/*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) version 3.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with the program; if not, see
*
*
* Authors:
* Developed by Jon Trowbridge
* Rewritten significantly to handle multiple strings and improve performance
* by Michael Zucchi
*
* Copyright (C) 1999-2008 Novell, Inc. (www.novell.com)
*
*/
#ifdef HAVE_CONFIG_H
#include
#endif
#include
#include
#include
#include
#include "e-searching-tokenizer.h"
#include "libedataserver/e-memory.h"
#include "libedataserver/e-msgport.h"
#define d(x)
enum {
MATCH_SIGNAL,
LAST_SIGNAL
};
static guint signals[LAST_SIGNAL] = { 0, };
static void e_searching_tokenizer_begin (HTMLTokenizer *, const char *);
static void e_searching_tokenizer_end (HTMLTokenizer *);
static char *e_searching_tokenizer_peek_token (HTMLTokenizer *);
static char *e_searching_tokenizer_next_token (HTMLTokenizer *);
static gboolean e_searching_tokenizer_has_more (HTMLTokenizer *);
static HTMLTokenizer *e_searching_tokenizer_clone (HTMLTokenizer *);
/*
static const gchar *space_tags[] = { "br", NULL };*/
static HTMLTokenizerClass *parent_class = NULL;
/** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** **/
/* ???
typedef struct _SharedState SharedState;
struct _SharedState {
gint refs;
gchar *str_primary;
gchar *str_secondary;
gboolean case_sensitive_primary;
gboolean case_sensitive_secondary;
};
*/
/* ********************************************************************** */
#if 0
static SharedState *
shared_state_new (void)
{
SharedState *shared = g_new0 (SharedState, 1);
shared->refs = 1;
return shared;
}
static void
shared_state_ref (SharedState *shared)
{
g_return_if_fail (shared != NULL);
g_return_if_fail (shared->refs > 0);
++shared->refs;
}
static void
shared_state_unref (SharedState *shared)
{
if (shared) {
g_return_if_fail (shared->refs > 0);
--shared->refs;
if (shared->refs == 0) {
g_free (shared->str_primary);
g_free (shared->str_secondary);
g_free (shared);
}
}
}
#endif
/** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** **/
/* ********************************************************************** */
/* Utility functions */
/* This is faster and safer than glib2's utf8 abomination, but isn't exported from camel as yet */
static inline guint32
camel_utf8_getc(const unsigned char **ptr)
{
register unsigned char *p = (unsigned char *)*ptr;
register unsigned char c, r;
register guint32 v, m;
again:
r = *p++;
loop:
if (r < 0x80) {
*ptr = p;
v = r;
} else if (r < 0xfe) { /* valid start char? */
v = r;
m = 0x7f80; /* used to mask out the length bits */
do {
c = *p++;
if ((c & 0xc0) != 0x80) {
r = c;
goto loop;
}
v = (v<<6) | (c & 0x3f);
r<<=1;
m<<=5;
} while (r & 0x40);
*ptr = p;
v &= ~m;
} else {
goto again;
}
return v;
}
/* note: our tags of interest are 7 bit ascii, only, no need to do any fancy utf8 stuff */
/* tags should be upper case
if this list gets longer than 10 entries, consider binary search */
static char *ignored_tags[] = { "B", "I", "FONT", "TT", "EM", /* and more? */};
static int
ignore_tag (const char *tag)
{
char *t = alloca(strlen(tag)+1), c, *out;
const char *in;
int i;
/* we could use a aho-corasick matcher here too ... but we wont */
/* normalise tag into 't'.
Note we use the property that the only tags we're interested in
are 7 bit ascii to shortcut and simplify case insensitivity */
in = tag+2; /* skip: TAG_ESCAPE '<' */
if (*in == '/')
in++;
out = t;
while ((c = *in++)) {
if (c >= 'A' && c <= 'Z')
*out++ = c;
else if (c >= 'a' && c <= 'z')
*out++ = c & 0xdf; /* convert ASCII to upper case */
else
/* maybe should check for > or ' ' etc? */
break;
}
*out = 0;
for (i=0;i%p\n", p, s, s->final, s->fail);
m = s->matches;
while (m) {
printf(" %s'%c' -> %p\n", p, m->ch, m->match);
if (m->match)
dump_trie(m->match, d+1);
m = m->next;
}
}
#endif
/* This builds an Aho-Corasick search trie for a set of utf8 words */
/* See
http://www-sr.informatik.uni-tuebingen.de/~buehler/AC/AC.html
for a neat demo */
static inline struct _match *
g(struct _state *q, guint32 c)
{
struct _match *m = q->matches;
while (m && m->ch != c)
m = m->next;
return m;
}
static struct _trie *
build_trie(int nocase, int len, unsigned char **words)
{
struct _state *q, *qt, *r;
const unsigned char *word;
struct _match *m, *n = NULL;
int i, depth;
guint32 c;
struct _trie *trie;
int state_depth_max, state_depth_size;
struct _state **state_depth;
trie = g_malloc(sizeof(*trie));
trie->root.matches = NULL;
trie->root.final = 0;
trie->root.fail = NULL;
trie->root.next = NULL;
trie->state_chunks = e_memchunk_new(8, sizeof(struct _state));
trie->match_chunks = e_memchunk_new(8, sizeof(struct _match));
/* This will correspond to the length of the longest pattern */
state_depth_size = 0;
state_depth_max = 64;
state_depth = g_malloc(sizeof(*state_depth[0])*64);
state_depth[0] = NULL;
/* Step 1: Build trie */
/* This just builds a tree that merges all common prefixes into the same branch */
for (i=0;iroot;
depth = 0;
while ((c = camel_utf8_getc (&word))) {
if (nocase)
c = g_unichar_tolower(c);
m = g(q, c);
if (m == NULL) {
m = e_memchunk_alloc(trie->match_chunks);
m->ch = c;
m->next = q->matches;
q->matches = m;
q = m->match = e_memchunk_alloc(trie->state_chunks);
q->matches = NULL;
q->fail = &trie->root;
q->final = 0;
if (state_depth_max < depth) {
state_depth_max += 64;
state_depth = g_realloc(state_depth, sizeof(*state_depth[0])*state_depth_max);
}
if (state_depth_size < depth) {
state_depth[depth] = NULL;
state_depth_size = depth;
}
q->next = state_depth[depth];
state_depth[depth] = q;
} else {
q = m->match;
}
depth++;
}
q->final = depth;
}
d(printf("Dumping trie:\n"));
d(dump_trie(&trie->root, 0));
/* Step 2: Build failure graph */
/* This searches for the longest substring which is a prefix of another string and
builds a graph of failure links so you can find multiple substrings concurrently,
using aho-corasick's algorithm */
for (i=0;imatches;
while (m) {
c = m->ch;
qt = m->match;
r = q->fail;
while (r && (n = g(r, c)) == NULL)
r = r->fail;
if (r != NULL) {
qt->fail = n->match;
if (qt->fail->final > qt->final)
qt->final = qt->fail->final;
} else {
if ((n = g(&trie->root, c)))
qt->fail = n->match;
else
qt->fail = &trie->root;
}
m = m->next;
}
q = q->next;
}
}
d(printf("After failure analysis\n"));
d(dump_trie(&trie->root, 0));
g_free(state_depth);
trie->max_depth = state_depth_size;
return trie;
}
static void
free_trie(struct _trie *t)
{
e_memchunk_destroy(t->match_chunks);
e_memchunk_destroy(t->state_chunks);
g_free(t);
}
/* ********************************************************************** */
/* html token searcher */
struct _token {
struct _token *next;
struct _token *prev;
unsigned int offset;
/* we need to copy the token for memory management, so why not copy it whole */
char tok[1];
};
/* stack of submatches currently being scanned, used for merging */
struct _submatch {
unsigned int offstart, offend; /* in bytes */
};
/* flags for new func */
#define SEARCH_CASE (1)
#define SEARCH_BOLD (2)
struct _searcher {
struct _trie *t;
char *(*next_token)(); /* callbacks for more tokens */
void *next_data;
int words; /* how many words */
char *tags, *tage; /* the tag we used to highlight */
int flags; /* case sensitive or not */
struct _state *state; /* state is the current trie state */
int matchcount;
EDList input; /* pending 'input' tokens, processed but might match */
EDList output; /* output tokens ready for source */
struct _token *current; /* for token output memory management */
guint32 offset; /* current offset through searchable stream? */
guint32 offout; /* last output position */
unsigned int lastp; /* current position in rotating last buffer */
guint32 *last; /* buffer that goes back last 'n' positions */
guint32 last_mask; /* bitmask for efficient rotation calculation */
unsigned int submatchp; /* submatch stack */
struct _submatch *submatches;
};
static void
searcher_set_tokenfunc(struct _searcher *s, char *(*next)(), void *data)
{
s->next_token = next;
s->next_data = data;
}
static struct _searcher *
searcher_new (int flags, int argc, unsigned char **argv, const char *tags, const char *tage)
{
int i, m;
struct _searcher *s;
s = g_malloc(sizeof(*s));
s->t = build_trie((flags&SEARCH_CASE) == 0, argc, argv);
s->words = argc;
s->tags = g_strdup(tags);
s->tage = g_strdup(tage);
s->flags = flags;
s->state = &s->t->root;
s->matchcount = 0;
e_dlist_init(&s->input);
e_dlist_init(&s->output);
s->current = NULL;
s->offset = 0;
s->offout = 0;
/* rotating queue of previous character positions */
m = s->t->max_depth+1;
i = 2;
while (ilast = g_malloc(sizeof(s->last[0])*i);
s->last_mask = i-1;
s->lastp = 0;
/* a stack of possible submatches */
s->submatchp = 0;
s->submatches = g_malloc(sizeof(s->submatches[0])*argc+1);
return s;
}
static void
searcher_free(struct _searcher *s)
{
struct _token *t;
while ((t = (struct _token *)e_dlist_remhead(&s->input)))
g_free(t);
while ((t = (struct _token *)e_dlist_remhead(&s->output)))
g_free(t);
g_free(s->tags);
g_free(s->tage);
g_free(s->last);
g_free(s->submatches);
free_trie(s->t);
g_free(s);
}
static struct _token *
append_token(EDList *list, const char *tok, int len)
{
struct _token *token;
if (len == -1)
len = strlen(tok);
token = g_malloc(sizeof(*token) + len+1);
token->offset = 0; /* set by caller when required */
memcpy(token->tok, tok, len);
token->tok[len] = 0;
e_dlist_addtail(list, (EDListNode *)token);
return token;
}
#define free_token(x) (g_free(x))
static void
output_token(struct _searcher *s, struct _token *token)
{
int offend;
int left, pre;
if (token->tok[0] == TAG_ESCAPE) {
if (token->offset >= s->offout) {
d(printf("moving tag token '%s' from input to output\n", token->tok[0]==TAG_ESCAPE?token->tok+1:token->tok));
e_dlist_addtail(&s->output, (EDListNode *)token);
} else {
d(printf("discarding tag token '%s' from input\n", token->tok[0]==TAG_ESCAPE?token->tok+1:token->tok));
free_token(token);
}
} else {
offend = token->offset + strlen(token->tok);
left = offend-s->offout;
if (left > 0) {
pre = s->offout - token->offset;
if (pre>0)
memmove(token->tok, token->tok+pre, left+1);
d(printf("adding partial remaining/failed '%s'\n", token->tok[0]==TAG_ESCAPE?token->tok+1:token->tok));
s->offout = offend;
e_dlist_addtail(&s->output, (EDListNode *)token);
} else {
d(printf("discarding whole token '%s'\n", token->tok[0]==TAG_ESCAPE?token->tok+1:token->tok));
free_token(token);
}
}
}
static struct _token *
find_token(struct _searcher *s, int start)
{
register struct _token *token;
/* find token which is start token, from end of list back */
token = (struct _token *)s->input.tailpred;
while (token->prev) {
if (token->offset <= start)
return token;
token = token->prev;
}
return NULL;
}
static void
output_match(struct _searcher *s, unsigned int start, unsigned int end)
{
register struct _token *token;
struct _token *starttoken, *endtoken;
char b[8];
d(printf("output match: %d-%d at %d\n", start, end, s->offout));
starttoken = find_token(s, start);
endtoken = find_token(s, end);
if (starttoken == NULL || endtoken == NULL) {
d(printf("Cannot find match history for match %d-%d\n", start, end));
return;
}
d(printf("start in token '%s'\n", starttoken->tok[0]==TAG_ESCAPE?starttoken->tok+1:starttoken->tok));
d(printf("end in token '%s'\n", endtoken->tok[0]==TAG_ESCAPE?endtoken->tok+1:endtoken->tok));
/* output pending stuff that didn't match afterall */
while ((struct _token *)s->input.head != starttoken) {
token = (struct _token *)e_dlist_remhead(&s->input);
d(printf("appending failed match '%s'\n", token->tok[0]==TAG_ESCAPE?token->tok+1:token->tok));
output_token(s, token);
}
/* output any pre-match text */
if (s->offout < start) {
token = append_token(&s->output, starttoken->tok + (s->offout-starttoken->offset), start-s->offout);
d(printf("adding pre-match text '%s'\n", token->tok[0]==TAG_ESCAPE?token->tok+1:token->tok));
s->offout = start;
}
/* output highlight/bold */
if (s->flags & SEARCH_BOLD) {
sprintf(b, "%c", (char)TAG_ESCAPE);
append_token(&s->output, b, -1);
}
if (s->tags)
append_token(&s->output, s->tags, -1);
/* output match node(s) */
if (starttoken != endtoken) {
while ((struct _token *)s->input.head != endtoken) {
token = (struct _token *)e_dlist_remhead(&s->input);
d(printf("appending (partial) match node (head) '%s'\n", token->tok[0]==TAG_ESCAPE?token->tok+1:token->tok));
output_token(s, token);
}
}
/* any remaining partial content */
if (s->offout < end) {
token = append_token(&s->output, endtoken->tok+(s->offout-endtoken->offset), end-s->offout);
d(printf("appending (partial) match node (tail) '%s'\n", token->tok[0]==TAG_ESCAPE?token->tok+1:token->tok));
s->offout = end;
}
/* end highlight */
if (s->tage)
append_token(&s->output, s->tage, -1);
/* and close bold if we need to */
if (s->flags & SEARCH_BOLD) {
sprintf(b, "%c", (char)TAG_ESCAPE);
append_token(&s->output, b, -1);
}
}
/* output any sub-pending blocks */
static void
output_subpending(struct _searcher *s)
{
int i;
for (i=s->submatchp-1;i>=0;i--)
output_match(s, s->submatches[i].offstart, s->submatches[i].offend);
s->submatchp = 0;
}
/* returns true if a merge took place */
static int
merge_subpending(struct _searcher *s, int offstart, int offend)
{
int i;
/* merges overlapping or abutting match strings */
if (s->submatchp &&
s->submatches[s->submatchp-1].offend >= offstart) {
/* go from end, any that match 'invalidate' follow-on ones too */
for (i=s->submatchp-1;i>=0;i--) {
if (s->submatches[i].offend >= offstart) {
if (offstart < s->submatches[i].offstart)
s->submatches[i].offstart = offstart;
s->submatches[i].offend = offend;
if (s->submatchp > i)
s->submatchp = i+1;
}
}
return 1;
}
return 0;
}
static void
push_subpending(struct _searcher *s, int offstart, int offend)
{
/* This is really an assertion, we just ignore the last pending match instead of crashing though */
if (s->submatchp >= s->words) {
d(printf("ERROR: submatch pending stack overflow\n"));
s->submatchp = s->words-1;
}
s->submatches[s->submatchp].offstart = offstart;
s->submatches[s->submatchp].offend = offend;
s->submatchp++;
}
/* move any (partial) tokens from input to output if they are beyond the current output position */
static void
output_pending(struct _searcher *s)
{
struct _token *token;
while ( (token = (struct _token *)e_dlist_remhead(&s->input)) )
output_token(s, token);
}
/* flushes any nodes we cannot possibly match anymore */
static void
flush_extra(struct _searcher *s)
{
unsigned int start;
int i;
struct _token *starttoken, *token;
/* find earliest char that can be in contention */
start = s->offset - s->t->max_depth;
for (i=0;isubmatchp;i++)
if (s->submatches[i].offstart < start)
start = s->submatches[i].offstart;
/* now, flush out any tokens which are before this point */
starttoken = find_token(s, start);
if (starttoken == NULL)
return;
while ((struct _token *)s->input.head != starttoken) {
token = (struct _token *)e_dlist_remhead(&s->input);
output_token(s, token);
}
}
static char *
searcher_next_token(struct _searcher *s)
{
struct _token *token;
const unsigned char *tok, *stok, *pre_tok;
struct _trie *t = s->t;
struct _state *q = s->state;
struct _match *m = NULL;
int offstart, offend;
guint32 c;
while (e_dlist_empty(&s->output)) {
/* get next token */
tok = (unsigned char *)s->next_token(s->next_data);
if (tok == NULL) {
output_subpending(s);
output_pending(s);
break;
}
/* we dont always have to copy each token, e.g. if we dont match anything */
token = append_token(&s->input, (char *)tok, -1);
token->offset = s->offset;
tok = (unsigned char *)token->tok;
d(printf("new token %d '%s'\n", token->offset, token->tok[0]==TAG_ESCAPE?token->tok+1:token->tok));
/* tag test, reset state on unknown tags */
if (tok[0] == TAG_ESCAPE) {
if (!ignore_tag ((char *)tok)) {
/* force reset */
output_subpending(s);
output_pending(s);
q = &t->root;
}
continue;
}
/* process whole token */
pre_tok = stok = tok;
while ((c = camel_utf8_getc (&tok))) {
if ((s->flags & SEARCH_CASE) == 0)
c = g_unichar_tolower(c);
while (q && (m = g(q, c)) == NULL)
q = q->fail;
if (q == NULL) {
/* mismatch ... reset state */
output_subpending(s);
q = &t->root;
} else if (m != NULL) {
/* keep track of previous offsets of utf8 chars, rotating buffer */
s->last[s->lastp] = s->offset + (pre_tok-stok);
s->lastp = (s->lastp+1)&s->last_mask;
q = m->match;
/* we have a match of q->final characters for a matching word */
if (q->final) {
s->matchcount++;
/* use the last buffer to find the real offset of this char */
offstart = s->last[(s->lastp - q->final)&s->last_mask];
offend = s->offset + (tok - stok);
if (q->matches == NULL) {
if (s->submatchp == 0) {
/* nothing pending, always put something in so we can try merge */
push_subpending(s, offstart, offend);
} else if (!merge_subpending(s, offstart, offend)) {
/* can't merge, output what we have, and start againt */
output_subpending(s);
push_subpending(s, offstart, offend);
/*output_match(s, offstart, offend);*/
} else if (e_dlist_length(&s->input) > 8) {
/* we're continuing to match and merge, but we have a lot of stuff
waiting, so flush it out now since this is a safe point to do it */
output_subpending(s);
}
} else {
/* merge/add subpending */
if (!merge_subpending(s, offstart, offend))
push_subpending(s, offstart, offend);
}
}
}
pre_tok = tok;
}
s->offset += (pre_tok-stok);
flush_extra(s);
}
s->state = q;
if (s->current)
free_token(s->current);
s->current = token = (struct _token *)e_dlist_remhead(&s->output);
return token ? g_strdup (token->tok) : NULL;
}
static char *
searcher_peek_token(struct _searcher *s)
{
char *tok;
/* we just get it and then put it back, it's fast enuf */
tok = searcher_next_token(s);
if (tok) {
/* need to clear this so we dont free it while its still active */
e_dlist_addhead(&s->output, (EDListNode *)s->current);
s->current = NULL;
}
return tok;
}
static int
searcher_pending(struct _searcher *s)
{
return !(e_dlist_empty(&s->input) && e_dlist_empty(&s->output));
}
/* ********************************************************************** */
struct _search_info {
GPtrArray *strv;
char *colour;
unsigned int size:8;
unsigned int flags:8;
};
/** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** **/
static struct _search_info *
search_info_new(void)
{
struct _search_info *s;
s = g_malloc0(sizeof(struct _search_info));
s->strv = g_ptr_array_new();
return s;
}
static void
search_info_set_flags(struct _search_info *si, unsigned int flags, unsigned int mask)
{
si->flags = (si->flags & ~mask) | (flags & mask);
}
static void
search_info_set_colour(struct _search_info *si, const char *colour)
{
g_free(si->colour);
si->colour = g_strdup(colour);
}
static void
search_info_add_string(struct _search_info *si, const char *s)
{
const unsigned char *start;
guint32 c;
if (s && s[0]) {
const unsigned char *us = (unsigned char *) s;
/* strip leading whitespace */
start = us;
while ((c = camel_utf8_getc (&us))) {
if (!g_unichar_isspace (c)) {
break;
}
start = us;
}
/* should probably also strip trailing, but i'm lazy today */
if (start[0])
g_ptr_array_add(si->strv, g_strdup ((char *)start));
}
}
static void
search_info_clear(struct _search_info *si)
{
int i;
for (i=0;istrv->len;i++)
g_free(si->strv->pdata[i]);
g_ptr_array_set_size(si->strv, 0);
}
static void
search_info_free(struct _search_info *si)
{
int i;
for (i=0;istrv->len;i++)
g_free(si->strv->pdata[i]);
g_ptr_array_free(si->strv, TRUE);
g_free(si->colour);
g_free(si);
}
static struct _search_info *
search_info_clone(struct _search_info *si)
{
struct _search_info *out;
int i;
out = search_info_new();
for (i=0;istrv->len;i++)
g_ptr_array_add(out->strv, g_strdup(si->strv->pdata[i]));
out->colour = g_strdup(si->colour);
out->flags = si->flags;
out->size = si->size;
return out;
}
static struct _searcher *
search_info_to_searcher(struct _search_info *si)
{
char *tags, *tage;
char *col;
if (si->strv->len == 0)
return NULL;
if (si->colour == NULL)
col = "red";
else
col = si->colour;
tags = alloca(20+strlen(col));
sprintf(tags, "%c", TAG_ESCAPE, col);
tage = alloca(20);
sprintf(tage, "%c", TAG_ESCAPE);
return searcher_new (si->flags, si->strv->len, (unsigned char **)si->strv->pdata, tags, tage);
}
/* ********************************************************************** */
struct _ESearchingTokenizerPrivate {
struct _search_info *primary, *secondary;
struct _searcher *engine;
};
/** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** **/
static void
e_searching_tokenizer_finalise (GObject *obj)
{
ESearchingTokenizer *st = E_SEARCHING_TOKENIZER (obj);
struct _ESearchingTokenizerPrivate *p = st->priv;
search_info_free (p->primary);
search_info_free (p->secondary);
if (p->engine)
searcher_free(p->engine);
/* again wtf?
shared_state_unref (st->priv->shared);
*/
g_free (p);
if (G_OBJECT_CLASS (parent_class)->finalize)
G_OBJECT_CLASS (parent_class)->finalize(obj);
}
static void
e_searching_tokenizer_class_init (ESearchingTokenizerClass *klass)
{
GObjectClass *obj_class = (GObjectClass *) klass;
HTMLTokenizerClass *tok_class = HTML_TOKENIZER_CLASS (klass);
parent_class = g_type_class_ref (HTML_TYPE_TOKENIZER);
signals[MATCH_SIGNAL] =
g_signal_new ("match",
E_TYPE_SEARCHING_TOKENIZER,
G_SIGNAL_RUN_LAST,
G_STRUCT_OFFSET (ESearchingTokenizerClass, match),
NULL,
NULL,
g_cclosure_marshal_VOID__VOID,
G_TYPE_NONE, 0);
obj_class->finalize = e_searching_tokenizer_finalise;
tok_class->begin = e_searching_tokenizer_begin;
tok_class->end = e_searching_tokenizer_end;
tok_class->peek_token = e_searching_tokenizer_peek_token;
tok_class->next_token = e_searching_tokenizer_next_token;
tok_class->has_more = e_searching_tokenizer_has_more;
tok_class->clone = e_searching_tokenizer_clone;
}
static void
e_searching_tokenizer_init (ESearchingTokenizer *st)
{
struct _ESearchingTokenizerPrivate *p;
p = st->priv = g_new0 (struct _ESearchingTokenizerPrivate, 1);
p->primary = search_info_new();
search_info_set_flags(p->primary, SEARCH_BOLD, SEARCH_CASE|SEARCH_BOLD);
search_info_set_colour(p->primary, "red");
p->secondary = search_info_new();
search_info_set_flags(p->secondary, SEARCH_BOLD, SEARCH_CASE|SEARCH_BOLD);
search_info_set_colour(p->secondary, "purple");
}
GType
e_searching_tokenizer_get_type (void)
{
static GType type = 0;
if (!type) {
static const GTypeInfo info = {
sizeof (ESearchingTokenizerClass),
NULL, NULL,
(GClassInitFunc) e_searching_tokenizer_class_init,
NULL, NULL,
sizeof (ESearchingTokenizer),
0,
(GInstanceInitFunc) e_searching_tokenizer_init,
};
type = g_type_register_static (HTML_TYPE_TOKENIZER, "ESearchingTokenizer", &info, 0);
}
return type;
}
ESearchingTokenizer *
e_searching_tokenizer_new (void)
{
return g_object_new (E_TYPE_SEARCHING_TOKENIZER, NULL);
}
/** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** **/
/* blah blah the htmltokeniser doesn't like being asked
for a token if it doens't hvae any! */
static char *get_token(HTMLTokenizer *t)
{
HTMLTokenizerClass *klass = HTML_TOKENIZER_CLASS (parent_class);
return klass->has_more(t) ? klass->next_token(t) : NULL;
}
static void
e_searching_tokenizer_begin (HTMLTokenizer *t, const char *content_type)
{
ESearchingTokenizer *st = E_SEARCHING_TOKENIZER (t);
struct _ESearchingTokenizerPrivate *p = st->priv;
/* reset search */
if (p->engine) {
searcher_free(p->engine);
p->engine = NULL;
}
if ((p->engine = search_info_to_searcher(p->primary))
|| (p->engine = search_info_to_searcher(p->secondary))) {
/*HTMLTokenizerClass *klass = HTML_TOKENIZER_CLASS (parent_class);*/
/*searcher_set_tokenfunc(p->engine, klass->next_token, st);*/
searcher_set_tokenfunc(p->engine, get_token, st);
}
/* else - no engine, no search active */
HTML_TOKENIZER_CLASS (parent_class)->begin (t, content_type);
}
static void
e_searching_tokenizer_end (HTMLTokenizer *t)
{
/* so end gets called before any get/next tokens.
I dont get it. */
#if 0
ESearchingTokenizer *st = E_SEARCHING_TOKENIZER (t);
struct _ESearchingTokenizerPrivate *p = st->priv;
/* not sure if we should reset search every time ... *shrug* */
if (p->engine) {
searcher_free(p->engine);
p->engine = NULL;
}
#endif
HTML_TOKENIZER_CLASS (parent_class)->end (t);
}
static char *
e_searching_tokenizer_peek_token (HTMLTokenizer *tok)
{
ESearchingTokenizer *st = E_SEARCHING_TOKENIZER (tok);
/* If no search is active, just use the default method. */
if (st->priv->engine == NULL)
return HTML_TOKENIZER_CLASS (parent_class)->peek_token (tok);
return searcher_peek_token(st->priv->engine);
}
static char *
e_searching_tokenizer_next_token (HTMLTokenizer *tok)
{
ESearchingTokenizer *st = E_SEARCHING_TOKENIZER (tok);
int oldmatched;
char *token;
/* If no search is active, just use the default method. */
if (st->priv->engine == NULL)
return HTML_TOKENIZER_CLASS (parent_class)->next_token (tok);
oldmatched = st->priv->engine->matchcount;
token = searcher_next_token(st->priv->engine);
/* not sure if this has to be accurate or just say we had some matches */
if (oldmatched != st->priv->engine->matchcount)
g_signal_emit (st, signals[MATCH_SIGNAL], 0);
return token;
}
static gboolean
e_searching_tokenizer_has_more (HTMLTokenizer *tok)
{
ESearchingTokenizer *st = E_SEARCHING_TOKENIZER (tok);
return (st->priv->engine != NULL && searcher_pending(st->priv->engine))
|| HTML_TOKENIZER_CLASS (parent_class)->has_more (tok);
}
/* proxy matched event, not sure what its for otherwise */
static void
matched (ESearchingTokenizer *st)
{
/*++st->priv->match_count;*/
g_signal_emit (st, signals[MATCH_SIGNAL], 0);
}
static HTMLTokenizer *
e_searching_tokenizer_clone (HTMLTokenizer *tok)
{
ESearchingTokenizer *orig_st = E_SEARCHING_TOKENIZER (tok);
ESearchingTokenizer *new_st = E_SEARCHING_TOKENIZER (e_searching_tokenizer_new ());
search_info_free(new_st->priv->primary);
search_info_free(new_st->priv->secondary);
new_st->priv->primary = search_info_clone(orig_st->priv->primary);
new_st->priv->secondary = search_info_clone(orig_st->priv->secondary);
#if 0
shared_state_ref (orig_st->priv->shared);
shared_state_unref (new_st->priv->shared);
new_st->priv->shared = orig_st->priv->shared;
#endif
g_signal_connect_swapped (new_st, "match", G_CALLBACK(matched), orig_st);
return HTML_TOKENIZER (new_st);
}
/* ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** ** */
void
e_searching_tokenizer_set_primary_search_string (ESearchingTokenizer *st, const gchar *search_str)
{
g_return_if_fail (st && E_IS_SEARCHING_TOKENIZER (st));
search_info_clear(st->priv->primary);
search_info_add_string(st->priv->primary, search_str);
}
void
e_searching_tokenizer_add_primary_search_string (ESearchingTokenizer *st, const gchar *search_str)
{
g_return_if_fail (st && E_IS_SEARCHING_TOKENIZER (st));
search_info_add_string(st->priv->primary, search_str);
}
void
e_searching_tokenizer_set_primary_case_sensitivity (ESearchingTokenizer *st, gboolean iscase)
{
g_return_if_fail (st && E_IS_SEARCHING_TOKENIZER (st));
search_info_set_flags(st->priv->primary, iscase?SEARCH_CASE:0, SEARCH_CASE);
}
void
e_searching_tokenizer_set_secondary_search_string (ESearchingTokenizer *st, const gchar *search_str)
{
g_return_if_fail (st && E_IS_SEARCHING_TOKENIZER (st));
search_info_clear(st->priv->secondary);
search_info_add_string(st->priv->secondary, search_str);
}
void
e_searching_tokenizer_add_secondary_search_string (ESearchingTokenizer *st, const gchar *search_str)
{
g_return_if_fail (st && E_IS_SEARCHING_TOKENIZER (st));
search_info_add_string(st->priv->secondary, search_str);
}
void
e_searching_tokenizer_set_secondary_case_sensitivity (ESearchingTokenizer *st, gboolean iscase)
{
g_return_if_fail (st && E_IS_SEARCHING_TOKENIZER (st));
search_info_set_flags(st->priv->secondary, iscase?SEARCH_CASE:0, SEARCH_CASE);
}
/* Note: only returns the primary search string count */
gint
e_searching_tokenizer_match_count (ESearchingTokenizer *st)
{
g_return_val_if_fail (E_IS_SEARCHING_TOKENIZER (st), -1);
if (st->priv->engine && st->priv->primary->strv->len)
return st->priv->engine->matchcount;
return 0;
}