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source: trunk/src/sh_utils.c@ 101

Last change on this file since 101 was 93, checked in by rainer, 18 years ago
Add check for PCI ROMs; fix ticket #51 (symlinks in root directory reported with leading double slash).
File size: 47.3 KB

Rev	Line
[1]	1	/* SAMHAIN file system integrity testing */
	2	/* Copyright (C) 1999, 2000 Rainer Wichmann */
	3	/* */
	4	/* This program is free software; you can redistribute it */
	5	/* and/or modify */
	6	/* it under the terms of the GNU General Public License as */
	7	/* published by */
	8	/* the Free Software Foundation; either version 2 of the License, or */
	9	/* (at your option) any later version. */
	10	/* */
	11	/* This program is distributed in the hope that it will be useful, */
	12	/* but WITHOUT ANY WARRANTY; without even the implied warranty of */
	13	/* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the */
	14	/* GNU General Public License for more details. */
	15	/* */
	16	/* You should have received a copy of the GNU General Public License */
	17	/* along with this program; if not, write to the Free Software */
	18	/* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */
	19
	20	#include "config_xor.h"
	21
	22
	23	#include <stdlib.h>
	24	#include <stdio.h>
	25	#include <string.h>
	26	#include <ctype.h>
	27	#include <unistd.h>
	28
	29	#if TIME_WITH_SYS_TIME
	30	#include <sys/time.h>
	31	#include <time.h>
	32	#else
	33	#if HAVE_SYS_TIME_H
	34	#include <sys/time.h>
	35	#else
	36	#include <time.h>
	37	#endif
	38	#endif
	39
	40
	41	#include "samhain.h"
	42	#include "sh_error.h"
	43	#include "sh_utils.h"
	44	#include "sh_unix.h"
	45	#include "sh_tiger.h"
	46	#include "sh_entropy.h"
	47
	48	#undef FIL__
	49	#define FIL__ _("sh_utils.c")
	50
	51	UINT32 ErrFlag[2];
	52
[20]	53	int sh_util_flagval(const char * c, int * fval)
[1]	54	{
	55	SL_ENTER(_("sh_util_flagval"));
	56	if (c == NULL)
	57	SL_RETURN( (-1), _("sh_util_flagval"));
	58	if ( c[0] == '1' \|\| c[0] == 'y' \|\| c[0] == 'Y' \|\|
	59	c[0] == 't' \|\| c[0] == 'T')
	60	{
	61	*fval = S_TRUE;
	62	SL_RETURN( (0), _("sh_util_flagval"));
	63	}
	64	if ( c[0] == '0' \|\| c[0] == 'n' \|\| c[0] == 'N' \|\|
	65	c[0] == 'f' \|\| c[0] == 'F')
	66	{
	67	*fval = S_FALSE;
	68	SL_RETURN( (0), _("sh_util_flagval"));
	69	}
	70	SL_RETURN( (-1), _("sh_util_flagval"));
	71	}
	72
	73	int sh_util_timeout_check (SH_TIMEOUT * sh_timer)
	74	{
	75	UINT64 now = (UINT64) time(NULL);
	76	UINT64 dif;
	77
	78	if (sh_timer->flag_ok == S_FALSE)
	79	{
	80	/* first time
	81	*/
	82	if (sh_timer->time_last == 0)
	83	{
	84	sh_timer->time_last = now;
	85	return S_TRUE;
	86	}
	87	/* later on
	88	*/
	89	dif = now - sh_timer->time_last;
	90	if (dif < sh_timer->time_dist)
	91	{
	92	return S_FALSE;
	93	}
	94	sh_timer->time_last = now;
	95	return S_TRUE;
	96	}
	97	sh_timer->time_last = now;
	98	return S_FALSE;
	99	}
	100
	101	static int sh_ask_update = S_FALSE;
	102
[20]	103	int sh_util_set_interactive(const char * str)
[1]	104	{
[20]	105	(void) str;
[1]	106
[20]	107	sh_ask_update = S_TRUE;
	108
[1]	109	sh_unix_setnodeamon(NULL);
	110
	111	return 0;
	112	}
	113
	114	#if !defined(STDIN_FILENO)
	115	#define STDIN_FILENO 0
	116	#endif
	117	#if !defined(STDERR_FILENO)
	118	#define STDERR_FILENO 0
	119	#endif
	120
	121	int sh_util_ask_update(char * path)
	122	{
	123	int inchar, c;
	124	int i = S_TRUE;
	125	char * tmp = NULL;
	126
	127	SL_ENTER(_("sh_util_ask_update"));
	128
	129	if (sh_ask_update != S_TRUE)
	130	{
	131	SL_RETURN(i, _("sh_util_ask_update"));
	132	}
	133
	134	#ifdef HAVE_TTYNAME
	135	if (!ttyname(STDIN_FILENO))
	136	{
	137	if (NULL != ttyname(STDERR_FILENO))
	138	{
	139	if (NULL == freopen(ttyname(STDERR_FILENO), "r", stdin))
	140	{
	141	sh_error_handle ((-1), FIL__, __LINE__, 0,
	142	MSG_E_SUBGEN,
	143	_("Cannot continue: stdin is not a terminal"),
	144	_("sh_util_ask_update"));
	145	exit(EXIT_FAILURE);
	146	}
	147	}
	148	else
	149	{
	150	sh_error_handle ((-1), FIL__, __LINE__, 0,
	151	MSG_E_SUBGEN,
	152	_("Cannot continue: stdin is not a terminal"),
	153	_("sh_util_ask_update"));
	154	exit(EXIT_FAILURE);
	155	}
	156	}
	157	#endif
	158
	159	if (sh_ask_update == S_TRUE)
	160	{
	161	tmp = sh_util_safe_name (path);
	162	fprintf (stderr, _("Update %s [Y/n] ? "), tmp);
	163	SH_FREE(tmp);
	164	while (1 == 1)
	165	{
	166	c = fgetc(stdin); inchar = c;
	167	/@+charintliteral@/
	168	while (c != '\n' && c != EOF)
	169	c = fgetc(stdin);
	170	/* fprintf(stderr, "CHAR (1): %c\n", inchar); */
	171	if (inchar == 'Y' \|\| inchar == 'y' \|\| inchar == '\n')
	172	{
	173	break;
	174	}
	175	else if (inchar == 'n' \|\| inchar == 'N')
	176	{
	177	i = S_FALSE;
	178	break;
	179	}
	180	else
	181	{
	182	fprintf(stderr, _("Please answer y(es) or n(o)\n"));
	183	}
	184	/@-charintliteral@/
	185	}
	186	}
	187
	188	SL_RETURN(i, _("sh_util_ask_update"));
	189	}
	190
[22]	191	int sh_util_hidesetup(const char * c)
[1]	192	{
	193	int i;
	194	SL_ENTER(_("sh_util_hidesetup"));
	195	i = sh_util_flagval(c, &(sh.flag.hidefile));
	196
	197	SL_RETURN(i, _("sh_util_hidesetup"));
	198	}
[68]	199
	200	char * sh_util_acl_compact(char * buf, ssize_t len)
	201	{
	202	unsigned char * p = (unsigned char *) buf;
	203	int state = 0;
	204	ssize_t rem = 0;
	205	char * out;
	206
	207	SH_VALIDATE_NE(buf, NULL);
	208	SH_VALIDATE_GE(len, 0);
	209
	210	out = SH_ALLOC(len + 1);
	211
	212	while (*p != '\0') {
	213
	214	/* -- not at start or after newline
	215	*/
	216	if (state == 1) {
	217	if (p == '\n' \|\| p == ' ' \|\| p == '\t' \|\| p == '#') {
	218	while (*p != '\n') {
	219	++p;
	220	if (*p == '\0') {
	221	goto exit_it;
	222	}
	223	}
	224	out[rem] = ','; ++rem;
	225	while (p[1] == '\n') ++p; /* scan over consecutive newlines */
	226	state = 0;
	227	if (p[1] == '\0') {
	228	if (rem > 0) out[rem-1] = '\0';
	229	break;
	230	}
	231	}
	232	else {
	233	if (p <= 0x7F && isgraph((int) p)) {
	234	out[rem] = (char) *p; ++rem;
	235	}
	236	}
	237	}
	238
	239	/* -- at start or after newline
	240	*/
	241	else /* if (state == 0) */ {
	242	if (0 == strncmp((char *) p, "user", 4)) {
	243	out[rem] = 'u'; ++rem;
	244	p += 3; state = 1;
	245	} else if (0 == strncmp((char *) p, "group", 5)) {
	246	out[rem] = 'g'; ++rem;
	247	p += 4; state = 1;
	248	} else if (0 == strncmp((char *) p, "mask", 4)) {
	249	out[rem] = 'm'; ++rem;
	250	p += 3; state = 1;
	251	} else if (0 == strncmp((char *) p, "other", 5)) {
	252	out[rem] = 'o';
	253	p += 4; state = 1; ++rem;
	254	} else if (*p == '\0') {
	255	if (rem > 0) { out[rem-1] = '\0'; }
	256	break;
	257	} else {
	258	if (p <= 0x7F && isprint((int) p)) {
	259	out[rem] = (char) *p; ++rem;
	260	}
	261	}
	262	state = 1;
	263	}
	264	++p;
	265	}
	266	exit_it:
	267	out[rem] = '\0';
	268	return out;
	269	}
[76]	270
	271
	272	char * sh_util_strdup_l (const char * str, size_t len)
	273	{
	274	char * p = NULL;
	275
	276	SL_ENTER(_("sh_util_strdup_l"));
	277
	278	SH_VALIDATE_NE(str, NULL);
	279	SH_VALIDATE_NE(len, 0);
	280
	281	if (sl_ok_adds (len, 1))
	282	{
	283	p = SH_ALLOC (len + 1);
	284	(void) sl_strlcpy (p, str, len+1);
	285	}
	286	else
	287	{
	288	safe_fatal(_("integer overflow in sh_util_strdup_l"), FIL__, __LINE__);
	289	}
	290	SL_RETURN( p, _("sh_util_strdup_l"));
	291	}
	292
[1]	293	char * sh_util_strdup (const char * str)
	294	{
	295	char * p = NULL;
	296	size_t len;
	297
	298	SL_ENTER(_("sh_util_strdup"));
	299
[25]	300	SH_VALIDATE_NE(str, NULL);
	301
	302	len = sl_strlen(str);
	303	p = SH_ALLOC (len + 1);
	304	(void) sl_strlcpy (p, str, len+1);
	305
[1]	306	SL_RETURN( p, _("sh_util_strdup"));
	307	}
	308
	309	/* by the eircom.net computer incident
	310	* response team
	311	*/
	312	char * sh_util_strsep (char *str, const char delim)
	313	{
	314	char ret, c, *d;
	315
	316	SL_ENTER(_("sh_util_strsep"));
	317	ret = *str;
	318
[25]	319	SH_VALIDATE_NE(ret, NULL);
[1]	320
	321	for (c = str; c != '\0'; c++) {
	322	for (d = (char ) delim; d != '\0'; d++) {
	323	if (c == d) {
	324	*c = '\0';
	325	*str = c + 1;
	326	SL_RETURN(ret, _("sh_util_strsep"));
	327	}
	328	}
	329	}
	330
	331	/* If we get to here, there's no delimiters in the string */
	332	*str = NULL;
	333	SL_RETURN(ret, _("sh_util_strsep"));
	334	}
	335
	336
[13]	337	/* returned string must be free'd by caller.
[1]	338	*/
	339	char * sh_util_formatted (const char * formatt, st_format * ftab)
	340	{
	341	struct tm * time_ptr;
	342	size_t size;
	343	size_t isiz;
	344	char * fmt = NULL;
	345	char * p;
	346	char * q;
	347	char * outstr;
	348	int i;
	349	int j;
	350	time_t inpp;
	351
[13]	352	char * clist[16] = { NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
	353	NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL };
[1]	354	int nn = 0;
	355
	356	SL_ENTER(_("sh_util_formatted"));
	357
[13]	358	if (formatt == NULL \|\| ftab == NULL \|\| *formatt == '\0')
[1]	359	SL_RETURN(NULL, _("sh_util_formatted"));
	360
	361	/* -- save the format (we overwrite it !!) --
	362	*/
	363	size = sl_strlen(formatt);
	364
[34]	365	if (!sl_ok_adds(size, 1))
	366	SL_RETURN(NULL, _("sh_util_formatted"));
[13]	367
[34]	368	++size;
	369	fmt = SH_ALLOC(size);
	370	(void) sl_strlcpy(fmt, formatt, size);
	371
[1]	372	p = fmt;
	373
	374	j = 0;
[13]	375	while (ftab[j].fchar != '\0') {
	376	if (ftab[j].type != S_FMT_STRING)
	377	ftab[j].data_str = NULL;
	378	++j;
	379	}
	380
[1]	381	while (p != NULL && *p != '\0' && NULL != (q = strchr(p, '%')))
	382	{
	383	++q;
	384
	385	/* fprintf(stderr, "p == %s q == %s\n", p, q); */
	386
	387	/* -- end of string is a '%' --
	388	*/
	389	if (*q == '\0')
	390	{
	391	--q;
	392	*q = '\0';
	393	break;
	394	}
	395
	396	i = 0;
	397	j = 0;
	398
	399	/* -- search the format char in input table --
	400	* put (nn < 16) here -> all remaining %foo will be
	401	* converted to %%
	402	*/
	403	while (ftab[j].fchar != '\0' && nn < 16)
	404	{
	405	if (ftab[j].fchar == *q)
	406	{
	407	/* -- Convert it to a string format (%s). --
	408	*/
	409	*q = 's'
	410	;
	411	i = 1;
	412
[13]	413	switch(ftab[j].type) {
	414
	415	case S_FMT_STRING:
[1]	416	{
	417	isiz = sl_strlen(ftab[j].data_str);
[34]	418	if (isiz > 0 && sl_ok_adds(size, isiz))
[1]	419	{
	420	size += isiz;
	421	clist[nn] = ftab[j].data_str;
	422	++nn;
	423	}
	424	else
	425	*q = '%';
[13]	426	goto endsrch;
[1]	427	}
[13]	428	break;
	429
	430	case S_FMT_ULONG:
[1]	431	{
	432	ftab[j].data_str = (char *) SH_ALLOC(64);
	433	/@-bufferoverflowhigh@/
	434	sprintf (ftab[j].data_str, "%lu", /* known to fit */
	435	ftab[j].data_ulong);
	436	/@+bufferoverflowhigh@/
	437	isiz = sl_strlen(ftab[j].data_str);
[34]	438	if (isiz > 0 && sl_ok_adds(size, isiz))
[1]	439	{
	440	size += isiz;
	441	clist[nn] = ftab[j].data_str;
	442	++nn;
	443	}
	444	else
	445	*q = '%';
[13]	446	goto endsrch;
[1]	447	}
[13]	448	break;
	449
	450	case S_FMT_LONG:
[1]	451	{
	452	ftab[j].data_str = (char *) SH_ALLOC(64);
	453	/@-bufferoverflowhigh@/
	454	sprintf (ftab[j].data_str, "%ld", /* known to fit */
	455	ftab[j].data_long);
	456	/@+bufferoverflowhigh@/
	457	isiz = sl_strlen(ftab[j].data_str);
[34]	458	if (isiz > 0 && sl_ok_adds(size, isiz))
[1]	459	{
	460	size += isiz;
	461	clist[nn] = ftab[j].data_str;
	462	++nn;
	463	}
	464	else
	465	*q = '%';
[13]	466	goto endsrch;
[1]	467	}
[13]	468	break;
	469
	470	case S_FMT_TIME:
[1]	471	{
	472	ftab[j].data_str = (char *) SH_ALLOC(64);
	473	inpp = (time_t)ftab[j].data_ulong;
	474	if (inpp != 0)
	475	{
	476	time_ptr = localtime (&(inpp));
	477	if (time_ptr != NULL)
	478	(void) strftime(ftab[j].data_str, 64,
	479	_("%d-%m-%Y %H:%M:%S"), time_ptr);
	480	else
	481	(void) sl_strlcpy(ftab[j].data_str,
	482	_("00-00-0000 00:00:00"), 64);
	483	}
	484	else
	485	{
	486	(void) sl_strlcpy(ftab[j].data_str,
	487	_("(None)"), 64);
	488	}
	489	isiz = sl_strlen(ftab[j].data_str);
[34]	490	if (isiz > 0 && sl_ok_adds(size, isiz))
[1]	491	{
	492	size += isiz;
	493	clist[nn] = ftab[j].data_str;
	494	++nn;
	495	}
	496	else
	497	*q = '%';
[13]	498	goto endsrch;
[1]	499	}
[13]	500	break;
[1]	501
[13]	502	default:
	503	/* do nothing */;
	504	}
	505
[1]	506	}
[13]	507	++j;
[1]	508	}
	509
[13]	510	endsrch:
	511
	512	p = q;
	513
[1]	514	/* -- not found -- */
	515	if (i == 0)
	516	{
	517	*q = '%';
	518	++p;
	519	}
[13]	520
[1]	521	}
	522
	523	/* -- Format string evaluated.
	524	clist[] List of strings
	525	size Total size of format string + clist[] strings
	526	-- */
	527
	528	/* -- closing '\0' --
	529	*/
[34]	530	if (sl_ok_adds(size, 1))
	531	size++;
[1]	532	outstr = (char *) SH_ALLOC(size);
	533
	534	/* -- print it --
	535	*/
	536	(void) sl_snprintf( outstr, size, fmt,
	537	clist[0], clist[1], clist[2], clist[3],
	538	clist[4], clist[5], clist[6], clist[7],
	539	clist[8], clist[9], clist[10], clist[11],
	540	clist[12], clist[13], clist[14], clist[15]);
[34]	541	outstr[size-1] = '\0';
	542
[1]	543	/* -- cleanup --
	544	*/
	545	j = 0;
[13]	546	while (ftab[j].fchar != '\0') {
	547	if (ftab[j].type != S_FMT_STRING && ftab[j].data_str != NULL)
	548	SH_FREE(ftab[j].data_str);
	549	++j;
	550	}
[1]	551	SH_FREE(fmt);
	552
	553	SL_RETURN(outstr, _("sh_util_formatted"));
	554	}
	555
[93]	556	/* read a hexchar, return int value (0-15)
	557	* can't inline (AIX)
[1]	558	*/
[12]	559	int sh_util_hexchar( const char c )
[1]	560	{
	561	/@+charint@/
	562	if ( c >= '0' && c <= '9' )
	563	return c - '0';
	564	else if ( c >= 'a' && c <= 'f' )
	565	return c - 'a' + 10;
	566	else if ( c >= 'A' && c <= 'F' )
	567	return c - 'A' + 10;
	568	else return -1;
	569	/@-charint@/
	570	}
	571
[93]	572	char * sh_util_charhex( unsigned char i )
	573	{
	574	static char i2h[2];
	575	int j, k;
	576
	577	j = i / 16;
	578	k = i - (j*16);
	579
	580	if (j < 10) i2h[0] = '0'+j;
	581	else i2h[0] = 'A'+(j-10);
	582
	583	if (k < 10) i2h[1] = '0'+k;
	584	else i2h[1] = 'A'+(k-10);
	585
	586	return i2h;
	587	}
	588
[1]	589	/* read a hexadecimal key, convert to binary
	590	*/
[12]	591	int sh_util_hextobinary (char * binary, const char * hex, int bytes)
[1]	592	{
	593	int i = 0, j, k, l = 0;
[13]	594	char c;
[1]	595
[13]	596	#define SH_HEXCHAR(x, y) \
	597	c = (x); \
	598	if ( c >= '0' && c <= '9' ) \
	599	y = c - '0'; \
	600	else if ( c >= 'a' && c <= 'f' ) \
	601	y = c - 'a' + 10; \
	602	else if ( c >= 'A' && c <= 'F' ) \
	603	y = c - 'A' + 10; \
	604	else \
	605	SL_RETURN((-1), _("sh_util_hextobinary"))
	606
	607
[1]	608	SL_ENTER(_("sh_util_hextobinary"));
	609
[34]	610	if (bytes < 2)
	611	SL_RETURN((-1), _("sh_util_hextobinary"));
	612
	613	while (i < (bytes-1))
[1]	614	{
[13]	615	SH_HEXCHAR(hex[i], k);
	616	SH_HEXCHAR(hex[i+1], j);
	617
	618	binary[l] = (char)(k * 16 + j);
	619	++l; i+= 2;
[1]	620	}
	621
	622	SL_RETURN((0), _("sh_util_hextobinary"));
	623	}
	624
	625	static void copy_four (unsigned char * dest, UINT32 in)
	626	{
	627	UINT32 i, j;
	628	int count;
	629
	630	SL_ENTER(_("copy_four"));
	631	for (count = 0; count < 4; ++count)
	632	{
	633	i = in / 256;
	634	j = in - (i*256);
	635	dest[count] = (unsigned char) j;
	636	in = i;
	637	}
	638	SL_RET0(_("copy_four"));
	639	}
	640
	641	/* compute HMAC-TIGER
	642	*/
	643	static char * sh_util_hmac_tiger (char * hexkey,
	644	char * text, size_t textlen)
	645	{
	646	static char opad[KEY_BLOCK] = {
	647	(char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C,
	648	(char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C,
	649	(char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C,
	650	(char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C, (char)0x5C
	651	};
	652	static char ipad[KEY_BLOCK] = {
	653	(char)0x36, (char)0x36, (char)0x36, (char)0x36, (char)0x36, (char)0x36,
	654	(char)0x36, (char)0x36, (char)0x36, (char)0x36, (char)0x36, (char)0x36,
	655	(char)0x36, (char)0x36, (char)0x36, (char)0x36, (char)0x36, (char)0x36,
	656	(char)0x36, (char)0x36, (char)0x36, (char)0x36, (char)0x36, (char)0x36
	657	};
[11]	658	static char zap[KEY_BLOCK] = {
	659	(char)0x00, (char)0x00, (char)0x00, (char)0x00, (char)0x00, (char)0x00,
	660	(char)0x00, (char)0x00, (char)0x00, (char)0x00, (char)0x00, (char)0x00,
	661	(char)0x00, (char)0x00, (char)0x00, (char)0x00, (char)0x00, (char)0x00,
	662	(char)0x00, (char)0x00, (char)0x00, (char)0x00, (char)0x00, (char)0x00
	663	};
[1]	664	char K[KEY_BLOCK];
	665	char outer[KEY_BLOCK];
	666	char * inner;
	667	UINT32 * h1;
	668	UINT32 * h2;
	669	UINT32 cc[KEY_LEN/4];
	670	char * res;
	671
	672	size_t i;
	673
	674	SL_ENTER(_("sh_util_hmac_tiger"));
	675	ASSERT((KEY_BLOCK <= (KEY_LEN/2)), _("KEY_BLOCK <= (KEY_LEN/2)"))
	676
	677	if (KEY_BLOCK > (KEY_LEN/2))
	678	{
	679	res = sh_tiger_hash (NULL, TIGER_DATA, 0);
	680	SL_RETURN(res, _("sh_util_hmac_tiger"));
	681	}
	682
[11]	683	memcpy (K, zap, KEY_BLOCK);
[1]	684
	685	if (sh_util_hextobinary (K, hexkey, KEY_LEN) < 0)
	686	{
	687	res = sh_tiger_hash (NULL, TIGER_DATA, 0);
	688	SL_RETURN(res, _("sh_util_hmac_tiger"));
	689	}
	690
[34]	691	if (sl_ok_adds(textlen, KEY_BLOCK))
	692	{
	693	inner = (char *) SH_ALLOC (textlen + KEY_BLOCK);
[1]	694
[34]	695	for (i = 0; i < KEY_BLOCK; ++i)
	696	{
	697	outer[i] = K[i] ^ opad[i];
	698	inner[i] = K[i] ^ ipad[i];
	699	}
	700	for (i = KEY_BLOCK; i < (KEY_BLOCK+textlen); ++i)
	701	{
	702	inner[i] = text[i - KEY_BLOCK];
	703	}
[1]	704	}
[34]	705	else
[1]	706	{
[34]	707	sh_error_handle((-1), FIL__, __LINE__, -1, MSG_E_SUBGEN,
	708	_("integer overflow"),
	709	_("sh_util_hmac_tiger"));
	710	res = sh_tiger_hash (NULL, TIGER_DATA, 0);
	711	SL_RETURN(res, _("sh_util_hmac_tiger"));
[1]	712	}
	713
	714	/* now compute the hash
	715	*/
	716	h1 = sh_tiger_hash_uint32 ( outer,
	717	TIGER_DATA,
	718	KEY_BLOCK);
	719	for (i = 0; i < (KEY_LEN/8); ++i)
	720	{
	721	/* cc[i] = h1[i]; */
	722	copy_four ( (unsigned char *) &(cc[i]), h1[i]);
	723	}
	724
	725	h2 = sh_tiger_hash_uint32 ( inner,
	726	TIGER_DATA,
	727	(unsigned long) KEY_BLOCK+textlen);
	728	for (i = KEY_LEN/8; i < (KEY_LEN/4); ++i)
	729	{
	730	copy_four ( (unsigned char *) &(cc[i]), h2[i - (KEY_LEN/8)]);
	731	/* cc[i] = h2[i - (KEY_LEN/8)]; */
	732	}
	733	SH_FREE(inner);
	734
	735	res = sh_tiger_hash ((char *) &cc[0],
	736	TIGER_DATA,
	737	(unsigned long) (KEY_LEN/4 * sizeof(UINT32)));
	738
	739	SL_RETURN(res, _("sh_util_hmac_tiger"));
	740	}
	741
	742	static char * sh_util_hash_tiger ( char * hexkey,
	743	char * text, size_t textlen)
	744	{
	745	char * res;
	746	char h2[2*KEY_LEN+1];
	747	SL_ENTER(_("sh_util_hash_tiger"));
	748
	749	(void) sl_strlcpy(h2, hexkey, KEY_LEN+1);
	750	(void) sl_strlcat(h2, sh_tiger_hash(text, TIGER_DATA,
	751	(unsigned long) textlen), 2*KEY_LEN+1);
	752
	753	res = sh_tiger_hash(h2, TIGER_DATA, 2*KEY_LEN);
	754
	755	SL_RETURN(res, _("sh_util_hash_tiger"));
	756	}
	757
	758	/* --- compute signature on data ---
	759	*/
	760	#define TYPE_HMAC 0
	761	#define TYPE_HASH 1
	762
	763	static int sigtype = TYPE_HMAC;
	764
[22]	765	int sh_util_sigtype (const char * c)
[1]	766	{
	767	SL_ENTER(_("sh_util_sigtype"));
	768	if (c == NULL)
	769	SL_RETURN( -1, _("sh_util_sigtype"));
	770
	771	if (0 == strcmp(_("HMAC-TIGER"), c))
	772	sigtype = TYPE_HMAC;
	773	else if (0 == strcmp(_("HASH-TIGER"), c))
	774	sigtype = TYPE_HASH;
	775	else
	776	SL_RETURN( -1, _("sh_util_sigtype"));
	777
	778	SL_RETURN( 0, _("sh_util_sigtype"));
	779	}
	780
	781	char * sh_util_siggen (char * hexkey,
	782	char * text, size_t textlen)
	783	{
	784	char * p;
	785
	786	SL_ENTER(_("sh_util_siggen"));
	787	if (sigtype == TYPE_HMAC)
	788	p = sh_util_hmac_tiger (hexkey,
	789	text, textlen);
	790	else
	791	p = sh_util_hash_tiger (hexkey,
	792	text, textlen);
	793	SL_RETURN(p, _("sh_util_siggen"));
	794	}
	795
	796
	797	/* a simple compressor
	798	*/
	799	long sh_util_compress (char * dest, char * src, size_t dest_size)
	800	{
	801	char * add;
	802	char * get;
	803	size_t count = 0;
	804	size_t dest_end;
	805
	806	SL_ENTER(_("sh_util_compress"));
	807
	808	if (dest_size == 0)
	809	SL_RETURN((0), _("sh_util_compress"));
	810
	811	if ((dest == NULL) \|\| (src == NULL))
	812	SL_RETURN((0), _("sh_util_compress"));
	813
	814	dest_end = sl_strlen(dest);
	815
	816	if (dest_end > dest_size)
	817	SL_RETURN((0), _("sh_util_compress"));
	818
	819	add = &dest[dest_end];
	820	get = src;
	821
	822	while (count < (dest_size-dest_end))
	823	{
	824	if (isalnum((int) *get))
	825	{
	826	add = get;
	827	++add;
	828	++count;
	829	}
	830	++get;
	831	if (*get == '\0' && (count < (dest_size-dest_end)))
	832	/* end of src reached */
	833	{
	834	add = get; /* copy the '\0' */
	835	break; /* and stop copying */
	836	}
	837	}
	838
	839	dest[dest_size-1] = '\0'; /* paranoia */
	840	SL_RETURN(((long)count), _("sh_util_compress")); /* no of chars copied */
	841	}
	842
	843
	844	/* copy the four least significant bytes
	845	*/
	846	void sh_util_cpylong (char * dest, const char * src, int len )
	847	{
	848	int i, j;
	849	union
	850	{
	851	long l;
	852	char c[sizeof(long)];
	853	} u;
	854
	855	SL_ENTER(_("sh_util_cpylong"));
	856
	857	u.l = 1;
	858
	859	/* MSB is first
	860	*/
	861	if (sizeof(long)>4 &&/@+charint@/(u.c[sizeof(long)-1] == 1)/@-charint@/)
	862	{
	863	j = (int) (sizeof(long)-4);
	864	for (i = 0; i < j; ++i) ++src;
	865	}
	866
	867	i = 0;
	868
	869	while (i < 4)
	870	{
	871	dest = (src);
	872	++dest; ++src;
	873	if (i == (len-1)) break;
	874	++i;
	875	}
	876	SL_RET0(_("sh_util_cpylong"));
	877	}
	878
	879	/* This is a maximally equidistributed combined Tausworthe
	880	* generator. The sequence is,
	881	*
	882	* x_n = (s1_n ^ s2_n ^ s3_n)
	883	*
	884	* s1_{n+1} = (((s1_n & 4294967294) <<12) ^ (((s1_n <<13) ^ s1_n) >>19))
	885	* s2_{n+1} = (((s2_n & 4294967288) << 4) ^ (((s2_n << 2) ^ s2_n) >>25))
	886	* s3_{n+1} = (((s3_n & 4294967280) <<17) ^ (((s3_n << 3) ^ s3_n) >>11))
	887	*
	888	* computed modulo 2^32. In the three formulas above '^' means
	889	* exclusive-or (C-notation), not exponentiation. Note that the
	890	* algorithm relies on the properties of 32-bit unsigned integers (it
	891	* is formally defined on bit-vectors of length 32).
	892	*
	893	* Stolen from GSL (GNU scientific library) and modified somewhat.
	894	* I am using UINT32, which is guaranteed to be 32 bits. Also made
	895	* sure that the initialization vector is valid.
	896	*/
	897
	898
	899	/* interval [0, 4294967296]
	900	*/
	901	static UINT32 taus_get_long (void *vstate)
	902	{
	903	UINT32 * state = (UINT32 *) vstate;
	904
	905	if (skey->rngI == BAD)
	906	(void)taus_seed();
	907
	908	#define TAUSWORTHE(s,a,b,c,d) ((s &c) <<d) ^ (((s <<a) ^s) >>b)
	909	/@+ignorequals@/
	910	state[0] = TAUSWORTHE (state[0], 13, 19, 4294967294UL, 12);
	911	state[1] = TAUSWORTHE (state[1], 2, 25, 4294967288UL, 4);
	912	state[2] = TAUSWORTHE (state[2], 3, 11, 4294967280UL, 17);
	913	/@-ignorequals@/
	914	return (state[0] ^ state[1] ^ state[2]);
	915	}
	916
	917	/* Hide the internal state of the PRNG by using its output as
	918	* input for a one-way hash function.
	919	*/
[11]	920	UINT32 taus_svec[6];
	921
[1]	922	UINT32 taus_get (void state1, void state2, void *state3)
	923	{
	924	UINT32 retval;
	925	UINT32 * res;
[13]	926	static UINT32 res_vec[6];
	927	static int res_num = 0;
[1]	928	register int i;
	929
[13]	930	if (res_num > 0)
	931	{
	932	retval = res_vec[res_num];
	933	res_num = (res_num == 5) ? 0 : (res_num + 1);
	934	return retval;
	935	}
	936
[11]	937	taus_svec[0] = taus_get_long (state1);
	938	taus_svec[1] = taus_get_long (state2);
	939	taus_svec[2] = taus_get_long (state3);
	940	taus_svec[3] = taus_get_long (state1);
	941	taus_svec[4] = taus_get_long (state2);
	942	taus_svec[5] = taus_get_long (state3);
[1]	943
[11]	944	res = sh_tiger_hash_uint32 ( (char *) &taus_svec[0],
[1]	945	TIGER_DATA,
	946	(unsigned long)(6 * sizeof(UINT32)));
	947
[13]	948	for (i = 1; i < 6; ++i)
[11]	949	{
[13]	950	res_vec[i] = res[i];
[11]	951	}
[13]	952	retval = taus_svec[0];
	953	res_num = 1;
[1]	954
[11]	955	taus_svec[0] = 0; taus_svec[1] = 0; taus_svec[2] = 0;
	956	taus_svec[3] = 0; taus_svec[4] = 0; taus_svec[5] = 0;
[1]	957
	958	return retval;
	959	}
	960
	961	/* interval [0,1)
	962	*/
	963	double taus_get_double (void *vstate)
	964	{
	965	return taus_get_long (vstate) / (4294967296.0 + 1.0) ;
	966	}
	967
	968	#define LCG(n) ((69069 * n) & 0xffffffffUL)
	969
	970	/* TAKE CARE: state[0], state[1], state[2] must be > 2,8,16, respectively
	971	*/
	972	static void taus_set_from_ulong (void *vstate, unsigned long int s)
	973	{
	974	UINT32 state = (UINT32 ) vstate;
	975
	976	if (s == 0)
	977	s = 1; /* default seed is 1 */
	978
	979	state[0] = (UINT32)(LCG (s) \| (UINT32) 0x03);
	980	state[1] = (UINT32)(LCG (state[0]) \| (UINT32) 0x09);
	981	state[2] = (UINT32)(LCG (state[1]) \| (UINT32) 0x17);
	982
	983	/* 'warm up'
	984	*/
	985	(void) taus_get_long (state);
	986	(void) taus_get_long (state);
	987	(void) taus_get_long (state);
	988	(void) taus_get_long (state);
	989	(void) taus_get_long (state);
	990	(void) taus_get_long (state);
	991
	992	return;
	993	}
	994
	995	static void taus_set_from_state (void vstate, void init_state)
	996	{
	997	UINT32 state = (UINT32 ) vstate;
	998	UINT32 state0 = (UINT32 ) init_state;
	999
	1000	state[0] = state0[0] \| (UINT32) 0x03;
	1001	state[1] = state0[1] \| (UINT32) 0x09;
	1002	state[2] = state0[2] \| (UINT32) 0x17;
	1003
	1004	return;
	1005	}
	1006
	1007
	1008	int taus_seed ()
	1009	{
	1010	char bufx[9 * sizeof(UINT32) + 1];
	1011	int status;
	1012	static unsigned long seed_time = 0;
	1013
	1014	SL_ENTER(_("taus_seed"));
	1015
	1016	if (skey->rngI == GOOD)
	1017	{
	1018	if ( (sh_unix_longtime () - seed_time) < 3600)
	1019	SL_RETURN( (0), _("taus_seed"));
	1020	}
	1021
	1022	seed_time = sh_unix_longtime ();
	1023
	1024	status = sh_entropy (24, bufx);
	1025
	1026	if (!SL_ISERROR(status))
	1027	{
	1028	skey->rngI = GOOD;
	1029	memcpy (&skey->rng0[0], &bufx[0], 2*sizeof(UINT32));
	1030	memcpy (&skey->rng1[0], &bufx[2sizeof(UINT32)], 2sizeof(UINT32));
	1031	memcpy (&skey->rng2[0], &bufx[4sizeof(UINT32)], 2sizeof(UINT32));
	1032	memset (bufx, 0, 9 * sizeof(UINT32) + 1);
	1033
	1034	skey->rng0[2] = 0;
	1035	skey->rng1[2] = 0;
	1036	skey->rng2[2] = 0;
	1037
	1038	taus_set_from_state( &(skey->rng0[0]), &(skey->rng0[0]));
	1039	taus_set_from_state( &(skey->rng1[0]), &(skey->rng1[0]));
	1040	taus_set_from_state( &(skey->rng2[0]), &(skey->rng2[0]));
	1041
	1042	SL_RETURN( (0), _("taus_seed"));
	1043	}
	1044
	1045	sh_error_handle ((-1), FIL__, __LINE__, status, MSG_ES_ENT,
	1046	_("sh_entropy"));
	1047
	1048	/* emergency backup - unsafe !
	1049	*/
	1050	skey->rngI = GOOD;
	1051	#ifdef HAVE_GETTIMEOFDAY
	1052	taus_set_from_ulong ( &(skey->rng0[0]), LCG (sh_unix_notime()) );
	1053	#else
	1054	taus_set_from_ulong ( &(skey->rng0[0]), LCG (seed_time) );
	1055	#endif
	1056	taus_set_from_ulong ( &(skey->rng1[0]), LCG (skey->rng0[0]) );
	1057	taus_set_from_ulong ( &(skey->rng2[0]), LCG (skey->rng1[0]) );
	1058	skey->rngI = BAD;
	1059
	1060	SL_RETURN( (-1), _("taus_seed"));
	1061	}
	1062
	1063	/@+charint@/
	1064	static unsigned char new_key[] = { 0xA7,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xA7 };
	1065	/@-charint@/
	1066	static void copy_four (unsigned char * dest, UINT32 in);
	1067
[20]	1068	int sh_util_set_newkey (const char * new_in)
[1]	1069	{
	1070	size_t i, j = 0;
	1071	size_t len;
	1072	SL_TICKET fp;
	1073	SL_TICKET fout;
	1074	char * key;
	1075	char * path;
[22]	1076	char * outpath = NULL;
[1]	1077	unsigned char * image = NULL;
	1078	long s = 0;
	1079	long ilen = 0;
	1080	long ii, k = 0;
	1081	UINT32 * h1;
[22]	1082	char * new = NULL;
[1]	1083
	1084	if (0 != sl_is_suid())
	1085	{
	1086	fprintf(stderr, _("ERROR: insufficient privilege\n"));
	1087	_exit (EXIT_FAILURE);
	1088	/@notreached@/
	1089	return -1; /* braindead MAC OSX compiler needs this */
	1090	}
	1091
[20]	1092	if (new_in == NULL \|\| new_in[0] == '\0')
[1]	1093	{
	1094	fprintf(stderr,
	1095	_("ERROR: no key given\n Argument must be 'key@path'\n"));
	1096	_exit (EXIT_FAILURE);
	1097	/@notreached@/
	1098	return -1;
	1099	}
[20]	1100
	1101	if (NULL == (new = malloc(strlen(new_in) + 1)))
	1102	goto bail_mem;
	1103	sl_strncpy(new, new_in, strlen(new_in) + 1);
	1104
[1]	1105	key = new;
	1106	len = strlen(new);
	1107	for (i = 1; i < (len-2); ++i)
	1108	{
	1109	if (new[i] == '@' && new[i+1] == '/')
	1110	{
	1111	j = i+1; new[i] = '\0'; break;
	1112	}
	1113	}
	1114	if (j == 0)
	1115	{
	1116	fprintf(stderr,
	1117	_("ERROR: no path to executable given\n Argument must be 'key@path'\n"));
[22]	1118	free(new);
[1]	1119	_exit (EXIT_FAILURE);
	1120	/@notreached@/
	1121	return -1;
	1122	}
	1123	else
	1124	path = &new[j];
[22]	1125
	1126	len = strlen(path) + 1 + 4;
[1]	1127	/@-usedef@/
[22]	1128	if (NULL == (outpath = malloc(len)))
[1]	1129	goto bail_mem;
	1130	/@-usedef@/
[22]	1131	sl_snprintf (outpath, len, _("%s.out"), path);
[1]	1132
	1133	fp = sl_open_read(path, SL_NOPRIV);
	1134	if (SL_ISERROR(fp))
	1135	{
	1136	fprintf(stderr,
	1137	_("ERROR: cannot open %s for read (errnum = %ld)\n"), path, fp);
[22]	1138	free(new); free (outpath);
[1]	1139	_exit (EXIT_FAILURE);
	1140	/@notreached@/
	1141	return -1;
	1142	}
	1143
	1144	fout = sl_open_write(outpath, SL_NOPRIV);
	1145	if (SL_ISERROR(fout))
	1146	{
	1147	fprintf(stderr,
	1148	_("ERROR: cannot open %s (errnum = %ld)\n"), outpath, fout);
[22]	1149	free(new); free (outpath);
[1]	1150	_exit (EXIT_FAILURE);
	1151	/@notreached@/
	1152	return -1;
	1153	}
	1154
	1155
	1156	image = malloc (4096);
	1157	if (!image)
	1158	goto bail_mem;
	1159	while (0 < (ii = sl_read (fp, &image[s], 4096)))
	1160	{
	1161	ilen += ii;
	1162	s += 4096;
	1163	image = realloc (image, (size_t) (4096 + s));
	1164	if (!image)
	1165	goto bail_mem;
	1166	}
	1167
	1168	printf(_("%ld bytes read\n"), ilen);
	1169
	1170
	1171	for (k = 0; k < (ilen - 8); ++k)
	1172	{
	1173	if (image[k] == new_key[0] &&
	1174	image[k+1] == new_key[1] &&
	1175	image[k+2] == new_key[2] &&
	1176	image[k+3] == new_key[3] &&
	1177	image[k+4] == new_key[4] &&
	1178	image[k+5] == new_key[5] &&
	1179	image[k+6] == new_key[6] &&
	1180	image[k+7] == new_key[7])
	1181	{
	1182	printf(_("old key found\n"));
	1183	h1 = sh_tiger_hash_uint32 (key, TIGER_DATA,
	1184	(unsigned long)strlen(key));
	1185	copy_four( (unsigned char *) &(image[k]), h1[0]);
	1186	copy_four( (unsigned char *) &(image[k+4]), h1[1]);
	1187	(void) sl_write (fout, image, ilen);
	1188	(void) sl_close (fout);
	1189	printf(_("new file %s written\n"), outpath);
[22]	1190	free(new); free (outpath); free(image);
[1]	1191	_exit (EXIT_SUCCESS);
	1192	/@notreached@/
	1193	return 0;
	1194	}
	1195	}
	1196
	1197	fprintf(stderr,
	1198	_("ERROR: old key not found\n"));
[22]	1199	free(new); free (outpath); free(image);
[1]	1200	_exit (EXIT_FAILURE);
	1201	/@notreached@/
	1202	return -1;
	1203
	1204
	1205	bail_mem:
	1206	fprintf(stderr,
	1207	_("ERROR: out of memory\n"));
[22]	1208	if (new) free(new);
	1209	if (outpath) free (outpath);
	1210	if (image) free (image);
[1]	1211	_exit (EXIT_FAILURE);
	1212	/@notreached@/
	1213	return -1;
	1214	}
	1215
	1216
	1217
	1218
	1219	/* A simple en-/decoder, based on Vernam cipher. We use the
	1220	* message as salt to hide the key by obtaining a different one-time
	1221	* pad each time.
	1222	* Should be safe against a listener on the network, but not against someone
	1223	* with read access to the binary.
	1224	*/
	1225	void sh_util_encode (char * data, char * salt, int mode, char fill)
	1226	{
	1227	static char cc1[17] = N_("0123456789ABCDEF");
	1228	char cc[17] = "\0";
	1229	register int i, j, j1 = 0, j2 = 0, j3;
	1230	char * dez;
	1231
	1232	SL_ENTER(_("sh_util_encode"));
	1233
	1234	/* init
	1235	*/
	1236	(void) sl_strlcpy( cc, _(cc1), sizeof(cc));
	1237
	1238	/* max 128 bits keyspace
	1239	*/
	1240	memset (skey->vernam, (int)fill, KEY_LEN+1);
	1241
	1242	dez = (char *) &(skey->ErrFlag[0]);
	1243	sh_util_cpylong (skey->vernam, dez, 4);
	1244	dez = (char *) &(skey->ErrFlag[1]);
	1245	sh_util_cpylong (&skey->vernam[4], dez, 4);
	1246
	1247	skey->vernam[KEY_LEN] = '\0';
	1248
	1249	(void) sl_strlcpy(skey->vernam,
	1250	sh_tiger_hash(skey->vernam, TIGER_DATA, KEY_LEN),
	1251	KEY_LEN+1);
	1252
	1253	(void) sl_strlcpy(skey->vernam,
	1254	sh_util_hmac_tiger (skey->vernam, salt, strlen(salt)),
	1255	KEY_LEN+1);
	1256
	1257	(void) sl_strlcpy(skey->vernam,
	1258	sh_util_hmac_tiger (skey->vernam, (char*) new_key, 8),
	1259	KEY_LEN+1);
	1260
	1261	/* The following routine adds/subtracts data[j] and vernam[j] mod 16.
	1262	*/
	1263	j = 0;
	1264	while (j < KEY_LEN)
	1265	{
	1266	for (i = 0; i < 16; ++i)
	1267	{
	1268	if (cc[i] == data[j]) j1 = i;
	1269	if (cc[i] == skey->vernam[j]) j2 = i;
	1270	}
	1271	if (mode == 0)
	1272	{
	1273	j3 = j1 + j2;
	1274	if (j3 > 15) j3 -= 16;
	1275	data[j] = cc[j3];
	1276	}
	1277	else
	1278	{
	1279	j3 = j1 - j2;
	1280	if (j3 < 0) j3 += 16;
	1281	data[j] = cc[j3];
	1282	}
	1283	++j;
	1284	}
	1285	SL_RET0(_("sh_util_encode"));
	1286	}
	1287
	1288	/* server mode
	1289	*/
[20]	1290	int sh_util_setserver (const char * dummy)
[1]	1291	{
	1292	SL_ENTER(_("sh_util_setserver"));
	1293
[20]	1294	(void) dummy;
	1295	sh.flag.isserver = GOOD;
[1]	1296	SL_RETURN((0),_("sh_util_setserver"));
	1297	}
	1298
	1299
[20]	1300	int sh_util_setlooptime (const char * str)
[1]	1301	{
	1302	int i = atoi (str);
	1303
	1304	SL_ENTER(_("sh_util_setlooptime"));
	1305
	1306	if (i >= 0 && i < INT_MAX) {
	1307	sh.looptime = i;
	1308	SL_RETURN((0),_("sh_util_setlooptime"));
	1309	} else {
	1310	sh_error_handle ((-1), FIL__, __LINE__, EINVAL, MSG_EINVALS,
	1311	_("loop time"), str);
	1312	SL_RETURN((-1),_("sh_util_setlooptime"));
	1313	}
	1314	}
	1315
	1316	#if defined (SH_WITH_CLIENT) \|\| defined (SH_STANDALONE)
[20]	1317	int sh_util_setchecksum (const char * str)
[1]	1318	{
	1319	static int reject = 0;
	1320
	1321	SL_ENTER(_("sh_util_setchecksum"));
	1322
	1323	if (reject == 1)
	1324	SL_RETURN((0), _("sh_util_setchecksum"));
	1325	reject = 1;
	1326
	1327	if (sl_strncmp (str, _("init"), sizeof("init")-1) == 0)
	1328	{
	1329	sh.flag.checkSum = SH_CHECK_INIT;
	1330	}
	1331	else if (sl_strncmp (str, _("update"), sizeof("update")-1) == 0)
	1332	{
	1333	if (S_TRUE == file_is_remote())
	1334	{
	1335	sh_error_handle ((-1), FIL__, __LINE__, EINVAL, MSG_EINVALS,
	1336	_("checksum testing"), str);
	1337	SL_RETURN((-1), _("sh_util_setchecksum"));
	1338	}
	1339	else
	1340	{
	1341	sh.flag.checkSum = SH_CHECK_CHECK;
	1342	sh.flag.update = S_TRUE;
	1343	}
	1344	}
	1345	else if (sl_strncmp (str, _("check"), sizeof("check")-1) == 0)
	1346	{
	1347	sh.flag.checkSum = SH_CHECK_CHECK;
	1348	}
	1349	/*
	1350	else if (sl_strncmp (str, _("update"), sizeof("update")-1) == 0)
	1351	{
	1352	sh.flag.checkSum = SH_CHECK_INIT;
	1353	sh.flag.update = S_TRUE;
	1354	}
	1355	*/
	1356	else if (sl_strncmp (str, _("none"), sizeof("none")-1) == 0)
	1357	{
	1358	sh.flag.checkSum = SH_CHECK_NONE;
	1359	}
	1360	else
	1361	{
	1362	sh_error_handle ((-1), FIL__, __LINE__, EINVAL, MSG_EINVALS,
	1363	_("checksum testing"), str);
	1364	SL_RETURN((-1), _("sh_util_setchecksum"));
	1365	}
	1366	SL_RETURN((0), _("sh_util_setchecksum"));
	1367	}
	1368	#endif
	1369
	1370	/@+charint@/
	1371	unsigned char TcpFlag[8][PW_LEN+1] = {
	1372	#if (POS_TF == 1)
	1373	{ 0xF7,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xF7,0x00 },
	1374	#endif
	1375	{ 0xFF,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xFF,0x00 },
	1376	#if (POS_TF == 2)
	1377	{ 0xF7,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xF7,0x00 },
	1378	#endif
	1379	{ 0xFF,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xFF,0x00 },
	1380	#if (POS_TF == 3)
	1381	{ 0xF7,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xF7,0x00 },
	1382	#endif
	1383	{ 0xFF,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xFF,0x00 },
	1384	#if (POS_TF == 4)
	1385	{ 0xF7,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xF7,0x00 },
	1386	#endif
	1387	{ 0xFF,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xFF,0x00 },
	1388	#if (POS_TF == 5)
	1389	{ 0xF7,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xF7,0x00 },
	1390	#endif
	1391	{ 0xFF,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xFF,0x00 },
	1392	#if (POS_TF == 6)
	1393	{ 0xF7,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xF7,0x00 },
	1394	#endif
	1395	{ 0xFF,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xFF,0x00 },
	1396	#if (POS_TF == 7)
	1397	{ 0xF7,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xF7,0x00 },
	1398	#endif
	1399	{ 0xFF,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xFF,0x00 },
	1400	#if (POS_TF == 8)
	1401	{ 0xF7,0xC3,0x12,0xAA,0xAA,0x12,0xC3,0xF7,0x00 },
	1402	#endif
	1403	};
	1404	/@-charint@/
	1405
	1406	/* initialize a key to a random value
	1407	* rev 0.8
	1408	*/
	1409	int sh_util_keyinit (char * buf, long size)
	1410	{
	1411	UINT32 bufy[6];
	1412	int i;
	1413	int status = 0;
	1414	char * p;
	1415
	1416	SL_ENTER(_("sh_util_keyinit"));
	1417
	1418	ASSERT((size <= KEY_LEN+1), _("size <= KEY_LEN+1"))
	1419
	1420	if (size > KEY_LEN+1)
	1421	size = KEY_LEN+1;
	1422
	1423	/* seed / re-seed the PRNG if required
	1424	*/
	1425	status = taus_seed ();
	1426
	1427	if (status == -1)
	1428	sh_error_handle ((-1), FIL__, __LINE__, -1, MSG_ES_KEY1,
	1429	_("taus_seed"));
	1430
	1431	for (i = 0; i < 6; ++i)
	1432	bufy[i] = taus_get(&(skey->rng0[0]), &(skey->rng1[0]), &(skey->rng2[0]));
	1433
	1434	p = sh_tiger_hash ((char *) bufy, TIGER_DATA,
	1435	(unsigned long)(6*sizeof(UINT32)));
	1436	p[size-1] = '\0';
	1437
	1438	i = sl_strlcpy(buf, p, (size_t)size);
	1439
	1440	memset (bufy, 0, 6*sizeof(UINT32));
	1441
	1442	if ((status == 0) && (!SL_ISERROR(i)) )
	1443	SL_RETURN((0),_("sh_util_keyinit"));
	1444
	1445	if (SL_ISERROR(i))
	1446	sh_error_handle ((-1), FIL__, __LINE__, i, MSG_ES_KEY2,
	1447	_("sl_strlcpy"));
	1448
	1449	SL_RETURN((-1),_("sh_util_keyinit"));
	1450	}
	1451
	1452	#if defined(SH_WITH_CLIENT) \|\| defined(SH_STANDALONE)
	1453
	1454	static unsigned char sh_obscure_index[256];
[76]	1455	static int sh_obscure_no_check = S_FALSE;
[1]	1456
[68]	1457	int sh_util_valid_utf8 (const unsigned char * str)
	1458	{
[76]	1459	const int sh_val_utf8_1 = 1;
	1460	const int sh_val_utf8_2 = 2;
	1461	const int sh_val_utf8_3 = 3;
	1462	const int sh_val_utf8_4 = 4;
	1463
[68]	1464	size_t len = strlen((char *)str);
	1465	size_t l = 0;
[76]	1466	int typ = 0;
	1467	unsigned char c = '\0';
	1468	unsigned char c2[2] = { 0x00, 0x00 };
	1469	unsigned char c3[3] = { 0x00, 0x00, 0x00 };
[68]	1470
[76]	1471
[68]	1472	#define SH_VAL_UTF8_1 ((c != '\0') && ((c & 0x80) == 0x00))
	1473	#define SH_VAL_UTF8_2 ((c != '\0') && ((c & 0xE0) == 0xC0)) /* 110x xxxx */
	1474	#define SH_VAL_UTF8_3 ((c != '\0') && ((c & 0xF0) == 0xE0)) /* 1110 xxxx */
	1475	#define SH_VAL_UTF8_4 ((c != '\0') && ((c & 0xF8) == 0xF0)) /* 1111 0xxx */
	1476	#define SH_VAL_UTF8_N ((c != '\0') && ((c & 0xC0) == 0x80)) /* 10xx xxxx */
[76]	1477	#define SH_VAL_BAD ((c == '"') \|\| (c == '\t') \|\| (c == '\b') \|\| \
	1478	(c == '\f') \|\| (c == '\n') \|\| \
[68]	1479	(c == '\r') \|\| (c == '\v') \|\| iscntrl((int) c) \|\| \
	1480	(c != ' ' && !isgraph ((int) c)))
	1481
	1482	while(l < len)
	1483	{
	1484	c = str[l];
	1485
	1486	if (SH_VAL_UTF8_1)
	1487	{
[76]	1488	if (!(SH_VAL_BAD && (sh_obscure_index[c] != 1)))
	1489	{
	1490	typ = sh_val_utf8_1;
	1491	++l; continue;
	1492	}
	1493	else
	1494	{
	1495	return S_FALSE;
	1496	}
[68]	1497	}
	1498	else if (SH_VAL_UTF8_2)
	1499	{
[76]	1500	typ = sh_val_utf8_2;
	1501	c2[0] = c;
	1502	if ((c & 0x3e) != 0x00) /* !(overlong 2-byte seq.) */
	1503	{
	1504	++l;
	1505	if (l != len) {
	1506	c = str[l];
	1507	if(SH_VAL_UTF8_N) {
	1508	c2[1] = c;
	1509	++l; continue;
	1510	}
	1511	else {
	1512	return S_FALSE;
	1513	}
	1514	}
	1515	else {
	1516	return S_FALSE;
	1517	}
	1518	}
	1519	else
	1520	{
	1521	return S_FALSE; /* overlong 2-byte seq. */
	1522	}
[68]	1523	}
	1524	else if (SH_VAL_UTF8_3)
	1525	{
[76]	1526	typ = sh_val_utf8_3;
	1527	c3[0] = c;
[68]	1528	++l; if (l == len) return S_FALSE; c = str[l];
	1529	if(!SH_VAL_UTF8_N) return S_FALSE;
	1530	if (((str[l-1] & 0x1F) == 0x00) && ((c & 0x60) == 0x00))
	1531	return S_FALSE; /* overlong 3-byte seq. */
[76]	1532	c3[1] = c;
[68]	1533	++l; if (l == len) return S_FALSE; c = str[l];
	1534	if(!SH_VAL_UTF8_N) return S_FALSE;
[76]	1535	c3[2] = c;
[68]	1536	++l; continue;
	1537	}
	1538	else if (SH_VAL_UTF8_4)
	1539	{
[76]	1540	typ = sh_val_utf8_4;
[68]	1541	++l; if (l == len) return S_FALSE; c = str[l];
	1542	if(!SH_VAL_UTF8_N) return S_FALSE;
	1543	if (((str[l-1] & 0x0F) == 0x00) && ((c & 0x70) == 0x00))
	1544	return S_FALSE; /* overlong 4-byte seq. */
	1545	++l; if (l == len) return S_FALSE; c = str[l];
	1546	if(!SH_VAL_UTF8_N) return S_FALSE;
	1547	++l; if (l == len) return S_FALSE; c = str[l];
	1548	if(!SH_VAL_UTF8_N) return S_FALSE;
	1549	++l; continue;
	1550	}
	1551	return S_FALSE;
	1552	}
[76]	1553
	1554	/* last character is invisible (space or else)
	1555	*/
	1556	if (typ == sh_val_utf8_1)
	1557	{
	1558	if (c != ' ')
	1559	return S_TRUE;
	1560	else
	1561	return S_FALSE;
	1562	}
	1563	else if (typ == sh_val_utf8_2)
	1564	{
	1565	if (c2[0] == 0xC2 && c2[1] == 0xA0) /* nbsp */
	1566	return S_FALSE;
	1567	else
	1568	return S_TRUE;
	1569	}
	1570	else if (typ == sh_val_utf8_3)
	1571	{
	1572	if (c3[0] == 0xE2)
	1573	{
	1574	if (c3[1] == 0x80 && c3[2] >= 0x80 && c3[2] <= 0x8F)
	1575	return S_FALSE; /* various spaces, left-to-right, right-to-left */
	1576	else if (c3[1] == 0x80 && (c3[2] == 0xA8 \|\| c3[2] == 0xA9 \|\|
	1577	c3[2] == 0xAD \|\| c3[2] == 0xAF))
	1578	return S_FALSE; /* line sep, para sep, zw word joiner, nnbsp */
	1579	else if (c3[1] == 0x81 && (c3[2] == 0xA0 \|\| c3[2] == 0xA1 \|\|
	1580	c3[2] == 0x9F))
	1581	return S_FALSE; /* word joiner, function app, math space */
	1582	else
	1583	return S_TRUE;
	1584	}
	1585	else if (c3[0] == 0xE3 && c3[1] == 0x80 && c3[2] == 0x80)
	1586	{
	1587	return S_FALSE; /* ideographic space */
	1588	}
	1589	else if (c3[0] == 0xEF && c3[1] == 0xBB && c3[2] == 0xBF)
	1590	{
	1591	return S_FALSE; /* zwnbsp */
	1592	}
	1593	else
	1594	{
	1595	return S_TRUE;
	1596	}
	1597	}
	1598	else
	1599	{
	1600	return S_TRUE;
	1601	}
[68]	1602	}
	1603
	1604
[22]	1605	int sh_util_obscure_ok (const char * str)
[1]	1606	{
	1607	unsigned long i;
[22]	1608	char * endptr = NULL;
[1]	1609
[29]	1610	SL_ENTER(_("sh_util_obscure_ok"));
[1]	1611
	1612	if (0 == sl_strncmp("all", str, 3))
	1613	{
	1614	for (i = 0; i < 255; ++i)
	1615	{
	1616	sh_obscure_index[i] = (unsigned char)1;
	1617	}
[76]	1618	sh_obscure_no_check = S_TRUE;
[29]	1619	SL_RETURN(0, _("sh_util_obscure_ok"));
[1]	1620	}
	1621
[76]	1622	sh_obscure_no_check = S_FALSE;
	1623
[1]	1624	for (i = 0; i < 255; ++i)
	1625	{
	1626	sh_obscure_index[i] = (unsigned char)0;
	1627	}
	1628
[22]	1629	i = strtoul (str, &endptr, 0);
	1630	if (i > 255)
	1631	{
[29]	1632	SL_RETURN(-1, _("sh_util_obscure_ok"));
[22]	1633	}
	1634	sh_obscure_index[i] = (unsigned char)1;
	1635	if (*endptr == ',')
	1636	++endptr;
	1637
[1]	1638	while (*endptr != '\0')
	1639	{
	1640	i = strtoul (endptr, &endptr, 0);
	1641	if (i > 255)
	1642	{
[29]	1643	SL_RETURN(-1, _("sh_util_obscure_ok"));
[1]	1644	}
	1645	sh_obscure_index[i] = (unsigned char)1;
	1646	if (*endptr == ',')
	1647	++endptr;
	1648	}
[29]	1649	SL_RETURN(0, _("sh_util_obscure_ok"));
[1]	1650	}
	1651
[68]	1652	static int sh_obscure_check_utf8 = S_FALSE;
	1653
	1654	int sh_util_obscure_utf8 (const char * c)
	1655	{
	1656	int i;
	1657	SL_ENTER(_("sh_util_obscure_utf8"));
	1658	i = sh_util_flagval(c, &(sh_obscure_check_utf8));
[76]	1659	if (sh_obscure_check_utf8 == S_TRUE)
	1660	sh_obscure_no_check = S_FALSE;
[68]	1661	SL_RETURN(i, _("sh_util_obscure_utf8"));
	1662	}
	1663
	1664
[1]	1665	int sh_util_obscurename (ShErrLevel level, char * name_orig, int flag)
	1666	{
[29]	1667	unsigned char * name = (unsigned char *) name_orig;
[1]	1668	char * safe;
	1669	unsigned int i;
[76]	1670	size_t len = 0;
[1]	1671
	1672	SL_ENTER(_("sh_util_obscurename"));
	1673
	1674	ASSERT_RET((name != NULL), _("name != NULL"), (0))
	1675
[76]	1676	if (sh_obscure_no_check == S_FALSE)
[68]	1677	{
[76]	1678	if (sh_obscure_check_utf8 != S_TRUE)
[68]	1679	{
[76]	1680	/* -- Check name. --
	1681	*/
	1682	while (*name != '\0')
	1683	{
	1684	if ( (name) > 0x7F \|\| (name) == '"' \|\| (*name) == '\t' \|\|
	1685	(name) == '\b' \|\| (name) == '\f' \|\|
	1686	(name) == '\n' \|\| (name) == '\r' \|\|
	1687	(name) == '\v' \|\| iscntrl((int) name) \|\|
	1688	((name) != ' ' && !isgraph ((int) name)) )
	1689	{
	1690	i = (unsigned char) *name;
	1691	if (sh_obscure_index[i] != (unsigned char)1)
	1692	{
	1693	goto err;
	1694	}
	1695	}
	1696	name++; ++len;
	1697	}
	1698
	1699	/* Check for blank at end of name
	1700	*/
	1701	if ((len > 0) && (name_orig[len-1] == ' '))
	1702	{
	1703	goto err;
	1704	}
[68]	1705	}
[76]	1706	else
[1]	1707	{
[76]	1708	if (S_FALSE == sh_util_valid_utf8(name))
[1]	1709	{
[68]	1710	goto err;
[1]	1711	}
[76]	1712	SL_RETURN((0),_("sh_util_obscurename"));
[1]	1713	}
	1714	}
[76]	1715
[1]	1716	SL_RETURN((0),_("sh_util_obscurename"));
[68]	1717
	1718	err:
[76]	1719
[68]	1720	if (flag == S_TRUE)
	1721	{
	1722	safe = sh_util_safe_name (name_orig);
	1723	sh_error_handle (level, FIL__, __LINE__, 0, MSG_FI_OBSC,
	1724	safe);
	1725	SH_FREE(safe);
	1726	}
	1727	SL_RETURN((-1),_("sh_util_obscurename"));
[1]	1728	}
[68]	1729
[1]	1730	#endif
	1731
	1732	/* returns freshly allocated memory, return value should be free'd
	1733	*/
[34]	1734	char * sh_util_dirname(const char * fullpath)
[1]	1735	{
	1736	char * retval;
[34]	1737	size_t len;
[93]	1738	char * tmp;
[1]	1739
[34]	1740	SL_ENTER(_("sh_util_dirname"));
[1]	1741
	1742	ASSERT_RET ((fullpath != NULL), _("fullpath != NULL"), (NULL))
[93]	1743	ASSERT_RET ((fullpath == '/'), _("fullpath == '/'"), (NULL))
[1]	1744
[93]	1745	retval = sh_util_strdup(fullpath);
[1]	1746
[93]	1747	tmp = retval;
	1748	while (*tmp == '/') ++tmp;
[34]	1749
[93]	1750	/* (1) only leading slashes -- return exact copy
	1751	*/
	1752	if (*tmp == '\0')
	1753	{
	1754	SL_RETURN(retval, _("sh_util_dirname"));
	1755	}
	1756
	1757	/* (2) there are non-slash characters, so delete trailing slashes
	1758	*/
	1759	len = sl_strlen (retval); /* retval[len] is terminating '\0' */
	1760
	1761	while (len > 1 && retval[len-1] == '/') /* delete trailing slash */
	1762	{
	1763	retval[len-1] = '\0';
	1764	--len;
	1765	}
	1766
	1767	/* (3) now delete all non-slash characters up to the preceding slash
	1768	*/
	1769	while (len > 1 && retval[len-1] != '/') {
	1770	retval[len-1] = '\0';
[34]	1771	--len;
[1]	1772	}
	1773
[93]	1774	/* (4a) only leading slashes left, so return this
[1]	1775	*/
[93]	1776	if (&(retval[len]) == tmp)
	1777	{
	1778	SL_RETURN(retval, _("sh_util_dirname"));
[34]	1779	}
[1]	1780
[93]	1781	/* (4b) strip trailing slash(es) of parent directory
	1782	*/
	1783	while (len > 1 && retval[len-1] == '/') {
	1784	retval[len-1] = '\0';
	1785	--len;
	1786	}
	1787	SL_RETURN(retval, _("sh_util_dirname"));
[1]	1788
	1789	}
	1790
	1791	/* returns freshly allocated memory, return value should be free'd
	1792	*/
[34]	1793	char * sh_util_basename(const char * fullpath)
[1]	1794	{
[93]	1795	char * retval = NULL;
	1796	const char * tmp;
	1797	char * tmp2;
	1798	char * c;
	1799	size_t len;
[1]	1800
[34]	1801	SL_ENTER(_("sh_util_basename"));
[1]	1802
	1803	ASSERT_RET ((fullpath != NULL), _("fullpath != NULL"), (NULL))
	1804
[93]	1805	tmp = fullpath; while (*tmp == '/') ++tmp;
	1806	if (*tmp == '\0')
[34]	1807	{
[93]	1808	retval = sh_util_strdup(fullpath);
[34]	1809	}
	1810	else
	1811	{
[93]	1812	tmp2 = sh_util_strdup(tmp);
	1813	len = sl_strlen (tmp2);
	1814
	1815	while (len > 1 && tmp2[len-1] == '/')
[34]	1816	{
[93]	1817	tmp2[len-1] = '\0';
	1818	--len;
	1819	}
	1820
	1821	c = strrchr(tmp2, '/');
	1822	if (c)
	1823	{
[34]	1824	retval = sh_util_strdup(++c);
[93]	1825	SH_FREE(tmp2);
[34]	1826	}
	1827	else
	1828	{
[93]	1829	retval = tmp2;
[34]	1830	}
	1831	}
[1]	1832
[34]	1833	SL_RETURN(retval, _("sh_util_basename"));
[1]	1834	}
	1835
	1836
	1837	/* returns freshly allocated memory, return value should be free'd
	1838	*/
	1839	char * sh_util_safe_name (const char * name)
	1840	{
	1841	register int i = 0;
	1842	const char * p;
	1843	char * retval;
	1844	char oct[32];
	1845	char format[16];
[34]	1846	size_t len;
[1]	1847
	1848	SL_ENTER(_("sh_util_safe_name"));
	1849
	1850	if (name == NULL)
	1851	{
	1852	/* return an allocated array
	1853	*/
	1854	retval = SH_ALLOC(7);
	1855	(void) sl_strlcpy(retval, _("(null)"), 7);
	1856	SL_RETURN(retval, _("sh_util_safe_name"));
	1857	}
	1858
	1859	/*
	1860	ASSERT_RET ((name != NULL), _("name != NULL"), _("NULL"))
	1861	*/
	1862
[34]	1863	len = sl_strlen(name);
	1864	p = name;
	1865
[1]	1866	#ifdef SH_USE_XML
[34]	1867	if (sl_ok_muls (6, len) && sl_ok_adds ((6*len), 2))
	1868	{ retval = SH_ALLOC(6 * len + 2); }
	1869	else
	1870	{
	1871	/* return an allocated array
	1872	*/
	1873	retval = SH_ALLOC(11);
	1874	(void) sl_strlcpy(retval, _("(overflow)"), 11);
	1875	SL_RETURN(retval, _("sh_util_safe_name"));
	1876	}
[1]	1877	#else
[34]	1878	if (sl_ok_muls (4, len) && sl_ok_adds ((4*len), 2))
	1879	{ retval = SH_ALLOC(4 * len + 2); }
	1880	else
	1881	{
	1882	/* return an allocated array
	1883	*/
	1884	retval = SH_ALLOC(11);
	1885	(void) sl_strlcpy(retval, _("(overflow)"), 11);
	1886	SL_RETURN(retval, _("sh_util_safe_name"));
	1887	}
[1]	1888	#endif
	1889
	1890	(void) sl_strncpy(format, _("%c%03o"), 16);
	1891
	1892	while (*p != '\0') {
	1893	/* Most frequent cases first
	1894	*/
	1895	if ( ((p) >= 'a' && (p) <= 'z') \|\| ((p) == '/') \|\| ((p) == '.') \|\|
	1896	((p) >= '0' && (p) <= '9') \|\|
	1897	((p) >= 'A' && (p) <= 'Z')) {
	1898	retval[i] = *p;
	1899	} else if ( (p) == '\\') { / backslash */
	1900	retval[i] = '\\'; ++i;
	1901	retval[i] = '\\';
	1902	} else if ( (p) == '\n') { / newline */
	1903	retval[i] = '\\'; ++i;
	1904	retval[i] = 'n';
	1905	} else if ( (p) == '\b') { / backspace */
	1906	retval[i] = '\\'; ++i;
	1907	retval[i] = 'b';
	1908	} else if ( (p) == '\r') { / carriage return */
	1909	retval[i] = '\\'; ++i;
	1910	retval[i] = 'r';
	1911	} else if ( (p) == '\t') { / horizontal tab */
	1912	retval[i] = '\\'; ++i;
	1913	retval[i] = 't';
	1914	} else if ( (p) == '\v') { / vertical tab */
	1915	retval[i] = '\\'; ++i;
	1916	retval[i] = 'v';
	1917	} else if ( (p) == '\f') { / form-feed */
	1918	retval[i] = '\\'; ++i;
	1919	retval[i] = 'f';
	1920	#ifdef WITH_DATABASE
	1921	} else if ( (p) == '\'') { / single quote */
	1922	retval[i] = '\\'; ++i;
	1923	retval[i] = '\'';
	1924	#endif
	1925	} else if ( (p) == ' ') { / space */
	1926	retval[i] = '\\'; ++i;
	1927	retval[i] = ' ';
	1928	#ifdef SH_USE_XML
	1929	} else if ( (p) == '"') { / double quote */
	1930	retval[i] = '&'; ++i;
	1931	retval[i] = 'q'; ++i;
	1932	retval[i] = 'u'; ++i;
	1933	retval[i] = 'o'; ++i;
	1934	retval[i] = 't'; ++i;
	1935	retval[i] = ';';
	1936	} else if ( (p) == '&') { / ampersand */
	1937	retval[i] = '&'; ++i;
	1938	retval[i] = 'a'; ++i;
	1939	retval[i] = 'm'; ++i;
	1940	retval[i] = 'p'; ++i;
	1941	retval[i] = ';';
	1942	} else if ( (p) == '<') { / left angle */
	1943	retval[i] = '&'; ++i;
	1944	retval[i] = 'l'; ++i;
	1945	retval[i] = 't'; ++i;
	1946	retval[i] = ';';
	1947	} else if ( (p) == '>') { / right angle */
	1948	retval[i] = '&'; ++i;
	1949	retval[i] = 'g'; ++i;
	1950	retval[i] = 't'; ++i;
	1951	retval[i] = ';';
	1952	#else
	1953	} else if ( (p) == '"') { / double quote */
	1954	retval[i] = '\\'; ++i;
	1955	retval[i] = '\"';
	1956	#endif
	1957	} else if (!isgraph ((int) p)) { / not printable */
	1958	/@-bufferoverflowhigh -formatconst@/
[22]	1959	/* flawfinder: ignore */
[1]	1960	sprintf(oct, format, '\\', /* known to fit */
	1961	(unsigned char) *p);
	1962	/@+bufferoverflowhigh +formatconst@/
	1963	retval[i] = oct[0]; ++i;
	1964	retval[i] = oct[1]; ++i;
	1965	retval[i] = oct[2]; ++i;
	1966	retval[i] = oct[3];
	1967	} else {
	1968	retval[i] = *p;
	1969	}
	1970	++p;
	1971	++i;
	1972	}
	1973	retval[i] = '\0';
	1974	SL_RETURN(retval, _("sh_util_safe_name"));
	1975	}
	1976
	1977	int sh_util_isnum (char *str)
	1978	{
	1979	char *p = str;
	1980
	1981	SL_ENTER(_("sh_util_isnum"));
	1982
	1983	ASSERT_RET ((str != NULL), _("str != NULL"), (-1))
	1984
	1985	while (p) {
	1986	if (!isdigit((int) *p) )
	1987	SL_RETURN((-1), _("sh_util_isnum"));
	1988	++p;
	1989	}
	1990	SL_RETURN((0), _("sh_util_isnum"));
	1991	}
	1992
[76]	1993	char * sh_util_strconcat (const char * arg1, ...)
[1]	1994	{
[34]	1995	size_t length, l2;
[1]	1996	char * s;
	1997	char * strnew;
	1998	va_list vl;
	1999
	2000	SL_ENTER(_("sh_util_strconcat"));
	2001
	2002	ASSERT_RET ((arg1 != NULL), _("arg1 != NULL"), (NULL))
	2003
	2004	length = sl_strlen (arg1) + 1;
	2005
	2006	va_start (vl, arg1);
	2007	s = va_arg (vl, char * );
	2008	while (s != NULL)
	2009	{
[34]	2010	l2 = sl_strlen (s);
	2011	if (sl_ok_adds(length, l2))
	2012	length += l2;
	2013	else
	2014	SL_RETURN(NULL, _("sh_util_strconcat"));
[1]	2015	s = va_arg (vl, char * );
	2016	}
	2017	va_end (vl);
	2018
[34]	2019	if (sl_ok_adds(length, 2))
	2020	strnew = SH_ALLOC( length + 2 );
	2021	else
	2022	SL_RETURN(NULL, _("sh_util_strconcat"));
	2023
[1]	2024	strnew[0] = '\0';
	2025
	2026	(void) sl_strlcpy (strnew, arg1, length + 2);
	2027
	2028	va_start (vl, arg1);
	2029	s = va_arg (vl, char * );
	2030	while (s)
	2031	{
	2032	(void) sl_strlcat (strnew, s, length + 2);
	2033	s = va_arg (vl, char * );
	2034	}
	2035	va_end (vl);
	2036
	2037	SL_RETURN(strnew, _("sh_util_strconcat"));
	2038	}
	2039
	2040
	2041	#ifdef HAVE_REGEX_H
	2042
	2043	#include <regex.h>
	2044
	2045	int sh_util_regcmp (char * regex_str, char * in_str)
	2046	{
	2047	#if defined(REG_ESPACE)
	2048	int status = REG_ESPACE;
	2049	#else
	2050	int status = -1;
	2051	#endif
	2052	regex_t preg;
	2053	char * errbuf;
	2054
	2055	SL_ENTER(_("sh_util_regcmp"));
	2056
	2057	status = regcomp(&preg, regex_str, REG_NOSUB\|REG_EXTENDED);
	2058
	2059	if (status == 0)
	2060	{
	2061	if ((status = regexec(&preg, in_str, 0, NULL, 0)) == 0)
	2062	{
	2063	regfree (&preg);
	2064	SL_RETURN((0), _("sh_util_regcmp"));
	2065	}
	2066	}
	2067
	2068	if (status != 0 && status != REG_NOMATCH)
	2069	{
[34]	2070	errbuf = SH_ALLOC(BUFSIZ);
[1]	2071	(void) regerror(status, &preg, errbuf, BUFSIZ);
[34]	2072	errbuf[BUFSIZ-1] = '\0';
[1]	2073	sh_error_handle ((-1), FIL__, __LINE__, status, MSG_E_REGEX,
	2074	errbuf, regex_str);
	2075	SH_FREE(errbuf);
	2076	}
	2077
	2078	regfree (&preg);
	2079	SL_RETURN((-1), _("sh_util_regcmp"));
	2080	}
	2081
	2082	#endif
	2083
	2084
	2085
	2086
	2087
	2088
	2089
	2090

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