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source: vendor/3.5.0/source3/lib/util.c

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Last change on this file was 414, checked in by Herwig Bauernfeind, 15 years ago
Samba 3.5.0: Initial import
File size: 72.1 KB

Line
1	/*
2	Unix SMB/CIFS implementation.
3	Samba utility functions
4	Copyright (C) Andrew Tridgell 1992-1998
5	Copyright (C) Jeremy Allison 2001-2007
6	Copyright (C) Simo Sorce 2001
7	Copyright (C) Jim McDonough <jmcd@us.ibm.com> 2003
8	Copyright (C) James Peach 2006
9
10	This program is free software; you can redistribute it and/or modify
11	it under the terms of the GNU General Public License as published by
12	the Free Software Foundation; either version 3 of the License, or
13	(at your option) any later version.
14
15	This program is distributed in the hope that it will be useful,
16	but WITHOUT ANY WARRANTY; without even the implied warranty of
17	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
18	GNU General Public License for more details.
19
20	You should have received a copy of the GNU General Public License
21	along with this program. If not, see <http://www.gnu.org/licenses/>.
22	*/
23
24	#include "includes.h"
25
26	extern char *global_clobber_region_function;
27	extern unsigned int global_clobber_region_line;
28
29	/* Max allowable allococation - 256mb - 0x10000000 */
30	#define MAX_ALLOC_SIZE (10241024256)
31
32	#if (defined(HAVE_NETGROUP) && defined (WITH_AUTOMOUNT))
33	#ifdef WITH_NISPLUS_HOME
34	#ifdef BROKEN_NISPLUS_INCLUDE_FILES
35	/*
36	* The following lines are needed due to buggy include files
37	* in Solaris 2.6 which define GROUP in both /usr/include/sys/acl.h and
38	* also in /usr/include/rpcsvc/nis.h. The definitions conflict. JRA.
39	* Also GROUP_OBJ is defined as 0x4 in /usr/include/sys/acl.h and as
40	* an enum in /usr/include/rpcsvc/nis.h.
41	*/
42
43	#if defined(GROUP)
44	#undef GROUP
45	#endif
46
47	#if defined(GROUP_OBJ)
48	#undef GROUP_OBJ
49	#endif
50
51	#endif /* BROKEN_NISPLUS_INCLUDE_FILES */
52
53	#include <rpcsvc/nis.h>
54
55	#endif /* WITH_NISPLUS_HOME */
56	#endif /* HAVE_NETGROUP && WITH_AUTOMOUNT */
57
58	static enum protocol_types Protocol = PROTOCOL_COREPLUS;
59
60	enum protocol_types get_Protocol(void)
61	{
62	return Protocol;
63	}
64
65	void set_Protocol(enum protocol_types p)
66	{
67	Protocol = p;
68	}
69
70	static enum remote_arch_types ra_type = RA_UNKNOWN;
71
72	/***********************************************************************
73	Definitions for all names.
74	***********************************************************************/
75
76	static char *smb_myname;
77	static char *smb_myworkgroup;
78	static char *smb_scope;
79	static int smb_num_netbios_names;
80	static char **smb_my_netbios_names;
81
82	/***********************************************************************
83	Allocate and set myname. Ensure upper case.
84	***********************************************************************/
85
86	bool set_global_myname(const char *myname)
87	{
88	SAFE_FREE(smb_myname);
89	smb_myname = SMB_STRDUP(myname);
90	if (!smb_myname)
91	return False;
92	strupper_m(smb_myname);
93	return True;
94	}
95
96	const char *global_myname(void)
97	{
98	return smb_myname;
99	}
100
101	/***********************************************************************
102	Allocate and set myworkgroup. Ensure upper case.
103	***********************************************************************/
104
105	bool set_global_myworkgroup(const char *myworkgroup)
106	{
107	SAFE_FREE(smb_myworkgroup);
108	smb_myworkgroup = SMB_STRDUP(myworkgroup);
109	if (!smb_myworkgroup)
110	return False;
111	strupper_m(smb_myworkgroup);
112	return True;
113	}
114
115	const char *lp_workgroup(void)
116	{
117	return smb_myworkgroup;
118	}
119
120	/***********************************************************************
121	Allocate and set scope. Ensure upper case.
122	***********************************************************************/
123
124	bool set_global_scope(const char *scope)
125	{
126	SAFE_FREE(smb_scope);
127	smb_scope = SMB_STRDUP(scope);
128	if (!smb_scope)
129	return False;
130	strupper_m(smb_scope);
131	return True;
132	}
133
134	/*********************************************************************
135	Ensure scope is never null string.
136	*********************************************************************/
137
138	const char *global_scope(void)
139	{
140	if (!smb_scope)
141	set_global_scope("");
142	return smb_scope;
143	}
144
145	static void free_netbios_names_array(void)
146	{
147	int i;
148
149	for (i = 0; i < smb_num_netbios_names; i++)
150	SAFE_FREE(smb_my_netbios_names[i]);
151
152	SAFE_FREE(smb_my_netbios_names);
153	smb_num_netbios_names = 0;
154	}
155
156	static bool allocate_my_netbios_names_array(size_t number)
157	{
158	free_netbios_names_array();
159
160	smb_num_netbios_names = number + 1;
161	smb_my_netbios_names = SMB_MALLOC_ARRAY( char *, smb_num_netbios_names );
162
163	if (!smb_my_netbios_names)
164	return False;
165
166	memset(smb_my_netbios_names, '\0', sizeof(char ) smb_num_netbios_names);
167	return True;
168	}
169
170	static bool set_my_netbios_names(const char *name, int i)
171	{
172	SAFE_FREE(smb_my_netbios_names[i]);
173
174	smb_my_netbios_names[i] = SMB_STRDUP(name);
175	if (!smb_my_netbios_names[i])
176	return False;
177	strupper_m(smb_my_netbios_names[i]);
178	return True;
179	}
180
181	/***********************************************************************
182	Free memory allocated to global objects
183	***********************************************************************/
184
185	void gfree_names(void)
186	{
187	SAFE_FREE( smb_myname );
188	SAFE_FREE( smb_myworkgroup );
189	SAFE_FREE( smb_scope );
190	free_netbios_names_array();
191	free_local_machine_name();
192	}
193
194	void gfree_all( void )
195	{
196	gfree_names();
197	gfree_loadparm();
198	gfree_case_tables();
199	gfree_charcnv();
200	gfree_interfaces();
201	gfree_debugsyms();
202	}
203
204	const char *my_netbios_names(int i)
205	{
206	return smb_my_netbios_names[i];
207	}
208
209	bool set_netbios_aliases(const char **str_array)
210	{
211	size_t namecount;
212
213	/* Work out the max number of netbios aliases that we have */
214	for( namecount=0; str_array && (str_array[namecount] != NULL); namecount++ )
215	;
216
217	if ( global_myname() && *global_myname())
218	namecount++;
219
220	/* Allocate space for the netbios aliases */
221	if (!allocate_my_netbios_names_array(namecount))
222	return False;
223
224	/* Use the global_myname string first */
225	namecount=0;
226	if ( global_myname() && *global_myname()) {
227	set_my_netbios_names( global_myname(), namecount );
228	namecount++;
229	}
230
231	if (str_array) {
232	size_t i;
233	for ( i = 0; str_array[i] != NULL; i++) {
234	size_t n;
235	bool duplicate = False;
236
237	/* Look for duplicates */
238	for( n=0; n<namecount; n++ ) {
239	if( strequal( str_array[i], my_netbios_names(n) ) ) {
240	duplicate = True;
241	break;
242	}
243	}
244	if (!duplicate) {
245	if (!set_my_netbios_names(str_array[i], namecount))
246	return False;
247	namecount++;
248	}
249	}
250	}
251	return True;
252	}
253
254	/****************************************************************************
255	Common name initialization code.
256	****************************************************************************/
257
258	bool init_names(void)
259	{
260	int n;
261
262	if (global_myname() == NULL \|\| *global_myname() == '\0') {
263	if (!set_global_myname(myhostname())) {
264	DEBUG( 0, ( "init_structs: malloc fail.\n" ) );
265	return False;
266	}
267	}
268
269	if (!set_netbios_aliases(lp_netbios_aliases())) {
270	DEBUG( 0, ( "init_structs: malloc fail.\n" ) );
271	return False;
272	}
273
274	set_local_machine_name(global_myname(),false);
275
276	DEBUG( 5, ("Netbios name list:-\n") );
277	for( n=0; my_netbios_names(n); n++ ) {
278	DEBUGADD( 5, ("my_netbios_names[%d]=\"%s\"\n",
279	n, my_netbios_names(n) ) );
280	}
281
282	return( True );
283	}
284
285	/**************************************************************************n
286	Code to cope with username/password auth options from the commandline.
287	Used mainly in client tools.
288	****************************************************************************/
289
290	struct user_auth_info user_auth_info_init(TALLOC_CTX mem_ctx)
291	{
292	struct user_auth_info *result;
293
294	result = TALLOC_ZERO_P(mem_ctx, struct user_auth_info);
295	if (result == NULL) {
296	return NULL;
297	}
298
299	result->signing_state = Undefined;
300	return result;
301	}
302
303	const char get_cmdline_auth_info_username(const struct user_auth_info auth_info)
304	{
305	if (!auth_info->username) {
306	return "";
307	}
308	return auth_info->username;
309	}
310
311	void set_cmdline_auth_info_username(struct user_auth_info *auth_info,
312	const char *username)
313	{
314	TALLOC_FREE(auth_info->username);
315	auth_info->username = talloc_strdup(auth_info, username);
316	if (!auth_info->username) {
317	exit(ENOMEM);
318	}
319	}
320
321	const char get_cmdline_auth_info_domain(const struct user_auth_info auth_info)
322	{
323	if (!auth_info->domain) {
324	return "";
325	}
326	return auth_info->domain;
327	}
328
329	void set_cmdline_auth_info_domain(struct user_auth_info *auth_info,
330	const char *domain)
331	{
332	TALLOC_FREE(auth_info->domain);
333	auth_info->domain = talloc_strdup(auth_info, domain);
334	if (!auth_info->domain) {
335	exit(ENOMEM);
336	}
337	}
338
339	const char get_cmdline_auth_info_password(const struct user_auth_info auth_info)
340	{
341	if (!auth_info->password) {
342	return "";
343	}
344	return auth_info->password;
345	}
346
347	void set_cmdline_auth_info_password(struct user_auth_info *auth_info,
348	const char *password)
349	{
350	TALLOC_FREE(auth_info->password);
351	if (password == NULL) {
352	password = "";
353	}
354	auth_info->password = talloc_strdup(auth_info, password);
355	if (!auth_info->password) {
356	exit(ENOMEM);
357	}
358	auth_info->got_pass = true;
359	}
360
361	bool set_cmdline_auth_info_signing_state(struct user_auth_info *auth_info,
362	const char *arg)
363	{
364	auth_info->signing_state = -1;
365	if (strequal(arg, "off") \|\| strequal(arg, "no") \|\|
366	strequal(arg, "false")) {
367	auth_info->signing_state = false;
368	} else if (strequal(arg, "on") \|\| strequal(arg, "yes") \|\|
369	strequal(arg, "true") \|\| strequal(arg, "auto")) {
370	auth_info->signing_state = true;
371	} else if (strequal(arg, "force") \|\| strequal(arg, "required") \|\|
372	strequal(arg, "forced")) {
373	auth_info->signing_state = Required;
374	} else {
375	return false;
376	}
377	return true;
378	}
379
380	int get_cmdline_auth_info_signing_state(const struct user_auth_info *auth_info)
381	{
382	return auth_info->signing_state;
383	}
384
385	void set_cmdline_auth_info_use_ccache(struct user_auth_info *auth_info, bool b)
386	{
387	auth_info->use_ccache = b;
388	}
389
390	bool get_cmdline_auth_info_use_ccache(const struct user_auth_info *auth_info)
391	{
392	return auth_info->use_ccache;
393	}
394
395	void set_cmdline_auth_info_use_kerberos(struct user_auth_info *auth_info,
396	bool b)
397	{
398	auth_info->use_kerberos = b;
399	}
400
401	bool get_cmdline_auth_info_use_kerberos(const struct user_auth_info *auth_info)
402	{
403	return auth_info->use_kerberos;
404	}
405
406	void set_cmdline_auth_info_fallback_after_kerberos(struct user_auth_info *auth_info,
407	bool b)
408	{
409	auth_info->fallback_after_kerberos = b;
410	}
411
412	bool get_cmdline_auth_info_fallback_after_kerberos(const struct user_auth_info *auth_info)
413	{
414	return auth_info->fallback_after_kerberos;
415	}
416
417	/* This should only be used by lib/popt_common.c JRA */
418	void set_cmdline_auth_info_use_krb5_ticket(struct user_auth_info *auth_info)
419	{
420	auth_info->use_kerberos = true;
421	auth_info->got_pass = true;
422	}
423
424	/* This should only be used by lib/popt_common.c JRA */
425	void set_cmdline_auth_info_smb_encrypt(struct user_auth_info *auth_info)
426	{
427	auth_info->smb_encrypt = true;
428	}
429
430	void set_cmdline_auth_info_use_machine_account(struct user_auth_info *auth_info)
431	{
432	auth_info->use_machine_account = true;
433	}
434
435	bool get_cmdline_auth_info_got_pass(const struct user_auth_info *auth_info)
436	{
437	return auth_info->got_pass;
438	}
439
440	bool get_cmdline_auth_info_smb_encrypt(const struct user_auth_info *auth_info)
441	{
442	return auth_info->smb_encrypt;
443	}
444
445	bool get_cmdline_auth_info_use_machine_account(const struct user_auth_info *auth_info)
446	{
447	return auth_info->use_machine_account;
448	}
449
450	struct user_auth_info get_cmdline_auth_info_copy(TALLOC_CTX mem_ctx,
451	const struct user_auth_info *src)
452	{
453	struct user_auth_info *result;
454
455	result = user_auth_info_init(mem_ctx);
456	if (result == NULL) {
457	return NULL;
458	}
459
460	result = src;
461
462	result->username = talloc_strdup(
463	result, get_cmdline_auth_info_username(src));
464	result->password = talloc_strdup(
465	result, get_cmdline_auth_info_password(src));
466	if ((result->username == NULL) \|\| (result->password == NULL)) {
467	TALLOC_FREE(result);
468	return NULL;
469	}
470
471	return result;
472	}
473
474	bool set_cmdline_auth_info_machine_account_creds(struct user_auth_info *auth_info)
475	{
476	char *pass = NULL;
477	char *account = NULL;
478
479	if (!get_cmdline_auth_info_use_machine_account(auth_info)) {
480	return false;
481	}
482
483	if (!secrets_init()) {
484	d_printf("ERROR: Unable to open secrets database\n");
485	return false;
486	}
487
488	if (asprintf(&account, "%s$@%s", global_myname(), lp_realm()) < 0) {
489	return false;
490	}
491
492	pass = secrets_fetch_machine_password(lp_workgroup(), NULL, NULL);
493	if (!pass) {
494	d_printf("ERROR: Unable to fetch machine password for "
495	"%s in domain %s\n",
496	account, lp_workgroup());
497	SAFE_FREE(account);
498	return false;
499	}
500
501	set_cmdline_auth_info_username(auth_info, account);
502	set_cmdline_auth_info_password(auth_info, pass);
503
504	SAFE_FREE(account);
505	SAFE_FREE(pass);
506
507	return true;
508	}
509
510	/****************************************************************************
511	Ensure we have a password if one not given.
512	****************************************************************************/
513
514	void set_cmdline_auth_info_getpass(struct user_auth_info *auth_info)
515	{
516	char *label = NULL;
517	char *pass;
518	TALLOC_CTX *frame;
519
520	if (get_cmdline_auth_info_got_pass(auth_info) \|\|
521	get_cmdline_auth_info_use_kerberos(auth_info)) {
522	/* Already got one... */
523	return;
524	}
525
526	frame = talloc_stackframe();
527	label = talloc_asprintf(frame, "Enter %s's password: ",
528	get_cmdline_auth_info_username(auth_info));
529	pass = getpass(label);
530	if (pass) {
531	set_cmdline_auth_info_password(auth_info, pass);
532	}
533	TALLOC_FREE(frame);
534	}
535
536	/*******************************************************************
537	Check if a file exists - call vfs_file_exist for samba files.
538	********************************************************************/
539
540	bool file_exist_stat(const char fname,SMB_STRUCT_STAT sbuf,
541	bool fake_dir_create_times)
542	{
543	SMB_STRUCT_STAT st;
544	if (!sbuf)
545	sbuf = &st;
546
547	if (sys_stat(fname, sbuf, fake_dir_create_times) != 0)
548	return(False);
549
550	return((S_ISREG(sbuf->st_ex_mode)) \|\| (S_ISFIFO(sbuf->st_ex_mode)));
551	}
552
553	/*******************************************************************
554	Check if a unix domain socket exists - call vfs_file_exist for samba files.
555	********************************************************************/
556
557	bool socket_exist(const char *fname)
558	{
559	SMB_STRUCT_STAT st;
560	if (sys_stat(fname, &st, false) != 0)
561	return(False);
562
563	return S_ISSOCK(st.st_ex_mode);
564	}
565
566	/*******************************************************************
567	Returns the size in bytes of the named given the stat struct.
568	********************************************************************/
569
570	uint64_t get_file_size_stat(const SMB_STRUCT_STAT *sbuf)
571	{
572	return sbuf->st_ex_size;
573	}
574
575	/*******************************************************************
576	Returns the size in bytes of the named file.
577	********************************************************************/
578
579	SMB_OFF_T get_file_size(char *file_name)
580	{
581	SMB_STRUCT_STAT buf;
582	buf.st_ex_size = 0;
583	if (sys_stat(file_name, &buf, false) != 0)
584	return (SMB_OFF_T)-1;
585	return get_file_size_stat(&buf);
586	}
587
588	/*******************************************************************
589	Return a string representing an attribute for a file.
590	********************************************************************/
591
592	char *attrib_string(uint16 mode)
593	{
594	fstring attrstr;
595
596	attrstr[0] = 0;
597
598	if (mode & aVOLID) fstrcat(attrstr,"V");
599	if (mode & aDIR) fstrcat(attrstr,"D");
600	if (mode & aARCH) fstrcat(attrstr,"A");
601	if (mode & aHIDDEN) fstrcat(attrstr,"H");
602	if (mode & aSYSTEM) fstrcat(attrstr,"S");
603	if (mode & aRONLY) fstrcat(attrstr,"R");
604
605	return talloc_strdup(talloc_tos(), attrstr);
606	}
607
608	/*******************************************************************
609	Show a smb message structure.
610	********************************************************************/
611
612	void show_msg(char *buf)
613	{
614	int i;
615	int bcc=0;
616
617	if (!DEBUGLVL(5))
618	return;
619
620	DEBUG(5,("size=%d\nsmb_com=0x%x\nsmb_rcls=%d\nsmb_reh=%d\nsmb_err=%d\nsmb_flg=%d\nsmb_flg2=%d\n",
621	smb_len(buf),
622	(int)CVAL(buf,smb_com),
623	(int)CVAL(buf,smb_rcls),
624	(int)CVAL(buf,smb_reh),
625	(int)SVAL(buf,smb_err),
626	(int)CVAL(buf,smb_flg),
627	(int)SVAL(buf,smb_flg2)));
628	DEBUGADD(5,("smb_tid=%d\nsmb_pid=%d\nsmb_uid=%d\nsmb_mid=%d\n",
629	(int)SVAL(buf,smb_tid),
630	(int)SVAL(buf,smb_pid),
631	(int)SVAL(buf,smb_uid),
632	(int)SVAL(buf,smb_mid)));
633	DEBUGADD(5,("smt_wct=%d\n",(int)CVAL(buf,smb_wct)));
634
635	for (i=0;i<(int)CVAL(buf,smb_wct);i++)
636	DEBUGADD(5,("smb_vwv[%2d]=%5d (0x%X)\n",i,
637	SVAL(buf,smb_vwv+2i),SVAL(buf,smb_vwv+2i)));
638
639	bcc = (int)SVAL(buf,smb_vwv+2*(CVAL(buf,smb_wct)));
640
641	DEBUGADD(5,("smb_bcc=%d\n",bcc));
642
643	if (DEBUGLEVEL < 10)
644	return;
645
646	if (DEBUGLEVEL < 50)
647	bcc = MIN(bcc, 512);
648
649	dump_data(10, (uint8 *)smb_buf(buf), bcc);
650	}
651
652	/*******************************************************************
653	Set the length and marker of an encrypted smb packet.
654	********************************************************************/
655
656	void smb_set_enclen(char *buf,int len,uint16 enc_ctx_num)
657	{
658	_smb_setlen(buf,len);
659
660	SCVAL(buf,4,0xFF);
661	SCVAL(buf,5,'E');
662	SSVAL(buf,6,enc_ctx_num);
663	}
664
665	/*******************************************************************
666	Set the length and marker of an smb packet.
667	********************************************************************/
668
669	void smb_setlen(char *buf,int len)
670	{
671	_smb_setlen(buf,len);
672
673	SCVAL(buf,4,0xFF);
674	SCVAL(buf,5,'S');
675	SCVAL(buf,6,'M');
676	SCVAL(buf,7,'B');
677	}
678
679	/*******************************************************************
680	Setup only the byte count for a smb message.
681	********************************************************************/
682
683	int set_message_bcc(char *buf,int num_bytes)
684	{
685	int num_words = CVAL(buf,smb_wct);
686	SSVAL(buf,smb_vwv + num_words*SIZEOFWORD,num_bytes);
687	_smb_setlen(buf,smb_size + num_words*2 + num_bytes - 4);
688	return (smb_size + num_words*2 + num_bytes);
689	}
690
691	/*******************************************************************
692	Add a data blob to the end of a smb_buf, adjusting bcc and smb_len.
693	Return the bytes added
694	********************************************************************/
695
696	ssize_t message_push_blob(uint8 **outbuf, DATA_BLOB blob)
697	{
698	size_t newlen = smb_len(*outbuf) + 4 + blob.length;
699	uint8 *tmp;
700
701	if (!(tmp = TALLOC_REALLOC_ARRAY(NULL, *outbuf, uint8, newlen))) {
702	DEBUG(0, ("talloc failed\n"));
703	return -1;
704	}
705	*outbuf = tmp;
706
707	memcpy(tmp + smb_len(tmp) + 4, blob.data, blob.length);
708	set_message_bcc((char *)tmp, smb_buflen(tmp) + blob.length);
709	return blob.length;
710	}
711
712	/*******************************************************************
713	Reduce a file name, removing .. elements.
714	********************************************************************/
715
716	static char dos_clean_name(TALLOC_CTX ctx, const char *s)
717	{
718	char *p = NULL;
719	char *str = NULL;
720
721	DEBUG(3,("dos_clean_name [%s]\n",s));
722
723	/* remove any double slashes */
724	str = talloc_all_string_sub(ctx, s, "\\\\", "\\");
725	if (!str) {
726	return NULL;
727	}
728
729	/* Remove leading .\\ characters */
730	if(strncmp(str, ".\\", 2) == 0) {
731	trim_string(str, ".\\", NULL);
732	if(*str == 0) {
733	str = talloc_strdup(ctx, ".\\");
734	if (!str) {
735	return NULL;
736	}
737	}
738	}
739
740	while ((p = strstr_m(str,"\\..\\")) != NULL) {
741	char *s1;
742
743	*p = 0;
744	s1 = p+3;
745
746	if ((p=strrchr_m(str,'\\')) != NULL) {
747	*p = 0;
748	} else {
749	*str = 0;
750	}
751	str = talloc_asprintf(ctx,
752	"%s%s",
753	str,
754	s1);
755	if (!str) {
756	return NULL;
757	}
758	}
759
760	trim_string(str,NULL,"\\..");
761	return talloc_all_string_sub(ctx, str, "\\.\\", "\\");
762	}
763
764	/*******************************************************************
765	Reduce a file name, removing .. elements.
766	********************************************************************/
767
768	char unix_clean_name(TALLOC_CTX ctx, const char *s)
769	{
770	char *p = NULL;
771	char *str = NULL;
772
773	DEBUG(3,("unix_clean_name [%s]\n",s));
774
775	/* remove any double slashes */
776	str = talloc_all_string_sub(ctx, s, "//","/");
777	if (!str) {
778	return NULL;
779	}
780
781	/* Remove leading ./ characters */
782	if(strncmp(str, "./", 2) == 0) {
783	trim_string(str, "./", NULL);
784	if(*str == 0) {
785	str = talloc_strdup(ctx, "./");
786	if (!str) {
787	return NULL;
788	}
789	}
790	}
791
792	while ((p = strstr_m(str,"/../")) != NULL) {
793	char *s1;
794
795	*p = 0;
796	s1 = p+3;
797
798	if ((p=strrchr_m(str,'/')) != NULL) {
799	*p = 0;
800	} else {
801	*str = 0;
802	}
803	str = talloc_asprintf(ctx,
804	"%s%s",
805	str,
806	s1);
807	if (!str) {
808	return NULL;
809	}
810	}
811
812	trim_string(str,NULL,"/..");
813	return talloc_all_string_sub(ctx, str, "/./", "/");
814	}
815
816	char clean_name(TALLOC_CTX ctx, const char *s)
817	{
818	char *str = dos_clean_name(ctx, s);
819	if (!str) {
820	return NULL;
821	}
822	return unix_clean_name(ctx, str);
823	}
824
825	/*******************************************************************
826	Write data into an fd at a given offset. Ignore seek errors.
827	********************************************************************/
828
829	ssize_t write_data_at_offset(int fd, const char *buffer, size_t N, SMB_OFF_T pos)
830	{
831	size_t total=0;
832	ssize_t ret;
833
834	if (pos == (SMB_OFF_T)-1) {
835	return write_data(fd, buffer, N);
836	}
837	#if defined(HAVE_PWRITE) \|\| defined(HAVE_PRWITE64)
838	while (total < N) {
839	ret = sys_pwrite(fd,buffer + total,N - total, pos);
840	if (ret == -1 && errno == ESPIPE) {
841	return write_data(fd, buffer + total,N - total);
842	}
843	if (ret == -1) {
844	DEBUG(0,("write_data_at_offset: write failure. Error = %s\n", strerror(errno) ));
845	return -1;
846	}
847	if (ret == 0) {
848	return total;
849	}
850	total += ret;
851	pos += ret;
852	}
853	return (ssize_t)total;
854	#else
855	/* Use lseek and write_data. */
856	if (sys_lseek(fd, pos, SEEK_SET) == -1) {
857	if (errno != ESPIPE) {
858	return -1;
859	}
860	}
861	return write_data(fd, buffer, N);
862	#endif
863	}
864
865	/*******************************************************************
866	Sleep for a specified number of milliseconds.
867	********************************************************************/
868
869	void smb_msleep(unsigned int t)
870	{
871	#if defined(HAVE_NANOSLEEP)
872	struct timespec tval;
873	int ret;
874
875	tval.tv_sec = t/1000;
876	tval.tv_nsec = 1000000*(t%1000);
877
878	do {
879	errno = 0;
880	ret = nanosleep(&tval, &tval);
881	} while (ret < 0 && errno == EINTR && (tval.tv_sec > 0 \|\| tval.tv_nsec > 0));
882	#else
883	unsigned int tdiff=0;
884	struct timeval tval,t1,t2;
885	fd_set fds;
886
887	GetTimeOfDay(&t1);
888	t2 = t1;
889
890	while (tdiff < t) {
891	tval.tv_sec = (t-tdiff)/1000;
892	tval.tv_usec = 1000*((t-tdiff)%1000);
893
894	/* Never wait for more than 1 sec. */
895	if (tval.tv_sec > 1) {
896	tval.tv_sec = 1;
897	tval.tv_usec = 0;
898	}
899
900	FD_ZERO(&fds);
901	errno = 0;
902	sys_select_intr(0,&fds,NULL,NULL,&tval);
903
904	GetTimeOfDay(&t2);
905	if (t2.tv_sec < t1.tv_sec) {
906	/* Someone adjusted time... */
907	t1 = t2;
908	}
909
910	tdiff = TvalDiff(&t1,&t2);
911	}
912	#endif
913	}
914
915	NTSTATUS reinit_after_fork(struct messaging_context *msg_ctx,
916	struct event_context *ev_ctx,
917	bool parent_longlived)
918	{
919	NTSTATUS status = NT_STATUS_OK;
920
921	/* Reset the state of the random
922	* number generation system, so
923	* children do not get the same random
924	* numbers as each other */
925	set_need_random_reseed();
926
927	/* tdb needs special fork handling */
928	if (tdb_reopen_all(parent_longlived ? 1 : 0) == -1) {
929	DEBUG(0,("tdb_reopen_all failed.\n"));
930	status = NT_STATUS_OPEN_FAILED;
931	goto done;
932	}
933
934	if (ev_ctx) {
935	event_context_reinit(ev_ctx);
936	}
937
938	if (msg_ctx) {
939	/*
940	* For clustering, we need to re-init our ctdbd connection after the
941	* fork
942	*/
943	status = messaging_reinit(msg_ctx);
944	if (!NT_STATUS_IS_OK(status)) {
945	DEBUG(0,("messaging_reinit() failed: %s\n",
946	nt_errstr(status)));
947	}
948	}
949	done:
950	return status;
951	}
952
953	/****************************************************************************
954	Put up a yes/no prompt.
955	****************************************************************************/
956
957	bool yesno(const char *p)
958	{
959	char ans[20];
960	printf("%s",p);
961
962	if (!fgets(ans,sizeof(ans)-1,stdin))
963	return(False);
964
965	if (ans == 'y' \|\| ans == 'Y')
966	return(True);
967
968	return(False);
969	}
970
971	#if defined(PARANOID_MALLOC_CHECKER)
972
973	/****************************************************************************
974	Internal malloc wrapper. Externally visible.
975	****************************************************************************/
976
977	void *malloc_(size_t size)
978	{
979	if (size == 0) {
980	return NULL;
981	}
982	#undef malloc
983	return malloc(size);
984	#define malloc(s) __ERROR_DONT_USE_MALLOC_DIRECTLY
985	}
986
987	/****************************************************************************
988	Internal calloc wrapper. Not externally visible.
989	****************************************************************************/
990
991	static void *calloc_(size_t count, size_t size)
992	{
993	if (size == 0 \|\| count == 0) {
994	return NULL;
995	}
996	#undef calloc
997	return calloc(count, size);
998	#define calloc(n,s) __ERROR_DONT_USE_CALLOC_DIRECTLY
999	}
1000
1001	/****************************************************************************
1002	Internal realloc wrapper. Not externally visible.
1003	****************************************************************************/
1004
1005	static void realloc_(void ptr, size_t size)
1006	{
1007	#undef realloc
1008	return realloc(ptr, size);
1009	#define realloc(p,s) __ERROR_DONT_USE_RELLOC_DIRECTLY
1010	}
1011
1012	#endif /* PARANOID_MALLOC_CHECKER */
1013
1014	/****************************************************************************
1015	Type-safe memalign
1016	****************************************************************************/
1017
1018	void *memalign_array(size_t el_size, size_t align, unsigned int count)
1019	{
1020	if (count >= MAX_ALLOC_SIZE/el_size) {
1021	return NULL;
1022	}
1023
1024	return sys_memalign(align, el_size*count);
1025	}
1026
1027	/****************************************************************************
1028	Type-safe calloc.
1029	****************************************************************************/
1030
1031	void *calloc_array(size_t size, size_t nmemb)
1032	{
1033	if (nmemb >= MAX_ALLOC_SIZE/size) {
1034	return NULL;
1035	}
1036	if (size == 0 \|\| nmemb == 0) {
1037	return NULL;
1038	}
1039	#if defined(PARANOID_MALLOC_CHECKER)
1040	return calloc_(nmemb, size);
1041	#else
1042	return calloc(nmemb, size);
1043	#endif
1044	}
1045
1046	/****************************************************************************
1047	Expand a pointer to be a particular size.
1048	Note that this version of Realloc has an extra parameter that decides
1049	whether to free the passed in storage on allocation failure or if the
1050	new size is zero.
1051
1052	This is designed for use in the typical idiom of :
1053
1054	p = SMB_REALLOC(p, size)
1055	if (!p) {
1056	return error;
1057	}
1058
1059	and not to have to keep track of the old 'p' contents to free later, nor
1060	to worry if the size parameter was zero. In the case where NULL is returned
1061	we guarentee that p has been freed.
1062
1063	If free later semantics are desired, then pass 'free_old_on_error' as False which
1064	guarentees that the old contents are not freed on error, even if size == 0. To use
1065	this idiom use :
1066
1067	tmp = SMB_REALLOC_KEEP_OLD_ON_ERROR(p, size);
1068	if (!tmp) {
1069	SAFE_FREE(p);
1070	return error;
1071	} else {
1072	p = tmp;
1073	}
1074
1075	Changes were instigated by Coverity error checking. JRA.
1076	****************************************************************************/
1077
1078	void Realloc(void p, size_t size, bool free_old_on_error)
1079	{
1080	void *ret=NULL;
1081
1082	if (size == 0) {
1083	if (free_old_on_error) {
1084	SAFE_FREE(p);
1085	}
1086	DEBUG(2,("Realloc asked for 0 bytes\n"));
1087	return NULL;
1088	}
1089
1090	#if defined(PARANOID_MALLOC_CHECKER)
1091	if (!p) {
1092	ret = (void *)malloc_(size);
1093	} else {
1094	ret = (void *)realloc_(p,size);
1095	}
1096	#else
1097	if (!p) {
1098	ret = (void *)malloc(size);
1099	} else {
1100	ret = (void *)realloc(p,size);
1101	}
1102	#endif
1103
1104	if (!ret) {
1105	if (free_old_on_error && p) {
1106	SAFE_FREE(p);
1107	}
1108	DEBUG(0,("Memory allocation error: failed to expand to %d bytes\n",(int)size));
1109	}
1110
1111	return(ret);
1112	}
1113
1114	/****************************************************************************
1115	(Hopefully) efficient array append.
1116	****************************************************************************/
1117
1118	void add_to_large_array(TALLOC_CTX *mem_ctx, size_t element_size,
1119	void element, void _array, uint32 *num_elements,
1120	ssize_t *array_size)
1121	{
1122	void array = (void )_array;
1123
1124	if (*array_size < 0) {
1125	return;
1126	}
1127
1128	if (*array == NULL) {
1129	if (*array_size == 0) {
1130	*array_size = 128;
1131	}
1132
1133	if (*array_size >= MAX_ALLOC_SIZE/element_size) {
1134	goto error;
1135	}
1136
1137	array = TALLOC(mem_ctx, element_size (*array_size));
1138	if (*array == NULL) {
1139	goto error;
1140	}
1141	}
1142
1143	if (num_elements == array_size) {
1144	array_size = 2;
1145
1146	if (*array_size >= MAX_ALLOC_SIZE/element_size) {
1147	goto error;
1148	}
1149
1150	array = TALLOC_REALLOC(mem_ctx, array,
1151	element_size * (*array_size));
1152
1153	if (*array == NULL) {
1154	goto error;
1155	}
1156	}
1157
1158	memcpy((char )(array) + element_size(num_elements),
1159	element, element_size);
1160	*num_elements += 1;
1161
1162	return;
1163
1164	error:
1165	*num_elements = 0;
1166	*array_size = -1;
1167	}
1168
1169	/****************************************************************************
1170	Get my own domain name, or "" if we have none.
1171	****************************************************************************/
1172
1173	char get_mydnsdomname(TALLOC_CTX ctx)
1174	{
1175	const char *domname;
1176	char *p;
1177
1178	domname = get_mydnsfullname();
1179	if (!domname) {
1180	return NULL;
1181	}
1182
1183	p = strchr_m(domname, '.');
1184	if (p) {
1185	p++;
1186	return talloc_strdup(ctx, p);
1187	} else {
1188	return talloc_strdup(ctx, "");
1189	}
1190	}
1191
1192	/****************************************************************************
1193	Interpret a protocol description string, with a default.
1194	****************************************************************************/
1195
1196	int interpret_protocol(const char *str,int def)
1197	{
1198	if (strequal(str,"NT1"))
1199	return(PROTOCOL_NT1);
1200	if (strequal(str,"LANMAN2"))
1201	return(PROTOCOL_LANMAN2);
1202	if (strequal(str,"LANMAN1"))
1203	return(PROTOCOL_LANMAN1);
1204	if (strequal(str,"CORE"))
1205	return(PROTOCOL_CORE);
1206	if (strequal(str,"COREPLUS"))
1207	return(PROTOCOL_COREPLUS);
1208	if (strequal(str,"CORE+"))
1209	return(PROTOCOL_COREPLUS);
1210
1211	DEBUG(0,("Unrecognised protocol level %s\n",str));
1212
1213	return(def);
1214	}
1215
1216
1217	#if (defined(HAVE_NETGROUP) && defined(WITH_AUTOMOUNT))
1218	/******************************************************************
1219	Remove any mount options such as -rsize=2048,wsize=2048 etc.
1220	Based on a fix from <Thomas.Hepper@icem.de>.
1221	Returns a malloc'ed string.
1222	*******************************************************************/
1223
1224	static char strip_mount_options(TALLOC_CTX ctx, const char *str)
1225	{
1226	if (*str == '-') {
1227	const char *p = str;
1228	while(p && !isspace(p))
1229	p++;
1230	while(p && isspace(p))
1231	p++;
1232	if(*p) {
1233	return talloc_strdup(ctx, p);
1234	}
1235	}
1236	return NULL;
1237	}
1238
1239	/*******************************************************************
1240	Patch from jkf@soton.ac.uk
1241	Split Luke's automount_server into YP lookup and string splitter
1242	so can easily implement automount_path().
1243	Returns a malloc'ed string.
1244	*******************************************************************/
1245
1246	#ifdef WITH_NISPLUS_HOME
1247	char automount_lookup(TALLOC_CTX ctx, const char *user_name)
1248	{
1249	char *value = NULL;
1250
1251	char nis_map = (char )lp_nis_home_map_name();
1252
1253	char buffer[NIS_MAXATTRVAL + 1];
1254	nis_result *result;
1255	nis_object *object;
1256	entry_obj *entry;
1257
1258	snprintf(buffer, sizeof(buffer), "[key=%s],%s", user_name, nis_map);
1259	DEBUG(5, ("NIS+ querystring: %s\n", buffer));
1260
1261	if (result = nis_list(buffer, FOLLOW_PATH\|EXPAND_NAME\|HARD_LOOKUP, NULL, NULL)) {
1262	if (result->status != NIS_SUCCESS) {
1263	DEBUG(3, ("NIS+ query failed: %s\n", nis_sperrno(result->status)));
1264	} else {
1265	object = result->objects.objects_val;
1266	if (object->zo_data.zo_type == ENTRY_OBJ) {
1267	entry = &object->zo_data.objdata_u.en_data;
1268	DEBUG(5, ("NIS+ entry type: %s\n", entry->en_type));
1269	DEBUG(3, ("NIS+ result: %s\n", entry->en_cols.en_cols_val[1].ec_value.ec_value_val));
1270
1271	value = talloc_strdup(ctx,
1272	entry->en_cols.en_cols_val[1].ec_value.ec_value_val);
1273	if (!value) {
1274	nis_freeresult(result);
1275	return NULL;
1276	}
1277	value = talloc_string_sub(ctx,
1278	value,
1279	"&",
1280	user_name);
1281	}
1282	}
1283	}
1284	nis_freeresult(result);
1285
1286	if (value) {
1287	value = strip_mount_options(ctx, value);
1288	DEBUG(4, ("NIS+ Lookup: %s resulted in %s\n",
1289	user_name, value));
1290	}
1291	return value;
1292	}
1293	#else /* WITH_NISPLUS_HOME */
1294
1295	char automount_lookup(TALLOC_CTX ctx, const char *user_name)
1296	{
1297	char *value = NULL;
1298
1299	int nis_error; /* returned by yp all functions */
1300	char nis_result; / yp_match inits this */
1301	int nis_result_len; /* and set this */
1302	char nis_domain; / yp_get_default_domain inits this */
1303	char nis_map = (char )lp_nis_home_map_name();
1304
1305	if ((nis_error = yp_get_default_domain(&nis_domain)) != 0) {
1306	DEBUG(3, ("YP Error: %s\n", yperr_string(nis_error)));
1307	return NULL;
1308	}
1309
1310	DEBUG(5, ("NIS Domain: %s\n", nis_domain));
1311
1312	if ((nis_error = yp_match(nis_domain, nis_map, user_name,
1313	strlen(user_name), &nis_result,
1314	&nis_result_len)) == 0) {
1315	value = talloc_strdup(ctx, nis_result);
1316	if (!value) {
1317	return NULL;
1318	}
1319	value = strip_mount_options(ctx, value);
1320	} else if(nis_error == YPERR_KEY) {
1321	DEBUG(3, ("YP Key not found: while looking up \"%s\" in map \"%s\"\n",
1322	user_name, nis_map));
1323	DEBUG(3, ("using defaults for server and home directory\n"));
1324	} else {
1325	DEBUG(3, ("YP Error: \"%s\" while looking up \"%s\" in map \"%s\"\n",
1326	yperr_string(nis_error), user_name, nis_map));
1327	}
1328
1329	if (value) {
1330	DEBUG(4, ("YP Lookup: %s resulted in %s\n", user_name, value));
1331	}
1332	return value;
1333	}
1334	#endif /* WITH_NISPLUS_HOME */
1335	#endif
1336
1337	/****************************************************************************
1338	Check if a process exists. Does this work on all unixes?
1339	****************************************************************************/
1340
1341	bool process_exists(const struct server_id pid)
1342	{
1343	if (procid_is_me(&pid)) {
1344	return True;
1345	}
1346
1347	if (procid_is_local(&pid)) {
1348	return (kill(pid.pid,0) == 0 \|\| errno != ESRCH);
1349	}
1350
1351	#ifdef CLUSTER_SUPPORT
1352	return ctdbd_process_exists(messaging_ctdbd_connection(), pid.vnn,
1353	pid.pid);
1354	#else
1355	return False;
1356	#endif
1357	}
1358
1359	/*******************************************************************
1360	Convert a uid into a user name.
1361	********************************************************************/
1362
1363	const char *uidtoname(uid_t uid)
1364	{
1365	TALLOC_CTX *ctx = talloc_tos();
1366	char *name = NULL;
1367	struct passwd *pass = NULL;
1368
1369	pass = getpwuid_alloc(ctx,uid);
1370	if (pass) {
1371	name = talloc_strdup(ctx,pass->pw_name);
1372	TALLOC_FREE(pass);
1373	} else {
1374	name = talloc_asprintf(ctx,
1375	"%ld",
1376	(long int)uid);
1377	}
1378	return name;
1379	}
1380
1381	/*******************************************************************
1382	Convert a gid into a group name.
1383	********************************************************************/
1384
1385	char *gidtoname(gid_t gid)
1386	{
1387	struct group *grp;
1388
1389	grp = getgrgid(gid);
1390	if (grp) {
1391	return talloc_strdup(talloc_tos(), grp->gr_name);
1392	}
1393	else {
1394	return talloc_asprintf(talloc_tos(),
1395	"%d",
1396	(int)gid);
1397	}
1398	}
1399
1400	/*******************************************************************
1401	Convert a user name into a uid.
1402	********************************************************************/
1403
1404	uid_t nametouid(const char *name)
1405	{
1406	struct passwd *pass;
1407	char *p;
1408	uid_t u;
1409
1410	pass = getpwnam_alloc(talloc_autofree_context(), name);
1411	if (pass) {
1412	u = pass->pw_uid;
1413	TALLOC_FREE(pass);
1414	return u;
1415	}
1416
1417	u = (uid_t)strtol(name, &p, 0);
1418	if ((p != name) && (*p == '\0'))
1419	return u;
1420
1421	return (uid_t)-1;
1422	}
1423
1424	/*******************************************************************
1425	Convert a name to a gid_t if possible. Return -1 if not a group.
1426	********************************************************************/
1427
1428	gid_t nametogid(const char *name)
1429	{
1430	struct group *grp;
1431	char *p;
1432	gid_t g;
1433
1434	g = (gid_t)strtol(name, &p, 0);
1435	if ((p != name) && (*p == '\0'))
1436	return g;
1437
1438	grp = sys_getgrnam(name);
1439	if (grp)
1440	return(grp->gr_gid);
1441	return (gid_t)-1;
1442	}
1443
1444	/*******************************************************************
1445	Something really nasty happened - panic !
1446	********************************************************************/
1447
1448	void smb_panic(const char *const why)
1449	{
1450	char *cmd;
1451	int result;
1452
1453	#ifdef DEVELOPER
1454	{
1455
1456	if (global_clobber_region_function) {
1457	DEBUG(0,("smb_panic: clobber_region() last called from [%s(%u)]\n",
1458	global_clobber_region_function,
1459	global_clobber_region_line));
1460	}
1461	}
1462	#endif
1463
1464	DEBUG(0,("PANIC (pid %llu): %s\n",
1465	(unsigned long long)sys_getpid(), why));
1466	log_stack_trace();
1467
1468	cmd = lp_panic_action();
1469	if (cmd && *cmd) {
1470	DEBUG(0, ("smb_panic(): calling panic action [%s]\n", cmd));
1471	result = system(cmd);
1472
1473	if (result == -1)
1474	DEBUG(0, ("smb_panic(): fork failed in panic action: %s\n",
1475	strerror(errno)));
1476	else
1477	DEBUG(0, ("smb_panic(): action returned status %d\n",
1478	WEXITSTATUS(result)));
1479	}
1480
1481	dump_core();
1482	}
1483
1484	/*******************************************************************
1485	Print a backtrace of the stack to the debug log. This function
1486	DELIBERATELY LEAKS MEMORY. The expectation is that you should
1487	exit shortly after calling it.
1488	********************************************************************/
1489
1490	#ifdef HAVE_LIBUNWIND_H
1491	#include <libunwind.h>
1492	#endif
1493
1494	#ifdef HAVE_EXECINFO_H
1495	#include <execinfo.h>
1496	#endif
1497
1498	#ifdef HAVE_LIBEXC_H
1499	#include <libexc.h>
1500	#endif
1501
1502	void log_stack_trace(void)
1503	{
1504	#ifdef HAVE_LIBUNWIND
1505	/* Try to use libunwind before any other technique since on ia64
1506	* libunwind correctly walks the stack in more circumstances than
1507	* backtrace.
1508	*/
1509	unw_cursor_t cursor;
1510	unw_context_t uc;
1511	unsigned i = 0;
1512
1513	char procname[256];
1514	unw_word_t ip, sp, off;
1515
1516	procname[sizeof(procname) - 1] = '\0';
1517
1518	if (unw_getcontext(&uc) != 0) {
1519	goto libunwind_failed;
1520	}
1521
1522	if (unw_init_local(&cursor, &uc) != 0) {
1523	goto libunwind_failed;
1524	}
1525
1526	DEBUG(0, ("BACKTRACE:\n"));
1527
1528	do {
1529	ip = sp = 0;
1530	unw_get_reg(&cursor, UNW_REG_IP, &ip);
1531	unw_get_reg(&cursor, UNW_REG_SP, &sp);
1532
1533	switch (unw_get_proc_name(&cursor,
1534	procname, sizeof(procname) - 1, &off) ) {
1535	case 0:
1536	/* Name found. */
1537	case -UNW_ENOMEM:
1538	/* Name truncated. */
1539	DEBUGADD(0, (" #%u %s + %#llx [ip=%#llx] [sp=%#llx]\n",
1540	i, procname, (long long)off,
1541	(long long)ip, (long long) sp));
1542	break;
1543	default:
1544	/* case -UNW_ENOINFO: */
1545	/* case -UNW_EUNSPEC: */
1546	/* No symbol name found. */
1547	DEBUGADD(0, (" #%u %s [ip=%#llx] [sp=%#llx]\n",
1548	i, "<unknown symbol>",
1549	(long long)ip, (long long) sp));
1550	}
1551	++i;
1552	} while (unw_step(&cursor) > 0);
1553
1554	return;
1555
1556	libunwind_failed:
1557	DEBUG(0, ("unable to produce a stack trace with libunwind\n"));
1558
1559	#elif HAVE_BACKTRACE_SYMBOLS
1560	void *backtrace_stack[BACKTRACE_STACK_SIZE];
1561	size_t backtrace_size;
1562	char **backtrace_strings;
1563
1564	/* get the backtrace (stack frames) */
1565	backtrace_size = backtrace(backtrace_stack,BACKTRACE_STACK_SIZE);
1566	backtrace_strings = backtrace_symbols(backtrace_stack, backtrace_size);
1567
1568	DEBUG(0, ("BACKTRACE: %lu stack frames:\n",
1569	(unsigned long)backtrace_size));
1570
1571	if (backtrace_strings) {
1572	int i;
1573
1574	for (i = 0; i < backtrace_size; i++)
1575	DEBUGADD(0, (" #%u %s\n", i, backtrace_strings[i]));
1576
1577	/* Leak the backtrace_strings, rather than risk what free() might do */
1578	}
1579
1580	#elif HAVE_LIBEXC
1581
1582	/* The IRIX libexc library provides an API for unwinding the stack. See
1583	* libexc(3) for details. Apparantly trace_back_stack leaks memory, but
1584	* since we are about to abort anyway, it hardly matters.
1585	*/
1586
1587	#define NAMESIZE 32 /* Arbitrary */
1588
1589	__uint64_t addrs[BACKTRACE_STACK_SIZE];
1590	char * names[BACKTRACE_STACK_SIZE];
1591	char namebuf[BACKTRACE_STACK_SIZE * NAMESIZE];
1592
1593	int i;
1594	int levels;
1595
1596	ZERO_ARRAY(addrs);
1597	ZERO_ARRAY(names);
1598	ZERO_ARRAY(namebuf);
1599
1600	/* We need to be root so we can open our /proc entry to walk
1601	* our stack. It also helps when we want to dump core.
1602	*/
1603	become_root();
1604
1605	for (i = 0; i < BACKTRACE_STACK_SIZE; i++) {
1606	names[i] = namebuf + (i * NAMESIZE);
1607	}
1608
1609	levels = trace_back_stack(0, addrs, names,
1610	BACKTRACE_STACK_SIZE, NAMESIZE - 1);
1611
1612	DEBUG(0, ("BACKTRACE: %d stack frames:\n", levels));
1613	for (i = 0; i < levels; i++) {
1614	DEBUGADD(0, (" #%d 0x%llx %s\n", i, addrs[i], names[i]));
1615	}
1616	#undef NAMESIZE
1617
1618	#else
1619	DEBUG(0, ("unable to produce a stack trace on this platform\n"));
1620	#endif
1621	}
1622
1623	/*******************************************************************
1624	A readdir wrapper which just returns the file name.
1625	********************************************************************/
1626
1627	const char readdirname(SMB_STRUCT_DIR p)
1628	{
1629	SMB_STRUCT_DIRENT *ptr;
1630	char *dname;
1631
1632	if (!p)
1633	return(NULL);
1634
1635	ptr = (SMB_STRUCT_DIRENT *)sys_readdir(p);
1636	if (!ptr)
1637	return(NULL);
1638
1639	dname = ptr->d_name;
1640
1641	#ifdef NEXT2
1642	if (telldir(p) < 0)
1643	return(NULL);
1644	#endif
1645
1646	#ifdef HAVE_BROKEN_READDIR_NAME
1647	/* using /usr/ucb/cc is BAD */
1648	dname = dname - 2;
1649	#endif
1650
1651	return talloc_strdup(talloc_tos(), dname);
1652	}
1653
1654	/*******************************************************************
1655	Utility function used to decide if the last component
1656	of a path matches a (possibly wildcarded) entry in a namelist.
1657	********************************************************************/
1658
1659	bool is_in_path(const char name, name_compare_entry namelist, bool case_sensitive)
1660	{
1661	const char *last_component;
1662
1663	/* if we have no list it's obviously not in the path */
1664	if((namelist == NULL ) \|\| ((namelist != NULL) && (namelist[0].name == NULL))) {
1665	return False;
1666	}
1667
1668	DEBUG(8, ("is_in_path: %s\n", name));
1669
1670	/* Get the last component of the unix name. */
1671	last_component = strrchr_m(name, '/');
1672	if (!last_component) {
1673	last_component = name;
1674	} else {
1675	last_component++; /* Go past '/' */
1676	}
1677
1678	for(; namelist->name != NULL; namelist++) {
1679	if(namelist->is_wild) {
1680	if (mask_match(last_component, namelist->name, case_sensitive)) {
1681	DEBUG(8,("is_in_path: mask match succeeded\n"));
1682	return True;
1683	}
1684	} else {
1685	if((case_sensitive && (strcmp(last_component, namelist->name) == 0))\|\|
1686	(!case_sensitive && (StrCaseCmp(last_component, namelist->name) == 0))) {
1687	DEBUG(8,("is_in_path: match succeeded\n"));
1688	return True;
1689	}
1690	}
1691	}
1692	DEBUG(8,("is_in_path: match not found\n"));
1693	return False;
1694	}
1695
1696	/*******************************************************************
1697	Strip a '/' separated list into an array of
1698	name_compare_enties structures suitable for
1699	passing to is_in_path(). We do this for
1700	speed so we can pre-parse all the names in the list
1701	and don't do it for each call to is_in_path().
1702	namelist is modified here and is assumed to be
1703	a copy owned by the caller.
1704	We also check if the entry contains a wildcard to
1705	remove a potentially expensive call to mask_match
1706	if possible.
1707	********************************************************************/
1708
1709	void set_namearray(name_compare_entry *ppname_array, const char namelist)
1710	{
1711	char *name_end;
1712	char nameptr = (char )namelist;
1713	int num_entries = 0;
1714	int i;
1715
1716	(*ppname_array) = NULL;
1717
1718	if((nameptr == NULL ) \|\| ((nameptr != NULL) && (*nameptr == '\0')))
1719	return;
1720
1721	/* We need to make two passes over the string. The
1722	first to count the number of elements, the second
1723	to split it.
1724	*/
1725
1726	while(*nameptr) {
1727	if ( *nameptr == '/' ) {
1728	/* cope with multiple (useless) /s) */
1729	nameptr++;
1730	continue;
1731	}
1732	/* anything left? */
1733	if ( *nameptr == '\0' )
1734	break;
1735
1736	/* find the next '/' or consume remaining */
1737	name_end = strchr_m(nameptr, '/');
1738	if (name_end == NULL)
1739	name_end = (char *)nameptr + strlen(nameptr);
1740
1741	/* next segment please */
1742	nameptr = name_end + 1;
1743	num_entries++;
1744	}
1745
1746	if(num_entries == 0)
1747	return;
1748
1749	if(( (*ppname_array) = SMB_MALLOC_ARRAY(name_compare_entry, num_entries + 1)) == NULL) {
1750	DEBUG(0,("set_namearray: malloc fail\n"));
1751	return;
1752	}
1753
1754	/* Now copy out the names */
1755	nameptr = (char *)namelist;
1756	i = 0;
1757	while(*nameptr) {
1758	if ( *nameptr == '/' ) {
1759	/* cope with multiple (useless) /s) */
1760	nameptr++;
1761	continue;
1762	}
1763	/* anything left? */
1764	if ( *nameptr == '\0' )
1765	break;
1766
1767	/* find the next '/' or consume remaining */
1768	name_end = strchr_m(nameptr, '/');
1769	if (name_end)
1770	*name_end = '\0';
1771	else
1772	name_end = nameptr + strlen(nameptr);
1773
1774	(*ppname_array)[i].is_wild = ms_has_wild(nameptr);
1775	if(((*ppname_array)[i].name = SMB_STRDUP(nameptr)) == NULL) {
1776	DEBUG(0,("set_namearray: malloc fail (1)\n"));
1777	return;
1778	}
1779
1780	/* next segment please */
1781	nameptr = name_end + 1;
1782	i++;
1783	}
1784
1785	(*ppname_array)[i].name = NULL;
1786
1787	return;
1788	}
1789
1790	/****************************************************************************
1791	Routine to free a namearray.
1792	****************************************************************************/
1793
1794	void free_namearray(name_compare_entry *name_array)
1795	{
1796	int i;
1797
1798	if(name_array == NULL)
1799	return;
1800
1801	for(i=0; name_array[i].name!=NULL; i++)
1802	SAFE_FREE(name_array[i].name);
1803	SAFE_FREE(name_array);
1804	}
1805
1806	#undef DBGC_CLASS
1807	#define DBGC_CLASS DBGC_LOCKING
1808
1809	/****************************************************************************
1810	Simple routine to query existing file locks. Cruft in NFS and 64->32 bit mapping
1811	is dealt with in posix.c
1812	Returns True if we have information regarding this lock region (and returns
1813	F_UNLCK in *ptype if the region is unlocked). False if the call failed.
1814	****************************************************************************/
1815
1816	bool fcntl_getlock(int fd, SMB_OFF_T poffset, SMB_OFF_T pcount, int ptype, pid_t ppid)
1817	{
1818	SMB_STRUCT_FLOCK lock;
1819	int ret;
1820
1821	DEBUG(8,("fcntl_getlock fd=%d offset=%.0f count=%.0f type=%d\n",
1822	fd,(double)poffset,(double)pcount,*ptype));
1823
1824	lock.l_type = *ptype;
1825	lock.l_whence = SEEK_SET;
1826	lock.l_start = *poffset;
1827	lock.l_len = *pcount;
1828	lock.l_pid = 0;
1829
1830	ret = sys_fcntl_ptr(fd,SMB_F_GETLK,&lock);
1831
1832	if (ret == -1) {
1833	int sav = errno;
1834	DEBUG(3,("fcntl_getlock: lock request failed at offset %.0f count %.0f type %d (%s)\n",
1835	(double)poffset,(double)pcount,*ptype,strerror(errno)));
1836	errno = sav;
1837	return False;
1838	}
1839
1840	*ptype = lock.l_type;
1841	*poffset = lock.l_start;
1842	*pcount = lock.l_len;
1843	*ppid = lock.l_pid;
1844
1845	DEBUG(3,("fcntl_getlock: fd %d is returned info %d pid %u\n",
1846	fd, (int)lock.l_type, (unsigned int)lock.l_pid));
1847	return True;
1848	}
1849
1850	#undef DBGC_CLASS
1851	#define DBGC_CLASS DBGC_ALL
1852
1853	/*******************************************************************
1854	Is the name specified one of my netbios names.
1855	Returns true if it is equal, false otherwise.
1856	********************************************************************/
1857
1858	bool is_myname(const char *s)
1859	{
1860	int n;
1861	bool ret = False;
1862
1863	for (n=0; my_netbios_names(n); n++) {
1864	if (strequal(my_netbios_names(n), s)) {
1865	ret=True;
1866	break;
1867	}
1868	}
1869	DEBUG(8, ("is_myname(\"%s\") returns %d\n", s, ret));
1870	return(ret);
1871	}
1872
1873	/*******************************************************************
1874	Is the name specified our workgroup/domain.
1875	Returns true if it is equal, false otherwise.
1876	********************************************************************/
1877
1878	bool is_myworkgroup(const char *s)
1879	{
1880	bool ret = False;
1881
1882	if (strequal(s, lp_workgroup())) {
1883	ret=True;
1884	}
1885
1886	DEBUG(8, ("is_myworkgroup(\"%s\") returns %d\n", s, ret));
1887	return(ret);
1888	}
1889
1890	/*******************************************************************
1891	we distinguish between 2K and XP by the "Native Lan Manager" string
1892	WinXP => "Windows 2002 5.1"
1893	WinXP 64bit => "Windows XP 5.2"
1894	Win2k => "Windows 2000 5.0"
1895	NT4 => "Windows NT 4.0"
1896	Win9x => "Windows 4.0"
1897	Windows 2003 doesn't set the native lan manager string but
1898	they do set the domain to "Windows 2003 5.2" (probably a bug).
1899	********************************************************************/
1900
1901	void ra_lanman_string( const char *native_lanman )
1902	{
1903	if ( strcmp( native_lanman, "Windows 2002 5.1" ) == 0 )
1904	set_remote_arch( RA_WINXP );
1905	else if ( strcmp( native_lanman, "Windows XP 5.2" ) == 0 )
1906	set_remote_arch( RA_WINXP64 );
1907	else if ( strcmp( native_lanman, "Windows Server 2003 5.2" ) == 0 )
1908	set_remote_arch( RA_WIN2K3 );
1909	}
1910
1911	static const char *remote_arch_str;
1912
1913	const char *get_remote_arch_str(void)
1914	{
1915	if (!remote_arch_str) {
1916	return "UNKNOWN";
1917	}
1918	return remote_arch_str;
1919	}
1920
1921	/*******************************************************************
1922	Set the horrid remote_arch string based on an enum.
1923	********************************************************************/
1924
1925	void set_remote_arch(enum remote_arch_types type)
1926	{
1927	ra_type = type;
1928	switch( type ) {
1929	case RA_WFWG:
1930	remote_arch_str = "WfWg";
1931	break;
1932	case RA_OS2:
1933	remote_arch_str = "OS2";
1934	break;
1935	case RA_WIN95:
1936	remote_arch_str = "Win95";
1937	break;
1938	case RA_WINNT:
1939	remote_arch_str = "WinNT";
1940	break;
1941	case RA_WIN2K:
1942	remote_arch_str = "Win2K";
1943	break;
1944	case RA_WINXP:
1945	remote_arch_str = "WinXP";
1946	break;
1947	case RA_WINXP64:
1948	remote_arch_str = "WinXP64";
1949	break;
1950	case RA_WIN2K3:
1951	remote_arch_str = "Win2K3";
1952	break;
1953	case RA_VISTA:
1954	remote_arch_str = "Vista";
1955	break;
1956	case RA_SAMBA:
1957	remote_arch_str = "Samba";
1958	break;
1959	case RA_CIFSFS:
1960	remote_arch_str = "CIFSFS";
1961	break;
1962	default:
1963	ra_type = RA_UNKNOWN;
1964	remote_arch_str = "UNKNOWN";
1965	break;
1966	}
1967
1968	DEBUG(10,("set_remote_arch: Client arch is \'%s\'\n",
1969	remote_arch_str));
1970	}
1971
1972	/*******************************************************************
1973	Get the remote_arch type.
1974	********************************************************************/
1975
1976	enum remote_arch_types get_remote_arch(void)
1977	{
1978	return ra_type;
1979	}
1980
1981	const char *tab_depth(int level, int depth)
1982	{
1983	if( CHECK_DEBUGLVL(level) ) {
1984	dbgtext("%s", depth4, "");
1985	}
1986	return "";
1987	}
1988
1989	/*****************************************************************************
1990	Provide a checksum on a string
1991
1992	Input: s - the null-terminated character string for which the checksum
1993	will be calculated.
1994
1995	Output: The checksum value calculated for s.
1996	*****************************************************************************/
1997
1998	int str_checksum(const char *s)
1999	{
2000	int res = 0;
2001	int c;
2002	int i=0;
2003
2004	while(*s) {
2005	c = *s;
2006	res ^= (c << (i % 15)) ^ (c >> (15-(i%15)));
2007	s++;
2008	i++;
2009	}
2010	return(res);
2011	}
2012
2013	/*****************************************************************
2014	Zero a memory area then free it. Used to catch bugs faster.
2015	*****************************************************************/
2016
2017	void zero_free(void *p, size_t size)
2018	{
2019	memset(p, 0, size);
2020	SAFE_FREE(p);
2021	}
2022
2023	/*****************************************************************
2024	Set our open file limit to a requested max and return the limit.
2025	*****************************************************************/
2026
2027	int set_maxfiles(int requested_max)
2028	{
2029	#if (defined(HAVE_GETRLIMIT) && defined(RLIMIT_NOFILE))
2030	struct rlimit rlp;
2031	int saved_current_limit;
2032
2033	if(getrlimit(RLIMIT_NOFILE, &rlp)) {
2034	DEBUG(0,("set_maxfiles: getrlimit (1) for RLIMIT_NOFILE failed with error %s\n",
2035	strerror(errno) ));
2036	/* just guess... */
2037	return requested_max;
2038	}
2039
2040	/*
2041	* Set the fd limit to be real_max_open_files + MAX_OPEN_FUDGEFACTOR to
2042	* account for the extra fd we need
2043	* as well as the log files and standard
2044	* handles etc. Save the limit we want to set in case
2045	* we are running on an OS that doesn't support this limit (AIX)
2046	* which always returns RLIM_INFINITY for rlp.rlim_max.
2047	*/
2048
2049	/* Try raising the hard (max) limit to the requested amount. */
2050
2051	#if defined(RLIM_INFINITY)
2052	if (rlp.rlim_max != RLIM_INFINITY) {
2053	int orig_max = rlp.rlim_max;
2054
2055	if ( rlp.rlim_max < requested_max )
2056	rlp.rlim_max = requested_max;
2057
2058	/* This failing is not an error - many systems (Linux) don't
2059	support our default request of 10,000 open files. JRA. */
2060
2061	if(setrlimit(RLIMIT_NOFILE, &rlp)) {
2062	DEBUG(3,("set_maxfiles: setrlimit for RLIMIT_NOFILE for %d max files failed with error %s\n",
2063	(int)rlp.rlim_max, strerror(errno) ));
2064
2065	/* Set failed - restore original value from get. */
2066	rlp.rlim_max = orig_max;
2067	}
2068	}
2069	#endif
2070
2071	/* Now try setting the soft (current) limit. */
2072
2073	saved_current_limit = rlp.rlim_cur = MIN(requested_max,rlp.rlim_max);
2074
2075	if(setrlimit(RLIMIT_NOFILE, &rlp)) {
2076	DEBUG(0,("set_maxfiles: setrlimit for RLIMIT_NOFILE for %d files failed with error %s\n",
2077	(int)rlp.rlim_cur, strerror(errno) ));
2078	/* just guess... */
2079	return saved_current_limit;
2080	}
2081
2082	if(getrlimit(RLIMIT_NOFILE, &rlp)) {
2083	DEBUG(0,("set_maxfiles: getrlimit (2) for RLIMIT_NOFILE failed with error %s\n",
2084	strerror(errno) ));
2085	/* just guess... */
2086	return saved_current_limit;
2087	}
2088
2089	#if defined(RLIM_INFINITY)
2090	if(rlp.rlim_cur == RLIM_INFINITY)
2091	return saved_current_limit;
2092	#endif
2093
2094	if((int)rlp.rlim_cur > saved_current_limit)
2095	return saved_current_limit;
2096
2097	return rlp.rlim_cur;
2098	#else /* !defined(HAVE_GETRLIMIT) \|\| !defined(RLIMIT_NOFILE) */
2099	/*
2100	* No way to know - just guess...
2101	*/
2102	return requested_max;
2103	#endif
2104	}
2105
2106	/*****************************************************************
2107	malloc that aborts with smb_panic on fail or zero size.
2108	*****************************************************************/
2109
2110	void *smb_xmalloc_array(size_t size, unsigned int count)
2111	{
2112	void *p;
2113	if (size == 0) {
2114	smb_panic("smb_xmalloc_array: called with zero size");
2115	}
2116	if (count >= MAX_ALLOC_SIZE/size) {
2117	smb_panic("smb_xmalloc_array: alloc size too large");
2118	}
2119	if ((p = SMB_MALLOC(size*count)) == NULL) {
2120	DEBUG(0, ("smb_xmalloc_array failed to allocate %lu * %lu bytes\n",
2121	(unsigned long)size, (unsigned long)count));
2122	smb_panic("smb_xmalloc_array: malloc failed");
2123	}
2124	return p;
2125	}
2126
2127	/*
2128	vasprintf that aborts on malloc fail
2129	*/
2130
2131	int smb_xvasprintf(char *ptr, const char format, va_list ap)
2132	{
2133	int n;
2134	va_list ap2;
2135
2136	va_copy(ap2, ap);
2137
2138	n = vasprintf(ptr, format, ap2);
2139	va_end(ap2);
2140	if (n == -1 \|\| ! *ptr) {
2141	smb_panic("smb_xvasprintf: out of memory");
2142	}
2143	return n;
2144	}
2145
2146	/*****************************************************************
2147	Get local hostname and cache result.
2148	*****************************************************************/
2149
2150	char *myhostname(void)
2151	{
2152	static char *ret;
2153	if (ret == NULL) {
2154	/* This is cached forever so
2155	* use talloc_autofree_context() ctx. */
2156	ret = get_myname(talloc_autofree_context());
2157	}
2158	return ret;
2159	}
2160
2161	/**
2162	* @brief Returns an absolute path to a file concatenating the provided
2163	* @a rootpath and @a basename
2164	*
2165	* @param name Filename, relative to @a rootpath
2166	*
2167	* @retval Pointer to a string containing the full path.
2168	**/
2169
2170	static char xx_path(const char name, const char *rootpath)
2171	{
2172	char *fname = NULL;
2173
2174	fname = talloc_strdup(talloc_tos(), rootpath);
2175	if (!fname) {
2176	return NULL;
2177	}
2178	trim_string(fname,"","/");
2179
2180	if (!directory_exist(fname)) {
2181	if (!mkdir(fname,0755))
2182	DEBUG(1, ("Unable to create directory %s for file %s. "
2183	"Error was %s\n", fname, name, strerror(errno)));
2184	}
2185
2186	return talloc_asprintf(talloc_tos(),
2187	"%s/%s",
2188	fname,
2189	name);
2190	}
2191
2192	/**
2193	* @brief Returns an absolute path to a file in the Samba lock directory.
2194	*
2195	* @param name File to find, relative to LOCKDIR.
2196	*
2197	* @retval Pointer to a talloc'ed string containing the full path.
2198	**/
2199
2200	char lock_path(const char name)
2201	{
2202	return xx_path(name, lp_lockdir());
2203	}
2204
2205	/**
2206	* @brief Returns an absolute path to a file in the Samba pid directory.
2207	*
2208	* @param name File to find, relative to PIDDIR.
2209	*
2210	* @retval Pointer to a talloc'ed string containing the full path.
2211	**/
2212
2213	char pid_path(const char name)
2214	{
2215	return xx_path(name, lp_piddir());
2216	}
2217
2218	/**
2219	* @brief Returns an absolute path to a file in the Samba lib directory.
2220	*
2221	* @param name File to find, relative to LIBDIR.
2222	*
2223	* @retval Pointer to a string containing the full path.
2224	**/
2225
2226	char lib_path(const char name)
2227	{
2228	return talloc_asprintf(talloc_tos(), "%s/%s", get_dyn_LIBDIR(), name);
2229	}
2230
2231	/**
2232	* @brief Returns an absolute path to a file in the Samba modules directory.
2233	*
2234	* @param name File to find, relative to MODULESDIR.
2235	*
2236	* @retval Pointer to a string containing the full path.
2237	**/
2238
2239	char modules_path(const char name)
2240	{
2241	return talloc_asprintf(talloc_tos(), "%s/%s", get_dyn_MODULESDIR(), name);
2242	}
2243
2244	/**
2245	* @brief Returns an absolute path to a file in the Samba data directory.
2246	*
2247	* @param name File to find, relative to CODEPAGEDIR.
2248	*
2249	* @retval Pointer to a talloc'ed string containing the full path.
2250	**/
2251
2252	char data_path(const char name)
2253	{
2254	return talloc_asprintf(talloc_tos(), "%s/%s", get_dyn_CODEPAGEDIR(), name);
2255	}
2256
2257	/**
2258	* @brief Returns an absolute path to a file in the Samba state directory.
2259	*
2260	* @param name File to find, relative to STATEDIR.
2261	*
2262	* @retval Pointer to a talloc'ed string containing the full path.
2263	**/
2264
2265	char state_path(const char name)
2266	{
2267	return xx_path(name, lp_statedir());
2268	}
2269
2270	/**
2271	* @brief Returns an absolute path to a file in the Samba cache directory.
2272	*
2273	* @param name File to find, relative to CACHEDIR.
2274	*
2275	* @retval Pointer to a talloc'ed string containing the full path.
2276	**/
2277
2278	char cache_path(const char name)
2279	{
2280	return xx_path(name, lp_cachedir());
2281	}
2282
2283	/**
2284	* @brief Returns the platform specific shared library extension.
2285	*
2286	* @retval Pointer to a const char * containing the extension.
2287	**/
2288
2289	const char *shlib_ext(void)
2290	{
2291	return get_dyn_SHLIBEXT();
2292	}
2293
2294	/*******************************************************************
2295	Given a filename - get its directory name
2296	********************************************************************/
2297
2298	bool parent_dirname(TALLOC_CTX mem_ctx, const char dir, char **parent,
2299	const char **name)
2300	{
2301	char *p;
2302	ptrdiff_t len;
2303
2304	p = strrchr_m(dir, '/'); /* Find final '/', if any */
2305
2306	if (p == NULL) {
2307	if (!(*parent = talloc_strdup(mem_ctx, "."))) {
2308	return False;
2309	}
2310	if (name) {
2311	*name = dir;
2312	}
2313	return True;
2314	}
2315
2316	len = p-dir;
2317
2318	if (!(parent = (char )TALLOC_MEMDUP(mem_ctx, dir, len+1))) {
2319	return False;
2320	}
2321	(*parent)[len] = '\0';
2322
2323	if (name) {
2324	*name = p+1;
2325	}
2326	return True;
2327	}
2328
2329	/*******************************************************************
2330	Determine if a pattern contains any Microsoft wildcard characters.
2331	*******************************************************************/
2332
2333	bool ms_has_wild(const char *s)
2334	{
2335	char c;
2336
2337	if (lp_posix_pathnames()) {
2338	/* With posix pathnames no characters are wild. */
2339	return False;
2340	}
2341
2342	while ((c = *s++)) {
2343	switch (c) {
2344	case '*':
2345	case '?':
2346	case '<':
2347	case '>':
2348	case '"':
2349	return True;
2350	}
2351	}
2352	return False;
2353	}
2354
2355	bool ms_has_wild_w(const smb_ucs2_t *s)
2356	{
2357	smb_ucs2_t c;
2358	if (!s) return False;
2359	while ((c = *s++)) {
2360	switch (c) {
2361	case UCS2_CHAR('*'):
2362	case UCS2_CHAR('?'):
2363	case UCS2_CHAR('<'):
2364	case UCS2_CHAR('>'):
2365	case UCS2_CHAR('"'):
2366	return True;
2367	}
2368	}
2369	return False;
2370	}
2371
2372	/*******************************************************************
2373	A wrapper that handles case sensitivity and the special handling
2374	of the ".." name.
2375	*******************************************************************/
2376
2377	bool mask_match(const char string, const char pattern, bool is_case_sensitive)
2378	{
2379	if (strcmp(string,"..") == 0)
2380	string = ".";
2381	if (strcmp(pattern,".") == 0)
2382	return False;
2383
2384	return ms_fnmatch(pattern, string, Protocol <= PROTOCOL_LANMAN2, is_case_sensitive) == 0;
2385	}
2386
2387	/*******************************************************************
2388	A wrapper that handles case sensitivity and the special handling
2389	of the ".." name. Varient that is only called by old search code which requires
2390	pattern translation.
2391	*******************************************************************/
2392
2393	bool mask_match_search(const char string, const char pattern, bool is_case_sensitive)
2394	{
2395	if (strcmp(string,"..") == 0)
2396	string = ".";
2397	if (strcmp(pattern,".") == 0)
2398	return False;
2399
2400	return ms_fnmatch(pattern, string, True, is_case_sensitive) == 0;
2401	}
2402
2403	/*******************************************************************
2404	A wrapper that handles a list of patters and calls mask_match()
2405	on each. Returns True if any of the patterns match.
2406	*******************************************************************/
2407
2408	bool mask_match_list(const char string, char *list, int listLen, bool is_case_sensitive)
2409	{
2410	while (listLen-- > 0) {
2411	if (mask_match(string, *list++, is_case_sensitive))
2412	return True;
2413	}
2414	return False;
2415	}
2416
2417	/*********************************************************
2418	Recursive routine that is called by unix_wild_match.
2419	*********************************************************/
2420
2421	static bool unix_do_match(const char regexp, const char str)
2422	{
2423	const char *p;
2424
2425	for( p = regexp; p && str; ) {
2426
2427	switch(*p) {
2428	case '?':
2429	str++;
2430	p++;
2431	break;
2432
2433	case '*':
2434
2435	/*
2436	* Look for a character matching
2437	* the one after the '*'.
2438	*/
2439	p++;
2440	if(!*p)
2441	return true; /* Automatic match */
2442	while(*str) {
2443
2444	while(str && (p != *str))
2445	str++;
2446
2447	/*
2448	* Patch from weidel@multichart.de. In the case of the regexp
2449	* 'XX' we want to ensure there are at least 2 'X' characters
2450	* in the string after the '*' for a match to be made.
2451	*/
2452
2453	{
2454	int matchcount=0;
2455
2456	/*
2457	* Eat all the characters that match, but count how many there were.
2458	*/
2459
2460	while(str && (p == *str)) {
2461	str++;
2462	matchcount++;
2463	}
2464
2465	/*
2466	* Now check that if the regexp had n identical characters that
2467	* matchcount had at least that many matches.
2468	*/
2469
2470	while ( (p+1) && ((p+1) == *p)) {
2471	p++;
2472	matchcount--;
2473	}
2474
2475	if ( matchcount <= 0 )
2476	return false;
2477	}
2478
2479	str--; /* We've eaten the match char after the '' /
2480
2481	if(unix_do_match(p, str))
2482	return true;
2483
2484	if(!*str)
2485	return false;
2486	else
2487	str++;
2488	}
2489	return false;
2490
2491	default:
2492	if(str != p)
2493	return false;
2494	str++;
2495	p++;
2496	break;
2497	}
2498	}
2499
2500	if(!p && !str)
2501	return true;
2502
2503	if (!*p && str[0] == '.' && str[1] == 0)
2504	return true;
2505
2506	if (!str && p == '?') {
2507	while (*p == '?')
2508	p++;
2509	return(!*p);
2510	}
2511
2512	if(!str && (p == '*' && p[1] == '\0'))
2513	return true;
2514
2515	return false;
2516	}
2517
2518	/*******************************************************************
2519	Simple case insensitive interface to a UNIX wildcard matcher.
2520	Returns True if match, False if not.
2521	*******************************************************************/
2522
2523	bool unix_wild_match(const char pattern, const char string)
2524	{
2525	TALLOC_CTX *ctx = talloc_stackframe();
2526	char *p2;
2527	char *s2;
2528	char *p;
2529	bool ret = false;
2530
2531	p2 = talloc_strdup(ctx,pattern);
2532	s2 = talloc_strdup(ctx,string);
2533	if (!p2 \|\| !s2) {
2534	TALLOC_FREE(ctx);
2535	return false;
2536	}
2537	strlower_m(p2);
2538	strlower_m(s2);
2539
2540	/* Remove any ? and * from the pattern as they are meaningless */
2541	for(p = p2; *p; p++) {
2542	while( p == '' && (p[1] == '?' \|\|p[1] == '*')) {
2543	memmove(&p[1], &p[2], strlen(&p[2])+1);
2544	}
2545	}
2546
2547	if (strequal(p2,"*")) {
2548	TALLOC_FREE(ctx);
2549	return true;
2550	}
2551
2552	ret = unix_do_match(p2, s2);
2553	TALLOC_FREE(ctx);
2554	return ret;
2555	}
2556
2557	/**********************************************************************
2558	Converts a name to a fully qualified domain name.
2559	Returns true if lookup succeeded, false if not (then fqdn is set to name)
2560	Note we deliberately use gethostbyname here, not getaddrinfo as we want
2561	to examine the h_aliases and I don't know how to do that with getaddrinfo.
2562	***********************************************************************/
2563
2564	bool name_to_fqdn(fstring fqdn, const char *name)
2565	{
2566	char *full = NULL;
2567	struct hostent *hp = gethostbyname(name);
2568
2569	if (!hp \|\| !hp->h_name \|\| !*hp->h_name) {
2570	DEBUG(10,("name_to_fqdn: lookup for %s failed.\n", name));
2571	fstrcpy(fqdn, name);
2572	return false;
2573	}
2574
2575	/* Find out if the fqdn is returned as an alias
2576	* to cope with /etc/hosts files where the first
2577	* name is not the fqdn but the short name */
2578	if (hp->h_aliases && (! strchr_m(hp->h_name, '.'))) {
2579	int i;
2580	for (i = 0; hp->h_aliases[i]; i++) {
2581	if (strchr_m(hp->h_aliases[i], '.')) {
2582	full = hp->h_aliases[i];
2583	break;
2584	}
2585	}
2586	}
2587	if (full && (StrCaseCmp(full, "localhost.localdomain") == 0)) {
2588	DEBUG(1, ("WARNING: your /etc/hosts file may be broken!\n"));
2589	DEBUGADD(1, (" Specifing the machine hostname for address 127.0.0.1 may lead\n"));
2590	DEBUGADD(1, (" to Kerberos authentication problems as localhost.localdomain\n"));
2591	DEBUGADD(1, (" may end up being used instead of the real machine FQDN.\n"));
2592	full = hp->h_name;
2593	}
2594	if (!full) {
2595	full = hp->h_name;
2596	}
2597
2598	DEBUG(10,("name_to_fqdn: lookup for %s -> %s.\n", name, full));
2599	fstrcpy(fqdn, full);
2600	return true;
2601	}
2602
2603	/**********************************************************************
2604	Append a DATA_BLOB to a talloc'ed object
2605	***********************************************************************/
2606
2607	void talloc_append_blob(TALLOC_CTX mem_ctx, void *buf, DATA_BLOB blob)
2608	{
2609	size_t old_size = 0;
2610	char *result;
2611
2612	if (blob.length == 0) {
2613	return buf;
2614	}
2615
2616	if (buf != NULL) {
2617	old_size = talloc_get_size(buf);
2618	}
2619
2620	result = (char *)TALLOC_REALLOC(mem_ctx, buf, old_size + blob.length);
2621	if (result == NULL) {
2622	return NULL;
2623	}
2624
2625	memcpy(result + old_size, blob.data, blob.length);
2626	return result;
2627	}
2628
2629	uint32 map_share_mode_to_deny_mode(uint32 share_access, uint32 private_options)
2630	{
2631	switch (share_access & ~FILE_SHARE_DELETE) {
2632	case FILE_SHARE_NONE:
2633	return DENY_ALL;
2634	case FILE_SHARE_READ:
2635	return DENY_WRITE;
2636	case FILE_SHARE_WRITE:
2637	return DENY_READ;
2638	case FILE_SHARE_READ\|FILE_SHARE_WRITE:
2639	return DENY_NONE;
2640	}
2641	if (private_options & NTCREATEX_OPTIONS_PRIVATE_DENY_DOS) {
2642	return DENY_DOS;
2643	} else if (private_options & NTCREATEX_OPTIONS_PRIVATE_DENY_FCB) {
2644	return DENY_FCB;
2645	}
2646
2647	return (uint32)-1;
2648	}
2649
2650	pid_t procid_to_pid(const struct server_id *proc)
2651	{
2652	return proc->pid;
2653	}
2654
2655	static uint32 my_vnn = NONCLUSTER_VNN;
2656
2657	void set_my_vnn(uint32 vnn)
2658	{
2659	DEBUG(10, ("vnn pid %d = %u\n", (int)sys_getpid(), (unsigned int)vnn));
2660	my_vnn = vnn;
2661	}
2662
2663	uint32 get_my_vnn(void)
2664	{
2665	return my_vnn;
2666	}
2667
2668	struct server_id pid_to_procid(pid_t pid)
2669	{
2670	struct server_id result;
2671	result.pid = pid;
2672	#ifdef CLUSTER_SUPPORT
2673	result.vnn = my_vnn;
2674	#endif
2675	return result;
2676	}
2677
2678	struct server_id procid_self(void)
2679	{
2680	return pid_to_procid(sys_getpid());
2681	}
2682
2683	struct server_id server_id_self(void)
2684	{
2685	return procid_self();
2686	}
2687
2688	bool procid_equal(const struct server_id p1, const struct server_id p2)
2689	{
2690	if (p1->pid != p2->pid)
2691	return False;
2692	#ifdef CLUSTER_SUPPORT
2693	if (p1->vnn != p2->vnn)
2694	return False;
2695	#endif
2696	return True;
2697	}
2698
2699	bool cluster_id_equal(const struct server_id *id1,
2700	const struct server_id *id2)
2701	{
2702	return procid_equal(id1, id2);
2703	}
2704
2705	bool procid_is_me(const struct server_id *pid)
2706	{
2707	if (pid->pid != sys_getpid())
2708	return False;
2709	#ifdef CLUSTER_SUPPORT
2710	if (pid->vnn != my_vnn)
2711	return False;
2712	#endif
2713	return True;
2714	}
2715
2716	struct server_id interpret_pid(const char *pid_string)
2717	{
2718	struct server_id result;
2719	int pid;
2720	#ifdef CLUSTER_SUPPORT
2721	unsigned int vnn;
2722	if (sscanf(pid_string, "%u:%d", &vnn, &pid) == 2) {
2723	result.vnn = vnn;
2724	result.pid = pid;
2725	}
2726	else if (sscanf(pid_string, "%d", &pid) == 1) {
2727	result.vnn = get_my_vnn();
2728	result.pid = pid;
2729	}
2730	else {
2731	result.vnn = NONCLUSTER_VNN;
2732	result.pid = -1;
2733	}
2734	#else
2735	if (sscanf(pid_string, "%d", &pid) != 1) {
2736	result.pid = -1;
2737	} else {
2738	result.pid = pid;
2739	}
2740	#endif
2741	/* Assigning to result.pid may have overflowed
2742	Map negative pid to -1: i.e. error */
2743	if (result.pid < 0) {
2744	result.pid = -1;
2745	}
2746	return result;
2747	}
2748
2749	char procid_str(TALLOC_CTX mem_ctx, const struct server_id *pid)
2750	{
2751	#ifdef CLUSTER_SUPPORT
2752	if (pid->vnn == NONCLUSTER_VNN) {
2753	return talloc_asprintf(mem_ctx,
2754	"%d",
2755	(int)pid->pid);
2756	}
2757	else {
2758	return talloc_asprintf(mem_ctx,
2759	"%u:%d",
2760	(unsigned)pid->vnn,
2761	(int)pid->pid);
2762	}
2763	#else
2764	return talloc_asprintf(mem_ctx,
2765	"%d",
2766	(int)pid->pid);
2767	#endif
2768	}
2769
2770	char procid_str_static(const struct server_id pid)
2771	{
2772	return procid_str(talloc_tos(), pid);
2773	}
2774
2775	bool procid_valid(const struct server_id *pid)
2776	{
2777	return (pid->pid != -1);
2778	}
2779
2780	bool procid_is_local(const struct server_id *pid)
2781	{
2782	#ifdef CLUSTER_SUPPORT
2783	return pid->vnn == my_vnn;
2784	#else
2785	return True;
2786	#endif
2787	}
2788
2789	int this_is_smp(void)
2790	{
2791	#if defined(HAVE_SYSCONF)
2792
2793	#if defined(SYSCONF_SC_NPROC_ONLN)
2794	return (sysconf(_SC_NPROC_ONLN) > 1) ? 1 : 0;
2795	#elif defined(SYSCONF_SC_NPROCESSORS_ONLN)
2796	return (sysconf(_SC_NPROCESSORS_ONLN) > 1) ? 1 : 0;
2797	#else
2798	return 0;
2799	#endif
2800
2801	#else
2802	return 0;
2803	#endif
2804	}
2805
2806	/****************************************************************
2807	Check if offset/length fit into bufsize. Should probably be
2808	merged with is_offset_safe, but this would require a rewrite
2809	of lanman.c. Later :-)
2810	****************************************************************/
2811
2812	bool trans_oob(uint32_t bufsize, uint32_t offset, uint32_t length)
2813	{
2814	if ((offset + length < offset) \|\| (offset + length < length)) {
2815	/* wrap */
2816	return true;
2817	}
2818	if ((offset > bufsize) \|\| (offset + length > bufsize)) {
2819	/* overflow */
2820	return true;
2821	}
2822	return false;
2823	}
2824
2825	/****************************************************************
2826	Check if an offset into a buffer is safe.
2827	If this returns True it's safe to indirect into the byte at
2828	pointer ptr+off.
2829	****************************************************************/
2830
2831	bool is_offset_safe(const char buf_base, size_t buf_len, char ptr, size_t off)
2832	{
2833	const char *end_base = buf_base + buf_len;
2834	char *end_ptr = ptr + off;
2835
2836	if (!buf_base \|\| !ptr) {
2837	return False;
2838	}
2839
2840	if (end_base < buf_base \|\| end_ptr < ptr) {
2841	return False; /* wrap. */
2842	}
2843
2844	if (end_ptr < end_base) {
2845	return True;
2846	}
2847	return False;
2848	}
2849
2850	/****************************************************************
2851	Return a safe pointer into a buffer, or NULL.
2852	****************************************************************/
2853
2854	char get_safe_ptr(const char buf_base, size_t buf_len, char *ptr, size_t off)
2855	{
2856	return is_offset_safe(buf_base, buf_len, ptr, off) ?
2857	ptr + off : NULL;
2858	}
2859
2860	/****************************************************************
2861	Return a safe pointer into a string within a buffer, or NULL.
2862	****************************************************************/
2863
2864	char get_safe_str_ptr(const char buf_base, size_t buf_len, char *ptr, size_t off)
2865	{
2866	if (!is_offset_safe(buf_base, buf_len, ptr, off)) {
2867	return NULL;
2868	}
2869	/* Check if a valid string exists at this offset. */
2870	if (skip_string(buf_base,buf_len, ptr + off) == NULL) {
2871	return NULL;
2872	}
2873	return ptr + off;
2874	}
2875
2876	/****************************************************************
2877	Return an SVAL at a pointer, or failval if beyond the end.
2878	****************************************************************/
2879
2880	int get_safe_SVAL(const char buf_base, size_t buf_len, char ptr, size_t off, int failval)
2881	{
2882	/*
2883	* Note we use off+1 here, not off+2 as SVAL accesses ptr[0] and ptr[1],
2884	* NOT ptr[2].
2885	*/
2886	if (!is_offset_safe(buf_base, buf_len, ptr, off+1)) {
2887	return failval;
2888	}
2889	return SVAL(ptr,off);
2890	}
2891
2892	/****************************************************************
2893	Return an IVAL at a pointer, or failval if beyond the end.
2894	****************************************************************/
2895
2896	int get_safe_IVAL(const char buf_base, size_t buf_len, char ptr, size_t off, int failval)
2897	{
2898	/*
2899	* Note we use off+3 here, not off+4 as IVAL accesses
2900	* ptr[0] ptr[1] ptr[2] ptr[3] NOT ptr[4].
2901	*/
2902	if (!is_offset_safe(buf_base, buf_len, ptr, off+3)) {
2903	return failval;
2904	}
2905	return IVAL(ptr,off);
2906	}
2907
2908	/****************************************************************
2909	Split DOM\user into DOM and user. Do not mix with winbind variants of that
2910	call (they take care of winbind separator and other winbind specific settings).
2911	****************************************************************/
2912
2913	void split_domain_user(TALLOC_CTX *mem_ctx,
2914	const char *full_name,
2915	char **domain,
2916	char **user)
2917	{
2918	const char *p = NULL;
2919
2920	p = strchr_m(full_name, '\\');
2921
2922	if (p != NULL) {
2923	*domain = talloc_strndup(mem_ctx, full_name,
2924	PTR_DIFF(p, full_name));
2925	*user = talloc_strdup(mem_ctx, p+1);
2926	} else {
2927	*domain = talloc_strdup(mem_ctx, "");
2928	*user = talloc_strdup(mem_ctx, full_name);
2929	}
2930	}
2931
2932	#if 0
2933
2934	Disable these now we have checked all code paths and ensured
2935	NULL returns on zero request. JRA.
2936
2937	/****************************************************************
2938	talloc wrapper functions that guarentee a null pointer return
2939	if size == 0.
2940	****************************************************************/
2941
2942	#ifndef MAX_TALLOC_SIZE
2943	#define MAX_TALLOC_SIZE 0x10000000
2944	#endif
2945
2946	/*
2947	* talloc and zero memory.
2948	* - returns NULL if size is zero.
2949	*/
2950
2951	void _talloc_zero_zeronull(const void ctx, size_t size, const char *name)
2952	{
2953	void *p;
2954
2955	if (size == 0) {
2956	return NULL;
2957	}
2958
2959	p = talloc_named_const(ctx, size, name);
2960
2961	if (p) {
2962	memset(p, '\0', size);
2963	}
2964
2965	return p;
2966	}
2967
2968	/*
2969	* memdup with a talloc.
2970	* - returns NULL if size is zero.
2971	*/
2972
2973	void _talloc_memdup_zeronull(const void t, const void p, size_t size, const char name)
2974	{
2975	void *newp;
2976
2977	if (size == 0) {
2978	return NULL;
2979	}
2980
2981	newp = talloc_named_const(t, size, name);
2982	if (newp) {
2983	memcpy(newp, p, size);
2984	}
2985
2986	return newp;
2987	}
2988
2989	/*
2990	* alloc an array, checking for integer overflow in the array size.
2991	* - returns NULL if count or el_size are zero.
2992	*/
2993
2994	void _talloc_array_zeronull(const void ctx, size_t el_size, unsigned count, const char *name)
2995	{
2996	if (count >= MAX_TALLOC_SIZE/el_size) {
2997	return NULL;
2998	}
2999
3000	if (el_size == 0 \|\| count == 0) {
3001	return NULL;
3002	}
3003
3004	return talloc_named_const(ctx, el_size * count, name);
3005	}
3006
3007	/*
3008	* alloc an zero array, checking for integer overflow in the array size
3009	* - returns NULL if count or el_size are zero.
3010	*/
3011
3012	void _talloc_zero_array_zeronull(const void ctx, size_t el_size, unsigned count, const char *name)
3013	{
3014	if (count >= MAX_TALLOC_SIZE/el_size) {
3015	return NULL;
3016	}
3017
3018	if (el_size == 0 \|\| count == 0) {
3019	return NULL;
3020	}
3021
3022	return _talloc_zero(ctx, el_size * count, name);
3023	}
3024
3025	/*
3026	* Talloc wrapper that returns NULL if size == 0.
3027	*/
3028	void talloc_zeronull(const void context, size_t size, const char *name)
3029	{
3030	if (size == 0) {
3031	return NULL;
3032	}
3033	return talloc_named_const(context, size, name);
3034	}
3035	#endif
3036
3037	bool is_valid_policy_hnd(const struct policy_handle *hnd)
3038	{
3039	struct policy_handle tmp;
3040	ZERO_STRUCT(tmp);
3041	return (memcmp(&tmp, hnd, sizeof(tmp)) != 0);
3042	}
3043
3044	bool policy_hnd_equal(const struct policy_handle *hnd1,
3045	const struct policy_handle *hnd2)
3046	{
3047	if (!hnd1 \|\| !hnd2) {
3048	return false;
3049	}
3050
3051	return (memcmp(hnd1, hnd2, sizeof(*hnd1)) == 0);
3052	}
3053
3054	/****************************************************************
3055	strip off leading '\\' from a hostname
3056	****************************************************************/
3057
3058	const char strip_hostname(const char s)
3059	{
3060	if (!s) {
3061	return NULL;
3062	}
3063
3064	if (strlen_m(s) < 3) {
3065	return s;
3066	}
3067
3068	if (s[0] == '\\') s++;
3069	if (s[0] == '\\') s++;
3070
3071	return s;
3072	}

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