_list_order.
332 rx_se_list_order se_list_cmp
;
334 struct rx_superset
* start_set
;
342 /* Compilation is in stages.
344 * In the first stage, a pattern specified by a string is
345 * translated into a syntax tree. Later stages will convert
346 * the syntax tree into an NFA optimized for conversion to a
349 * This page is about syntax trees.
354 r_cset
, /* Match from a character set. `a' or `[a-z]'*/
355 r_concat
, /* Concat two subexpressions. `ab' */
356 r_alternate
, /* Choose one of two subexpressions. `a\|b' */
357 r_opt
, /* Optional subexpression. `a?' */
358 r_star
, /* Repeated subexpression. `a*' */
361 /* A 2phase-star is a variation on a repeated subexpression.
362 * In this case, there are two subexpressions. The first, if matched,
363 * begins a repitition (otherwise, the whole expression is matches the
366 * After matching the first subexpression, a 2phase star either finishes,
367 * or matches the second subexpression. If the second subexpression is
368 * matched, then the whole construct repeats.
370 * 2phase stars are used in two circumstances. First, they
371 * are used as part of the implementation of POSIX intervals (counted
372 * repititions). Second, they are used to implement proper star
373 * semantics when the repeated subexpression contains paths of
374 * only side effects. See rx_compile for more information.
379 /* c.f. "typedef void * rx_side_effect" */
382 /* This is an extension type: It is for transient use in source->source
383 * transformations (implemented over syntax trees).
388 /* A side effect is a matcher-specific action associated with
389 * transitions in the NFA. The details of side effects are up
390 * to the matcher. To the compiler and superstate constructors
391 * side effects are opaque:
394 typedef void * rx_side_effect
;
396 /* Nodes in a syntax tree are of this type:
400 enum rexp_node_type type
;
404 rx_side_effect side_effect
;
407 struct rexp_node
*left
;
408 struct rexp_node
*right
;
418 * A syntax tree is compiled into an NFA. This page defines the structure
424 /* These are kept in a list as the NFA is being built. */
425 struct rx_nfa_state
*next
;
427 /* After the NFA is built, states are given integer id's.
428 * States whose outgoing transitions are all either epsilon or
429 * side effect edges are given ids less than 0. Other states
430 * are given successive non-negative ids starting from 0.
434 /* The list of NFA edges that go from this state to some other. */
435 struct rx_nfa_edge
*edges
;
437 /* If you land in this state, then you implicitly land
438 * in all other states reachable by only epsilon translations.
439 * Call the set of maximal paths to such states the epsilon closure
442 * There may be other states that are reachable by a mixture of
443 * epsilon and side effect edges. Consider the set of maximal paths
444 * of that sort from this state. Call it the epsilon-side-effect
445 * closure of the state.
447 * The epsilon closure of the state is a subset of the epsilon-side-
448 * effect closure. It consists of all the paths that contain
449 * no side effects -- only epsilon edges.
451 * The paths in the epsilon-side-effect closure can be partitioned
452 * into equivalance sets. Two paths are equivalant if they have the
453 * same set of side effects, in the same order. The epsilon-closure
454 * is one of these equivalance sets. Let's call these equivalance
455 * sets: observably equivalant path sets. That name is chosen
456 * because equivalance of two paths means they cause the same side
457 * effects -- so they lead to the same subsequent observations other
458 * than that they may wind up in different target states.
460 * The superstate nfa, which is derived from this nfa, is based on
461 * the observation that all of the paths in an observably equivalant
462 * path set can be explored at the same time, provided that the
463 * matcher keeps track not of a single nfa state, but of a set of
464 * states. In particular, after following all the paths in an
465 * observably equivalant set, you wind up at a set of target states.
466 * That set of target states corresponds to one state in the
469 * Staticly, before matching begins, it is convenient to analyze the
470 * nfa. Each state is labeled with a list of the observably
471 * equivalant path sets who's union covers all the
472 * epsilon-side-effect paths beginning in this state. This list is
473 * called the possible futures of the state.
475 * A trivial example is this NFA:
483 * ---------> D ------> E
486 * In this example, A has two possible futures.
487 * One invokes the side effect `s1' and contains two paths,
488 * one ending in state B, the other in state E.
489 * The other invokes the side effect `s2' and contains only
490 * one path, landing in state C.
492 struct rx_possible_future
*futures
;
495 /* There are exactly two distinguished states in every NFA: */
496 unsigned int is_final
:1;
497 unsigned int is_start
:1;
499 /* These are used during NFA construction... */
500 unsigned int eclosure_needed
:1;
505 /* An edge in an NFA is typed: */
508 /* A cset edge is labled with a set of characters one of which
509 * must be matched for the edge to be taken.
513 /* An epsilon edge is taken whenever its starting state is
518 /* A side effect edge is taken whenever its starting state is
519 * reached. Side effects may cause the match to fail or the
520 * position of the matcher to advance.
522 ne_side_effect
/* A special kind of epsilon. */
527 struct rx_nfa_edge
*next
;
528 enum rx_nfa_etype type
;
529 struct rx_nfa_state
*dest
;
533 rx_side_effect side_effect
;
539 /* A possible future consists of a list of side effects
540 * and a set of destination states. Below are their
541 * representations. These structures are hash-consed which
542 * means that lists with the same elements share a representation
543 * (their addresses are ==).
546 struct rx_nfa_state_set
548 struct rx_nfa_state
* car
;
549 struct rx_nfa_state_set
* cdr
;
555 struct rx_se_list
* cdr
;
558 struct rx_possible_future
560 struct rx_possible_future
*next
;
561 struct rx_se_list
* effects
;
562 struct rx_nfa_state_set
* destset
;
567 /* This begins the description of the superstate NFA.
569 * The superstate NFA corresponds to the NFA in these ways:
571 * Every superstate NFA states SUPER correspond to sets of NFA states,
574 * Superstate edges correspond to NFA paths.
576 * The superstate has no epsilon transitions;
577 * every edge has a character label, and a (possibly empty) side
578 * effect label. The side effect label corresponds to a list of
579 * side effects that occur in the NFA. These parts are referred
580 * to as: superedge_character(EDGE) and superedge_sides(EDGE).
582 * For a superstate edge EDGE starting in some superstate SUPER,
583 * the following is true (in pseudo-notation :-):
585 * exists DEST in nfa_states s.t.
586 * exists nfaEDGE in nfa_edges s.t.
587 * origin (nfaEDGE) == DEST
588 * && origin (nfaEDGE) is a member of nfa_states(SUPER)
589 * && exists PF in possible_futures(dest(nfaEDGE)) s.t.
590 * sides_of_possible_future (PF) == superedge_sides (EDGE)
594 * let SUPER2 := superedge_destination(EDGE)
596 * == union of all nfa state sets S s.t.
597 * exists PF in possible_futures(dest(nfaEDGE)) s.t.
598 * sides_of_possible_future (PF) == superedge_sides (EDGE)
599 * && S == dests_of_possible_future (PF) }
601 * Or in english, every superstate is a set of nfa states. A given
602 * character and a superstate implies many transitions in the NFA --
603 * those that begin with an edge labeled with that character from a
604 * state in the set corresponding to the superstate.
606 * The destinations of those transitions each have a set of possible
607 * futures. A possible future is a list of side effects and a set of
608 * destination NFA states. Two sets of possible futures can be
609 * `merged' by combining all pairs of possible futures that have the
610 * same side effects. A pair is combined by creating a new future
611 * with the same side effect but the union of the two destination sets.
612 * In this way, all the possible futures suggested by a superstate
613 * and a character can be merged into a set of possible futures where
614 * no two elements of the set have the same set of side effects.
616 * The destination of a possible future, being a set of NFA states,
617 * corresponds to a supernfa state. So, the merged set of possible
618 * futures we just created can serve as a set of edges in the
621 * The representation of the superstate nfa and the nfa is critical.
622 * The nfa has to be compact, but has to facilitate the rapid
623 * computation of missing superstates. The superstate nfa has to
624 * be fast to interpret, lazilly constructed, and bounded in space.
626 * To facilitate interpretation, the superstate data structures are
627 * peppered with `instruction frames'. There is an instruction set
628 * defined below which matchers using the supernfa must be able to
631 * We'd like to make it possible but not mandatory to use code
632 * addresses to represent instructions (c.f. gcc's computed goto).
633 * Therefore, we define an enumerated type of opcodes, and when
634 * writing one of these instructions into a data structure, use
635 * the opcode as an index into a table of instruction values.
637 * Here are the opcodes that occur in the superstate nfa:
641 /* Every superstate contains a table of instruction frames indexed
642 * by characters. A normal `move' in a matcher is to fetch the next
643 * character and use it as an index into a superstates transition
646 * In the fasted case, only one edge follows from that character.
647 * In other cases there is more work to do.
649 * The descriptions of the opcodes refer to data structures that are
650 * described further below.
656 * BACKTRACK_POINT is invoked when a character transition in
657 * a superstate leads to more than one edge. In that case,
658 * the edges have to be explored independently using a backtracking
661 * A BACKTRACK_POINT instruction is stored in a superstate's
662 * transition table for some character when it is known that that
663 * character crosses more than one edge. On encountering this
664 * instruction, the matcher saves enough state to backtrack to this
665 * point in the match later.
667 rx_backtrack_point
= 0, /* data is (struct transition_class *) */
670 * RX_DO_SIDE_EFFECTS evaluates the side effects of an epsilon path.
671 * There is one occurence of this instruction per rx_distinct_future.
672 * This instruction is skipped if a rx_distinct_future has no side effects.
674 rx_do_side_effects
= rx_backtrack_point
+ 1,
676 /* data is (struct rx_distinct_future *) */
679 * RX_CACHE_MISS instructions are stored in rx_distinct_futures whose
680 * destination superstate has been reclaimed (or was never built).
681 * It recomputes the destination superstate.
682 * RX_CACHE_MISS is also stored in a superstate transition table before
683 * any of its edges have been built.
685 rx_cache_miss
= rx_do_side_effects
+ 1,
686 /* data is (struct rx_distinct_future *) */
689 * RX_NEXT_CHAR is called to consume the next character and take the
690 * corresponding transition. This is the only instruction that uses
691 * the DATA field of the instruction frame instead of DATA_2.
692 * (see EXPLORE_FUTURE in regex.c).
694 rx_next_char
= rx_cache_miss
+ 1, /* data is (struct superstate *) */
696 /* RX_BACKTRACK indicates that a transition fails.
698 rx_backtrack
= rx_next_char
+ 1, /* no data */
701 * RX_ERROR_INX is stored only in places that should never be executed.
703 rx_error_inx
= rx_backtrack
+ 1, /* Not supposed to occur. */
705 rx_num_instructions
= rx_error_inx
+ 1
708 /* An id_instruction_table holds the values stored in instruction
709 * frames. The table is indexed by the enums declared above.
711 extern void * rx_id_instruction_table
[rx_num_instructions
];
713 /* The heart of the matcher is a `word-code-interpreter'
714 * (like a byte-code interpreter, except that instructions
715 * are a full word wide).
717 * Instructions are not stored in a vector of code, instead,
718 * they are scattered throughout the data structures built
719 * by the regexp compiler and the matcher. One word-code instruction,
720 * together with the arguments to that instruction, constitute
721 * an instruction frame (struct rx_inx).
723 * This structure type is padded by hand to a power of 2 because
724 * in one of the dominant cases, we dispatch by indexing a table
725 * of instruction frames. If that indexing can be accomplished
726 * by just a shift of the index, we're happy.
728 * Instructions take at most one argument, but there are two
729 * slots in an instruction frame that might hold that argument.
730 * These are called data and data_2. The data slot is only
731 * used for one instruction (RX_NEXT_CHAR). For all other
732 * instructions, data should be set to 0.
734 * RX_NEXT_CHAR is the most important instruction by far.
735 * By reserving the data field for its exclusive use,
736 * instruction dispatch is sped up in that case. There is
737 * no need to fetch both the instruction and the data,
738 * only the data is needed. In other words, a `cycle' begins
739 * by fetching the field data. If that is non-0, then it must
740 * be the destination state of a next_char transition, so
741 * make that value the current state, advance the match position
742 * by one character, and start a new cycle. On the other hand,
743 * if data is 0, fetch the instruction and do a more complicated
755 #ifndef RX_TAIL_ARRAY
756 #define RX_TAIL_ARRAY 1
759 /* A superstate corresponds to a set of nfa states. Those sets are
760 * represented by STRUCT RX_SUPERSET. The constructors
761 * guarantee that only one (shared) structure is created for a given set.
765 int refs
; /* This is a reference counted structure. */
767 /* We keep these sets in a cache because (in an unpredictable way),
768 * the same set is often created again and again. But that is also
769 * problematic -- compatibility with POSIX and GNU regex requires
770 * that we not be able to tell when a program discards a particular
771 * NFA (thus invalidating the supersets created from it).
773 * But when a cache hit appears to occur, we will have in hand the
774 * nfa for which it may have happened. That is why every nfa is given
775 * its own sequence number. On a cache hit, the cache is validated
776 * by comparing the nfa sequence number to this field:
780 struct rx_nfa_state
* car
; /* May or may not be a valid addr. */
781 struct rx_superset
* cdr
;
783 /* If the corresponding superstate exists: */
784 struct rx_superstate
* superstate
;
787 /* There is another bookkeeping problem. It is expensive to
788 * compute the starting nfa state set for an nfa. So, once computed,
789 * it is cached in the `struct rx'.
791 * But, the state set can be flushed from the superstate cache.
792 * When that happens, we can't know if the corresponding `struct rx'
793 * is still alive or if it has been freed or re-used by the program.
794 * So, the cached pointer to this set in a struct rx might be invalid
795 * and we need a way to validate it.
797 * Fortunately, even if this set is flushed from the cache, it is
798 * not freed. It just goes on the free-list of supersets.
799 * So we can still examine it.
801 * So to validate a starting set memo, check to see if the
802 * starts_for field still points back to the struct rx in question,
803 * and if the ID matches the rx sequence number.
805 struct rx
* starts_for
;
807 /* This is used to link into a hash bucket so these objects can
810 struct rx_hash_item hash_item
;
813 #define rx_protect_superset(RX,CON) (++(CON)->refs)
815 /* The terminology may be confusing (rename this structure?).
816 * Every character occurs in at most one rx_super_edge per super-state.
817 * But, that structure might have more than one option, indicating a point
818 * of non-determinism.
820 * In other words, this structure holds a list of superstate edges
821 * sharing a common starting state and character label. The edges
822 * are in the field OPTIONS. All superstate edges sharing the same
823 * starting state and character are in this list.
827 struct rx_super_edge
*next
;
828 struct rx_inx rx_backtrack_frame
;
831 struct rx_distinct_future
*options
;
834 /* A superstate is a set of nfa states (RX_SUPERSET) along
835 * with a transition table. Superstates are built on demand and reclaimed
836 * without warning. To protect a superstate from this ghastly fate,
837 * use LOCK_SUPERSTATE.
841 int rx_id
; /* c.f. the id field of rx_superset */
842 int locks
; /* protection from reclamation */
844 /* Within a superstate cache, all the superstates are kept in a big
845 * queue. The tail of the queue is the state most likely to be
846 * reclaimed. The *recyclable fields hold the queue position of
849 struct rx_superstate
* next_recyclable
;
850 struct rx_superstate
* prev_recyclable
;
852 /* The supernfa edges that exist in the cache and that have
853 * this state as their destination are kept in this list:
855 struct rx_distinct_future
* transition_refs
;
857 /* The list of nfa states corresponding to this superstate: */
858 struct rx_superset
* contents
;
860 /* The list of edges in the cache beginning from this state. */
861 struct rx_super_edge
* edges
;
863 /* A tail of the recyclable queue is marked as semifree. A semifree
864 * state has no incoming next_char transitions -- any transition
865 * into a semifree state causes a complex dispatch with the side
866 * effect of rescuing the state from its semifree state.
868 * An alternative to this might be to make next_char more expensive,
869 * and to move a state to the head of the recyclable queue whenever
870 * it is entered. That way, popular states would never be recycled.
872 * But unilaterally making next_char more expensive actually loses.
873 * So, incoming transitions are only made expensive for states near
874 * the tail of the recyclable queue. The more cache contention
875 * there is, the more frequently a state will have to prove itself
876 * and be moved back to the front of the queue. If there is less
877 * contention, then popular states just aggregate in the front of
878 * the queue and stay there.
883 /* This keeps track of the size of the transition table for this
884 * state. There is a half-hearted attempt to support variable sized
889 /* Indexed by characters... */
890 struct rx_inx transitions
[RX_TAIL_ARRAY
];
894 /* A list of distinct futures define the edges that leave from a
895 * given superstate on a given character. c.f. rx_super_edge.
898 struct rx_distinct_future
900 struct rx_distinct_future
* next_same_super_edge
[2];
901 struct rx_distinct_future
* next_same_dest
;
902 struct rx_distinct_future
* prev_same_dest
;
903 struct rx_superstate
* present
; /* source state */
904 struct rx_superstate
* future
; /* destination state */
905 struct rx_super_edge
* edge
;
908 /* The future_frame holds the instruction that should be executed
909 * after all the side effects are done, when it is time to complete
910 * the transition to the next state.
912 * Normally this is a next_char instruction, but it may be a
913 * cache_miss instruction as well, depending on whether or not
914 * the superstate is in the cache and semifree.
916 * If this is the only future for a given superstate/char, and
917 * if there are no side effects to be performed, this frame is
918 * not used (directly) at all. Instead, its contents are copied
919 * into the transition table of the starting state of this dist. future.
921 struct rx_inx future_frame
;
923 struct rx_inx side_effects_frame
;
924 struct rx_se_list
* effects
;
927 #define rx_lock_superstate(R,S) ((S)->locks++)
928 #define rx_unlock_superstate(R,S) (--(S)->locks)
931 /* This page destined for rx.h */
935 struct rx_blocklist
* next
;
941 struct rx_freelist
* next
;
947 typedef void (*rx_morecore_fn
)(struct rx_cache
*);
949 typedef void (*rx_morecore_fn
)();
952 /* You use this to control the allocation of superstate data
953 * during matching. Most of it should be initialized to 0.
955 * A MORECORE function is necessary. It should allocate
956 * a new block of memory or return 0.
957 * A default that uses malloc is called `rx_morecore'.
959 * The number of SUPERSTATES_ALLOWED indirectly limits how much memory
960 * the system will try to allocate. The default is 128. Batch style
961 * applications that are very regexp intensive should use as high a number
962 * as possible without thrashing.
964 * The LOCAL_CSET_SIZE is the number of characters in a character set.
965 * It is therefore the number of entries in a superstate transition table.
966 * Generally, it should be 256. If your character set has 16 bits,
967 * it is better to translate your regexps into equivalent 8 bit patterns.
972 struct rx_hash_rules superset_hash_rules
;
974 /* Objects are allocated by incrementing a pointer that
975 * scans across rx_blocklists.
977 struct rx_blocklist
* memory
;
978 struct rx_blocklist
* memory_pos
;
981 rx_morecore_fn morecore
;
984 struct rx_freelist
* free_superstates
;
985 struct rx_freelist
* free_transition_classes
;
986 struct rx_freelist
* free_discernable_futures
;
987 struct rx_freelist
* free_supersets
;
988 struct rx_freelist
* free_hash
;
990 /* Two sets of superstates -- those that are semifreed, and those
991 * that are being used.
993 struct rx_superstate
* lru_superstate
;
994 struct rx_superstate
* semifree_superstate
;
996 struct rx_superset
* empty_superset
;
999 int semifree_superstates
;
1002 int superstates_allowed
;
1004 int local_cset_size
;
1005 void ** instruction_table
;
1007 struct rx_hash superset_table
;
1012 /* The lowest-level search function supports arbitrarily fragmented
1013 * strings and (optionally) suspendable/resumable searches.
1015 * Callers have to provide a few hooks.
1020 #define __const__ const
1026 /* This holds a matcher position */
1027 struct rx_string_position
1029 __const__
unsigned char * pos
; /* The current pos. */
1030 __const__
unsigned char * string
; /* The current string burst. */
1031 __const__
unsigned char * end
; /* First invalid position >= POS. */
1032 int offset
; /* Integer address of the current burst. */
1033 int size
; /* Current string's size. */
1034 int search_direction
; /* 1 or -1 */
1035 int search_end
; /* First position to not try. */
1039 enum rx_get_burst_return
1041 rx_get_burst_continuation
,
1044 rx_get_burst_no_more
1048 /* A call to get burst should make POS valid. It might be invalid
1049 * if the STRING field doesn't point to a burst that actually
1052 * GET_BURST should take a clue from SEARCH_DIRECTION (1 or -1) as to
1053 * whether or not to pad to the left. Padding to the right is always
1054 * appropriate, but need not go past the point indicated by STOP.
1056 * If a continuation is returned, then the reentering call to
1057 * a search function will retry the get_burst.
1061 typedef enum rx_get_burst_return
1062 (*rx_get_burst_fn
) (struct rx_string_position
* pos
,
1067 typedef enum rx_get_burst_return (*rx_get_burst_fn
) ();
1071 enum rx_back_check_return
1073 rx_back_check_continuation
,
1074 rx_back_check_error
,
1079 /* Back_check should advance the position it is passed
1080 * over rparen - lparen characters and return pass iff
1081 * the characters starting at POS match those indexed
1082 * by [LPAREN..RPAREN].
1084 * If a continuation is returned, then the reentering call to
1085 * a search function will retry the back_check.
1089 typedef enum rx_back_check_return
1090 (*rx_back_check_fn
) (struct rx_string_position
* pos
,
1093 unsigned char * translate
,
1098 typedef enum rx_back_check_return (*rx_back_check_fn
) ();
1104 /* A call to fetch_char should return the character at POS or POS + 1.
1105 * Returning continuations here isn't supported. OFFSET is either 0 or 1
1106 * and indicates which characters is desired.
1110 typedef int (*rx_fetch_char_fn
) (struct rx_string_position
* pos
,
1115 typedef int (*rx_fetch_char_fn
) ();
1119 enum rx_search_return
1121 rx_search_continuation
= -4,
1122 rx_search_error
= -3,
1123 rx_search_soft_fail
= -2, /* failed by running out of string */
1124 rx_search_fail
= -1 /* failed only by reaching failure states */
1125 /* return values >= 0 indicate the position of a successful match */
1135 * The remaining declarations replace regex.h.
1138 /* This is an array of error messages corresponding to the error codes.
1140 extern __const__
char *re_error_msg
[];
1142 /* If any error codes are removed, changed, or added, update the
1143 `re_error_msg' table in regex.c. */
1146 REG_NOERROR
= 0, /* Success. */
1147 REG_NOMATCH
, /* Didn't find a match (for regexec). */
1149 /* POSIX regcomp return error codes. (In the order listed in the
1151 REG_BADPAT
, /* Invalid pattern. */
1152 REG_ECOLLATE
, /* Not implemented. */
1153 REG_ECTYPE
, /* Invalid character class name. */
1154 REG_EESCAPE
, /* Trailing backslash. */
1155 REG_ESUBREG
, /* Invalid back reference. */
1156 REG_EBRACK
, /* Unmatched left bracket. */
1157 REG_EPAREN
, /* Parenthesis imbalance. */
1158 REG_EBRACE
, /* Unmatched \{. */
1159 REG_BADBR
, /* Invalid contents of \{\}. */
1160 REG_ERANGE
, /* Invalid range end. */
1161 REG_ESPACE
, /* Ran out of memory. */
1162 REG_BADRPT
, /* No preceding re for repetition op. */
1164 /* Error codes we've added. */
1165 REG_EEND
, /* Premature end. */
1166 REG_ESIZE
, /* Compiled pattern bigger than 2^16 bytes. */
1167 REG_ERPAREN
/* Unmatched ) or \); not returned from regcomp. */
1170 /* The regex.c support, as a client of rx, defines a set of possible
1171 * side effects that can be added to the edge lables of nfa edges.
1172 * Here is the list of sidef effects in use.
1175 enum re_side_effects
1177 #define RX_WANT_SE_DEFS 1
1179 #undef RX_DEF_CPLX_SE
1180 #define RX_DEF_SE(IDEM, NAME, VALUE) NAME VALUE,
1181 #define RX_DEF_CPLX_SE(IDEM, NAME, VALUE) NAME VALUE,
1184 #undef RX_DEF_CPLX_SE
1185 #undef RX_WANT_SE_DEFS
1186 re_floogle_flap
= 65533
1189 /* These hold paramaters for the kinds of side effects that are possible
1190 * in the supported pattern languages. These include things like the
1191 * numeric bounds of {} operators and the index of paren registers for
1192 * subexpression measurement or backreferencing.
1196 enum re_side_effects se
;
1201 typedef unsigned reg_syntax_t
;
1203 struct re_pattern_buffer
1206 reg_syntax_t syntax
; /* See below for syntax bit definitions. */
1208 unsigned int no_sub
:1; /* If set, don't return register offsets. */
1209 unsigned int not_bol
:1; /* If set, the anchors ('^' and '$') don't */
1210 unsigned int not_eol
:1; /* match at the ends of the string. */
1211 unsigned int newline_anchor
:1;/* If true, an anchor at a newline matches.*/
1212 unsigned int least_subs
:1; /* If set, and returning registers, return
1213 * as few values as possible. Only
1214 * backreferenced groups and group 0 (the whole
1215 * match) will be returned.
1218 /* If true, this says that the matcher should keep registers on its
1219 * backtracking stack. For many patterns, we can easily determine that
1220 * this isn't necessary.
1222 unsigned int match_regs_on_stack
:1;
1223 unsigned int search_regs_on_stack
:1;
1225 /* is_anchored and begbuf_only are filled in by rx_compile. */
1226 unsigned int is_anchored
:1; /* Anchorded by ^? */
1227 unsigned int begbuf_only
:1; /* Anchored to char position 0? */
1230 /* If REGS_UNALLOCATED, allocate space in the `regs' structure
1231 * for `max (RE_NREGS, re_nsub + 1)' groups.
1232 * If REGS_REALLOCATE, reallocate space if necessary.
1233 * If REGS_FIXED, use what's there.
1235 #define REGS_UNALLOCATED 0
1236 #define REGS_REALLOCATE 1
1237 #define REGS_FIXED 2
1238 unsigned int regs_allocated
:2;
1241 /* Either a translate table to apply to all characters before
1242 * comparing them, or zero for no translation. The translation
1243 * is applied to a pattern when it is compiled and to a string
1244 * when it is matched.
1246 unsigned char * translate
;
1248 /* If this is a valid pointer, it tells rx not to store the extents of
1249 * certain subexpressions (those corresponding to non-zero entries).
1250 * Passing 0x1 is the same as passing an array of all ones. Passing 0x0
1251 * is the same as passing an array of all zeros.
1252 * The array should contain as many entries as their are subexps in the
1255 * For POSIX compatability, when using regcomp and regexec this field
1256 * is zeroed and ignored.
1258 char * syntax_parens
;
1260 /* Number of subexpressions found by the compiler. */
1263 void * buffer
; /* Malloced memory for the nfa. */
1264 unsigned long allocated
; /* Size of that memory. */
1266 /* Pointer to a fastmap, if any, otherwise zero. re_search uses
1267 * the fastmap, if there is one, to skip over impossible
1268 * starting points for matches. */
1271 unsigned int fastmap_accurate
:1; /* These three are internal. */
1272 unsigned int can_match_empty
:1;
1273 struct rx_nfa_state
* start
; /* The nfa starting state. */
1275 /* This is the list of iterator bounds for {lo,hi} constructs.
1276 * The memory pointed to is part of the rx->buffer.
1278 struct re_se_params
*se_params
;
1280 /* This is a bitset representation of the fastmap.
1281 * This is a true fastmap that already takes the translate
1282 * table into account.
1287 /* Type for byte offsets within the string. POSIX mandates this. */
1288 typedef int regoff_t
;
1290 /* This is the structure we store register match data in. See
1291 regex.texinfo for a full description of what registers match. */
1299 typedef struct re_pattern_buffer regex_t
;
1301 /* POSIX specification for registers. Aside from the different names than
1302 `re_registers', POSIX uses an array of structures, instead of a
1303 structure of arrays. */
1306 regoff_t rm_so
; /* Byte offset from string's start to substring's start. */
1307 regoff_t rm_eo
; /* Byte offset from string's start to substring's end. */
1311 /* The following bits are used to determine the regexp syntax we
1312 recognize. The set/not-set meanings are chosen so that Emacs syntax
1313 remains the value 0. The bits are given in alphabetical order, and
1314 the definitions shifted by one from the previous bit; thus, when we
1315 add or remove a bit, only one other definition need change. */
1317 /* If this bit is not set, then \ inside a bracket expression is literal.
1318 If set, then such a \ quotes the following character. */
1319 #define RE_BACKSLASH_ESCAPE_IN_LISTS (1)
1321 /* If this bit is not set, then + and ? are operators, and \+ and \? are
1323 If set, then \+ and \? are operators and + and ? are literals. */
1324 #define RE_BK_PLUS_QM (RE_BACKSLASH_ESCAPE_IN_LISTS << 1)
1326 /* If this bit is set, then character classes are supported. They are:
1327 [:alpha:], [:upper:], [:lower:], [:digit:], [:alnum:], [:xdigit:],
1328 [:space:], [:print:], [:punct:], [:graph:], and [:cntrl:].
1329 If not set, then character classes are not supported. */
1330 #define RE_CHAR_CLASSES (RE_BK_PLUS_QM << 1)
1332 /* If this bit is set, then ^ and $ are always anchors (outside bracket
1333 expressions, of course).
1334 If this bit is not set, then it depends:
1335 ^ is an anchor if it is at the beginning of a regular
1336 expression or after an open-group or an alternation operator;
1337 $ is an anchor if it is at the end of a regular expression, or
1338 before a close-group or an alternation operator.
1340 This bit could be (re)combined with RE_CONTEXT_INDEP_OPS, because
1341 POSIX draft 11.2 says that * etc. in leading positions is undefined.
1342 We already implemented a previous draft which made those constructs
1343 invalid, though, so we haven't changed the code back. */
1344 #define RE_CONTEXT_INDEP_ANCHORS (RE_CHAR_CLASSES << 1)
1346 /* If this bit is set, then special characters are always special
1347 regardless of where they are in the pattern.
1348 If this bit is not set, then special characters are special only in
1349 some contexts; otherwise they are ordinary. Specifically,
1350 * + ? and intervals are only special when not after the beginning,
1351 open-group, or alternation operator. */
1352 #define RE_CONTEXT_INDEP_OPS (RE_CONTEXT_INDEP_ANCHORS << 1)
1354 /* If this bit is set, then *, +, ?, and { cannot be first in an re or
1355 immediately after an alternation or begin-group operator. */
1356 #define RE_CONTEXT_INVALID_OPS (RE_CONTEXT_INDEP_OPS << 1)
1358 /* If this bit is set, then . matches newline.
1359 If not set, then it doesn't. */
1360 #define RE_DOT_NEWLINE (RE_CONTEXT_INVALID_OPS << 1)
1362 /* If this bit is set, then . doesn't match NUL.
1363 If not set, then it does. */
1364 #define RE_DOT_NOT_NULL (RE_DOT_NEWLINE << 1)
1366 /* If this bit is set, nonmatching lists [^...] do not match newline.
1367 If not set, they do. */
1368 #define RE_HAT_LISTS_NOT_NEWLINE (RE_DOT_NOT_NULL << 1)
1370 /* If this bit is set, either \{...\} or {...} defines an
1371 interval, depending on RE_NO_BK_BRACES.
1372 If not set, \{, \}, {, and } are literals. */
1373 #define RE_INTERVALS (RE_HAT_LISTS_NOT_NEWLINE << 1)
1375 /* If this bit is set, +, ? and | aren't recognized as operators.
1376 If not set, they are. */
1377 #define RE_LIMITED_OPS (RE_INTERVALS << 1)
1379 /* If this bit is set, newline is an alternation operator.
1380 If not set, newline is literal. */
1381 #define RE_NEWLINE_ALT (RE_LIMITED_OPS << 1)
1383 /* If this bit is set, then `{...}' defines an interval, and \{ and \}
1385 If not set, then `\{...\}' defines an interval. */
1386 #define RE_NO_BK_BRACES (RE_NEWLINE_ALT << 1)
1388 /* If this bit is set, (...) defines a group, and \( and \) are literals.
1389 If not set, \(...\) defines a group, and ( and ) are literals. */
1390 #define RE_NO_BK_PARENS (RE_NO_BK_BRACES << 1)
1392 /* If this bit is set, then \<digit> matches <digit>.
1393 If not set, then \<digit> is a back-reference. */
1394 #define RE_NO_BK_REFS (RE_NO_BK_PARENS << 1)
1396 /* If this bit is set, then | is an alternation operator, and \| is literal.
1397 If not set, then \| is an alternation operator, and | is literal. */
1398 #define RE_NO_BK_VBAR (RE_NO_BK_REFS << 1)
1400 /* If this bit is set, then an ending range point collating higher
1401 than the starting range point, as in [z-a], is invalid.
1402 If not set, then when ending range point collates higher than the
1403 starting range point, the range is ignored. */
1404 #define RE_NO_EMPTY_RANGES (RE_NO_BK_VBAR << 1)
1406 /* If this bit is set, then an unmatched ) is ordinary.
1407 If not set, then an unmatched ) is invalid. */
1408 #define RE_UNMATCHED_RIGHT_PAREN_ORD (RE_NO_EMPTY_RANGES << 1)
1410 /* This global variable defines the particular regexp syntax to use (for
1411 some interfaces). When a regexp is compiled, the syntax used is
1412 stored in the pattern buffer, so changing this does not affect
1413 already-compiled regexps. */
1414 extern reg_syntax_t re_syntax_options
;
1416 /* Define combinations of the above bits for the standard possibilities.
1417 (The [[[ comments delimit what gets put into the Texinfo file, so
1418 don't delete them!) */
1419 /* [[[begin syntaxes]]] */
1420 #define RE_SYNTAX_EMACS 0
1422 #define RE_SYNTAX_AWK \
1423 (RE_BACKSLASH_ESCAPE_IN_LISTS | RE_DOT_NOT_NULL \
1424 | RE_NO_BK_PARENS | RE_NO_BK_REFS \
1425 | RE_NO_BK_VBAR | RE_NO_EMPTY_RANGES \
1426 | RE_UNMATCHED_RIGHT_PAREN_ORD)
1428 #define RE_SYNTAX_POSIX_AWK \
1429 (RE_SYNTAX_POSIX_EXTENDED | RE_BACKSLASH_ESCAPE_IN_LISTS)
1431 #define RE_SYNTAX_GREP \
1432 (RE_BK_PLUS_QM | RE_CHAR_CLASSES \
1433 | RE_HAT_LISTS_NOT_NEWLINE | RE_INTERVALS \
1436 #define RE_SYNTAX_EGREP \
1437 (RE_CHAR_CLASSES | RE_CONTEXT_INDEP_ANCHORS \
1438 | RE_CONTEXT_INDEP_OPS | RE_HAT_LISTS_NOT_NEWLINE \
1439 | RE_NEWLINE_ALT | RE_NO_BK_PARENS \
1442 #define RE_SYNTAX_POSIX_EGREP \
1443 (RE_SYNTAX_EGREP | RE_INTERVALS | RE_NO_BK_BRACES)
1445 #define RE_SYNTAX_SED RE_SYNTAX_POSIX_BASIC
1447 /* Syntax bits common to both basic and extended POSIX regex syntax. */
1448 #define _RE_SYNTAX_POSIX_COMMON \
1449 (RE_CHAR_CLASSES | RE_DOT_NEWLINE | RE_DOT_NOT_NULL \
1450 | RE_INTERVALS | RE_NO_EMPTY_RANGES)
1452 #define RE_SYNTAX_POSIX_BASIC \
1453 (_RE_SYNTAX_POSIX_COMMON | RE_BK_PLUS_QM)
1455 /* Differs from ..._POSIX_BASIC only in that RE_BK_PLUS_QM becomes
1456 RE_LIMITED_OPS, i.e., \? \+ \| are not recognized. Actually, this
1457 isn't minimal, since other operators, such as \`, aren't disabled. */
1458 #define RE_SYNTAX_POSIX_MINIMAL_BASIC \
1459 (_RE_SYNTAX_POSIX_COMMON | RE_LIMITED_OPS)
1461 #define RE_SYNTAX_POSIX_EXTENDED \
1462 (_RE_SYNTAX_POSIX_COMMON | RE_CONTEXT_INDEP_ANCHORS \
1463 | RE_CONTEXT_INDEP_OPS | RE_NO_BK_BRACES \
1464 | RE_NO_BK_PARENS | RE_NO_BK_VBAR \
1465 | RE_UNMATCHED_RIGHT_PAREN_ORD)
1467 /* Differs from ..._POSIX_EXTENDED in that RE_CONTEXT_INVALID_OPS
1468 replaces RE_CONTEXT_INDEP_OPS and RE_NO_BK_REFS is added. */
1469 #define RE_SYNTAX_POSIX_MINIMAL_EXTENDED \
1470 (_RE_SYNTAX_POSIX_COMMON | RE_CONTEXT_INDEP_ANCHORS \
1471 | RE_CONTEXT_INVALID_OPS | RE_NO_BK_BRACES \
1472 | RE_NO_BK_PARENS | RE_NO_BK_REFS \
1473 | RE_NO_BK_VBAR | RE_UNMATCHED_RIGHT_PAREN_ORD)
1474 /* [[[end syntaxes]]] */
1476 /* Maximum number of duplicates an interval can allow. Some systems
1477 (erroneously) define this in other header files, but we want our
1478 value, so remove any previous define. */
1482 #define RE_DUP_MAX ((1 << 15) - 1)
1486 /* POSIX `cflags' bits (i.e., information for `regcomp'). */
1488 /* If this bit is set, then use extended regular expression syntax.
1489 If not set, then use basic regular expression syntax. */
1490 #define REG_EXTENDED 1
1492 /* If this bit is set, then ignore case when matching.
1493 If not set, then case is significant. */
1494 #define REG_ICASE (REG_EXTENDED << 1)
1496 /* If this bit is set, then anchors do not match at newline
1497 characters in the string.
1498 If not set, then anchors do match at newlines. */
1499 #define REG_NEWLINE (REG_ICASE << 1)
1501 /* If this bit is set, then report only success or fail in regexec.
1502 If not set, then returns differ between not matching and errors. */
1503 #define REG_NOSUB (REG_NEWLINE << 1)
1506 /* POSIX `eflags' bits (i.e., information for regexec). */
1508 /* If this bit is set, then the beginning-of-line operator doesn't match
1509 the beginning of the string (presumably because it's not the
1510 beginning of a line).
1511 If not set, then the beginning-of-line operator does match the
1512 beginning of the string. */
1513 #define REG_NOTBOL 1
1515 /* Like REG_NOTBOL, except for the end-of-line. */
1516 #define REG_NOTEOL (1 << 1)
1518 /* If `regs_allocated' is REGS_UNALLOCATED in the pattern buffer,
1519 * `re_match_2' returns information about at least this many registers
1520 * the first time a `regs' structure is passed.
1522 * Also, this is the greatest number of backreferenced subexpressions
1523 * allowed in a pattern being matched without caller-supplied registers.
1529 extern int rx_cache_bound
;
1530 extern const char *rx_version_string
;
1534 #ifdef RX_WANT_RX_DEFS
1536 /* This is decls to the interesting subsystems and lower layers
1537 * of rx. Everything which doesn't have a public counterpart in
1538 * regex.c is declared here.
1543 typedef void (*rx_hash_freefn
) (struct rx_hash_item
* it
);
1544 #else /* ndef __STDC__ */
1545 typedef void (*rx_hash_freefn
) ();
1546 #endif /* ndef __STDC__ */
1552 RX_DECL
int rx_bitset_is_equal (int size
, rx_Bitset a
, rx_Bitset b
);
1553 RX_DECL
int rx_bitset_is_subset (int size
, rx_Bitset a
, rx_Bitset b
);
1554 RX_DECL
int rx_bitset_empty (int size
, rx_Bitset set
);
1555 RX_DECL
void rx_bitset_null (int size
, rx_Bitset b
);
1556 RX_DECL
void rx_bitset_universe (int size
, rx_Bitset b
);
1557 RX_DECL
void rx_bitset_complement (int size
, rx_Bitset b
);
1558 RX_DECL
void rx_bitset_assign (int size
, rx_Bitset a
, rx_Bitset b
);
1559 RX_DECL
void rx_bitset_union (int size
, rx_Bitset a
, rx_Bitset b
);
1560 RX_DECL
void rx_bitset_intersection (int size
,
1561 rx_Bitset a
, rx_Bitset b
);
1562 RX_DECL
void rx_bitset_difference (int size
, rx_Bitset a
, rx_Bitset b
);
1563 RX_DECL
void rx_bitset_revdifference (int size
,
1564 rx_Bitset a
, rx_Bitset b
);
1565 RX_DECL
void rx_bitset_xor (int size
, rx_Bitset a
, rx_Bitset b
);
1566 RX_DECL
unsigned long rx_bitset_hash (int size
, rx_Bitset b
);
1567 RX_DECL
struct rx_hash_item
* rx_hash_find (struct rx_hash
* table
,
1570 struct rx_hash_rules
* rules
);
1571 RX_DECL
struct rx_hash_item
* rx_hash_store (struct rx_hash
* table
,
1574 struct rx_hash_rules
* rules
);
1575 RX_DECL
void rx_hash_free (struct rx_hash_item
* it
, struct rx_hash_rules
* rules
);
1576 RX_DECL
void rx_free_hash_table (struct rx_hash
* tab
, rx_hash_freefn freefn
,
1577 struct rx_hash_rules
* rules
);
1578 RX_DECL rx_Bitset
rx_cset (struct rx
*rx
);
1579 RX_DECL rx_Bitset
rx_copy_cset (struct rx
*rx
, rx_Bitset a
);
1580 RX_DECL
void rx_free_cset (struct rx
* rx
, rx_Bitset c
);
1581 RX_DECL
struct rexp_node
* rexp_node (struct rx
*rx
,
1582 enum rexp_node_type type
);
1583 RX_DECL
struct rexp_node
* rx_mk_r_cset (struct rx
* rx
,
1585 RX_DECL
struct rexp_node
* rx_mk_r_concat (struct rx
* rx
,
1586 struct rexp_node
* a
,
1587 struct rexp_node
* b
);
1588 RX_DECL
struct rexp_node
* rx_mk_r_alternate (struct rx
* rx
,
1589 struct rexp_node
* a
,
1590 struct rexp_node
* b
);
1591 RX_DECL
struct rexp_node
* rx_mk_r_opt (struct rx
* rx
,
1592 struct rexp_node
* a
);
1593 RX_DECL
struct rexp_node
* rx_mk_r_star (struct rx
* rx
,
1594 struct rexp_node
* a
);
1595 RX_DECL
struct rexp_node
* rx_mk_r_2phase_star (struct rx
* rx
,
1596 struct rexp_node
* a
,
1597 struct rexp_node
* b
);
1598 RX_DECL
struct rexp_node
* rx_mk_r_side_effect (struct rx
* rx
,
1600 RX_DECL
struct rexp_node
* rx_mk_r_data (struct rx
* rx
,
1602 RX_DECL
void rx_free_rexp (struct rx
* rx
, struct rexp_node
* node
);
1603 RX_DECL
struct rexp_node
* rx_copy_rexp (struct rx
*rx
,
1604 struct rexp_node
*node
);
1605 RX_DECL
struct rx_nfa_state
* rx_nfa_state (struct rx
*rx
);
1606 RX_DECL
void rx_free_nfa_state (struct rx_nfa_state
* n
);
1607 RX_DECL
struct rx_nfa_state
* rx_id_to_nfa_state (struct rx
* rx
,
1609 RX_DECL
struct rx_nfa_edge
* rx_nfa_edge (struct rx
*rx
,
1610 enum rx_nfa_etype type
,
1611 struct rx_nfa_state
*start
,
1612 struct rx_nfa_state
*dest
);
1613 RX_DECL
void rx_free_nfa_edge (struct rx_nfa_edge
* e
);
1614 RX_DECL
void rx_free_nfa (struct rx
*rx
);
1615 RX_DECL
int rx_build_nfa (struct rx
*rx
,
1616 struct rexp_node
*rexp
,
1617 struct rx_nfa_state
**start
,
1618 struct rx_nfa_state
**end
);
1619 RX_DECL
void rx_name_nfa_states (struct rx
*rx
);
1620 RX_DECL
int rx_eclose_nfa (struct rx
*rx
);
1621 RX_DECL
void rx_delete_epsilon_transitions (struct rx
*rx
);
1622 RX_DECL
int rx_compactify_nfa (struct rx
*rx
,
1623 void **mem
, unsigned long *size
);
1624 RX_DECL
void rx_release_superset (struct rx
*rx
,
1625 struct rx_superset
*set
);
1626 RX_DECL
struct rx_superset
* rx_superset_cons (struct rx
* rx
,
1627 struct rx_nfa_state
*car
, struct rx_superset
*cdr
);
1628 RX_DECL
struct rx_superset
* rx_superstate_eclosure_union
1629 (struct rx
* rx
, struct rx_superset
*set
, struct rx_nfa_state_set
*ecl
);
1630 RX_DECL
struct rx_superstate
* rx_superstate (struct rx
*rx
,
1631 struct rx_superset
*set
);
1632 RX_DECL
struct rx_inx
* rx_handle_cache_miss
1633 (struct rx
*rx
, struct rx_superstate
*super
, unsigned char chr
, void *data
);
1634 RX_DECL reg_errcode_t
rx_compile (__const__
char *pattern
, int size
,
1635 reg_syntax_t syntax
,
1636 struct re_pattern_buffer
* rxb
);
1637 RX_DECL
void rx_blow_up_fastmap (struct re_pattern_buffer
* rxb
);
1639 RX_DECL
int rx_bitset_is_equal ();
1640 RX_DECL
int rx_bitset_is_subset ();
1641 RX_DECL
int rx_bitset_empty ();
1642 RX_DECL
void rx_bitset_null ();
1643 RX_DECL
void rx_bitset_universe ();
1644 RX_DECL
void rx_bitset_complement ();
1645 RX_DECL
void rx_bitset_assign ();
1646 RX_DECL
void rx_bitset_union ();
1647 RX_DECL
void rx_bitset_intersection ();
1648 RX_DECL
void rx_bitset_difference ();
1649 RX_DECL
void rx_bitset_revdifference ();
1650 RX_DECL
void rx_bitset_xor ();
1651 RX_DECL
unsigned long rx_bitset_hash ();
1652 RX_DECL
struct rx_hash_item
* rx_hash_find ();
1653 RX_DECL
struct rx_hash_item
* rx_hash_store ();
1654 RX_DECL
void rx_hash_free ();
1655 RX_DECL
void rx_free_hash_table ();
1656 RX_DECL rx_Bitset
rx_cset ();
1657 RX_DECL rx_Bitset
rx_copy_cset ();
1658 RX_DECL
void rx_free_cset ();
1659 RX_DECL
struct rexp_node
* rexp_node ();
1660 RX_DECL
struct rexp_node
* rx_mk_r_cset ();
1661 RX_DECL
struct rexp_node
* rx_mk_r_concat ();
1662 RX_DECL
struct rexp_node
* rx_mk_r_alternate ();
1663 RX_DECL
struct rexp_node
* rx_mk_r_opt ();
1664 RX_DECL
struct rexp_node
* rx_mk_r_star ();
1665 RX_DECL
struct rexp_node
* rx_mk_r_2phase_star ();
1666 RX_DECL
struct rexp_node
* rx_mk_r_side_effect ();
1667 RX_DECL
struct rexp_node
* rx_mk_r_data ();
1668 RX_DECL
void rx_free_rexp ();
1669 RX_DECL
struct rexp_node
* rx_copy_rexp ();
1670 RX_DECL
struct rx_nfa_state
* rx_nfa_state ();
1671 RX_DECL
void rx_free_nfa_state ();
1672 RX_DECL
struct rx_nfa_state
* rx_id_to_nfa_state ();
1673 RX_DECL
struct rx_nfa_edge
* rx_nfa_edge ();
1674 RX_DECL
void rx_free_nfa_edge ();
1675 RX_DECL
void rx_free_nfa ();
1676 RX_DECL
int rx_build_nfa ();
1677 RX_DECL
void rx_name_nfa_states ();
1678 RX_DECL
int rx_eclose_nfa ();
1679 RX_DECL
void rx_delete_epsilon_transitions ();
1680 RX_DECL
int rx_compactify_nfa ();
1681 RX_DECL
void rx_release_superset ();
1682 RX_DECL
struct rx_superset
* rx_superset_cons ();
1683 RX_DECL
struct rx_superset
* rx_superstate_eclosure_union ();
1684 RX_DECL
struct rx_superstate
* rx_superstate ();
1685 RX_DECL
struct rx_inx
* rx_handle_cache_miss ();
1686 RX_DECL reg_errcode_t
rx_compile ();
1687 RX_DECL
void rx_blow_up_fastmap ();
1691 #endif /* RX_WANT_RX_DEFS */
1696 extern int re_search_2 (struct re_pattern_buffer
*rxb
,
1697 __const__
char * string1
, int size1
,
1698 __const__
char * string2
, int size2
,
1699 int startpos
, int range
,
1700 struct re_registers
*regs
,
1702 extern int re_search (struct re_pattern_buffer
* rxb
, __const__
char *string
,
1703 int size
, int startpos
, int range
,
1704 struct re_registers
*regs
);
1705 extern int re_match_2 (struct re_pattern_buffer
* rxb
,
1706 __const__
char * string1
, int size1
,
1707 __const__
char * string2
, int size2
,
1708 int pos
, struct re_registers
*regs
, int stop
);
1709 extern int re_match (struct re_pattern_buffer
* rxb
,
1710 __const__
char * string
,
1712 struct re_registers
*regs
);
1713 extern reg_syntax_t
re_set_syntax (reg_syntax_t syntax
);
1714 extern void re_set_registers (struct re_pattern_buffer
*bufp
,
1715 struct re_registers
*regs
,
1717 regoff_t
* starts
, regoff_t
* ends
);
1718 extern __const__
char * re_compile_pattern (__const__
char *pattern
,
1720 struct re_pattern_buffer
* rxb
);
1721 extern int re_compile_fastmap (struct re_pattern_buffer
* rxb
);
1722 extern char * re_comp (__const__
char *s
);
1723 extern int re_exec (__const__
char *s
);
1724 extern int regcomp (regex_t
* preg
, __const__
char * pattern
, int cflags
);
1725 extern int regexec (__const__ regex_t
*preg
, __const__
char *string
,
1726 size_t nmatch
, regmatch_t pmatch
[],
1728 extern size_t regerror (int errcode
, __const__ regex_t
*preg
,
1729 char *errbuf
, size_t errbuf_size
);
1730 extern void regfree (regex_t
*preg
);
1733 extern int re_search_2 ();
1734 extern int re_search ();
1735 extern int re_match_2 ();
1736 extern int re_match ();
1737 extern reg_syntax_t
re_set_syntax ();
1738 extern void re_set_registers ();
1739 extern __const__
char * re_compile_pattern ();
1740 extern int re_compile_fastmap ();
1741 extern char * re_comp ();
1742 extern int re_exec ();
1743 extern int regcomp ();
1744 extern int regexec ();
1745 extern size_t regerror ();
1746 extern void regfree ();
1752 #ifdef RX_WANT_RX_DEFS
1754 struct rx_counter_frame
1758 struct rx_counter_frame
* inherited_from
; /* If this is a copy. */
1759 struct rx_counter_frame
* cdr
;
1762 struct rx_backtrack_frame
1764 char * counter_stack_sp
;
1766 /* A frame is used to save the matchers state when it crosses a
1767 * backtracking point. The `stk_' fields correspond to variables
1768 * in re_search_2 (just strip off thes `stk_'). They are documented
1771 struct rx_superstate
* stk_super
;
1773 struct rx_string_position stk_test_pos
;
1778 /* This is the list of options left to explore at the backtrack
1779 * point for which this frame was created.
1781 struct rx_distinct_future
* df
;
1782 struct rx_distinct_future
* first_df
;
1789 struct rx_stack_chunk
1791 struct rx_stack_chunk
* next_chunk
;
1801 rx_outer_restore_pos
1804 enum rx_fastmap_return
1806 rx_fastmap_continuation
,
1812 enum rx_fastmap_entry
1815 rx_fastmap_string_break
1820 rx_test_continuation
,
1826 enum rx_test_internal_return
1828 rx_test_internal_error
,
1829 rx_test_found_first
,
1830 rx_test_line_finished
1833 enum rx_test_match_entry
1836 rx_test_cache_hit_loop
,
1837 rx_test_backreference_check
,
1838 rx_test_backtrack_return
1841 struct rx_search_state
1843 /* Two groups of registers are kept. The group with the register state
1844 * of the current test match, and the group that holds the state at the end
1845 * of the best known match, if any.
1847 * For some patterns, there may also be registers saved on the stack.
1849 unsigned num_regs
; /* Includes an element for register zero. */
1850 regoff_t
* lparen
; /* scratch space for register returns */
1852 regoff_t
* best_lpspace
; /* in case the user doesn't want these */
1853 regoff_t
* best_rpspace
; /* values, we still need space to store
1854 * them. Normally, this memoryis unused
1855 * and the space pointed to by REGS is
1859 int last_l
; /* Highest index of a valid lparen. */
1860 int last_r
; /* It's dual. */
1862 int * best_lparen
; /* This contains the best known register */
1863 int * best_rparen
; /* assignments.
1864 * This may point to the same mem as
1865 * best_lpspace, or it might point to memory
1866 * passed by the caller.
1868 int best_last_l
; /* best_last_l:best_lparen::last_l:lparen */
1872 unsigned char * translate
;
1874 struct rx_string_position outer_pos
;
1876 struct rx_superstate
* start_super
;
1878 int first_found
; /* If true, return after finding any match. */
1881 /* For continuations... */
1882 enum rx_outer_entry outer_search_resume_pt
;
1883 struct re_pattern_buffer
* saved_rxb
;
1887 int saved_total_size
;
1888 rx_get_burst_fn saved_get_burst
;
1889 rx_back_check_fn saved_back_check
;
1890 struct re_registers
* saved_regs
;
1893 ** state for fastmap
1899 /* for continuations in the fastmap procedure: */
1900 enum rx_fastmap_entry fastmap_resume_pt
;
1903 ** state for test_match
1906 /* The current superNFA position of the matcher. */
1907 struct rx_superstate
* super
;
1909 /* The matcher interprets a series of instruction frames.
1910 * This is the `instruction counter' for the interpretation.
1912 struct rx_inx
* ifr
;
1914 /* We insert a ghost character in the string to prime
1915 * the nfa. test_pos.pos, test_pos.str_half, and test_pos.end_half
1916 * keep track of the test-match position and string-half.
1920 /* Position within the string. */
1921 struct rx_string_position test_pos
;
1923 struct rx_stack_chunk
* counter_stack
;
1924 struct rx_stack_chunk
* backtrack_stack
;
1925 int backtrack_frame_bytes
;
1927 struct rx_stack_chunk
* free_chunks
;
1929 /* To return from this function, set test_ret and
1930 * `goto test_do_return'.
1932 * Possible return values are:
1933 * 1 --- end of string while the superNFA is still going
1934 * 0 --- internal error (out of memory)
1935 * -1 --- search completed by reaching the superNFA fail state
1936 * -2 --- a match was found, maybe not the longest.
1938 * When the search is complete (-1), best_last_r indicates whether
1939 * a match was found.
1941 * -2 is return only if search_state.first_found is non-zero.
1943 * if search_state.first_found is non-zero, a return of -1 indicates no match,
1944 * otherwise, best_last_r has to be checked.
1948 int could_have_continued
;
1951 int backtrack_depth
;
1952 /* There is a search tree with every node as set of deterministic
1953 * transitions in the super nfa. For every branch of a
1954 * backtrack point is an edge in the tree.
1955 * This counts up a pre-order of nodes in that tree.
1956 * It's saved on the search stack and printed when debugging.
1963 /* For continuations within the match tester */
1964 enum rx_test_match_entry test_match_resume_pt
;
1965 struct rx_inx
* saved_next_tr_table
;
1966 struct rx_inx
* saved_this_tr_table
;
1968 struct rx_backtrack_frame
* saved_bf
;
1973 extern char rx_slowmap
[];
1974 extern unsigned char rx_id_translation
[];
1976 static __inline__
void
1977 init_fastmap (rxb
, search_state
)
1978 struct re_pattern_buffer
* rxb
;
1979 struct rx_search_state
* search_state
;
1981 search_state
->fastmap
= (rxb
->fastmap
1982 ? (char *)rxb
->fastmap
1983 : (char *)rx_slowmap
);
1984 /* Update the fastmap now if not correct already.
1985 * When the regexp was compiled, the fastmap was computed
1986 * and stored in a bitset. This expands the bitset into a
1987 * character array containing 1s and 0s.
1989 if ((search_state
->fastmap
== rxb
->fastmap
) && !rxb
->fastmap_accurate
)
1990 rx_blow_up_fastmap (rxb
);
1991 search_state
->fastmap_chr
= -1;
1992 search_state
->fastmap_val
= 0;
1993 search_state
->fastmap_resume_pt
= rx_fastmap_start
;
1996 static __inline__
void
1997 uninit_fastmap (rxb
, search_state
)
1998 struct re_pattern_buffer
* rxb
;
1999 struct rx_search_state
* search_state
;
2001 /* Unset the fastmap sentinel */
2002 if (search_state
->fastmap_chr
>= 0)
2003 search_state
->fastmap
[search_state
->fastmap_chr
]
2004 = search_state
->fastmap_val
;
2007 static __inline__
int
2008 fastmap_search (rxb
, stop
, get_burst
, app_closure
, search_state
)
2009 struct re_pattern_buffer
* rxb
;
2011 rx_get_burst_fn get_burst
;
2013 struct rx_search_state
* search_state
;
2015 enum rx_fastmap_entry pc
;
2019 return_continuation
:
2020 search_state
->fastmap_resume_pt
= pc
;
2021 return rx_fastmap_continuation
;
2024 pc
= search_state
->fastmap_resume_pt
;
2029 return rx_fastmap_error
;
2030 case rx_fastmap_start
:
2031 init_fastmap_sentinal
:
2032 /* For the sake of fast fastmapping, set a sentinal in the fastmap.
2033 * This sentinal will trap the fastmap loop when it reaches the last
2034 * valid character in a string half.
2036 * This must be reset when the fastmap/search loop crosses a string
2037 * boundry, and before returning to the caller. So sometimes,
2038 * the fastmap loop is restarted with `continue', othertimes by
2039 * `goto init_fastmap_sentinal'.
2041 if (search_state
->outer_pos
.size
)
2043 search_state
->fastmap_chr
= ((search_state
->outer_pos
.search_direction
== 1)
2044 ? *(search_state
->outer_pos
.end
- 1)
2045 : *search_state
->outer_pos
.string
);
2046 search_state
->fastmap_val
2047 = search_state
->fastmap
[search_state
->fastmap_chr
];
2048 search_state
->fastmap
[search_state
->fastmap_chr
] = 1;
2052 search_state
->fastmap_chr
= -1;
2053 search_state
->fastmap_val
= 0;
2056 if (search_state
->outer_pos
.pos
>= search_state
->outer_pos
.end
)
2057 goto fastmap_hit_bound
;
2060 if (search_state
->outer_pos
.search_direction
== 1)
2062 if (search_state
->fastmap_val
)
2066 while (!search_state
->fastmap
[*search_state
->outer_pos
.pos
])
2067 ++search_state
->outer_pos
.pos
;
2068 return rx_fastmap_ok
;
2075 while (!search_state
->fastmap
[*search_state
->outer_pos
.pos
])
2076 ++search_state
->outer_pos
.pos
;
2077 if (*search_state
->outer_pos
.pos
!= search_state
->fastmap_chr
)
2078 return rx_fastmap_ok
;
2081 ++search_state
->outer_pos
.pos
;
2082 if (search_state
->outer_pos
.pos
== search_state
->outer_pos
.end
)
2083 goto fastmap_hit_bound
;
2090 __const__
unsigned char * bound
;
2091 bound
= search_state
->outer_pos
.string
- 1;
2092 if (search_state
->fastmap_val
)
2096 while (!search_state
->fastmap
[*search_state
->outer_pos
.pos
])
2097 --search_state
->outer_pos
.pos
;
2098 return rx_fastmap_ok
;
2105 while (!search_state
->fastmap
[*search_state
->outer_pos
.pos
])
2106 --search_state
->outer_pos
.pos
;
2107 if ((*search_state
->outer_pos
.pos
!= search_state
->fastmap_chr
) || search_state
->fastmap_val
)
2108 return rx_fastmap_ok
;
2111 --search_state
->outer_pos
.pos
;
2112 if (search_state
->outer_pos
.pos
== bound
)
2113 goto fastmap_hit_bound
;
2120 case rx_fastmap_string_break
:
2123 /* If we hit a bound, it may be time to fetch another burst
2124 * of string, or it may be time to return a continuation to
2125 * the caller, or it might be time to fail.
2129 burst_state
= get_burst (&search_state
->outer_pos
, app_closure
, stop
);
2130 switch (burst_state
)
2133 case rx_get_burst_error
:
2134 return rx_fastmap_error
;
2135 case rx_get_burst_continuation
:
2137 pc
= rx_fastmap_string_break
;
2138 goto return_continuation
;
2140 case rx_get_burst_ok
:
2141 goto init_fastmap_sentinal
;
2142 case rx_get_burst_no_more
:
2143 /* ...not a string split, simply no more string.
2145 * When searching backward, running out of string
2146 * is reason to quit.
2148 * When searching forward, we allow the possibility
2149 * of an (empty) match after the last character in the
2150 * virtual string. So, fall through to the matcher
2152 return ( (search_state
->outer_pos
.search_direction
== 1)
2164 /* The `emacs' switch turns on certain matching commands
2165 * that make sense only in Emacs.
2173 /* Setting RX_MEMDBUG is useful if you have dbmalloc. Maybe with similar
2178 #endif /* RX_RX_MEMDBUG */
2180 /* We used to test for `BSTRING' here, but only GCC and Emacs define
2181 * `BSTRING', as far as I know, and neither of them use this code.
2183 #if HAVE_STRING_H || STDC_HEADERS
2187 #define bcmp(s1, s2, n) memcmp ((s1), (s2), (n))
2191 #define bcopy(s, d, n) memcpy ((d), (s), (n))
2195 #define bzero(s, n) memset ((s), 0, (n))
2198 #else /* HAVE_STRING_H || STDC_HEADERS */
2199 #include <strings.h>
2200 #endif /* not (HAVE_STRING_H || STDC_HEADERS) */
2204 #else /* not STDC_HEADERS */
2207 #endif /* not STDC_HEADERS */
2212 /* How many characters in the character set. */
2213 #define CHAR_SET_SIZE (1 << CHARBITS)
2216 /* Define the syntax basics for \<, \>, etc.
2217 * This must be nonzero for the wordchar and notwordchar pattern
2218 * commands in re_match_2.
2223 #define SYNTAX(c) re_syntax_table[c]
2224 RX_DECL
char re_syntax_table
[CHAR_SET_SIZE
];
2225 #endif /* not emacs */
2228 /* Test if at very beginning or at very end of the virtual concatenation
2229 * of `string1' and `string2'. If only one string, it's `string2'.
2232 #define AT_STRINGS_BEG() \
2234 == ((search_state.test_pos.pos - search_state.test_pos.string) \
2235 + search_state.test_pos.offset))
2237 #define AT_STRINGS_END() \
2238 ( (total_size - 1) \
2239 == ((search_state.test_pos.pos - search_state.test_pos.string) \
2240 + search_state.test_pos.offset))
2243 /* Test if POS + 1 points to a character which is word-constituent. We have
2244 * two special cases to check for: if past the end of string1, look at
2245 * the first character in string2; and if before the beginning of
2246 * string2, look at the last character in string1.
2248 * Assumes `string1' exists, so use in conjunction with AT_STRINGS_BEG ().
2250 #define LETTER_P(POS,OFF) \
2251 ( SYNTAX (fetch_char(POS, OFF, app_closure, stop)) \
2254 /* Test if the character at D and the one after D differ with respect
2255 * to being word-constituent.
2257 #define AT_WORD_BOUNDARY(d) \
2258 (AT_STRINGS_BEG () || AT_STRINGS_END () || LETTER_P (d,0) != LETTER_P (d, 1))
2261 #ifdef RX_SUPPORT_CONTINUATIONS
2262 #define RX_STACK_ALLOC(BYTES) malloc(BYTES)
2263 #define RX_STACK_FREE(MEM) free(MEM)
2265 #define RX_STACK_ALLOC(BYTES) alloca(BYTES)
2266 #define RX_STACK_FREE(MEM) \
2267 ((struct rx_stack_chunk *)MEM)->next_chunk = search_state.free_chunks; \
2268 search_state.free_chunks = ((struct rx_stack_chunk *)MEM);
2272 #define PUSH(CHUNK_VAR,BYTES) \
2273 if (!CHUNK_VAR || (CHUNK_VAR->bytes_left < (BYTES))) \
2275 struct rx_stack_chunk * new_chunk; \
2276 if (search_state.free_chunks) \
2278 new_chunk = search_state.free_chunks; \
2279 search_state.free_chunks = search_state.free_chunks->next_chunk; \
2283 new_chunk = (struct rx_stack_chunk *)RX_STACK_ALLOC(search_state.chunk_bytes); \
2286 search_state.ret_val = 0; \
2287 goto test_do_return; \
2290 new_chunk->sp = (char *)new_chunk + sizeof (struct rx_stack_chunk); \
2291 new_chunk->bytes_left = (search_state.chunk_bytes \
2293 - sizeof (struct rx_stack_chunk)); \
2294 new_chunk->next_chunk = CHUNK_VAR; \
2295 CHUNK_VAR = new_chunk; \
2298 (CHUNK_VAR->sp += (BYTES)), (CHUNK_VAR->bytes_left -= (BYTES))
2300 #define POP(CHUNK_VAR,BYTES) \
2301 if (CHUNK_VAR->sp == ((char *)CHUNK_VAR + sizeof(*CHUNK_VAR))) \
2303 struct rx_stack_chunk * new_chunk = CHUNK_VAR->next_chunk; \
2304 RX_STACK_FREE(CHUNK_VAR); \
2305 CHUNK_VAR = new_chunk; \
2308 (CHUNK_VAR->sp -= BYTES), (CHUNK_VAR->bytes_left += BYTES)
2312 #define SRCH_TRANSLATE(C) search_state.translate[(unsigned char) (C)]
2318 RX_DECL __inline__
int
2319 rx_search (struct re_pattern_buffer
* rxb
,
2324 rx_get_burst_fn get_burst
,
2325 rx_back_check_fn back_check
,
2326 rx_fetch_char_fn fetch_char
,
2328 struct re_registers
* regs
,
2329 struct rx_search_state
* resume_state
,
2330 struct rx_search_state
* save_state
)
2332 RX_DECL __inline__
int
2333 rx_search (rxb
, startpos
, range
, stop
, total_size
,
2334 get_burst
, back_check
, fetch_char
,
2335 app_closure
, regs
, resume_state
, save_state
)
2336 struct re_pattern_buffer
* rxb
;
2341 rx_get_burst_fn get_burst
;
2342 rx_back_check_fn back_check
;
2343 rx_fetch_char_fn fetch_char
;
2345 struct re_registers
* regs
;
2346 struct rx_search_state
* resume_state
;
2347 struct rx_search_state
* save_state
;
2352 struct rx_search_state search_state
;
2354 search_state
.free_chunks
= 0;
2356 pc
= rx_outer_start
;
2359 search_state
= *resume_state
;
2360 regs
= search_state
.saved_regs
;
2361 rxb
= search_state
.saved_rxb
;
2362 startpos
= search_state
.saved_startpos
;
2363 range
= search_state
.saved_range
;
2364 stop
= search_state
.saved_stop
;
2365 total_size
= search_state
.saved_total_size
;
2366 get_burst
= search_state
.saved_get_burst
;
2367 back_check
= search_state
.saved_back_check
;
2368 pc
= search_state
.outer_search_resume_pt
;
2371 return_continuation
:
2374 *save_state
= search_state
;
2375 save_state
->saved_regs
= regs
;
2376 save_state
->saved_rxb
= rxb
;
2377 save_state
->saved_startpos
= startpos
;
2378 save_state
->saved_range
= range
;
2379 save_state
->saved_stop
= stop
;
2380 save_state
->saved_total_size
= total_size
;
2381 save_state
->saved_get_burst
= get_burst
;
2382 save_state
->saved_back_check
= back_check
;
2383 save_state
->outer_search_resume_pt
= pc
;
2385 return rx_search_continuation
;
2391 case rx_outer_start
:
2392 search_state
.ret_val
= rx_search_fail
;
2393 ( search_state
.lparen
2394 = search_state
.rparen
2395 = search_state
.best_lpspace
2396 = search_state
.best_rpspace
2399 /* figure the number of registers we may need for use in backreferences.
2400 * the number here includes an element for register zero.
2402 search_state
.num_regs
= rxb
->re_nsub
+ 1;
2405 /* check for out-of-range startpos. */
2406 if ((startpos
< 0) || (startpos
> total_size
))
2407 return rx_search_fail
;
2409 /* fix up range if it might eventually take us outside the string. */
2412 endpos
= startpos
+ range
;
2414 range
= (-1 - startpos
);
2415 else if (endpos
> (total_size
+ 1))
2416 range
= total_size
- startpos
;
2419 /* if the search isn't to be a backwards one, don't waste time in a
2420 * long search for a pattern that says it is anchored.
2422 if (rxb
->begbuf_only
&& (range
> 0))
2425 return rx_search_fail
;
2430 /* decide whether to use internal or user-provided reg buffers. */
2431 if (!regs
|| rxb
->no_sub
)
2433 search_state
.best_lpspace
=
2434 (regoff_t
*)REGEX_ALLOCATE (search_state
.num_regs
* sizeof(regoff_t
));
2435 search_state
.best_rpspace
=
2436 (regoff_t
*)REGEX_ALLOCATE (search_state
.num_regs
* sizeof(regoff_t
));
2437 search_state
.best_lparen
= search_state
.best_lpspace
;
2438 search_state
.best_rparen
= search_state
.best_rpspace
;
2442 /* have the register data arrays been allocated? */
2443 if (rxb
->regs_allocated
== REGS_UNALLOCATED
)
2444 { /* no. so allocate them with malloc. we need one
2445 extra element beyond `search_state.num_regs' for the `-1' marker
2447 regs
->num_regs
= MAX (RE_NREGS
, rxb
->re_nsub
+ 1);
2448 regs
->start
= ((regoff_t
*)
2449 malloc (regs
->num_regs
* sizeof ( regoff_t
)));
2450 regs
->end
= ((regoff_t
*)
2451 malloc (regs
->num_regs
* sizeof ( regoff_t
)));
2452 if (regs
->start
== 0 || regs
->end
== 0)
2453 return rx_search_error
;
2454 rxb
->regs_allocated
= REGS_REALLOCATE
;
2456 else if (rxb
->regs_allocated
== REGS_REALLOCATE
)
2457 { /* yes. if we need more elements than were already
2458 allocated, reallocate them. if we need fewer, just
2460 if (regs
->num_regs
< search_state
.num_regs
+ 1)
2462 regs
->num_regs
= search_state
.num_regs
+ 1;
2463 regs
->start
= ((regoff_t
*)
2464 realloc (regs
->start
,
2465 regs
->num_regs
* sizeof (regoff_t
)));
2466 regs
->end
= ((regoff_t
*)
2468 regs
->num_regs
* sizeof ( regoff_t
)));
2469 if (regs
->start
== 0 || regs
->end
== 0)
2470 return rx_search_error
;
2473 else if (rxb
->regs_allocated
!= REGS_FIXED
)
2474 return rx_search_error
;
2476 if (regs
->num_regs
< search_state
.num_regs
+ 1)
2478 search_state
.best_lpspace
=
2480 REGEX_ALLOCATE (search_state
.num_regs
* sizeof(regoff_t
)));
2481 search_state
.best_rpspace
=
2483 REGEX_ALLOCATE (search_state
.num_regs
* sizeof(regoff_t
)));
2484 search_state
.best_lparen
= search_state
.best_lpspace
;
2485 search_state
.best_rparen
= search_state
.best_rpspace
;
2489 search_state
.best_lparen
= regs
->start
;
2490 search_state
.best_rparen
= regs
->end
;
2494 search_state
.lparen
=
2495 (regoff_t
*) REGEX_ALLOCATE (search_state
.num_regs
* sizeof(regoff_t
));
2496 search_state
.rparen
=
2497 (regoff_t
*) REGEX_ALLOCATE (search_state
.num_regs
* sizeof(regoff_t
));
2499 if (! ( search_state
.best_rparen
2500 && search_state
.best_lparen
2501 && search_state
.lparen
&& search_state
.rparen
))
2502 return rx_search_error
;
2504 search_state
.best_last_l
= search_state
.best_last_r
= -1;
2506 search_state
.translate
= (rxb
->translate
2508 : rx_id_translation
);
2513 * two nfa's were compiled.
2515 * `1' faster but gets registers wrong and ends too soon.
2517 search_state
.nfa_choice
= (regs
&& !rxb
->least_subs
) ? '\0' : '\1';
2519 /* we have the option to look for the best match or the first
2520 * one we can find. if the user isn't asking for register information,
2521 * we don't need to find the best match.
2523 search_state
.first_found
= !regs
;
2527 search_state
.outer_pos
.search_end
= startpos
+ range
;
2528 search_state
.outer_pos
.search_direction
= 1;
2532 search_state
.outer_pos
.search_end
= startpos
+ range
;
2533 search_state
.outer_pos
.search_direction
= -1;
2536 /* the vacuous search always turns up nothing. */
2537 if ((search_state
.outer_pos
.search_direction
== 1)
2538 ? (startpos
> search_state
.outer_pos
.search_end
)
2539 : (startpos
< search_state
.outer_pos
.search_end
))
2540 return rx_search_fail
;
2542 /* now we build the starting state of the supernfa. */
2544 struct rx_superset
* start_contents
;
2545 struct rx_nfa_state_set
* start_nfa_set
;
2547 /* we presume here that the nfa start state has only one
2548 * possible future with no side effects.
2550 start_nfa_set
= rxb
->start
->futures
->destset
;
2551 if ( rxb
->rx
.start_set
2552 && (rxb
->rx
.start_set
->starts_for
== &rxb
->rx
))
2553 start_contents
= rxb
->rx
.start_set
;
2557 rx_superstate_eclosure_union (&rxb
->rx
,
2558 rx_superset_cons (&rxb
->rx
, 0, 0),
2561 if (!start_contents
)
2562 return rx_search_fail
;
2564 start_contents
->starts_for
= &rxb
->rx
;
2565 rxb
->rx
.start_set
= start_contents
;
2567 if ( start_contents
->superstate
2568 && (start_contents
->superstate
->rx_id
== rxb
->rx
.rx_id
))
2570 search_state
.start_super
= start_contents
->superstate
;
2571 rx_lock_superstate (&rxb
->rx
, search_state
.start_super
);
2575 rx_protect_superset (&rxb
->rx
, start_contents
);
2577 search_state
.start_super
= rx_superstate (&rxb
->rx
, start_contents
);
2578 if (!search_state
.start_super
)
2579 return rx_search_fail
;
2580 rx_lock_superstate (&rxb
->rx
, search_state
.start_super
);
2581 rx_release_superset (&rxb
->rx
, start_contents
);
2586 /* The outer_pos tracks the position within the strings
2587 * as seen by loop that calls fastmap_search.
2589 * The caller supplied get_burst function actually
2590 * gives us pointers to chars.
2592 * Communication with the get_burst function is through an
2593 * rx_string_position structure. Here, the structure for
2594 * outer_pos is initialized. It is set to point to the
2595 * NULL string, at an offset of STARTPOS. STARTPOS is out
2596 * of range of the NULL string, so the first call to
2597 * getburst will patch up the rx_string_position to point
2598 * to valid characters.
2601 ( search_state
.outer_pos
.string
2602 = search_state
.outer_pos
.end
2605 search_state
.outer_pos
.offset
= 0;
2606 search_state
.outer_pos
.size
= 0;
2607 search_state
.outer_pos
.pos
= (unsigned char *)startpos
;
2608 init_fastmap (rxb
, &search_state
);
2610 search_state
.fastmap_resume_pt
= rx_fastmap_start
;
2611 case rx_outer_fastmap
:
2617 fastmap_state
= fastmap_search (rxb
, stop
, get_burst
, app_closure
,
2619 switch (fastmap_state
)
2621 case rx_fastmap_continuation
:
2622 pc
= rx_outer_fastmap
;
2623 goto return_continuation
;
2624 case rx_fastmap_fail
:
2631 /* now the fastmap loop has brought us to a plausible
2632 * starting point for a match. so, it's time to run the
2633 * nfa and see if a match occured.
2635 startpos
= ( search_state
.outer_pos
.pos
2636 - search_state
.outer_pos
.string
2637 + search_state
.outer_pos
.offset
);
2639 /*|*/ if ((range
> 0) && (startpos
== search_state
.outer_pos
.search_end
))
2644 search_state
.test_match_resume_pt
= rx_test_start
;
2645 /* do interrupted for entry point... */
2647 /* ...do continued */
2650 test_returns_to_search
:
2653 case rx_test_continuation
:
2655 goto return_continuation
;
2657 search_state
.ret_val
= rx_search_error
;
2664 search_state
.outer_pos
.pos
+= search_state
.outer_pos
.search_direction
;
2665 startpos
+= search_state
.outer_pos
.search_direction
;
2667 /*|*/ if (search_state
.test_pos
.pos
< search_state
.test_pos
.end
)
2671 /* do interrupted for entry point... */
2672 case rx_outer_restore_pos
:
2675 x
= get_burst (&search_state
.outer_pos
, app_closure
, stop
);
2678 case rx_get_burst_continuation
:
2679 pc
= rx_outer_restore_pos
;
2680 goto return_continuation
;
2681 case rx_get_burst_error
:
2682 search_state
.ret_val
= rx_search_error
;
2684 case rx_get_burst_no_more
:
2685 if (rxb
->can_match_empty
)
2688 case rx_get_burst_ok
:
2691 } /* } while (...see below...) */
2693 if ((search_state
.outer_pos
.search_direction
== 1)
2694 ? (startpos
<= search_state
.outer_pos
.search_end
)
2695 : (startpos
> search_state
.outer_pos
.search_end
))
2700 uninit_fastmap (rxb
, &search_state
);
2701 if (search_state
.start_super
)
2702 rx_unlock_superstate (&rxb
->rx
, search_state
.start_super
);
2705 if (search_state
.lparen
) free (search_state
.lparen
);
2706 if (search_state
.rparen
) free (search_state
.rparen
);
2707 if (search_state
.best_lpspace
) free (search_state
.best_lpspace
);
2708 if (search_state
.best_rpspace
) free (search_state
.best_rpspace
);
2710 return search_state
.ret_val
;
2716 enum rx_test_match_entry test_pc
;
2718 test_pc
= search_state
.test_match_resume_pt
;
2719 if (test_pc
== rx_test_start
)
2722 search_state
.backtrack_depth
= 0;
2724 search_state
.last_l
= search_state
.last_r
= 0;
2725 search_state
.lparen
[0] = startpos
;
2726 search_state
.super
= search_state
.start_super
;
2727 search_state
.c
= search_state
.nfa_choice
;
2728 search_state
.test_pos
.pos
= search_state
.outer_pos
.pos
- 1;
2729 search_state
.test_pos
.string
= search_state
.outer_pos
.string
;
2730 search_state
.test_pos
.end
= search_state
.outer_pos
.end
;
2731 search_state
.test_pos
.offset
= search_state
.outer_pos
.offset
;
2732 search_state
.test_pos
.size
= search_state
.outer_pos
.size
;
2733 search_state
.test_pos
.search_direction
= 1;
2734 search_state
.counter_stack
= 0;
2735 search_state
.backtrack_stack
= 0;
2736 search_state
.backtrack_frame_bytes
=
2737 (sizeof (struct rx_backtrack_frame
)
2738 + (rxb
->match_regs_on_stack
2739 ? sizeof (regoff_t
) * (search_state
.num_regs
+ 1) * 2
2741 search_state
.chunk_bytes
= search_state
.backtrack_frame_bytes
* 64;
2742 search_state
.test_ret
= rx_test_line_finished
;
2743 search_state
.could_have_continued
= 0;
2745 /* This is while (1)...except that the body of the loop is interrupted
2746 * by some alternative entry points.
2751 case rx_test_cache_hit_loop
:
2752 goto resume_continuation_1
;
2753 case rx_test_backreference_check
:
2754 goto resume_continuation_2
;
2755 case rx_test_backtrack_return
:
2756 goto resume_continuation_3
;
2759 /* There is a search tree with every node as set of deterministic
2760 * transitions in the super nfa. For every branch of a
2761 * backtrack point is an edge in the tree.
2762 * This counts up a pre-order of nodes in that tree.
2763 * It's saved on the search stack and printed when debugging.
2765 search_state
.line_no
= 0;
2766 search_state
.lines_found
= 0;
2770 /* A superstate is basicly a transition table, indexed by
2771 * characters from the string being tested, and containing
2772 * RX_INX (`instruction frame') structures.
2774 search_state
.ifr
= &search_state
.super
->transitions
[search_state
.c
];
2777 /* This is the point to which control is sent when the
2778 * test matcher `recurses'. Before jumping here, some variables
2779 * need to be saved on the stack and the next instruction frame
2780 * has to be computed.
2784 /* Some instructions don't advance the matcher, but just
2785 * carry out some side effects and fetch a new instruction.
2786 * To dispatch that new instruction, `goto restart'.
2790 struct rx_inx
* next_tr_table
;
2791 struct rx_inx
* this_tr_table
;
2792 /* The fastest route through the loop is when the instruction
2793 * is RX_NEXT_CHAR. This case is detected when SEARCH_STATE.IFR->DATA
2794 * is non-zero. In that case, it points to the next
2797 * This allows us to not bother fetching the bytecode.
2799 next_tr_table
= (struct rx_inx
*)search_state
.ifr
->data
;
2800 this_tr_table
= search_state
.super
->transitions
;
2801 while (next_tr_table
)
2806 struct rx_superset
* setp
;
2808 fprintf (stderr
, "%d %d>> re_next_char @ %d (%d)",
2809 search_state
.line_no
,
2810 search_state
.backtrack_depth
,
2811 (search_state
.test_pos
.pos
- search_state
.test_pos
.string
2812 + search_state
.test_pos
.offset
), search_state
.c
);
2814 search_state
.super
=
2815 ((struct rx_superstate
*)
2816 ((char *)this_tr_table
2818 ((struct rx_superstate
*)0)->transitions
)));
2820 setp
= search_state
.super
->contents
;
2821 fprintf (stderr
, " superstet (rx=%d, &=%x: ",
2822 rxb
->rx
.rx_id
, setp
);
2825 fprintf (stderr
, "%d ", setp
->id
);
2828 fprintf (stderr
, "\n");
2831 this_tr_table
= next_tr_table
;
2832 ++search_state
.test_pos
.pos
;
2833 if (search_state
.test_pos
.pos
== search_state
.test_pos
.end
)
2837 burst_state
= get_burst (&search_state
.test_pos
,
2839 switch (burst_state
)
2841 case rx_get_burst_continuation
:
2842 search_state
.saved_this_tr_table
= this_tr_table
;
2843 search_state
.saved_next_tr_table
= next_tr_table
;
2844 test_pc
= rx_test_cache_hit_loop
;
2845 goto test_return_continuation
;
2847 resume_continuation_1
:
2848 /* Continuation one jumps here to do its work: */
2849 search_state
.saved_this_tr_table
= this_tr_table
;
2850 search_state
.saved_next_tr_table
= next_tr_table
;
2853 case rx_get_burst_ok
:
2854 /* get_burst succeeded...keep going */
2857 case rx_get_burst_no_more
:
2858 search_state
.test_ret
= rx_test_line_finished
;
2859 search_state
.could_have_continued
= 1;
2860 goto test_do_return
;
2862 case rx_get_burst_error
:
2864 search_state
.test_ret
= rx_test_internal_error
;
2865 goto test_do_return
;
2868 search_state
.c
= *search_state
.test_pos
.pos
;
2869 search_state
.ifr
= this_tr_table
+ search_state
.c
;
2870 next_tr_table
= (struct rx_inx
*)search_state
.ifr
->data
;
2871 } /* Fast loop through cached transition tables */
2873 /* Here when we ran out of cached next-char transitions.
2874 * So, it will be necessary to do a more expensive
2875 * dispatch on the current instruction. The superstate
2876 * pointer is allowed to become invalid during next-char
2877 * transitions -- now we must bring it up to date.
2879 search_state
.super
=
2880 ((struct rx_superstate
*)
2881 ((char *)this_tr_table
2883 ((struct rx_superstate
*)0)->transitions
)));
2886 /* We've encountered an instruction other than next-char.
2887 * Dispatch that instruction:
2889 inx
= (int)search_state
.ifr
->inx
;
2893 struct rx_superset
* setp
= search_state
.super
->contents
;
2895 fprintf (stderr
, "%d %d>> %s @ %d (%d)", search_state
.line_no
,
2896 search_state
.backtrack_depth
,
2898 (search_state
.test_pos
.pos
- search_state
.test_pos
.string
2899 + (test_pos
.half
== 0 ? 0 : size1
)), search_state
.c
);
2901 fprintf (stderr
, " superstet (rx=%d, &=%x: ",
2902 rxb
->rx
.rx_id
, setp
);
2905 fprintf (stderr
, "%d ", setp
->id
);
2908 fprintf (stderr
, "\n");
2911 switch ((enum rx_opcode
)inx
)
2913 case rx_do_side_effects
:
2915 /* RX_DO_SIDE_EFFECTS occurs when we cross epsilon
2916 * edges associated with parentheses, backreferencing, etc.
2919 struct rx_distinct_future
* df
=
2920 (struct rx_distinct_future
*)search_state
.ifr
->data_2
;
2921 struct rx_se_list
* el
= df
->effects
;
2922 /* Side effects come in lists. This walks down
2923 * a list, dispatching.
2928 effect
= (long)el
->car
;
2934 struct rx_superset
* setp
= search_state
.super
->contents
;
2936 fprintf (stderr
, "....%d %d>> %s\n", search_state
.line_no
,
2937 search_state
.backtrack_depth
,
2941 switch ((enum re_side_effects
) effect
)
2944 case re_se_pushback
:
2945 search_state
.ifr
= &df
->future_frame
;
2946 if (!search_state
.ifr
->data
)
2948 struct rx_superstate
* sup
;
2949 sup
= search_state
.super
;
2950 rx_lock_superstate (rx
, sup
);
2951 if (!rx_handle_cache_miss (&rxb
->rx
,
2957 rx_unlock_superstate (rx
, sup
);
2958 search_state
.test_ret
= rx_test_internal_error
;
2959 goto test_do_return
;
2961 rx_unlock_superstate (rx
, sup
);
2963 /* --search_state.test_pos.pos; */
2964 search_state
.c
= 't';
2966 = ((struct rx_superstate
*)
2967 ((char *)search_state
.ifr
->data
2968 - (long)(((struct rx_superstate
*)0)
2974 struct rx_counter_frame
* old_cf
2975 = (search_state
.counter_stack
2976 ? ((struct rx_counter_frame
*)
2977 search_state
.counter_stack
->sp
)
2979 struct rx_counter_frame
* cf
;
2980 PUSH (search_state
.counter_stack
,
2981 sizeof (struct rx_counter_frame
));
2982 cf
= ((struct rx_counter_frame
*)
2983 search_state
.counter_stack
->sp
);
2984 cf
->tag
= re_se_iter
;
2986 cf
->inherited_from
= 0;
2991 goto test_do_return
;
2993 if (!AT_STRINGS_BEG ())
2994 goto test_do_return
;
2997 if (!AT_STRINGS_END ())
2998 goto test_do_return
;
3001 if ( LETTER_P (&search_state
.test_pos
, 1)
3002 && ( AT_STRINGS_BEG()
3003 || !LETTER_P (&search_state
.test_pos
, 0)))
3006 goto test_do_return
;
3008 if ( !AT_STRINGS_BEG ()
3009 && LETTER_P (&search_state
.test_pos
, 0)
3010 && (AT_STRINGS_END ()
3011 || !LETTER_P (&search_state
.test_pos
, 1)))
3014 goto test_do_return
;
3015 case re_se_wordbound
:
3016 if (AT_WORD_BOUNDARY (&search_state
.test_pos
))
3019 goto test_do_return
;
3020 case re_se_notwordbound
:
3021 if (!AT_WORD_BOUNDARY (&search_state
.test_pos
))
3024 goto test_do_return
;
3026 if (AT_STRINGS_BEG ())
3029 goto test_do_return
;
3035 char pos_c
= *search_state
.test_pos
.pos
;
3036 if ( (SRCH_TRANSLATE (pos_c
)
3037 == SRCH_TRANSLATE('\n'))
3038 && rxb
->newline_anchor
)
3041 goto test_do_return
;
3044 if (AT_STRINGS_END ())
3047 goto test_do_return
;
3053 if ( ( SRCH_TRANSLATE (fetch_char
3054 (&search_state
.test_pos
, 1,
3056 == SRCH_TRANSLATE ('\n'))
3057 && rxb
->newline_anchor
)
3060 goto test_do_return
;
3064 /* This is the first side effect in every
3067 * FOR NO GOOD REASON...get rid of it...
3074 ((int)(search_state
.test_pos
.pos
3075 - search_state
.test_pos
.string
)
3076 + search_state
.test_pos
.offset
);
3077 struct rx_counter_frame
* old_cf
3078 = (search_state
.counter_stack
3079 ? ((struct rx_counter_frame
*)
3080 search_state
.counter_stack
->sp
)
3082 struct rx_counter_frame
* cf
;
3083 PUSH(search_state
.counter_stack
,
3084 sizeof (struct rx_counter_frame
));
3085 cf
= ((struct rx_counter_frame
*)
3086 search_state
.counter_stack
->sp
);
3087 cf
->tag
= re_se_pushpos
;
3089 cf
->inherited_from
= 0;
3097 ((int)(search_state
.test_pos
.pos
3098 - search_state
.test_pos
.string
)
3099 + search_state
.test_pos
.offset
);
3100 struct rx_counter_frame
* cf
3101 = ((struct rx_counter_frame
*)
3102 search_state
.counter_stack
->sp
);
3103 if (cf
->val
== urhere
)
3104 goto test_do_return
;
3111 POP(search_state
.counter_stack
,
3112 sizeof (struct rx_counter_frame
));
3118 case re_se_not_syntax
:
3121 * this release lacks emacs support
3130 case re_se_end_iter
:
3132 case re_floogle_flap
:
3133 search_state
.ret_val
= 0;
3134 goto test_do_return
;
3141 fprintf (stderr
, "....%d %d>> %s %d %d\n", search_state
.line_no
,
3142 search_state
.backtrack_depth
,
3143 efnames2
[rxb
->se_params
[effect
].se
],
3144 rxb
->se_params
[effect
].op1
,
3145 rxb
->se_params
[effect
].op2
);
3147 switch (rxb
->se_params
[effect
].se
)
3150 /* This side effect indicates that we've
3151 * found a match, though not necessarily the
3152 * best match. This is a fancy assignment to
3153 * register 0 unless the caller didn't
3154 * care about registers. In which case,
3155 * this stops the match.
3159 ((int)(search_state
.test_pos
.pos
3160 - search_state
.test_pos
.string
)
3161 + search_state
.test_pos
.offset
);
3163 if ( (search_state
.best_last_r
< 0)
3164 || (urhere
+ 1 > search_state
.best_rparen
[0]))
3166 /* Record the best known and keep
3170 for (x
= 0; x
<= search_state
.last_l
; ++x
)
3171 search_state
.best_lparen
[x
] = search_state
.lparen
[x
];
3172 search_state
.best_last_l
= search_state
.last_l
;
3173 for (x
= 0; x
<= search_state
.last_r
; ++x
)
3174 search_state
.best_rparen
[x
] = search_state
.rparen
[x
];
3175 search_state
.best_rparen
[0] = urhere
+ 1;
3176 search_state
.best_last_r
= search_state
.last_r
;
3178 /* If we're not reporting the match-length
3179 * or other register info, we need look no
3182 if (search_state
.first_found
)
3184 search_state
.test_ret
= rx_test_found_first
;
3185 goto test_do_return
;
3192 ((int)(search_state
.test_pos
.pos
3193 - search_state
.test_pos
.string
)
3194 + search_state
.test_pos
.offset
);
3196 int reg
= rxb
->se_params
[effect
].op1
;
3198 if (reg
> search_state
.last_l
)
3201 search_state
.lparen
[reg
] = urhere
+ 1;
3202 /* In addition to making this assignment,
3203 * we now know that lower numbered regs
3204 * that haven't already been assigned,
3205 * won't be. We make sure they're
3206 * filled with -1, so they can be
3207 * recognized as unassigned.
3209 if (search_state
.last_l
< reg
)
3210 while (++search_state
.last_l
< reg
)
3211 search_state
.lparen
[search_state
.last_l
] = -1;
3219 ((int)(search_state
.test_pos
.pos
3220 - search_state
.test_pos
.string
)
3221 + search_state
.test_pos
.offset
);
3222 int reg
= rxb
->se_params
[effect
].op1
;
3223 search_state
.rparen
[reg
] = urhere
+ 1;
3224 if (search_state
.last_r
< reg
)
3226 while (++search_state
.last_r
< reg
)
3227 search_state
.rparen
[search_state
.last_r
]
3235 int reg
= rxb
->se_params
[effect
].op1
;
3236 if ( reg
> search_state
.last_r
3237 || search_state
.rparen
[reg
] < 0)
3238 goto test_do_return
;
3242 check_backreference
:
3244 = back_check (&search_state
.test_pos
,
3245 search_state
.lparen
[reg
],
3246 search_state
.rparen
[reg
],
3247 search_state
.translate
,
3250 switch (backref_status
)
3252 case rx_back_check_continuation
:
3253 search_state
.saved_reg
= reg
;
3254 test_pc
= rx_test_backreference_check
;
3255 goto test_return_continuation
;
3256 resume_continuation_2
:
3257 reg
= search_state
.saved_reg
;
3258 goto check_backreference
;
3259 case rx_back_check_fail
:
3261 goto test_do_return
;
3262 case rx_back_check_pass
:
3264 * test_pos now advanced to last
3265 * char matched by backref
3274 struct rx_counter_frame
* csp
3275 = ((struct rx_counter_frame
*)
3276 search_state
.counter_stack
->sp
);
3277 if (csp
->val
== rxb
->se_params
[effect
].op2
)
3278 goto test_do_return
;
3283 case re_se_end_iter
:
3285 struct rx_counter_frame
* csp
3286 = ((struct rx_counter_frame
*)
3287 search_state
.counter_stack
->sp
);
3288 if (csp
->val
< rxb
->se_params
[effect
].op1
)
3289 goto test_do_return
;
3292 struct rx_counter_frame
* source
= csp
;
3293 while (source
->inherited_from
)
3294 source
= source
->inherited_from
;
3295 if (!source
|| !source
->cdr
)
3297 POP(search_state
.counter_stack
,
3298 sizeof(struct rx_counter_frame
));
3302 source
= source
->cdr
;
3303 csp
->val
= source
->val
;
3304 csp
->tag
= source
->tag
;
3306 csp
->inherited_from
= source
;
3315 case re_se_pushback
:
3322 case re_se_not_syntax
:
3326 case re_se_wordbound
:
3327 case re_se_notwordbound
:
3332 case re_floogle_flap
:
3333 search_state
.ret_val
= 0;
3334 goto test_do_return
;
3339 /* Now the side effects are done,
3340 * so get the next instruction.
3343 search_state
.ifr
= &df
->future_frame
;
3347 case rx_backtrack_point
:
3349 /* A backtrack point indicates that we've reached a
3350 * non-determinism in the superstate NFA. This is a
3351 * loop that exhaustively searches the possibilities.
3353 * A backtracking strategy is used. We keep track of what
3354 * registers are valid so we can erase side effects.
3356 * First, make sure there is some stack space to hold
3360 struct rx_backtrack_frame
* bf
;
3362 PUSH(search_state
.backtrack_stack
,
3363 search_state
.backtrack_frame_bytes
);
3365 ++search_state
.backtrack_depth
;
3368 bf
= ((struct rx_backtrack_frame
*)
3369 search_state
.backtrack_stack
->sp
);
3371 bf
->stk_super
= search_state
.super
;
3372 /* We prevent the current superstate from being
3373 * deleted from the superstate cache.
3375 rx_lock_superstate (&rxb
->rx
, search_state
.super
);
3377 bf
->stk_search_state
.line_no
= search_state
.line_no
;
3379 bf
->stk_c
= search_state
.c
;
3380 bf
->stk_test_pos
= search_state
.test_pos
;
3381 bf
->stk_last_l
= search_state
.last_l
;
3382 bf
->stk_last_r
= search_state
.last_r
;
3383 bf
->df
= ((struct rx_super_edge
*)
3384 search_state
.ifr
->data_2
)->options
;
3385 bf
->first_df
= bf
->df
;
3386 bf
->counter_stack_sp
= (search_state
.counter_stack
3387 ? search_state
.counter_stack
->sp
3389 bf
->stk_test_ret
= search_state
.test_ret
;
3390 if (rxb
->match_regs_on_stack
)
3394 (regoff_t
*)((char *)bf
+ sizeof (*bf
));
3395 for (x
= 0; x
<= search_state
.last_l
; ++x
)
3396 stk
[x
] = search_state
.lparen
[x
];
3398 for (x
= 0; x
<= search_state
.last_r
; ++x
)
3399 stk
[x
] = search_state
.rparen
[x
];
3403 /* Here is a while loop whose body is mainly a function
3404 * call and some code to handle a return from that
3407 * From here on for the rest of `case backtrack_point' it
3408 * is unsafe to assume that the search_state copies of
3409 * variables saved on the backtracking stack are valid
3410 * -- so read their values from the backtracking stack.
3412 * This lets us use one generation fewer stack saves in
3413 * the call-graph of a search.
3416 while_non_det_options
:
3418 ++search_state
.lines_found
;
3420 fprintf (stderr
, "@@@ %d calls %d @@@\n",
3421 search_state
.line_no
, search_state
.lines_found
);
3423 search_state
.line_no
= search_state
.lines_found
;
3426 if (bf
->df
->next_same_super_edge
[0] == bf
->first_df
)
3428 /* This is a tail-call optimization -- we don't recurse
3429 * for the last of the possible futures.
3431 search_state
.ifr
= (bf
->df
->effects
3432 ? &bf
->df
->side_effects_frame
3433 : &bf
->df
->future_frame
);
3435 rx_unlock_superstate (&rxb
->rx
, search_state
.super
);
3436 POP(search_state
.backtrack_stack
,
3437 search_state
.backtrack_frame_bytes
);
3439 --search_state
.backtrack_depth
;
3445 if (search_state
.counter_stack
)
3447 struct rx_counter_frame
* old_cf
3448 = ((struct rx_counter_frame
*)search_state
.counter_stack
->sp
);
3449 struct rx_counter_frame
* cf
;
3450 PUSH(search_state
.counter_stack
, sizeof (struct rx_counter_frame
));
3451 cf
= ((struct rx_counter_frame
*)search_state
.counter_stack
->sp
);
3452 cf
->tag
= old_cf
->tag
;
3453 cf
->val
= old_cf
->val
;
3454 cf
->inherited_from
= old_cf
;
3457 /* `Call' this test-match block */
3458 search_state
.ifr
= (bf
->df
->effects
3459 ? &bf
->df
->side_effects_frame
3460 : &bf
->df
->future_frame
);
3461 goto recurse_test_match
;
3464 /* Returns in this block are accomplished by
3465 * goto test_do_return. There are two cases.
3466 * If there is some search-stack left,
3467 * then it is a return from a `recursive' call.
3468 * If there is no search-stack left, then
3469 * we should return to the fastmap/search loop.
3474 if (!search_state
.backtrack_stack
)
3478 fprintf (stderr
, "!!! %d bails returning %d !!!\n",
3479 search_state
.line_no
, search_state
.test_ret
);
3482 /* No more search-stack -- this test is done. */
3483 if (search_state
.test_ret
!= rx_test_internal_error
)
3484 goto return_from_test_match
;
3486 goto error_in_testing_match
;
3489 /* Returning from a recursive call to
3490 * the test match block:
3493 bf
= ((struct rx_backtrack_frame
*)
3494 search_state
.backtrack_stack
->sp
);
3497 fprintf (stderr
, "+++ %d returns %d (to %d)+++\n",
3498 search_state
.line_no
,
3499 search_state
.test_ret
,
3500 bf
->stk_search_state
.line_no
);
3503 while (search_state
.counter_stack
3504 && (!bf
->counter_stack_sp
3505 || (bf
->counter_stack_sp
3506 != search_state
.counter_stack
->sp
)))
3508 POP(search_state
.counter_stack
,
3509 sizeof (struct rx_counter_frame
));
3512 if (search_state
.test_ret
== rx_test_internal_error
)
3514 POP (search_state
.backtrack_stack
,
3515 search_state
.backtrack_frame_bytes
);
3516 search_state
.test_ret
= rx_test_internal_error
;
3517 goto test_do_return
;
3520 /* If a non-longest match was found and that is good
3521 * enough, return immediately.
3523 if ( (search_state
.test_ret
== rx_test_found_first
)
3524 && search_state
.first_found
)
3526 rx_unlock_superstate (&rxb
->rx
, bf
->stk_super
);
3527 POP (search_state
.backtrack_stack
,
3528 search_state
.backtrack_frame_bytes
);
3529 goto test_do_return
;
3532 search_state
.test_ret
= bf
->stk_test_ret
;
3533 search_state
.last_l
= bf
->stk_last_l
;
3534 search_state
.last_r
= bf
->stk_last_r
;
3535 bf
->df
= bf
->df
->next_same_super_edge
[0];
3536 search_state
.super
= bf
->stk_super
;
3537 search_state
.c
= bf
->stk_c
;
3539 search_state
.line_no
= bf
->stk_search_state
.line_no
;
3542 if (rxb
->match_regs_on_stack
)
3546 (regoff_t
*)((char *)bf
+ sizeof (*bf
));
3547 for (x
= 0; x
<= search_state
.last_l
; ++x
)
3548 search_state
.lparen
[x
] = stk
[x
];
3550 for (x
= 0; x
<= search_state
.last_r
; ++x
)
3551 search_state
.rparen
[x
] = stk
[x
];
3557 x
= get_burst (&bf
->stk_test_pos
, app_closure
, stop
);
3560 case rx_get_burst_continuation
:
3561 search_state
.saved_bf
= bf
;
3562 test_pc
= rx_test_backtrack_return
;
3563 goto test_return_continuation
;
3564 resume_continuation_3
:
3565 bf
= search_state
.saved_bf
;
3567 case rx_get_burst_no_more
:
3568 /* Since we've been here before, it is some kind of
3569 * error that we can't return.
3571 case rx_get_burst_error
:
3572 search_state
.test_ret
= rx_test_internal_error
;
3573 goto test_do_return
;
3574 case rx_get_burst_ok
:
3578 search_state
.test_pos
= bf
->stk_test_pos
;
3579 goto while_non_det_options
;
3584 /* Because the superstate NFA is lazily constructed,
3585 * and in fact may erode from underneath us, we sometimes
3586 * have to construct the next instruction from the hard way.
3587 * This invokes one step in the lazy-conversion.
3589 search_state
.ifr
= rx_handle_cache_miss (&rxb
->rx
,
3592 search_state
.ifr
->data_2
);
3593 if (!search_state
.ifr
)
3595 search_state
.test_ret
= rx_test_internal_error
;
3596 goto test_do_return
;
3601 /* RX_BACKTRACK means that we've reached the empty
3602 * superstate, indicating that match can't succeed
3605 goto test_do_return
;
3609 case rx_num_instructions
:
3610 search_state
.ret_val
= 0;
3611 goto test_do_return
;
3613 goto pseudo_while_1
;
3616 /* Healthy exits from the test-match loop do a
3617 * `goto return_from_test_match' On the other hand,
3618 * we might end up here.
3620 error_in_testing_match
:
3621 test_state
= rx_test_error
;
3622 goto test_returns_to_search
;
3624 /***** fastmap/search loop body
3625 * considering the results testing for a match
3628 return_from_test_match
:
3630 if (search_state
.best_last_l
>= 0)
3632 if (regs
&& (regs
->start
!= search_state
.best_lparen
))
3634 bcopy (search_state
.best_lparen
, regs
->start
,
3635 regs
->num_regs
* sizeof (int));
3636 bcopy (search_state
.best_rparen
, regs
->end
,
3637 regs
->num_regs
* sizeof (int));
3639 if (regs
&& !rxb
->no_sub
)
3642 int bound
= (regs
->num_regs
> search_state
.num_regs
3644 : search_state
.num_regs
);
3645 regoff_t
* s
= regs
->start
;
3646 regoff_t
* e
= regs
->end
;
3647 for (q
= search_state
.best_last_l
+ 1; q
< bound
; ++q
)
3650 search_state
.ret_val
= search_state
.best_lparen
[0];
3651 test_state
= rx_test_ok
;
3652 goto test_returns_to_search
;
3656 test_state
= rx_test_fail
;
3657 goto test_returns_to_search
;
3660 test_return_continuation
:
3661 search_state
.test_match_resume_pt
= test_pc
;
3662 test_state
= rx_test_continuation
;
3663 goto test_returns_to_search
;
3669 #endif /* RX_WANT_RX_DEFS */
3673 #else /* RX_WANT_SE_DEFS */
3674 /* Integers are used to represent side effects.
3676 * Simple side effects are given negative integer names by these enums.
3678 * Non-negative names are reserved for complex effects.
3680 * Complex effects are those that take arguments. For example,
3681 * a register assignment associated with a group is complex because
3682 * it requires an argument to tell which group is being matched.
3684 * The integer name of a complex effect is an index into rxb->se_params.
3687 RX_DEF_SE(1, re_se_try
, = -1) /* Epsilon from start state */
3689 RX_DEF_SE(0, re_se_pushback
, = re_se_try
- 1)
3690 RX_DEF_SE(0, re_se_push0
, = re_se_pushback
-1)
3691 RX_DEF_SE(0, re_se_pushpos
, = re_se_push0
- 1)
3692 RX_DEF_SE(0, re_se_chkpos
, = re_se_pushpos
-1)
3693 RX_DEF_SE(0, re_se_poppos
, = re_se_chkpos
- 1)
3695 RX_DEF_SE(1, re_se_at_dot
, = re_se_poppos
- 1) /* Emacs only */
3696 RX_DEF_SE(0, re_se_syntax
, = re_se_at_dot
- 1) /* Emacs only */
3697 RX_DEF_SE(0, re_se_not_syntax
, = re_se_syntax
- 1) /* Emacs only */
3699 RX_DEF_SE(1, re_se_begbuf
, = re_se_not_syntax
- 1) /* match beginning of buffer */
3700 RX_DEF_SE(1, re_se_hat
, = re_se_begbuf
- 1) /* match beginning of line */
3702 RX_DEF_SE(1, re_se_wordbeg
, = re_se_hat
- 1)
3703 RX_DEF_SE(1, re_se_wordbound
, = re_se_wordbeg
- 1)
3704 RX_DEF_SE(1, re_se_notwordbound
, = re_se_wordbound
- 1)
3706 RX_DEF_SE(1, re_se_wordend
, = re_se_notwordbound
- 1)
3707 RX_DEF_SE(1, re_se_endbuf
, = re_se_wordend
- 1)
3709 /* This fails except at the end of a line.
3710 * It deserves to go here since it is typicly one of the last steps
3713 RX_DEF_SE(1, re_se_dollar
, = re_se_endbuf
- 1)
3715 /* Simple effects: */
3716 RX_DEF_SE(1, re_se_fail
, = re_se_dollar
- 1)
3718 /* Complex effects. These are used in the 'se' field of
3719 * a struct re_se_params. Indexes into the se array
3720 * are stored as instructions on nfa edges.
3722 RX_DEF_CPLX_SE(1, re_se_win
, = 0)
3723 RX_DEF_CPLX_SE(1, re_se_lparen
, = re_se_win
+ 1)
3724 RX_DEF_CPLX_SE(1, re_se_rparen
, = re_se_lparen
+ 1)
3725 RX_DEF_CPLX_SE(0, re_se_backref
, = re_se_rparen
+ 1)
3726 RX_DEF_CPLX_SE(0, re_se_iter
, = re_se_backref
+ 1)
3727 RX_DEF_CPLX_SE(0, re_se_end_iter
, = re_se_iter
+ 1)
3728 RX_DEF_CPLX_SE(0, re_se_tv
, = re_se_end_iter
+ 1)