/*
* Copyright (C) 2002 - 2007 Tomasz Kojm <tkojm@clamav.net>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*
* 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
* MA 02110-1301, USA.
*/
#if HAVE_CONFIG_H
#include "clamav-config.h"
#endif
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#include "clamav.h"
#include "others.h"
#include "matcher.h"
#include "matcher-ac.h"
#include "filetypes.h"
#include "cltypes.h"
#include "str.h"
uint8_t cli_ac_mindepth = AC_DEFAULT_MIN_DEPTH;
uint8_t cli_ac_maxdepth = AC_DEFAULT_MAX_DEPTH;
int cli_ac_addpatt(struct cli_matcher *root, struct cli_ac_patt *pattern)
{
struct cli_ac_node *pt, *next, **newtable;
struct cli_ac_patt *ph;
struct cli_ac_alt *a1, *a2;
uint8_t i, match;
uint16_t len = MIN(root->ac_maxdepth, pattern->length);
for(i = 0; i < len; i++) {
if(pattern->pattern[i] & CLI_MATCH_WILDCARD) {
len = i;
break;
}
}
if(len < root->ac_mindepth)
return CL_EPATSHORT;
pt = root->ac_root;
for(i = 0; i < len; i++) {
if(!pt->trans) {
pt->trans = (struct cli_ac_node **) cli_calloc(256, sizeof(struct cli_ac_node *));
if(!pt->trans) {
cli_errmsg("cli_ac_addpatt: Can't allocate memory for pt->trans\n");
return CL_EMEM;
}
}
next = pt->trans[(unsigned char) (pattern->pattern[i] & 0xff)];
if(!next) {
next = (struct cli_ac_node *) cli_calloc(1, sizeof(struct cli_ac_node));
if(!next) {
cli_errmsg("cli_ac_addpatt: Can't allocate memory for AC node\n");
return CL_EMEM;
}
if(i != len - 1) {
next->trans = (struct cli_ac_node **) cli_calloc(256, sizeof(struct cli_ac_node *));
if(!next->trans) {
cli_errmsg("cli_ac_addpatt: Can't allocate memory for next->trans\n");
free(next);
return CL_EMEM;
}
} else {
next->leaf = 1;
}
root->ac_nodes++;
newtable = (struct cli_ac_node **) cli_realloc(root->ac_nodetable, root->ac_nodes * sizeof(struct cli_ac_node *));
if(!newtable) {
root->ac_nodes--;
cli_errmsg("cli_ac_addpatt: Can't realloc ac_nodetable\n");
if(next->trans)
free(next->trans);
free(next);
return CL_EMEM;
}
newtable[root->ac_nodes - 1] = next;
root->ac_nodetable = newtable;
pt->trans[(unsigned char) (pattern->pattern[i] & 0xff)] = next;
pt->leaf = 0;
}
pt = next;
}
root->ac_patterns++;
root->ac_pattable = (struct cli_ac_patt **) cli_realloc2(root->ac_pattable, root->ac_patterns * sizeof(struct cli_ac_patt *));
if(!root->ac_pattable) {
cli_errmsg("cli_ac_addpatt: Can't realloc ac_pattable\n");
return CL_EMEM;
}
root->ac_pattable[root->ac_patterns - 1] = pattern;
pt->final = 1;
pattern->depth = i;
ph = pt->list;
while(ph) {
if((ph->length == pattern->length) && (ph->prefix_length == pattern->prefix_length)) {
if(!memcmp(ph->pattern, pattern->pattern, ph->length * sizeof(uint16_t)) && !memcmp(ph->prefix, pattern->prefix, ph->prefix_length * sizeof(uint16_t))) {
if(!ph->alt && !pattern->alt) {
match = 1;
} else if(ph->alt == pattern->alt) {
match = 1;
for(i = 0; i < ph->alt; i++) {
a1 = ph->alttable[i];
a2 = pattern->alttable[i];
if(a1->num != a2->num) {
match = 0;
break;
}
if(a1->chmode != a2->chmode) {
match = 0;
break;
} else if(a1->chmode) {
if(memcmp(a1->str, a2->str, a1->num)) {
match = 0;
break;
}
} else {
while(a1 && a2) {
if((a1->len != a2->len) || memcmp(a1->str, a2->str, a1->len))
break;
a1 = a1->next;
a2 = a2->next;
}
if(a1 || a2) {
match = 0;
break;
}
}
}
} else {
match = 0;
}
if(match) {
pattern->next_same = ph->next_same;
ph->next_same = pattern;
return CL_SUCCESS;
}
}
}
ph = ph->next;
}
pattern->next = pt->list;
pt->list = pattern;
return CL_SUCCESS;
}
struct bfs_list {
struct cli_ac_node *node;
struct bfs_list *next;
};
static int bfs_enqueue(struct bfs_list **bfs, struct bfs_list **last, struct cli_ac_node *n)
{
struct bfs_list *new;
new = (struct bfs_list *) cli_malloc(sizeof(struct bfs_list));
if(!new) {
cli_errmsg("bfs_enqueue: Can't allocate memory for bfs_list\n");
return CL_EMEM;
}
new->next = NULL;
new->node = n;
if(*last) {
(*last)->next = new;
*last = new;
} else {
*bfs = *last = new;
}
return CL_SUCCESS;
}
static struct cli_ac_node *bfs_dequeue(struct bfs_list **bfs)
{
struct bfs_list *lpt;
struct cli_ac_node *pt;
if(!(lpt = *bfs)) {
return NULL;
} else {
*bfs = (*bfs)->next;
pt = lpt->node;
free(lpt);
return pt;
}
}
static int ac_maketrans(struct cli_matcher *root)
{
struct bfs_list *bfs = NULL, *bfs_last = NULL;
struct cli_ac_node *ac_root = root->ac_root, *child, *node, *fail;
struct cli_ac_patt *patt;
int i, ret;
for(i = 0; i < 256; i++) {
node = ac_root->trans[i];
if(!node) {
ac_root->trans[i] = ac_root;
} else {
node->fail = ac_root;
if((ret = bfs_enqueue(&bfs, &bfs_last, node)))
return ret;
}
}
while((node = bfs_dequeue(&bfs))) {
if(node->leaf)
continue;
for(i = 0; i < 256; i++) {
child = node->trans[i];
if(child) {
fail = node->fail;
while(fail->leaf || !fail->trans[i])
fail = fail->fail;
child->fail = fail->trans[i];
if(child->list) {
patt = child->list;
while(patt->next)
patt = patt->next;
patt->next = child->fail->list;
} else {
child->list = child->fail->list;
}
if(child->list)
child->final = 1;
if((ret = bfs_enqueue(&bfs, &bfs_last, child)) != 0)
return ret;
}
}
}
return CL_SUCCESS;
}
int cli_ac_buildtrie(struct cli_matcher *root)
{
if(!root)
return CL_EMALFDB;
if(!root->ac_root) {
cli_dbgmsg("cli_ac_buildtrie: AC pattern matcher is not initialised\n");
return CL_SUCCESS;
}
return ac_maketrans(root);
}
int cli_ac_init(struct cli_matcher *root, uint8_t mindepth, uint8_t maxdepth)
{
root->ac_root = (struct cli_ac_node *) cli_calloc(1, sizeof(struct cli_ac_node));
if(!root->ac_root) {
cli_errmsg("cli_ac_init: Can't allocate memory for ac_root\n");
return CL_EMEM;
}
root->ac_root->trans = (struct cli_ac_node **) cli_calloc(256, sizeof(struct cli_ac_node *));
if(!root->ac_root->trans) {
cli_errmsg("cli_ac_init: Can't allocate memory for ac_root->trans\n");
free(root->ac_root);
return CL_EMEM;
}
root->ac_mindepth = mindepth;
root->ac_maxdepth = maxdepth;
return CL_SUCCESS;
}
static void ac_free_alt(struct cli_ac_patt *p)
{
uint16_t i;
struct cli_ac_alt *a1, *a2;
if(!p->alt)
return;
for(i = 0; i < p->alt; i++) {
a1 = p->alttable[i];
while(a1) {
a2 = a1;
a1 = a1->next;
if(a2->str)
free(a2->str);
free(a2);
}
}
free(p->alttable);
}
void cli_ac_free(struct cli_matcher *root)
{
uint32_t i;
struct cli_ac_patt *patt;
for(i = 0; i < root->ac_patterns; i++) {
patt = root->ac_pattable[i];
if(patt->prefix)
free(patt->prefix);
else
free(patt->pattern);
free(patt->virname);
if(patt->offset)
free(patt->offset);
if(patt->alt)
ac_free_alt(patt);
free(patt);
}
if(root->ac_pattable)
free(root->ac_pattable);
for(i = 0; i < root->ac_nodes; i++) {
if(!root->ac_nodetable[i]->leaf)
free(root->ac_nodetable[i]->trans);
free(root->ac_nodetable[i]);
}
if(root->ac_nodetable)
free(root->ac_nodetable);
if(root->ac_root) {
free(root->ac_root->trans);
free(root->ac_root);
}
}
/*
* FIXME: the current support for string alternatives uses a brute-force
* approach and doesn't perform any kind of verification and
* backtracking. This may easily lead to false negatives, eg. when
* an alternative contains strings of different lengths and
* more than one of them can match at the current position.
*/
#define AC_MATCH_CHAR(p,b) \
switch(wc = p & CLI_MATCH_WILDCARD) { \
case CLI_MATCH_CHAR: \
if((unsigned char) p != b) \
return 0; \
break; \
\
case CLI_MATCH_IGNORE: \
break; \
\
case CLI_MATCH_ALTERNATIVE: \
found = 0; \
alt = pattern->alttable[altcnt]; \
if(alt->chmode) { \
for(j = 0; j < alt->num; j++) { \
if(alt->str[j] == b) { \
found = 1; \
break; \
} \
} \
} else { \
while(alt) { \
if(bp + alt->len <= length) { \
if(!memcmp(&buffer[bp], alt->str, alt->len)) { \
found = 1; \
bp += alt->len - 1; \
break; \
} \
} \
alt = alt->next; \
} \
} \
if(!found) \
return 0; \
altcnt++; \
break; \
\
case CLI_MATCH_NIBBLE_HIGH: \
if((unsigned char) (p & 0x00f0) != (b & 0xf0)) \
return 0; \
break; \
\
case CLI_MATCH_NIBBLE_LOW: \
if((unsigned char) (p & 0x000f) != (b & 0x0f)) \
return 0; \
break; \
\
default: \
cli_errmsg("ac_findmatch: Unknown wildcard 0x%x\n", wc); \
return 0; \
}
inline static int ac_findmatch(const unsigned char *buffer, uint32_t offset, uint32_t length, const struct cli_ac_patt *pattern, uint32_t *end)
{
uint32_t bp;
uint16_t wc, i, j, altcnt = pattern->alt_pattern;
uint8_t found;
struct cli_ac_alt *alt;
if((offset + pattern->length > length) || (pattern->prefix_length > offset))
return 0;
bp = offset + pattern->depth;
for(i = pattern->depth; i < pattern->length && bp < length; i++) {
AC_MATCH_CHAR(pattern->pattern[i],buffer[bp]);
bp++;
}
*end = bp;
if(pattern->prefix) {
altcnt = 0;
bp = offset - pattern->prefix_length;
for(i = 0; i < pattern->prefix_length; i++) {
AC_MATCH_CHAR(pattern->prefix[i],buffer[bp]);
bp++;
}
}
return 1;
}
int cli_ac_initdata(struct cli_ac_data *data, uint32_t partsigs, uint8_t tracklen)
{
if(!data) {
cli_errmsg("cli_ac_init: data == NULL\n");
return CL_ENULLARG;
}
data->partsigs = partsigs;
if(!partsigs)
return CL_SUCCESS;
data->offmatrix = (int32_t ***) cli_calloc(partsigs, sizeof(int32_t **));
if(!data->offmatrix) {
cli_errmsg("cli_ac_init: Can't allocate memory for data->offmatrix\n");
return CL_EMEM;
}
return CL_SUCCESS;
}
void cli_ac_freedata(struct cli_ac_data *data)
{
uint32_t i;
if(data && data->partsigs) {
for(i = 0; i < data->partsigs; i++) {
if(data->offmatrix[i]) {
free(data->offmatrix[i][0]);
free(data->offmatrix[i]);
}
}
free(data->offmatrix);
}
}
inline static int ac_addtype(struct cli_matched_type **list, cli_file_t type, off_t offset)
{
struct cli_matched_type *tnode, *tnode_last;
if(*list && (*list)->cnt >= MAX_EMBEDDED_OBJ)
return CL_SUCCESS;
if(!(tnode = cli_calloc(1, sizeof(struct cli_matched_type)))) {
cli_errmsg("cli_ac_addtype: Can't allocate memory for new type node\n");
return CL_EMEM;
}
tnode->type = type;
tnode->offset = offset;
tnode_last = *list;
while(tnode_last && tnode_last->next)
tnode_last = tnode_last->next;
if(tnode_last)
tnode_last->next = tnode;
else
*list = tnode;
(*list)->cnt++;
return CL_SUCCESS;
}
int cli_ac_scanbuff(const unsigned char *buffer, uint32_t length, const char **virname, const struct cli_matcher *root, struct cli_ac_data *mdata, uint8_t otfrec, uint32_t offset, cli_file_t ftype, int fd, struct cli_matched_type **ftoffset)
{
struct cli_ac_node *current;
struct cli_ac_patt *patt, *pt;
uint32_t i, bp, realoff, matchend;
uint16_t j;
int32_t **offmatrix;
uint8_t found;
struct cli_target_info info;
int type = CL_CLEAN;
if(!root->ac_root)
return CL_CLEAN;
if(!mdata) {
cli_errmsg("cli_ac_scanbuff: mdata == NULL\n");
return CL_ENULLARG;
}
memset(&info, 0, sizeof(info));
current = root->ac_root;
for(i = 0; i < length; i++) {
while(current->leaf || !current->trans[buffer[i]])
current = current->fail;
current = current->trans[buffer[i]];
if(current->final) {
patt = current->list;
while(patt) {
bp = i + 1 - patt->depth;
if(ac_findmatch(buffer, bp, length, patt, &matchend)) {
pt = patt;
while(pt) {
realoff = offset + bp - pt->prefix_length;
if((pt->offset || pt->target) && (!pt->sigid || pt->partno == 1)) {
if((fd == -1 && !ftype) || !cli_validatesig(ftype, pt->offset, realoff, &info, fd, pt->virname)) {
pt = pt->next_same;
continue;
}
}
if(pt->sigid) { /* it's a partial signature */
if(pt->partno != 1 && (!mdata->offmatrix[pt->sigid - 1] || !mdata->offmatrix[pt->sigid - 1][pt->partno - 2][0])) {
pt = pt->next_same;
continue;
}
if(!mdata->offmatrix[pt->sigid - 1]) {
mdata->offmatrix[pt->sigid - 1] = cli_malloc(pt->parts * sizeof(int32_t *));
if(!mdata->offmatrix[pt->sigid - 1]) {
cli_errmsg("cli_ac_scanbuff: Can't allocate memory for mdata->offmatrix[%u]\n", pt->sigid - 1);
return CL_EMEM;
}
mdata->offmatrix[pt->sigid - 1][0] = cli_malloc(pt->parts * (AC_DEFAULT_TRACKLEN + 1) * sizeof(int32_t));
if(!mdata->offmatrix[pt->sigid - 1][0]) {
cli_errmsg("cli_ac_scanbuff: Can't allocate memory for mdata->offmatrix[%u][0]\n", pt->sigid - 1);
free(mdata->offmatrix[pt->sigid - 1]);
mdata->offmatrix[pt->sigid - 1] = NULL;
return CL_EMEM;
}
memset(mdata->offmatrix[pt->sigid - 1][0], -1, pt->parts * (AC_DEFAULT_TRACKLEN + 1) * sizeof(int32_t));
mdata->offmatrix[pt->sigid - 1][0][0] = 0;
for(j = 1; j < pt->parts; j++) {
mdata->offmatrix[pt->sigid - 1][j] = mdata->offmatrix[pt->sigid - 1][0] + j * (AC_DEFAULT_TRACKLEN + 1);
mdata->offmatrix[pt->sigid - 1][j][0] = 0;
}
}
offmatrix = mdata->offmatrix[pt->sigid - 1];
if(pt->partno != 1) {
found = 0;
for(j = 1; j <= AC_DEFAULT_TRACKLEN && offmatrix[pt->partno - 2][j] != -1; j++) {
found = 1;
if(pt->maxdist)
if(realoff - offmatrix[pt->partno - 2][j] > pt->maxdist)
found = 0;
if(found && pt->mindist)
if(realoff - offmatrix[pt->partno - 2][j] < pt->mindist)
found = 0;
if(found)
break;
}
}
if(pt->partno == 1 || (found && (pt->partno != pt->parts))) {
offmatrix[pt->partno - 1][0] %= AC_DEFAULT_TRACKLEN;
offmatrix[pt->partno - 1][0]++;
offmatrix[pt->partno - 1][offmatrix[pt->partno - 1][0]] = offset + matchend;
if(pt->partno == 1) /* save realoff for the first part */
offmatrix[pt->parts - 1][offmatrix[pt->partno - 1][0]] = realoff;
} else if(found && pt->partno == pt->parts) {
if(pt->type) {
if(otfrec) {
if(pt->type > type || pt->type >= CL_TYPE_SFX || pt->type == CL_TYPE_MSEXE) {
cli_dbgmsg("Matched signature for file type %s\n", pt->virname);
type = pt->type;
if(ftoffset && (!*ftoffset || (*ftoffset)->cnt < MAX_EMBEDDED_OBJ) && ((ftype == CL_TYPE_MSEXE && type >= CL_TYPE_SFX) || ((ftype == CL_TYPE_MSEXE || ftype == CL_TYPE_ZIP) && type == CL_TYPE_MSEXE))) {
/* FIXME: we don't know which offset of the first part is the correct one */
for(j = 1; j <= AC_DEFAULT_TRACKLEN && offmatrix[0][j] != -1; j++) {
if(ac_addtype(ftoffset, type, offmatrix[pt->parts - 1][j])) {
if(info.exeinfo.section)
free(info.exeinfo.section);
return CL_EMEM;
}
}
}
memset(offmatrix[0], -1, pt->parts * (AC_DEFAULT_TRACKLEN + 1) * sizeof(int32_t));
for(j = 0; j < pt->parts; j++)
offmatrix[j][0] = 0;
}
}
} else { /* !pt->type */
if(virname)
*virname = pt->virname;
if(info.exeinfo.section)
free(info.exeinfo.section);
return CL_VIRUS;
}
}
} else { /* old type signature */
if(pt->type) {
if(otfrec) {
if(pt->type > type || pt->type >= CL_TYPE_SFX || pt->type == CL_TYPE_MSEXE) {
cli_dbgmsg("Matched signature for file type %s at %u\n", pt->virname, realoff);
type = pt->type;
if(ftoffset && (!*ftoffset || (*ftoffset)->cnt < MAX_EMBEDDED_OBJ) && ((ftype == CL_TYPE_MSEXE && type >= CL_TYPE_SFX) || ((ftype == CL_TYPE_MSEXE || ftype == CL_TYPE_ZIP) && type == CL_TYPE_MSEXE))) {
if(ac_addtype(ftoffset, type, realoff)) {
if(info.exeinfo.section)
free(info.exeinfo.section);
return CL_EMEM;
}
}
}
}
} else {
if(virname)
*virname = pt->virname;
if(info.exeinfo.section)
free(info.exeinfo.section);
return CL_VIRUS;
}
}
pt = pt->next_same;
}
}
patt = patt->next;
}
}
}
if(info.exeinfo.section)
free(info.exeinfo.section);
return otfrec ? type : CL_CLEAN;
}
/* FIXME: clean up the code */
int cli_ac_addsig(struct cli_matcher *root, const char *virname, const char *hexsig, uint32_t sigid, uint16_t parts, uint16_t partno, uint16_t type, uint32_t mindist, uint32_t maxdist, const char *offset, uint8_t target)
{
struct cli_ac_patt *new;
char *pt, *hex = NULL;
uint16_t i, j, ppos = 0, pend;
uint8_t wprefix = 0, zprefix = 1, namelen, plen = 0;
struct cli_ac_alt *newalt, *altpt, **newtable;
int ret, error = CL_SUCCESS;
if(strlen(hexsig) / 2 < root->ac_mindepth)
return CL_EPATSHORT;
if((new = (struct cli_ac_patt *) cli_calloc(1, sizeof(struct cli_ac_patt))) == NULL)
return CL_EMEM;
new->type = type;
new->sigid = sigid;
new->parts = parts;
new->partno = partno;
new->mindist = mindist;
new->maxdist = maxdist;
new->target = target;
if(strchr(hexsig, '(')) {
char *hexcpy, *hexnew, *start, *h, *c;
if(!(hexcpy = cli_strdup(hexsig))) {
free(new);
return CL_EMEM;
}
if(!(hexnew = (char *) cli_calloc(strlen(hexsig) + 1, 1))) {
free(hexcpy);
free(new);
return CL_EMEM;
}
start = pt = hexcpy;
while((pt = strchr(start, '('))) {
*pt++ = 0;
if(!start) {
error = CL_EMALFDB;
break;
}
strcat(hexnew, start);
strcat(hexnew, "()");
if(!(start = strchr(pt, ')'))) {
error = CL_EMALFDB;
break;
}
*start++ = 0;
newalt = (struct cli_ac_alt *) cli_calloc(1, sizeof(struct cli_ac_alt));
if(!newalt) {
cli_errmsg("cli_ac_addsig: Can't allocate newalt\n");
error = CL_EMEM;
break;
}
new->alt++;
newtable = (struct cli_ac_alt **) cli_realloc(new->alttable, new->alt * sizeof(struct cli_ac_alt *));
if(!newtable) {
new->alt--;
free(newalt);
cli_errmsg("cli_ac_addsig: Can't realloc new->alttable\n");
error = CL_EMEM;
break;
}
newtable[new->alt - 1] = newalt;
new->alttable = newtable;
for(i = 0; i < strlen(pt); i++)
if(pt[i] == '|')
newalt->num++;
if(!newalt->num) {
error = CL_EMALFDB;
break;
} else
newalt->num++;
if(3 * newalt->num - 1 == (uint16_t) strlen(pt)) {
newalt->chmode = 1;
newalt->str = (unsigned char *) cli_malloc(newalt->num);
if(!newalt->str) {
cli_errmsg("cli_ac_addsig: Can't allocate newalt->str\n");
error = CL_EMEM;
break;
}
}
for(i = 0; i < newalt->num; i++) {
if(!(h = cli_strtok(pt, i, "|"))) {
error = CL_EMALFDB;
break;
}
if(!(c = cli_hex2str(h))) {
free(h);
error = CL_EMALFDB;
break;
}
if(newalt->chmode) {
newalt->str[i] = *c;
free(c);
} else {
if(i) {
altpt = newalt;
while(altpt->next)
altpt = altpt->next;
altpt->next = (struct cli_ac_alt *) cli_calloc(1, sizeof(struct cli_ac_alt));
if(!altpt->next) {
cli_errmsg("cli_ac_addsig: Can't allocate altpt->next\n");
error = CL_EMEM;
free(c);
free(h);
break;
}
altpt->next->str = (unsigned char *) c;
altpt->next->len = strlen(h) / 2;
} else {
newalt->str = (unsigned char *) c;
newalt->len = strlen(h) / 2;
}
}
free(h);
}
if(error)
break;
}
if(start)
strcat(hexnew, start);
hex = hexnew;
free(hexcpy);
if(error) {
if(new->alt) {
free(hex);
ac_free_alt(new);
}
free(new);
return error;
}
}
if((new->pattern = cli_hex2ui(new->alt ? hex : hexsig)) == NULL) {
if(new->alt) {
free(hex);
ac_free_alt(new);
}
free(new);
return CL_EMALFDB;
}
new->length = strlen(new->alt ? hex : hexsig) / 2;
if(new->alt)
free(hex);
for(i = 0; i < root->ac_maxdepth && i < new->length; i++) {
if(new->pattern[i] & CLI_MATCH_WILDCARD) {
wprefix = 1;
break;
}
if(zprefix && new->pattern[i])
zprefix = 0;
}
if(wprefix || zprefix) {
pend = new->length - root->ac_mindepth + 1;
for(i = 0; i < pend; i++) {
for(j = i; j < i + root->ac_maxdepth && j < new->length; j++) {
if(new->pattern[j] & CLI_MATCH_WILDCARD) {
break;
} else {
if(j - i + 1 >= plen) {
plen = j - i + 1;
ppos = i;
}
}
if(plen >= root->ac_maxdepth && (new->pattern[ppos] || new->pattern[ppos + 1]))
break;
}
if(plen >= root->ac_maxdepth && (new->pattern[ppos] || new->pattern[ppos + 1]))
break;
}
if(plen < root->ac_mindepth) {
cli_errmsg("cli_ac_addsig: Can't find a static subpattern of length %u\n", root->ac_mindepth);
ac_free_alt(new);
free(new->pattern);
free(new);
return CL_EMALFDB;
}
new->prefix = new->pattern;
new->prefix_length = ppos;
new->pattern = &new->prefix[ppos];
new->length -= ppos;
for(i = 0; i < new->prefix_length; i++)
if((new->prefix[i] & CLI_MATCH_WILDCARD) == CLI_MATCH_ALTERNATIVE)
new->alt_pattern++;
}
if(new->length > root->maxpatlen)
root->maxpatlen = new->length;
if((pt = strstr(virname, " (Clam)")))
namelen = strlen(virname) - strlen(pt);
else
namelen = strlen(virname);
if(!namelen) {
cli_errmsg("cli_ac_addsig: No virus name\n");
if(new->prefix)
free(new->prefix);
else
free(new->pattern);
ac_free_alt(new);
free(new);
return CL_EMALFDB;
}
if((new->virname = cli_calloc(namelen + 1, sizeof(char))) == NULL) {
if(new->prefix)
free(new->prefix);
else
free(new->pattern);
ac_free_alt(new);
free(new);
return CL_EMEM;
}
strncpy(new->virname, virname, namelen);
if(offset) {
new->offset = cli_strdup(offset);
if(!new->offset) {
if(new->prefix)
free(new->prefix);
else
free(new->pattern);
ac_free_alt(new);
free(new->virname);
free(new);
return CL_EMEM;
}
}
if((ret = cli_ac_addpatt(root, new))) {
if(new->prefix)
free(new->prefix);
else
free(new->pattern);
free(new->virname);
ac_free_alt(new);
if(new->offset)
free(new->offset);
free(new);
return ret;
}
return CL_SUCCESS;
}
void cli_ac_setdepth(uint8_t mindepth, uint8_t maxdepth)
{
cli_ac_mindepth = mindepth;
cli_ac_maxdepth = maxdepth;
}