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source: trunk/lib/regfi.c @ 257

Last change on this file since 257 was 257, checked in by tim, 13 years ago
documentation fixes/additions
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File size: 106.4 KB

Rev	Line
[30]	1	/*
[169]	2	* Copyright (C) 2005-2010 Timothy D. Morgan
[30]	3	* Copyright (C) 2005 Gerald (Jerry) Carter
	4	*
	5	* This program is free software; you can redistribute it and/or modify
	6	* it under the terms of the GNU General Public License as published by
[111]	7	* the Free Software Foundation; version 3 of the License.
[30]	8	*
	9	* This program is distributed in the hope that it will be useful,
	10	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	11	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	12	* GNU General Public License for more details.
	13	*
	14	* You should have received a copy of the GNU General Public License
	15	* along with this program; if not, write to the Free Software
[161]	16	* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
[30]	17	*
	18	* $Id: regfi.c 257 2011-06-17 00:13:13Z tim $
	19	*/
	20
[169]	21	/**
	22	* @file
	23	*
	24	* Windows NT (and later) read-only registry library
	25	*
	26	* See @ref regfi.h for more information.
	27	*
	28	* Branched from Samba project Subversion repository, version #7470:
	29	* http://viewcvs.samba.org/cgi-bin/viewcvs.cgi/trunk/source/registry/regfio.c?rev=7470&view=auto
	30	*
	31	* Since then, it has been heavily rewritten, simplified, and improved.
	32	*/
[168]	33
[147]	34	#include "regfi.h"
[30]	35
[233]	36	/* Library version can be overridden at build time */
	37	#ifndef REGFI_VERSION
	38	#define REGFI_VERSION "trunk"
	39	#endif
[30]	40
[233]	41
[32]	42	/* Registry types mapping */
[78]	43	const unsigned int regfi_num_reg_types = 12;
	44	static const char* regfi_type_names[] =
[65]	45	{"NONE", "SZ", "EXPAND_SZ", "BINARY", "DWORD", "DWORD_BE", "LINK",
[72]	46	"MULTI_SZ", "RSRC_LIST", "RSRC_DESC", "RSRC_REQ_LIST", "QWORD"};
[30]	47
[161]	48	const char* regfi_encoding_names[] =
	49	{"US-ASCII//TRANSLIT", "UTF-8//TRANSLIT", "UTF-16LE//TRANSLIT"};
[32]	50
[135]	51
[185]	52	/* Ensures regfi_init runs only once */
	53	static pthread_once_t regfi_init_once = PTHREAD_ONCE_INIT;
[182]	54
[185]	55
[233]	56	/******************************************************************************
	57	******************************************************************************/
	58	const char* regfi_version()
	59	{
	60	return REGFI_VERSION;
	61	}
[185]	62
[233]	63
[135]	64	/******************************************************************************
	65	******************************************************************************/
[185]	66	void regfi_log_free(void* ptr)
[135]	67	{
[185]	68	REGFI_LOG* log_info = (REGFI_LOG*)ptr;
	69
	70	if(log_info->messages != NULL)
	71	free(log_info->messages);
	72
	73	talloc_free(log_info);
	74	}
	75
	76
	77	/******************************************************************************
	78	******************************************************************************/
	79	void regfi_init()
	80	{
	81	int err;
	82	if((err = pthread_key_create(&regfi_log_key, regfi_log_free)) != 0)
	83	fprintf(stderr, "ERROR: key_create: %s\n", strerror(err));
	84	errno = err;
	85	}
	86
	87
	88	/******************************************************************************
	89	******************************************************************************/
	90	REGFI_LOG* regfi_log_new()
	91	{
	92	int err;
[182]	93	REGFI_LOG* log_info = talloc(NULL, REGFI_LOG);
	94	if(log_info == NULL)
[185]	95	return NULL;
[182]	96
[185]	97	log_info->msg_mask = REGFI_DEFAULT_LOG_MASK;
[182]	98	log_info->messages = NULL;
	99
[185]	100	pthread_once(&regfi_init_once, regfi_init);
[182]	101
[185]	102	if((err = pthread_setspecific(regfi_log_key, log_info)) != 0)
[182]	103	{
[185]	104	fprintf(stderr, "ERROR: setspecific: %s\n", strerror(err));
[182]	105	goto fail;
	106	}
	107
[185]	108	return log_info;
[182]	109
	110	fail:
	111	talloc_free(log_info);
[185]	112	errno = err;
	113	return NULL;
[182]	114	}
	115
	116
	117	/******************************************************************************
	118	******************************************************************************/
	119	void regfi_log_add(uint16_t msg_type, const char* fmt, ...)
	120	{
	121	/* XXX: Switch internal storage over to a linked list or stack.
	122	* Then add a regfi_log_get function that returns the list in some
	123	* convenient, user-friendly data structure. regfi_log_get_str should
	124	* stick around and will simply smush the list into a big string when
	125	* it's called, rather than having messages smushed when they're first
	126	* written to the log.
[135]	127	*/
[168]	128	uint32_t buf_size, buf_used;
[136]	129	char* new_msg;
[182]	130	REGFI_LOG* log_info;
[136]	131	va_list args;
[135]	132
[185]	133	log_info = (REGFI_LOG*)pthread_getspecific(regfi_log_key);
	134	if(log_info == NULL && (log_info = regfi_log_new()) == NULL)
[182]	135	return;
	136
[185]	137	if((log_info->msg_mask & msg_type) == 0)
	138	return;
	139
[182]	140	if(log_info->messages == NULL)
	141	buf_used = 0;
	142	else
	143	buf_used = strlen(log_info->messages);
	144
	145	buf_size = buf_used+strlen(fmt)+160;
	146	new_msg = realloc(log_info->messages, buf_size);
	147	if(new_msg == NULL)
	148	/* XXX: should we report this? */
	149	return;
	150
	151	switch (msg_type)
[138]	152	{
[182]	153	case REGFI_LOG_INFO:
	154	strcpy(new_msg+buf_used, "INFO: ");
	155	buf_used += 6;
	156	break;
	157	case REGFI_LOG_WARN:
	158	strcpy(new_msg+buf_used, "WARN: ");
	159	buf_used += 6;
	160	break;
	161	case REGFI_LOG_ERROR:
	162	strcpy(new_msg+buf_used, "ERROR: ");
	163	buf_used += 7;
	164	break;
[138]	165	}
[182]	166
	167	va_start(args, fmt);
	168	vsnprintf(new_msg+buf_used, buf_size-buf_used, fmt, args);
	169	va_end(args);
	170	strncat(new_msg, "\n", buf_size-1);
	171
	172	log_info->messages = new_msg;
[135]	173	}
	174
	175
	176	/******************************************************************************
	177	******************************************************************************/
[182]	178	char* regfi_log_get_str()
[135]	179	{
[182]	180	char* ret_val;
[185]	181	REGFI_LOG* log_info = (REGFI_LOG*)pthread_getspecific(regfi_log_key);
	182	if(log_info == NULL && (log_info = regfi_log_new()) == NULL)
[182]	183	return NULL;
[185]	184
[182]	185	ret_val = log_info->messages;
	186	log_info->messages = NULL;
	187
[135]	188	return ret_val;
	189	}
	190
	191
[182]	192	/******************************************************************************
	193	******************************************************************************/
[185]	194	bool regfi_log_set_mask(uint16_t msg_mask)
[138]	195	{
[185]	196	REGFI_LOG* log_info = (REGFI_LOG*)pthread_getspecific(regfi_log_key);
	197	if(log_info == NULL && (log_info = regfi_log_new()) == NULL)
	198	{
	199	return false;
	200	}
[182]	201
	202	log_info->msg_mask = msg_mask;
[185]	203	return true;
[138]	204	}
	205
	206
[161]	207	/******************************************************************************
	208	* Returns NULL for an invalid e
	209	*****************************************************************************/
	210	static const char* regfi_encoding_int2str(REGFI_ENCODING e)
	211	{
	212	if(e < REGFI_NUM_ENCODINGS)
	213	return regfi_encoding_names[e];
	214
	215	return NULL;
	216	}
	217
	218
	219	/******************************************************************************
	220	* Returns NULL for an invalid val
	221	*****************************************************************************/
[78]	222	const char* regfi_type_val2str(unsigned int val)
[32]	223	{
[61]	224	if(val == REG_KEY)
	225	return "KEY";
	226
[78]	227	if(val >= regfi_num_reg_types)
[61]	228	return NULL;
	229
[78]	230	return regfi_type_names[val];
[32]	231	}
	232
	233
[161]	234	/******************************************************************************
	235	* Returns -1 on error
	236	*****************************************************************************/
[78]	237	int regfi_type_str2val(const char* str)
[32]	238	{
	239	int i;
	240
[61]	241	if(strcmp("KEY", str) == 0)
	242	return REG_KEY;
[32]	243
[78]	244	for(i=0; i < regfi_num_reg_types; i++)
	245	if (strcmp(regfi_type_names[i], str) == 0)
[61]	246	return i;
	247
	248	if(strcmp("DWORD_LE", str) == 0)
	249	return REG_DWORD_LE;
	250
	251	return -1;
[32]	252	}
	253
	254
[135]	255	/* Security descriptor formatting functions */
[53]	256
[168]	257	const char* regfi_ace_type2str(uint8_t type)
[53]	258	{
	259	static const char* map[7]
	260	= {"ALLOW", "DENY", "AUDIT", "ALARM",
	261	"ALLOW CPD", "OBJ ALLOW", "OBJ DENY"};
	262	if(type < 7)
	263	return map[type];
	264	else
	265	/* XXX: would be nice to return the unknown integer value.
	266	* However, as it is a const string, it can't be free()ed later on,
	267	* so that would need to change.
	268	*/
	269	return "UNKNOWN";
	270	}
	271
	272
[76]	273	/* XXX: need a better reference on the meaning of each flag. */
	274	/* For more info, see:
	275	* http://msdn2.microsoft.com/en-us/library/aa772242.aspx
	276	*/
[168]	277	char* regfi_ace_flags2str(uint8_t flags)
[53]	278	{
[76]	279	static const char* flag_map[32] =
[87]	280	{ "OI", /* Object Inherit */
	281	"CI", /* Container Inherit */
	282	"NP", /* Non-Propagate */
	283	"IO", /* Inherit Only */
	284	"IA", /* Inherited ACE */
[76]	285	NULL,
	286	NULL,
	287	NULL,
	288	};
[53]	289
[76]	290	char* ret_val = malloc(35*sizeof(char));
	291	char* fo = ret_val;
[168]	292	uint32_t i;
	293	uint8_t f;
[76]	294
	295	if(ret_val == NULL)
[53]	296	return NULL;
	297
[76]	298	fo[0] = '\0';
[53]	299	if (!flags)
[76]	300	return ret_val;
[53]	301
[76]	302	for(i=0; i < 8; i++)
	303	{
	304	f = (1<<i);
	305	if((flags & f) && (flag_map[i] != NULL))
	306	{
	307	strcpy(fo, flag_map[i]);
	308	fo += strlen(flag_map[i]);
	309	*(fo++) = ' ';
	310	flags ^= f;
	311	}
[53]	312	}
[76]	313
	314	/* Any remaining unknown flags are added at the end in hex. */
	315	if(flags != 0)
	316	sprintf(fo, "0x%.2X ", flags);
	317
	318	/* Chop off the last space if we've written anything to ret_val */
	319	if(fo != ret_val)
	320	fo[-1] = '\0';
	321
	322	return ret_val;
[53]	323	}
	324
	325
[168]	326	char* regfi_ace_perms2str(uint32_t perms)
[53]	327	{
[168]	328	uint32_t i, p;
[76]	329	/* This is more than is needed by a fair margin. */
	330	char* ret_val = malloc(350*sizeof(char));
	331	char* r = ret_val;
	332
	333	/* Each represents one of 32 permissions bits. NULL is for undefined/reserved bits.
	334	* For more information, see:
	335	* http://msdn2.microsoft.com/en-gb/library/aa374892.aspx
	336	* http://msdn2.microsoft.com/en-gb/library/ms724878.aspx
	337	*/
	338	static const char* perm_map[32] =
	339	{/* object-specific permissions (registry keys, in this case) */
	340	"QRY_VAL", /* KEY_QUERY_VALUE */
	341	"SET_VAL", /* KEY_SET_VALUE */
	342	"CREATE_KEY", /* KEY_CREATE_SUB_KEY */
	343	"ENUM_KEYS", /* KEY_ENUMERATE_SUB_KEYS */
	344	"NOTIFY", /* KEY_NOTIFY */
	345	"CREATE_LNK", /* KEY_CREATE_LINK - Reserved for system use. */
	346	NULL,
	347	NULL,
	348	"WOW64_64", /* KEY_WOW64_64KEY */
	349	"WOW64_32", /* KEY_WOW64_32KEY */
	350	NULL,
	351	NULL,
	352	NULL,
	353	NULL,
	354	NULL,
	355	NULL,
	356	/* standard access rights */
	357	"DELETE", /* DELETE */
	358	"R_CONT", /* READ_CONTROL */
	359	"W_DAC", /* WRITE_DAC */
	360	"W_OWNER", /* WRITE_OWNER */
	361	"SYNC", /* SYNCHRONIZE - Shouldn't be set in registries */
	362	NULL,
	363	NULL,
	364	NULL,
	365	/* other generic */
	366	"SYS_SEC", /* ACCESS_SYSTEM_SECURITY */
	367	"MAX_ALLWD", /* MAXIMUM_ALLOWED */
	368	NULL,
	369	NULL,
	370	"GEN_A", /* GENERIC_ALL */
	371	"GEN_X", /* GENERIC_EXECUTE */
	372	"GEN_W", /* GENERIC_WRITE */
	373	"GEN_R", /* GENERIC_READ */
	374	};
	375
	376
[53]	377	if(ret_val == NULL)
	378	return NULL;
	379
[76]	380	r[0] = '\0';
	381	for(i=0; i < 32; i++)
	382	{
	383	p = (1<<i);
	384	if((perms & p) && (perm_map[i] != NULL))
	385	{
	386	strcpy(r, perm_map[i]);
	387	r += strlen(perm_map[i]);
	388	*(r++) = ' ';
	389	perms ^= p;
	390	}
	391	}
	392
	393	/* Any remaining unknown permission bits are added at the end in hex. */
	394	if(perms != 0)
	395	sprintf(r, "0x%.8X ", perms);
[53]	396
[76]	397	/* Chop off the last space if we've written anything to ret_val */
	398	if(r != ret_val)
	399	r[-1] = '\0';
	400
[53]	401	return ret_val;
	402	}
	403
	404
[134]	405	char* regfi_get_acl(WINSEC_ACL* acl)
[53]	406	{
[168]	407	uint32_t i, extra, size = 0;
[53]	408	const char* type_str;
	409	char* flags_str;
	410	char* perms_str;
	411	char* sid_str;
[61]	412	char* ace_delim = "";
[53]	413	char* ret_val = NULL;
[61]	414	char* tmp_val = NULL;
	415	bool failed = false;
[53]	416	char field_delim = ':';
	417
[61]	418	for (i = 0; i < acl->num_aces && !failed; i++)
[53]	419	{
[253]	420	sid_str = winsec_sid2str(acl->aces[i]->trustee);
[134]	421	type_str = regfi_ace_type2str(acl->aces[i]->type);
	422	perms_str = regfi_ace_perms2str(acl->aces[i]->access_mask);
	423	flags_str = regfi_ace_flags2str(acl->aces[i]->flags);
[53]	424
[61]	425	if(flags_str != NULL && perms_str != NULL
	426	&& type_str != NULL && sid_str != NULL)
	427	{
	428	/* XXX: this is slow */
	429	extra = strlen(sid_str) + strlen(type_str)
[136]	430	+ strlen(perms_str) + strlen(flags_str) + 5;
[61]	431	tmp_val = realloc(ret_val, size+extra);
[53]	432
[61]	433	if(tmp_val == NULL)
	434	{
	435	free(ret_val);
[136]	436	ret_val = NULL;
[61]	437	failed = true;
	438	}
	439	else
	440	{
	441	ret_val = tmp_val;
[148]	442	size += sprintf(ret_val+size, "%s%s%c%s%c%s%c%s",
	443	ace_delim,sid_str,
	444	field_delim,type_str,
	445	field_delim,perms_str,
	446	field_delim,flags_str);
[61]	447	ace_delim = "\|";
	448	}
	449	}
	450	else
	451	failed = true;
	452
	453	if(sid_str != NULL)
	454	free(sid_str);
	455	if(sid_str != NULL)
	456	free(perms_str);
	457	if(sid_str != NULL)
	458	free(flags_str);
[53]	459	}
	460
	461	return ret_val;
	462	}
	463
	464
[134]	465	char* regfi_get_sacl(WINSEC_DESC *sec_desc)
[53]	466	{
	467	if (sec_desc->sacl)
[78]	468	return regfi_get_acl(sec_desc->sacl);
[53]	469	else
	470	return NULL;
	471	}
	472
	473
[134]	474	char* regfi_get_dacl(WINSEC_DESC *sec_desc)
[53]	475	{
	476	if (sec_desc->dacl)
[78]	477	return regfi_get_acl(sec_desc->dacl);
[53]	478	else
	479	return NULL;
	480	}
	481
	482
[134]	483	char* regfi_get_owner(WINSEC_DESC *sec_desc)
[53]	484	{
[253]	485	return winsec_sid2str(sec_desc->owner_sid);
[53]	486	}
	487
	488
[134]	489	char* regfi_get_group(WINSEC_DESC *sec_desc)
[53]	490	{
[253]	491	return winsec_sid2str(sec_desc->grp_sid);
[53]	492	}
	493
	494
[180]	495	bool regfi_read_lock(REGFI_FILE* file, pthread_rwlock_t* lock, const char* context)
	496	{
	497	int lock_ret = pthread_rwlock_rdlock(lock);
	498	if(lock_ret != 0)
	499	{
[182]	500	regfi_log_add(REGFI_LOG_ERROR, "Error obtaining read lock in"
[180]	501	"%s due to: %s\n", context, strerror(lock_ret));
	502	return false;
	503	}
	504
	505	return true;
	506	}
	507
	508
	509	bool regfi_write_lock(REGFI_FILE* file, pthread_rwlock_t* lock, const char* context)
	510	{
	511	int lock_ret = pthread_rwlock_wrlock(lock);
	512	if(lock_ret != 0)
	513	{
[182]	514	regfi_log_add(REGFI_LOG_ERROR, "Error obtaining write lock in"
[180]	515	"%s due to: %s\n", context, strerror(lock_ret));
	516	return false;
	517	}
	518
	519	return true;
	520	}
	521
	522
	523	bool regfi_rw_unlock(REGFI_FILE* file, pthread_rwlock_t* lock, const char* context)
	524	{
	525	int lock_ret = pthread_rwlock_unlock(lock);
	526	if(lock_ret != 0)
	527	{
[182]	528	regfi_log_add(REGFI_LOG_ERROR, "Error releasing lock in"
[180]	529	"%s due to: %s\n", context, strerror(lock_ret));
	530	return false;
	531	}
	532
	533	return true;
	534	}
	535
	536
	537	bool regfi_lock(REGFI_FILE* file, pthread_mutex_t* lock, const char* context)
	538	{
	539	int lock_ret = pthread_mutex_lock(lock);
	540	if(lock_ret != 0)
	541	{
[182]	542	regfi_log_add(REGFI_LOG_ERROR, "Error obtaining mutex lock in"
[180]	543	"%s due to: %s\n", context, strerror(lock_ret));
	544	return false;
	545	}
	546
	547	return true;
	548	}
	549
	550
	551	bool regfi_unlock(REGFI_FILE* file, pthread_mutex_t* lock, const char* context)
	552	{
	553	int lock_ret = pthread_mutex_unlock(lock);
	554	if(lock_ret != 0)
	555	{
[182]	556	regfi_log_add(REGFI_LOG_ERROR, "Error releasing mutex lock in"
[180]	557	"%s due to: %s\n", context, strerror(lock_ret));
	558	return false;
	559	}
	560
	561	return true;
	562	}
	563
	564
[226]	565	int64_t regfi_raw_seek(REGFI_RAW_FILE* self, uint64_t offset, int whence)
[178]	566	{
[226]	567	if(sizeof(off_t) == 4 && offset > 2147483647)
	568	{
	569	errno = EOVERFLOW;
	570	return -1;
	571	}
[178]	572	return lseek((int)self->state, offset, whence);
	573	}
	574
	575	ssize_t regfi_raw_read(REGFI_RAW_FILE* self, void* buf, size_t count)
	576	{
	577	return read((int)self->state, buf, count);
	578	}
	579
	580
[101]	581	/*****************************************************************************
[178]	582	* Convenience function to wrap up the ugly callback stuff
	583	*****************************************************************************/
[226]	584	uint64_t regfi_seek(REGFI_RAW_FILE* file_cb, uint64_t offset, int whence)
[178]	585	{
	586	return file_cb->seek(file_cb, offset, whence);
	587	}
	588
	589
	590	/*****************************************************************************
[101]	591	* This function is just like read(2), except that it continues to
	592	* re-try reading from the file descriptor if EINTR or EAGAIN is received.
[178]	593	* regfi_read will attempt to read length bytes from the file and write them to
	594	* buf.
[101]	595	*
	596	* On success, 0 is returned. Upon failure, an errno code is returned.
	597	*
	598	* The number of bytes successfully read is returned through the length
	599	* parameter by reference. If both the return value and length parameter are
	600	* returned as 0, then EOF was encountered immediately
	601	*****************************************************************************/
[178]	602	uint32_t regfi_read(REGFI_RAW_FILE* file_cb, uint8_t* buf, uint32_t* length)
[101]	603	{
[168]	604	uint32_t rsize = 0;
	605	uint32_t rret = 0;
[101]	606
	607	do
	608	{
[225]	609	rret = file_cb->read(file_cb,
	610	buf + rsize,
	611	*length - rsize);
[101]	612	if(rret > 0)
	613	rsize += rret;
	614	}while(*length - rsize > 0
	615	&& (rret > 0 \|\| (rret == -1 && (errno == EAGAIN \|\| errno == EINTR))));
	616
	617	*length = rsize;
	618	if (rret == -1 && errno != EINTR && errno != EAGAIN)
	619	return errno;
	620
	621	return 0;
	622	}
	623
	624
	625	/*****************************************************************************
	626	*
	627	*****************************************************************************/
[178]	628	bool regfi_parse_cell(REGFI_RAW_FILE* file_cb, uint32_t offset, uint8_t* hdr,
	629	uint32_t hdr_len, uint32_t* cell_length, bool* unalloc)
[101]	630	{
[168]	631	uint32_t length;
	632	int32_t raw_length;
	633	uint8_t tmp[4];
[101]	634
[178]	635	if(regfi_seek(file_cb, offset, SEEK_SET) == -1)
[101]	636	return false;
	637
	638	length = 4;
[178]	639	if((regfi_read(file_cb, tmp, &length) != 0) \|\| length != 4)
[101]	640	return false;
	641	raw_length = IVALS(tmp, 0);
	642
	643	if(raw_length < 0)
	644	{
	645	(cell_length) = raw_length(-1);
	646	(*unalloc) = false;
	647	}
	648	else
	649	{
	650	(*cell_length) = raw_length;
	651	(*unalloc) = true;
	652	}
	653
[103]	654	if(*cell_length - 4 < hdr_len)
	655	return false;
	656
	657	if(hdr_len > 0)
	658	{
	659	length = hdr_len;
[178]	660	if((regfi_read(file_cb, hdr, &length) != 0) \|\| length != hdr_len)
[103]	661	return false;
	662	}
	663
[101]	664	return true;
	665	}
	666
	667
[157]	668	/******************************************************************************
[106]	669	* Given an offset and an hbin, is the offset within that hbin?
	670	* The offset is a virtual file offset.
[157]	671	******************************************************************************/
[168]	672	static bool regfi_offset_in_hbin(const REGFI_HBIN* hbin, uint32_t voffset)
[30]	673	{
[106]	674	if(!hbin)
[31]	675	return false;
[106]	676
[145]	677	if((voffset > hbin->first_hbin_off)
	678	&& (voffset < (hbin->first_hbin_off + hbin->block_size)))
[31]	679	return true;
[30]	680
[31]	681	return false;
[30]	682	}
	683
	684
[106]	685
[157]	686	/******************************************************************************
	687	* Provide a physical offset and receive the correpsonding HBIN
[106]	688	* block for it. NULL if one doesn't exist.
[157]	689	******************************************************************************/
[168]	690	const REGFI_HBIN* regfi_lookup_hbin(REGFI_FILE* file, uint32_t offset)
[30]	691	{
[157]	692	return (const REGFI_HBIN*)range_list_find_data(file->hbins, offset);
[30]	693	}
	694
	695
[157]	696	/******************************************************************************
	697	* Calculate the largest possible cell size given a physical offset.
	698	* Largest size is based on the HBIN the offset is currently a member of.
	699	* Returns negative values on error.
	700	* (Since cells can only be ~2^31 in size, this works out.)
	701	******************************************************************************/
[168]	702	int32_t regfi_calc_maxsize(REGFI_FILE* file, uint32_t offset)
[157]	703	{
	704	const REGFI_HBIN* hbin = regfi_lookup_hbin(file, offset);
	705	if(hbin == NULL)
	706	return -1;
[139]	707
[157]	708	return (hbin->block_size + hbin->file_off) - offset;
	709	}
	710
	711
[139]	712	/******************************************************************************
	713	******************************************************************************/
[168]	714	REGFI_SUBKEY_LIST* regfi_load_subkeylist(REGFI_FILE* file, uint32_t offset,
	715	uint32_t num_keys, uint32_t max_size,
[139]	716	bool strict)
[127]	717	{
[135]	718	REGFI_SUBKEY_LIST* ret_val;
[134]	719
[139]	720	ret_val = regfi_load_subkeylist_aux(file, offset, max_size, strict,
	721	REGFI_MAX_SUBKEY_DEPTH);
[143]	722	if(ret_val == NULL)
	723	{
[182]	724	regfi_log_add(REGFI_LOG_WARN, "Failed to load subkey list at"
[143]	725	" offset 0x%.8X.", offset);
	726	return NULL;
	727	}
[139]	728
	729	if(num_keys != ret_val->num_keys)
	730	{
	731	/* Not sure which should be authoritative, the number from the
	732	* NK record, or the number in the subkey list. Just emit a warning for
	733	* now if they don't match.
	734	*/
[182]	735	regfi_log_add(REGFI_LOG_WARN, "Number of subkeys listed in parent"
[139]	736	" (%d) did not match number found in subkey list/tree (%d)"
	737	" while parsing subkey list/tree at offset 0x%.8X.",
	738	num_keys, ret_val->num_keys, offset);
	739	}
	740
	741	return ret_val;
	742	}
	743
	744
	745	/******************************************************************************
	746	******************************************************************************/
[168]	747	REGFI_SUBKEY_LIST* regfi_load_subkeylist_aux(REGFI_FILE* file, uint32_t offset,
	748	uint32_t max_size, bool strict,
	749	uint8_t depth_left)
[139]	750	{
	751	REGFI_SUBKEY_LIST* ret_val;
	752	REGFI_SUBKEY_LIST** sublists;
[168]	753	uint32_t i, num_sublists, off;
	754	int32_t sublist_maxsize;
[139]	755
	756	if(depth_left == 0)
	757	{
[182]	758	regfi_log_add(REGFI_LOG_WARN, "Maximum depth reached"
[139]	759	" while parsing subkey list/tree at offset 0x%.8X.",
	760	offset);
[127]	761	return NULL;
[139]	762	}
[134]	763
[139]	764	ret_val = regfi_parse_subkeylist(file, offset, max_size, strict);
[134]	765	if(ret_val == NULL)
	766	return NULL;
[139]	767
	768	if(ret_val->recursive_type)
[127]	769	{
[139]	770	num_sublists = ret_val->num_children;
[150]	771	sublists = (REGFI_SUBKEY_LIST**)malloc(num_sublists
[139]	772	* sizeof(REGFI_SUBKEY_LIST*));
	773	for(i=0; i < num_sublists; i++)
[127]	774	{
[139]	775	off = ret_val->elements[i].offset + REGFI_REGF_SIZE;
[157]	776
	777	sublist_maxsize = regfi_calc_maxsize(file, off);
	778	if(sublist_maxsize < 0)
[139]	779	sublists[i] = NULL;
	780	else
[157]	781	sublists[i] = regfi_load_subkeylist_aux(file, off, sublist_maxsize,
	782	strict, depth_left-1);
[127]	783	}
[150]	784	talloc_free(ret_val);
[134]	785
[139]	786	return regfi_merge_subkeylists(num_sublists, sublists, strict);
[127]	787	}
[30]	788
[127]	789	return ret_val;
	790	}
	791
	792
[139]	793	/******************************************************************************
	794	******************************************************************************/
[168]	795	REGFI_SUBKEY_LIST* regfi_parse_subkeylist(REGFI_FILE* file, uint32_t offset,
	796	uint32_t max_size, bool strict)
[30]	797	{
[135]	798	REGFI_SUBKEY_LIST* ret_val;
[168]	799	uint32_t i, cell_length, length, elem_size, read_len;
	800	uint8_t* elements = NULL;
	801	uint8_t buf[REGFI_SUBKEY_LIST_MIN_LEN];
[104]	802	bool unalloc;
[139]	803	bool recursive_type;
[30]	804
[186]	805	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_subkeylist"))
[180]	806	goto fail;
	807
[178]	808	if(!regfi_parse_cell(file->cb, offset, buf, REGFI_SUBKEY_LIST_MIN_LEN,
[104]	809	&cell_length, &unalloc))
[139]	810	{
[182]	811	regfi_log_add(REGFI_LOG_WARN, "Could not parse cell while "
[139]	812	"parsing subkey-list at offset 0x%.8X.", offset);
[180]	813	goto fail_locked;
[139]	814	}
[30]	815
[116]	816	if(cell_length > max_size)
	817	{
[182]	818	regfi_log_add(REGFI_LOG_WARN, "Cell size longer than max_size"
[139]	819	" while parsing subkey-list at offset 0x%.8X.", offset);
[116]	820	if(strict)
[180]	821	goto fail_locked;
[116]	822	cell_length = max_size & 0xFFFFFFF8;
	823	}
[30]	824
[139]	825	recursive_type = false;
[127]	826	if(buf[0] == 'r' && buf[1] == 'i')
[104]	827	{
[139]	828	recursive_type = true;
[168]	829	elem_size = sizeof(uint32_t);
[104]	830	}
[139]	831	else if(buf[0] == 'l' && buf[1] == 'i')
[203]	832	{
[168]	833	elem_size = sizeof(uint32_t);
[203]	834	}
[134]	835	else if((buf[0] == 'l') && (buf[1] == 'f' \|\| buf[1] == 'h'))
[135]	836	elem_size = sizeof(REGFI_SUBKEY_LIST_ELEM);
[134]	837	else
	838	{
[182]	839	regfi_log_add(REGFI_LOG_ERROR, "Unknown magic number"
[139]	840	" (0x%.2X, 0x%.2X) encountered while parsing"
	841	" subkey-list at offset 0x%.8X.", buf[0], buf[1], offset);
[180]	842	goto fail_locked;
[134]	843	}
	844
[150]	845	ret_val = talloc(NULL, REGFI_SUBKEY_LIST);
[127]	846	if(ret_val == NULL)
[180]	847	goto fail_locked;
[127]	848
	849	ret_val->offset = offset;
	850	ret_val->cell_size = cell_length;
[104]	851	ret_val->magic[0] = buf[0];
	852	ret_val->magic[1] = buf[1];
[139]	853	ret_val->recursive_type = recursive_type;
	854	ret_val->num_children = SVAL(buf, 0x2);
[101]	855
[139]	856	if(!recursive_type)
	857	ret_val->num_keys = ret_val->num_children;
[101]	858
[139]	859	length = elem_size*ret_val->num_children;
[168]	860	if(cell_length - REGFI_SUBKEY_LIST_MIN_LEN - sizeof(uint32_t) < length)
[134]	861	{
[182]	862	regfi_log_add(REGFI_LOG_WARN, "Number of elements too large for"
[139]	863	" cell while parsing subkey-list at offset 0x%.8X.",
	864	offset);
	865	if(strict)
[180]	866	goto fail_locked;
[168]	867	length = cell_length - REGFI_SUBKEY_LIST_MIN_LEN - sizeof(uint32_t);
[134]	868	}
[30]	869
[150]	870	ret_val->elements = talloc_array(ret_val, REGFI_SUBKEY_LIST_ELEM,
	871	ret_val->num_children);
[127]	872	if(ret_val->elements == NULL)
[180]	873	goto fail_locked;
[30]	874
[168]	875	elements = (uint8_t*)malloc(length);
[139]	876	if(elements == NULL)
[180]	877	goto fail_locked;
[30]	878
[150]	879	read_len = length;
[178]	880	if(regfi_read(file->cb, elements, &read_len) != 0 \|\| read_len!=length)
[180]	881	goto fail_locked;
[30]	882
[186]	883	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_subkeylist"))
[180]	884	goto fail;
	885
[168]	886	if(elem_size == sizeof(uint32_t))
[104]	887	{
[139]	888	for (i=0; i < ret_val->num_children; i++)
[134]	889	{
[139]	890	ret_val->elements[i].offset = IVAL(elements, i*elem_size);
[134]	891	ret_val->elements[i].hash = 0;
	892	}
[104]	893	}
[134]	894	else
	895	{
[139]	896	for (i=0; i < ret_val->num_children; i++)
[134]	897	{
[139]	898	ret_val->elements[i].offset = IVAL(elements, i*elem_size);
	899	ret_val->elements[i].hash = IVAL(elements, i*elem_size+4);
[134]	900	}
	901	}
[139]	902	free(elements);
[30]	903
[104]	904	return ret_val;
[150]	905
[180]	906	fail_locked:
[186]	907	regfi_unlock(file, &file->cb_lock, "regfi_parse_subkeylist");
[150]	908	fail:
	909	if(elements != NULL)
	910	free(elements);
	911	talloc_free(ret_val);
	912	return NULL;
[30]	913	}
	914
	915
[139]	916	/*******************************************************************
	917	*******************************************************************/
[168]	918	REGFI_SUBKEY_LIST* regfi_merge_subkeylists(uint16_t num_lists,
[139]	919	REGFI_SUBKEY_LIST** lists,
	920	bool strict)
	921	{
[168]	922	uint32_t i,j,k;
[139]	923	REGFI_SUBKEY_LIST* ret_val;
[102]	924
[139]	925	if(lists == NULL)
	926	return NULL;
[150]	927	ret_val = talloc(NULL, REGFI_SUBKEY_LIST);
[139]	928
	929	if(ret_val == NULL)
	930	return NULL;
	931
	932	/* Obtain total number of elements */
	933	ret_val->num_keys = 0;
	934	for(i=0; i < num_lists; i++)
	935	{
	936	if(lists[i] != NULL)
	937	ret_val->num_keys += lists[i]->num_children;
	938	}
	939	ret_val->num_children = ret_val->num_keys;
	940
	941	if(ret_val->num_keys > 0)
	942	{
[150]	943	ret_val->elements = talloc_array(ret_val, REGFI_SUBKEY_LIST_ELEM,
	944	ret_val->num_keys);
[139]	945	k=0;
	946
	947	if(ret_val->elements != NULL)
	948	{
	949	for(i=0; i < num_lists; i++)
	950	{
	951	if(lists[i] != NULL)
	952	{
	953	for(j=0; j < lists[i]->num_keys; j++)
	954	{
[150]	955	ret_val->elements[k].hash = lists[i]->elements[j].hash;
	956	ret_val->elements[k++].offset = lists[i]->elements[j].offset;
[139]	957	}
	958	}
	959	}
	960	}
	961	}
	962
	963	for(i=0; i < num_lists; i++)
[184]	964	talloc_free(lists[i]);
[139]	965	free(lists);
	966
	967	return ret_val;
	968	}
	969
	970
[147]	971	/******************************************************************************
	972	*
	973	******************************************************************************/
[203]	974	REGFI_SK* regfi_parse_sk(REGFI_FILE* file, uint32_t offset, uint32_t max_size,
[147]	975	bool strict)
[30]	976	{
[203]	977	REGFI_SK* ret_val = NULL;
[168]	978	uint8_t* sec_desc_buf = NULL;
	979	uint32_t cell_length, length;
	980	uint8_t sk_header[REGFI_SK_MIN_LENGTH];
[102]	981	bool unalloc = false;
[30]	982
[186]	983	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_sk"))
[180]	984	goto fail;
	985
[178]	986	if(!regfi_parse_cell(file->cb, offset, sk_header, REGFI_SK_MIN_LENGTH,
[102]	987	&cell_length, &unalloc))
[137]	988	{
[182]	989	regfi_log_add(REGFI_LOG_WARN, "Could not parse SK record cell"
[137]	990	" at offset 0x%.8X.", offset);
[180]	991	goto fail_locked;
[137]	992	}
[102]	993
	994	if(sk_header[0] != 's' \|\| sk_header[1] != 'k')
[137]	995	{
[182]	996	regfi_log_add(REGFI_LOG_WARN, "Magic number mismatch in parsing"
[138]	997	" SK record at offset 0x%.8X.", offset);
[180]	998	goto fail_locked;
[137]	999	}
	1000
[203]	1001	ret_val = talloc(NULL, REGFI_SK);
[102]	1002	if(ret_val == NULL)
[180]	1003	goto fail_locked;
[30]	1004
[102]	1005	ret_val->offset = offset;
[116]	1006	/* XXX: Is there a way to be more conservative (shorter) with
	1007	* cell length when cell is unallocated?
[111]	1008	*/
[102]	1009	ret_val->cell_size = cell_length;
[30]	1010
[102]	1011	if(ret_val->cell_size > max_size)
	1012	ret_val->cell_size = max_size & 0xFFFFFFF8;
	1013	if((ret_val->cell_size < REGFI_SK_MIN_LENGTH)
[157]	1014	\|\| (strict && (ret_val->cell_size & 0x00000007) != 0))
[102]	1015	{
[182]	1016	regfi_log_add(REGFI_LOG_WARN, "Invalid cell size found while"
[138]	1017	" parsing SK record at offset 0x%.8X.", offset);
[180]	1018	goto fail_locked;
[102]	1019	}
[30]	1020
[102]	1021	ret_val->magic[0] = sk_header[0];
	1022	ret_val->magic[1] = sk_header[1];
[30]	1023
[102]	1024	ret_val->unknown_tag = SVAL(sk_header, 0x2);
	1025	ret_val->prev_sk_off = IVAL(sk_header, 0x4);
	1026	ret_val->next_sk_off = IVAL(sk_header, 0x8);
	1027	ret_val->ref_count = IVAL(sk_header, 0xC);
	1028	ret_val->desc_size = IVAL(sk_header, 0x10);
[30]	1029
[157]	1030	if((ret_val->prev_sk_off & 0x00000007) != 0
	1031	\|\| (ret_val->next_sk_off & 0x00000007) != 0)
[140]	1032	{
[182]	1033	regfi_log_add(REGFI_LOG_WARN, "SK record's next/previous offsets"
[140]	1034	" are not a multiple of 8 while parsing SK record at"
	1035	" offset 0x%.8X.", offset);
[180]	1036	goto fail_locked;
[140]	1037	}
	1038
[102]	1039	if(ret_val->desc_size + REGFI_SK_MIN_LENGTH > ret_val->cell_size)
	1040	{
[182]	1041	regfi_log_add(REGFI_LOG_WARN, "Security descriptor too large for"
[138]	1042	" cell while parsing SK record at offset 0x%.8X.",
	1043	offset);
[180]	1044	goto fail_locked;
[102]	1045	}
[30]	1046
[168]	1047	sec_desc_buf = (uint8_t*)malloc(ret_val->desc_size);
[147]	1048	if(sec_desc_buf == NULL)
[180]	1049	goto fail_locked;
[102]	1050
[134]	1051	length = ret_val->desc_size;
[178]	1052	if(regfi_read(file->cb, sec_desc_buf, &length) != 0
[134]	1053	\|\| length != ret_val->desc_size)
	1054	{
[182]	1055	regfi_log_add(REGFI_LOG_ERROR, "Failed to read security"
[138]	1056	" descriptor while parsing SK record at offset 0x%.8X.",
	1057	offset);
[180]	1058	goto fail_locked;
[134]	1059	}
[102]	1060
[186]	1061	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_sk"))
[180]	1062	goto fail;
	1063
[147]	1064	if(!(ret_val->sec_desc = winsec_parse_desc(ret_val, sec_desc_buf,
	1065	ret_val->desc_size)))
[134]	1066	{
[182]	1067	regfi_log_add(REGFI_LOG_ERROR, "Failed to parse security"
[138]	1068	" descriptor while parsing SK record at offset 0x%.8X.",
	1069	offset);
[147]	1070	goto fail;
[134]	1071	}
[147]	1072
[134]	1073	free(sec_desc_buf);
[147]	1074	return ret_val;
[134]	1075
[180]	1076	fail_locked:
[186]	1077	regfi_unlock(file, &file->cb_lock, "regfi_parse_sk");
[147]	1078	fail:
	1079	if(sec_desc_buf != NULL)
	1080	free(sec_desc_buf);
	1081	talloc_free(ret_val);
	1082	return NULL;
[30]	1083	}
	1084
	1085
[168]	1086	REGFI_VALUE_LIST* regfi_parse_valuelist(REGFI_FILE* file, uint32_t offset,
	1087	uint32_t num_values, bool strict)
[111]	1088	{
[145]	1089	REGFI_VALUE_LIST* ret_val;
[168]	1090	uint32_t i, cell_length, length, read_len;
[111]	1091	bool unalloc;
[30]	1092
[186]	1093	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_valuelist"))
[180]	1094	goto fail;
	1095
[178]	1096	if(!regfi_parse_cell(file->cb, offset, NULL, 0, &cell_length, &unalloc))
[137]	1097	{
[182]	1098	regfi_log_add(REGFI_LOG_ERROR, "Failed to read cell header"
[137]	1099	" while parsing value list at offset 0x%.8X.", offset);
[180]	1100	goto fail_locked;
[137]	1101	}
[111]	1102
[157]	1103	if((cell_length & 0x00000007) != 0)
[111]	1104	{
[182]	1105	regfi_log_add(REGFI_LOG_WARN, "Cell length not a multiple of 8"
[145]	1106	" while parsing value list at offset 0x%.8X.", offset);
[111]	1107	if(strict)
[180]	1108	goto fail_locked;
[111]	1109	cell_length = cell_length & 0xFFFFFFF8;
	1110	}
[145]	1111
[168]	1112	if((num_values * sizeof(uint32_t)) > cell_length-sizeof(uint32_t))
[137]	1113	{
[182]	1114	regfi_log_add(REGFI_LOG_WARN, "Too many values found"
[137]	1115	" while parsing value list at offset 0x%.8X.", offset);
[145]	1116	if(strict)
[180]	1117	goto fail_locked;
[168]	1118	num_values = cell_length/sizeof(uint32_t) - sizeof(uint32_t);
[137]	1119	}
[111]	1120
[168]	1121	read_len = num_values*sizeof(uint32_t);
[150]	1122	ret_val = talloc(NULL, REGFI_VALUE_LIST);
[111]	1123	if(ret_val == NULL)
[180]	1124	goto fail_locked;
[111]	1125
[150]	1126	ret_val->elements = (REGFI_VALUE_LIST_ELEM*)talloc_size(ret_val, read_len);
[145]	1127	if(ret_val->elements == NULL)
[180]	1128	goto fail_locked;
	1129
[206]	1130	ret_val->offset = offset;
	1131	ret_val->cell_size = cell_length;
[145]	1132	ret_val->num_values = num_values;
	1133
[111]	1134	length = read_len;
[178]	1135	if((regfi_read(file->cb, (uint8_t*)ret_val->elements, &length) != 0)
[145]	1136	\|\| length != read_len)
[111]	1137	{
[182]	1138	regfi_log_add(REGFI_LOG_ERROR, "Failed to read value pointers"
[137]	1139	" while parsing value list at offset 0x%.8X.", offset);
[180]	1140	goto fail_locked;
[111]	1141	}
	1142
[186]	1143	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_valuelist"))
[180]	1144	goto fail;
	1145
[111]	1146	for(i=0; i < num_values; i++)
	1147	{
	1148	/* Fix endianness */
[145]	1149	ret_val->elements[i] = IVAL(&ret_val->elements[i], 0);
[111]	1150
	1151	/* Validate the first num_values values to ensure they make sense */
	1152	if(strict)
	1153	{
[145]	1154	/* XXX: Need to revisit this file length check when we start dealing
	1155	* with partial files. */
	1156	if((ret_val->elements[i] + REGFI_REGF_SIZE > file->file_length)
[157]	1157	\|\| ((ret_val->elements[i] & 0x00000007) != 0))
[111]	1158	{
[182]	1159	regfi_log_add(REGFI_LOG_WARN, "Invalid value pointer"
[138]	1160	" (0x%.8X) found while parsing value list at offset"
[145]	1161	" 0x%.8X.", ret_val->elements[i], offset);
[180]	1162	goto fail;
[111]	1163	}
	1164	}
	1165	}
	1166
	1167	return ret_val;
[180]	1168
	1169	fail_locked:
[186]	1170	regfi_unlock(file, &file->cb_lock, "regfi_parse_valuelist");
[180]	1171	fail:
	1172	talloc_free(ret_val);
	1173	return NULL;
[111]	1174	}
	1175
[206]	1176	/* XXX: should give this boolean return type to indicate errors */
[203]	1177	void regfi_interpret_valuename(REGFI_FILE* file, REGFI_VK* vk,
[162]	1178	REGFI_ENCODING output_encoding, bool strict)
[30]	1179	{
[165]	1180	/* XXX: Registry value names are supposedly limited to 16383 characters
	1181	* according to:
	1182	* http://msdn.microsoft.com/en-us/library/ms724872%28VS.85%29.aspx
	1183	* Might want to emit a warning if this is exceeded.
	1184	* It is expected that "characters" could be variable width.
	1185	* Also, it may be useful to use this information to limit false positives
	1186	* when recovering deleted VK records.
	1187	*/
[172]	1188	int32_t tmp_size;
	1189	REGFI_ENCODING from_encoding = (vk->flags & REGFI_VK_FLAG_ASCIINAME)
[162]	1190	? REGFI_ENCODING_ASCII : REGFI_ENCODING_UTF16LE;
[151]	1191
[256]	1192	if(vk->name_length == 0)
	1193	return;
	1194
[162]	1195	if(from_encoding == output_encoding)
	1196	{
[206]	1197	vk->name_raw[vk->name_length] = '\0';
	1198	vk->name = (char*)vk->name_raw;
[162]	1199	}
	1200	else
	1201	{
[206]	1202	vk->name = talloc_array(vk, char, vk->name_length+1);
	1203	if(vk->name == NULL)
[172]	1204	return;
[162]	1205
	1206	tmp_size = regfi_conv_charset(regfi_encoding_int2str(from_encoding),
	1207	regfi_encoding_int2str(output_encoding),
[206]	1208	vk->name_raw, vk->name,
[172]	1209	vk->name_length, vk->name_length+1);
[162]	1210	if(tmp_size < 0)
	1211	{
[182]	1212	regfi_log_add(REGFI_LOG_WARN, "Error occurred while converting"
[206]	1213	" value name to encoding %s. Error message: %s",
[162]	1214	regfi_encoding_int2str(output_encoding),
	1215	strerror(-tmp_size));
[206]	1216	talloc_free(vk->name);
	1217	vk->name = NULL;
[162]	1218	}
	1219	}
[172]	1220	}
[162]	1221
[172]	1222
	1223	/******************************************************************************
	1224	******************************************************************************/
[203]	1225	REGFI_VK* regfi_load_value(REGFI_FILE* file, uint32_t offset,
[206]	1226	REGFI_ENCODING output_encoding, bool strict)
[172]	1227	{
[203]	1228	REGFI_VK* ret_val = NULL;
[172]	1229	int32_t max_size;
	1230
	1231	max_size = regfi_calc_maxsize(file, offset);
	1232	if(max_size < 0)
	1233	return NULL;
	1234
	1235	ret_val = regfi_parse_vk(file, offset, max_size, strict);
	1236	if(ret_val == NULL)
	1237	return NULL;
	1238
	1239	regfi_interpret_valuename(file, ret_val, output_encoding, strict);
	1240
[103]	1241	return ret_val;
[30]	1242	}
	1243
	1244
[145]	1245	/******************************************************************************
	1246	* If !strict, the list may contain NULLs, VK records may point to NULL.
	1247	******************************************************************************/
[168]	1248	REGFI_VALUE_LIST* regfi_load_valuelist(REGFI_FILE* file, uint32_t offset,
	1249	uint32_t num_values, uint32_t max_size,
[145]	1250	bool strict)
	1251	{
[168]	1252	uint32_t usable_num_values;
[30]	1253
[168]	1254	if((num_values+1) * sizeof(uint32_t) > max_size)
[145]	1255	{
[182]	1256	regfi_log_add(REGFI_LOG_WARN, "Number of values indicated by"
[145]	1257	" parent key (%d) would cause cell to straddle HBIN"
	1258	" boundary while loading value list at offset"
	1259	" 0x%.8X.", num_values, offset);
	1260	if(strict)
	1261	return NULL;
[168]	1262	usable_num_values = max_size/sizeof(uint32_t) - sizeof(uint32_t);
[145]	1263	}
	1264	else
	1265	usable_num_values = num_values;
	1266
	1267	return regfi_parse_valuelist(file, offset, usable_num_values, strict);
	1268	}
	1269
	1270
[206]	1271	/* XXX: should give this boolean return type to indicate errors */
[203]	1272	void regfi_interpret_keyname(REGFI_FILE* file, REGFI_NK* nk,
[161]	1273	REGFI_ENCODING output_encoding, bool strict)
[30]	1274	{
[165]	1275	/* XXX: Registry key names are supposedly limited to 255 characters according to:
	1276	* http://msdn.microsoft.com/en-us/library/ms724872%28VS.85%29.aspx
	1277	* Might want to emit a warning if this is exceeded.
	1278	* It is expected that "characters" could be variable width.
	1279	* Also, it may be useful to use this information to limit false positives
	1280	* when recovering deleted NK records.
	1281	*/
[172]	1282	int32_t tmp_size;
	1283	REGFI_ENCODING from_encoding = (nk->flags & REGFI_NK_FLAG_ASCIINAME)
[161]	1284	? REGFI_ENCODING_ASCII : REGFI_ENCODING_UTF16LE;
[256]	1285
	1286	if(nk->name_length == 0)
	1287	return;
	1288
[161]	1289	if(from_encoding == output_encoding)
	1290	{
[206]	1291	nk->name_raw[nk->name_length] = '\0';
	1292	nk->name = (char*)nk->name_raw;
[161]	1293	}
	1294	else
	1295	{
[206]	1296	nk->name = talloc_array(nk, char, nk->name_length+1);
	1297	if(nk->name == NULL)
[172]	1298	return;
[161]	1299
[206]	1300	memset(nk->name,0,nk->name_length+1);
	1301
[161]	1302	tmp_size = regfi_conv_charset(regfi_encoding_int2str(from_encoding),
	1303	regfi_encoding_int2str(output_encoding),
[206]	1304	nk->name_raw, nk->name,
[161]	1305	nk->name_length, nk->name_length+1);
	1306	if(tmp_size < 0)
	1307	{
[182]	1308	regfi_log_add(REGFI_LOG_WARN, "Error occurred while converting"
[206]	1309	" key name to encoding %s. Error message: %s",
[161]	1310	regfi_encoding_int2str(output_encoding),
	1311	strerror(-tmp_size));
[206]	1312	talloc_free(nk->name);
	1313	nk->name = NULL;
[161]	1314	}
	1315	}
[172]	1316	}
[161]	1317
	1318
[172]	1319	/******************************************************************************
	1320	*
	1321	******************************************************************************/
[203]	1322	REGFI_NK* regfi_load_key(REGFI_FILE* file, uint32_t offset,
[206]	1323	REGFI_ENCODING output_encoding, bool strict)
[172]	1324	{
[203]	1325	REGFI_NK* nk;
[172]	1326	uint32_t off;
	1327	int32_t max_size;
	1328
[250]	1329	if(file->nk_cache != NULL)
	1330	{
	1331	/* First, check to see if we have this key in our cache */
	1332	if(!regfi_lock(file, &file->mem_lock, "regfi_load_nk"))
	1333	return NULL;
	1334	regfi_lock(file, &file->nk_lock, "regfi_load_nk");
	1335
	1336	nk = (REGFI_NK*)lru_cache_find(file->nk_cache, &offset, 4);
	1337	if(nk != NULL)
	1338	nk = talloc_reference(NULL, nk);
	1339
	1340	regfi_unlock(file, &file->nk_lock, "regfi_load_nk");
	1341	regfi_unlock(file, &file->mem_lock, "regfi_load_nk");
	1342	if(nk != NULL)
	1343	return nk;
	1344	}
	1345
	1346	/* Not cached currently, proceed with loading it */
[172]	1347	max_size = regfi_calc_maxsize(file, offset);
	1348	if (max_size < 0)
	1349	return NULL;
	1350
	1351	/* get the initial nk record */
	1352	if((nk = regfi_parse_nk(file, offset, max_size, true)) == NULL)
	1353	{
[182]	1354	regfi_log_add(REGFI_LOG_ERROR, "Could not load NK record at"
	1355	" offset 0x%.8X.", offset);
[172]	1356	return NULL;
	1357	}
	1358
	1359	regfi_interpret_keyname(file, nk, output_encoding, strict);
	1360
[146]	1361	/* get value list */
[135]	1362	if(nk->num_values && (nk->values_off!=REGFI_OFFSET_NONE))
[32]	1363	{
[157]	1364	off = nk->values_off + REGFI_REGF_SIZE;
	1365	max_size = regfi_calc_maxsize(file, off);
	1366	if(max_size < 0)
[32]	1367	{
[105]	1368	if(strict)
[32]	1369	{
[184]	1370	talloc_free(nk);
[99]	1371	return NULL;
[31]	1372	}
[105]	1373	else
	1374	nk->values = NULL;
[31]	1375	}
[105]	1376	else
[103]	1377	{
[157]	1378	nk->values = regfi_load_valuelist(file, off, nk->num_values,
	1379	max_size, true);
[145]	1380	if(nk->values == NULL)
[105]	1381	{
[182]	1382	regfi_log_add(REGFI_LOG_WARN, "Could not load value list"
	1383	" for NK record at offset 0x%.8X.", offset);
[145]	1384	if(strict)
	1385	{
[184]	1386	talloc_free(nk);
[145]	1387	return NULL;
	1388	}
[105]	1389	}
[223]	1390	talloc_reparent(NULL, nk, nk->values);
[103]	1391	}
[31]	1392	}
[105]	1393
[146]	1394	/* now get subkey list */
[135]	1395	if(nk->num_subkeys && (nk->subkeys_off != REGFI_OFFSET_NONE))
[32]	1396	{
[157]	1397	off = nk->subkeys_off + REGFI_REGF_SIZE;
	1398	max_size = regfi_calc_maxsize(file, off);
	1399	if(max_size < 0)
[32]	1400	{
[105]	1401	if(strict)
[32]	1402	{
[184]	1403	talloc_free(nk);
[99]	1404	return NULL;
[31]	1405	}
[105]	1406	else
	1407	nk->subkeys = NULL;
[31]	1408	}
[105]	1409	else
[104]	1410	{
[134]	1411	nk->subkeys = regfi_load_subkeylist(file, off, nk->num_subkeys,
[157]	1412	max_size, true);
[134]	1413
[105]	1414	if(nk->subkeys == NULL)
	1415	{
[182]	1416	regfi_log_add(REGFI_LOG_WARN, "Could not load subkey list"
	1417	" while parsing NK record at offset 0x%.8X.", offset);
[105]	1418	nk->num_subkeys = 0;
	1419	}
[223]	1420	talloc_reparent(NULL, nk, nk->subkeys);
[104]	1421	}
[31]	1422	}
[30]	1423
[250]	1424	if(file->nk_cache != NULL)
	1425	{
	1426	/* All is well, so let us cache this key for later */
	1427	if(!regfi_lock(file, &file->mem_lock, "regfi_load_nk"))
	1428	return NULL;
	1429	regfi_lock(file, &file->nk_lock, "regfi_load_nk");
	1430
	1431	lru_cache_update(file->nk_cache, &offset, 4, nk);
	1432
	1433	regfi_unlock(file, &file->nk_lock, "regfi_load_nk");
	1434	regfi_unlock(file, &file->mem_lock, "regfi_load_nk");
	1435	}
	1436
[99]	1437	return nk;
[30]	1438	}
	1439
[32]	1440
[102]	1441	/******************************************************************************
	1442	******************************************************************************/
[203]	1443	const REGFI_SK* regfi_load_sk(REGFI_FILE* file, uint32_t offset, bool strict)
[146]	1444	{
[203]	1445	REGFI_SK* ret_val = NULL;
[168]	1446	int32_t max_size;
[147]	1447	void* failure_ptr = NULL;
	1448
[184]	1449	max_size = regfi_calc_maxsize(file, offset);
	1450	if(max_size < 0)
	1451	return NULL;
	1452
	1453	if(file->sk_cache == NULL)
	1454	return regfi_parse_sk(file, offset, max_size, strict);
	1455
[250]	1456	if(!regfi_lock(file, &file->mem_lock, "regfi_load_sk"))
[180]	1457	return NULL;
[250]	1458	regfi_lock(file, &file->sk_lock, "regfi_load_sk");
[180]	1459
[146]	1460	/* First look if we have already parsed it */
[203]	1461	ret_val = (REGFI_SK*)lru_cache_find(file->sk_cache, &offset, 4);
[146]	1462
	1463	/* Bail out if we have previously cached a parse failure at this offset. */
	1464	if(ret_val == (void*)REGFI_OFFSET_NONE)
[250]	1465	{
	1466	ret_val = NULL;
	1467	goto unlock;
	1468	}
[146]	1469
	1470	if(ret_val == NULL)
	1471	{
[157]	1472	ret_val = regfi_parse_sk(file, offset, max_size, strict);
[146]	1473	if(ret_val == NULL)
	1474	{ /* Cache the parse failure and bail out. */
[147]	1475	failure_ptr = talloc(NULL, uint32_t);
	1476	if(failure_ptr == NULL)
[250]	1477	goto unlock;
	1478
[147]	1479	(uint32_t)failure_ptr = REGFI_OFFSET_NONE;
	1480	lru_cache_update(file->sk_cache, &offset, 4, failure_ptr);
[184]	1481
	1482	/* Let the cache be the only owner of this */
	1483	talloc_unlink(NULL, failure_ptr);
[146]	1484	}
	1485	}
[253]	1486	else
	1487	ret_val = talloc_reference(NULL, ret_val);
[146]	1488
[250]	1489	unlock:
	1490	regfi_unlock(file, &file->sk_lock, "regfi_load_sk");
	1491	regfi_unlock(file, &file->mem_lock, "regfi_load_sk");
[180]	1492
[146]	1493	return ret_val;
	1494	}
	1495
	1496
	1497
	1498	/******************************************************************************
	1499	******************************************************************************/
[203]	1500	REGFI_NK* regfi_find_root_nk(REGFI_FILE* file, const REGFI_HBIN* hbin,
[206]	1501	REGFI_ENCODING output_encoding)
[30]	1502	{
[203]	1503	REGFI_NK* nk = NULL;
[168]	1504	uint32_t cell_length;
	1505	uint32_t cur_offset = hbin->file_off+REGFI_HBIN_HEADER_SIZE;
	1506	uint32_t hbin_end = hbin->file_off+hbin->block_size;
[158]	1507	bool unalloc;
[30]	1508
[158]	1509	while(cur_offset < hbin_end)
[32]	1510	{
[180]	1511
[186]	1512	if(!regfi_lock(file, &file->cb_lock, "regfi_find_root_nk"))
[180]	1513	return NULL;
	1514
[178]	1515	if(!regfi_parse_cell(file->cb, cur_offset, NULL, 0, &cell_length, &unalloc))
[158]	1516	{
[182]	1517	regfi_log_add(REGFI_LOG_WARN, "Could not parse cell at offset"
	1518	" 0x%.8X while searching for root key.", cur_offset);
[255]	1519	goto error_locked;
[158]	1520	}
[180]	1521
[186]	1522	if(!regfi_unlock(file, &file->cb_lock, "regfi_find_root_nk"))
[180]	1523	return NULL;
	1524
[158]	1525	if(!unalloc)
[102]	1526	{
[161]	1527	nk = regfi_load_key(file, cur_offset, output_encoding, true);
[102]	1528	if(nk != NULL)
	1529	{
[161]	1530	if(nk->flags & REGFI_NK_FLAG_ROOT)
[158]	1531	return nk;
[102]	1532	}
[31]	1533	}
[30]	1534
[158]	1535	cur_offset += cell_length;
[31]	1536	}
[32]	1537
[158]	1538	return NULL;
[255]	1539
	1540	error_locked:
	1541	regfi_unlock(file, &file->cb_lock, "regfi_find_root_nk");
	1542	return NULL;
[30]	1543	}
	1544
	1545
[178]	1546
[166]	1547	/******************************************************************************
	1548	******************************************************************************/
[206]	1549	REGFI_FILE* regfi_alloc(int fd, REGFI_ENCODING output_encoding)
[30]	1550	{
[166]	1551	REGFI_FILE* ret_val;
[178]	1552	REGFI_RAW_FILE* file_cb = talloc(NULL, REGFI_RAW_FILE);
	1553	if(file_cb == NULL)
[31]	1554	return NULL;
[166]	1555
[178]	1556	file_cb->state = (void*)talloc(file_cb, int);
	1557	if(file_cb->state == NULL)
	1558	goto fail;
	1559	(int)file_cb->state = fd;
	1560
	1561	file_cb->cur_off = 0;
	1562	file_cb->size = 0;
	1563	file_cb->read = &regfi_raw_read;
	1564	file_cb->seek = &regfi_raw_seek;
	1565
[206]	1566	ret_val = regfi_alloc_cb(file_cb, output_encoding);
[166]	1567	if(ret_val == NULL)
[178]	1568	goto fail;
[166]	1569
[178]	1570	/* In this case, we want file_cb to be freed when ret_val is */
[223]	1571	talloc_reparent(NULL, ret_val, file_cb);
[166]	1572	return ret_val;
[178]	1573
	1574	fail:
	1575	talloc_free(file_cb);
	1576	return NULL;
[166]	1577	}
	1578
	1579
[186]	1580	/******************************************************************************
	1581	******************************************************************************/
[223]	1582	static int regfi_free_cb(void* f)
[186]	1583	{
	1584	REGFI_FILE* file = (REGFI_FILE*)f;
[178]	1585
[186]	1586	pthread_mutex_destroy(&file->cb_lock);
	1587	pthread_rwlock_destroy(&file->hbins_lock);
	1588	pthread_mutex_destroy(&file->sk_lock);
[250]	1589	pthread_mutex_destroy(&file->nk_lock);
	1590	pthread_mutex_destroy(&file->mem_lock);
[186]	1591
	1592	return 0;
	1593	}
	1594
	1595
	1596	/******************************************************************************
	1597	******************************************************************************/
[206]	1598	REGFI_FILE* regfi_alloc_cb(REGFI_RAW_FILE* file_cb,
	1599	REGFI_ENCODING output_encoding)
[166]	1600	{
	1601	REGFI_FILE* rb;
	1602	REGFI_HBIN* hbin = NULL;
[178]	1603	uint32_t hbin_off, cache_secret;
[226]	1604	int64_t file_length;
[166]	1605	bool rla;
	1606
[178]	1607	/* Determine file length. Must be at least big enough for the header
	1608	* and one hbin.
[137]	1609	*/
[226]	1610	file_length = regfi_seek(file_cb, 0, SEEK_END);
[137]	1611	if(file_length < REGFI_REGF_SIZE+REGFI_HBIN_ALLOC)
[182]	1612	{
	1613	regfi_log_add(REGFI_LOG_ERROR, "File length (%d) too short to contain a"
	1614	" header and at least one HBIN.", file_length);
[137]	1615	return NULL;
[182]	1616	}
[226]	1617	regfi_seek(file_cb, 0, SEEK_SET);
[137]	1618
[206]	1619	if(output_encoding != REGFI_ENCODING_UTF8
	1620	&& output_encoding != REGFI_ENCODING_ASCII)
	1621	{
	1622	regfi_log_add(REGFI_LOG_ERROR, "Invalid output_encoding supplied"
	1623	" in creation of regfi iterator.");
	1624	return NULL;
	1625	}
	1626
[166]	1627	/* Read file header */
[203]	1628	if ((rb = regfi_parse_regf(file_cb, false)) == NULL)
[97]	1629	{
[182]	1630	regfi_log_add(REGFI_LOG_ERROR, "Failed to read REGF block.");
[31]	1631	return NULL;
	1632	}
[203]	1633	rb->file_length = file_length;
[178]	1634	rb->cb = file_cb;
[206]	1635	rb->string_encoding = output_encoding;
[137]	1636
[186]	1637	if(pthread_mutex_init(&rb->cb_lock, NULL) != 0)
[182]	1638	{
	1639	regfi_log_add(REGFI_LOG_ERROR, "Failed to create cb_lock mutex.");
[180]	1640	goto fail;
[182]	1641	}
[180]	1642
[186]	1643	if(pthread_rwlock_init(&rb->hbins_lock, NULL) != 0)
[182]	1644	{
	1645	regfi_log_add(REGFI_LOG_ERROR, "Failed to create hbins_lock rwlock.");
[180]	1646	goto fail;
[182]	1647	}
[180]	1648
[186]	1649	if(pthread_mutex_init(&rb->sk_lock, NULL) != 0)
[182]	1650	{
	1651	regfi_log_add(REGFI_LOG_ERROR, "Failed to create sk_lock mutex.");
[180]	1652	goto fail;
[182]	1653	}
[180]	1654
[250]	1655	if(pthread_mutex_init(&rb->nk_lock, NULL) != 0)
	1656	{
	1657	regfi_log_add(REGFI_LOG_ERROR, "Failed to create nk_lock mutex.");
	1658	goto fail;
	1659	}
	1660
[228]	1661	if(pthread_mutex_init(&rb->mem_lock, NULL) != 0)
	1662	{
	1663	regfi_log_add(REGFI_LOG_ERROR, "Failed to create mem_lock mutex.");
	1664	goto fail;
	1665	}
	1666
[99]	1667	rb->hbins = range_list_new();
[110]	1668	if(rb->hbins == NULL)
[182]	1669	{
	1670	regfi_log_add(REGFI_LOG_ERROR, "Failed to create HBIN range_list.");
[180]	1671	goto fail;
[182]	1672	}
[223]	1673	talloc_reparent(NULL, rb, rb->hbins);
[150]	1674
[106]	1675	rla = true;
[135]	1676	hbin_off = REGFI_REGF_SIZE;
[110]	1677	hbin = regfi_parse_hbin(rb, hbin_off, true);
[106]	1678	while(hbin && rla)
	1679	{
[137]	1680	rla = range_list_add(rb->hbins, hbin->file_off, hbin->block_size, hbin);
[148]	1681	if(rla)
[223]	1682	talloc_reparent(NULL, rb->hbins, hbin);
[180]	1683
[106]	1684	hbin_off = hbin->file_off + hbin->block_size;
[110]	1685	hbin = regfi_parse_hbin(rb, hbin_off, true);
[106]	1686	}
	1687
[146]	1688	/* This secret isn't very secret, but we don't need a good one. This
	1689	* secret is just designed to prevent someone from trying to blow our
	1690	* caching and make things slow.
	1691	*/
	1692	cache_secret = 0x15DEAD05^time(NULL)^(getpid()<<16);
	1693
[250]	1694	rb->sk_cache = NULL;
	1695	if(REGFI_CACHE_SK_MAX > 0)
	1696	rb->sk_cache = lru_cache_create_ctx(rb, REGFI_CACHE_SK_MAX,
	1697	cache_secret, true);
[146]	1698
[250]	1699	rb->nk_cache = NULL;
	1700	if(REGFI_CACHE_NK_MAX > 0)
	1701	rb->nk_cache = lru_cache_create_ctx(rb, REGFI_CACHE_NK_MAX,
	1702	cache_secret, true);
	1703
[31]	1704	/* success */
[186]	1705	talloc_set_destructor(rb, regfi_free_cb);
[31]	1706	return rb;
[180]	1707
	1708	fail:
[186]	1709	pthread_mutex_destroy(&rb->cb_lock);
	1710	pthread_rwlock_destroy(&rb->hbins_lock);
	1711	pthread_mutex_destroy(&rb->sk_lock);
[250]	1712	pthread_mutex_destroy(&rb->nk_lock);
[228]	1713	pthread_mutex_destroy(&rb->mem_lock);
[180]	1714
	1715	range_list_free(rb->hbins);
	1716	talloc_free(rb);
	1717	return NULL;
[30]	1718	}
	1719
	1720
[148]	1721	/******************************************************************************
	1722	******************************************************************************/
[186]	1723	void regfi_free(REGFI_FILE* file)
[166]	1724	{
[186]	1725	/* Callback handles cleanup side effects */
[150]	1726	talloc_free(file);
[30]	1727	}
	1728
	1729
[80]	1730	/******************************************************************************
[158]	1731	* First checks the offset given by the file header, then checks the
	1732	* rest of the file if that fails.
[148]	1733	******************************************************************************/
[215]	1734	const REGFI_NK* regfi_get_rootkey(REGFI_FILE* file)
[30]	1735	{
[203]	1736	REGFI_NK* nk = NULL;
[146]	1737	REGFI_HBIN* hbin;
[168]	1738	uint32_t root_offset, i, num_hbins;
[99]	1739
	1740	if(!file)
[31]	1741	return NULL;
[99]	1742
[158]	1743	root_offset = file->root_cell+REGFI_REGF_SIZE;
[206]	1744	nk = regfi_load_key(file, root_offset, file->string_encoding, true);
[158]	1745	if(nk != NULL)
	1746	{
[161]	1747	if(nk->flags & REGFI_NK_FLAG_ROOT)
[158]	1748	return nk;
	1749	}
	1750
[182]	1751	regfi_log_add(REGFI_LOG_WARN, "File header indicated root key at"
	1752	" location 0x%.8X, but no root key found."
	1753	" Searching rest of file...", root_offset);
[158]	1754
	1755	/* If the file header gives bad info, scan through the file one HBIN
	1756	* block at a time looking for an NK record with a root key type.
[146]	1757	*/
[180]	1758
[215]	1759	if(!regfi_read_lock(file, &file->hbins_lock, "regfi_get_rootkey"))
[180]	1760	return NULL;
	1761
[107]	1762	num_hbins = range_list_size(file->hbins);
[158]	1763	for(i=0; i < num_hbins && nk == NULL; i++)
[99]	1764	{
[135]	1765	hbin = (REGFI_HBIN*)range_list_get(file->hbins, i)->data;
[206]	1766	nk = regfi_find_root_nk(file, hbin, file->string_encoding);
[31]	1767	}
[30]	1768
[215]	1769	if(!regfi_rw_unlock(file, &file->hbins_lock, "regfi_get_rootkey"))
[180]	1770	return NULL;
	1771
[80]	1772	return nk;
[30]	1773	}
	1774
	1775
[80]	1776	/******************************************************************************
	1777	*****************************************************************************/
[228]	1778	void regfi_free_record(REGFI_FILE* file, const void* record)
[30]	1779	{
[228]	1780	if(!regfi_lock(file, &file->mem_lock, "regfi_free_record"))
	1781	return;
	1782
[184]	1783	talloc_unlink(NULL, (void*)record);
[228]	1784
	1785	regfi_unlock(file, &file->mem_lock, "regfi_free_record");
[150]	1786	}
[127]	1787
[80]	1788
[224]	1789	/******************************************************************************
	1790	*****************************************************************************/
[252]	1791	const void* regfi_reference_record(REGFI_FILE* file, const void* record)
[224]	1792	{
[252]	1793	const void* ret_val = NULL;
	1794
[228]	1795	if(!regfi_lock(file, &file->mem_lock, "regfi_reference_record"))
	1796	return ret_val;
	1797
[252]	1798	ret_val = talloc_reference(NULL, record);
	1799
[228]	1800	regfi_unlock(file, &file->mem_lock, "regfi_reference_record");
	1801	return ret_val;
[224]	1802	}
[80]	1803
[207]	1804
[80]	1805	/******************************************************************************
	1806	*****************************************************************************/
[207]	1807	uint32_t regfi_fetch_num_subkeys(const REGFI_NK* key)
	1808	{
	1809	uint32_t num_in_list = 0;
[215]	1810	if(key == NULL)
	1811	return 0;
	1812
[207]	1813	if(key->subkeys != NULL)
	1814	num_in_list = key->subkeys->num_keys;
	1815
	1816	if(num_in_list != key->num_subkeys)
	1817	{
	1818	regfi_log_add(REGFI_LOG_INFO, "Key at offset 0x%.8X contains %d keys in its"
	1819	" subkey list but reports %d should be available.",
	1820	key->offset, num_in_list, key->num_subkeys);
	1821	return (num_in_list < key->num_subkeys)?num_in_list:key->num_subkeys;
	1822	}
	1823
	1824	return num_in_list;
	1825	}
	1826
	1827
	1828	/******************************************************************************
	1829	*****************************************************************************/
	1830	uint32_t regfi_fetch_num_values(const REGFI_NK* key)
	1831	{
	1832	uint32_t num_in_list = 0;
[215]	1833	if(key == NULL)
	1834	return 0;
	1835
[207]	1836	if(key->values != NULL)
	1837	num_in_list = key->values->num_values;
	1838
	1839	if(num_in_list != key->num_values)
	1840	{
	1841	regfi_log_add(REGFI_LOG_INFO, "Key at offset 0x%.8X contains %d values in"
	1842	" its value list but reports %d should be available.",
	1843	key->offset, num_in_list, key->num_values);
	1844	return (num_in_list < key->num_values)?num_in_list:key->num_values;
	1845	}
	1846
	1847	return num_in_list;
	1848	}
	1849
	1850
	1851	/******************************************************************************
	1852	*****************************************************************************/
[206]	1853	REGFI_ITERATOR* regfi_iterator_new(REGFI_FILE* file)
[80]	1854	{
[203]	1855	REGFI_NK* root;
[161]	1856	REGFI_ITERATOR* ret_val;
	1857
	1858	ret_val = talloc(NULL, REGFI_ITERATOR);
[80]	1859	if(ret_val == NULL)
	1860	return NULL;
[249]	1861
	1862	ret_val->cur = talloc(ret_val, REGFI_ITER_POSITION);
	1863	if(ret_val->cur == NULL)
[80]	1864	{
[150]	1865	talloc_free(ret_val);
[80]	1866	return NULL;
	1867	}
	1868
[135]	1869	ret_val->key_positions = void_stack_new(REGFI_MAX_DEPTH);
[80]	1870	if(ret_val->key_positions == NULL)
	1871	{
[150]	1872	talloc_free(ret_val);
[80]	1873	return NULL;
	1874	}
[223]	1875	talloc_reparent(NULL, ret_val, ret_val->key_positions);
[80]	1876
[249]	1877	root = (REGFI_NK*)regfi_get_rootkey(file);
	1878	if(root == NULL)
	1879	{
	1880	talloc_free(ret_val);
	1881	return NULL;
	1882	}
	1883
	1884	ret_val->cur->offset = root->offset;
	1885	if(root->subkeys_off == REGFI_OFFSET_NONE)
	1886	ret_val->cur->num_subkeys = 0;
	1887	else
	1888	ret_val->cur->num_subkeys = regfi_fetch_num_subkeys(root);
	1889
	1890	if(root->values_off == REGFI_OFFSET_NONE)
	1891	ret_val->cur->num_values = 0;
	1892	else
	1893	ret_val->cur->num_values = regfi_fetch_num_values(root);
	1894
	1895	ret_val->cur->cur_subkey = 0;
	1896	ret_val->cur->cur_value = 0;
[159]	1897	ret_val->f = file;
[249]	1898
	1899	regfi_free_record(ret_val->f, root);
[80]	1900	return ret_val;
	1901	}
	1902
	1903
	1904	/******************************************************************************
	1905	*****************************************************************************/
	1906	void regfi_iterator_free(REGFI_ITERATOR* i)
	1907	{
[228]	1908	talloc_unlink(NULL, i);
[80]	1909	}
	1910
	1911
	1912	/******************************************************************************
	1913	*****************************************************************************/
	1914	/* XXX: some way of indicating reason for failure should be added. */
	1915	bool regfi_iterator_down(REGFI_ITERATOR* i)
	1916	{
[203]	1917	REGFI_NK* subkey;
[249]	1918	REGFI_ITER_POSITION* pos = talloc(i, REGFI_ITER_POSITION);
[80]	1919	if(pos == NULL)
	1920	return false;
	1921
[203]	1922	subkey = (REGFI_NK*)regfi_iterator_cur_subkey(i);
[80]	1923	if(subkey == NULL)
	1924	{
[150]	1925	talloc_free(pos);
[80]	1926	return false;
	1927	}
	1928
[249]	1929	if(!void_stack_push(i->key_positions, i->cur))
[80]	1930	{
[150]	1931	talloc_free(pos);
[249]	1932	regfi_free_record(i->f, subkey);
[80]	1933	return false;
[249]	1934	}
[80]	1935
[249]	1936	pos->offset = subkey->offset;
	1937	if(subkey->subkeys_off == REGFI_OFFSET_NONE)
	1938	pos->num_subkeys = 0;
	1939	else
	1940	pos->num_subkeys = regfi_fetch_num_subkeys(subkey);
[80]	1941
[249]	1942	if(subkey->values_off == REGFI_OFFSET_NONE)
	1943	pos->num_values = 0;
	1944	else
	1945	pos->num_values = regfi_fetch_num_values(subkey);
	1946
	1947	pos->cur_subkey = 0;
	1948	pos->cur_value = 0;
	1949	i->cur = pos;
	1950
	1951	regfi_free_record(i->f, subkey);
[80]	1952	return true;
	1953	}
	1954
	1955
	1956	/******************************************************************************
	1957	*****************************************************************************/
	1958	bool regfi_iterator_up(REGFI_ITERATOR* i)
	1959	{
	1960	REGFI_ITER_POSITION* pos;
	1961
	1962	pos = (REGFI_ITER_POSITION*)void_stack_pop(i->key_positions);
	1963	if(pos == NULL)
	1964	return false;
	1965
[228]	1966	if(!regfi_lock(i->f, &i->f->mem_lock, "regfi_iterator_up"))
	1967	return false;
	1968
[249]	1969	talloc_unlink(i, i->cur);
	1970
[228]	1971	regfi_unlock(i->f, &i->f->mem_lock, "regfi_iterator_up");
	1972
[249]	1973	i->cur = pos;
[80]	1974	return true;
	1975	}
	1976
	1977
	1978	/******************************************************************************
	1979	*****************************************************************************/
	1980	bool regfi_iterator_to_root(REGFI_ITERATOR* i)
	1981	{
	1982	while(regfi_iterator_up(i))
	1983	continue;
	1984
	1985	return true;
	1986	}
	1987
	1988
	1989	/******************************************************************************
	1990	*****************************************************************************/
[207]	1991	bool regfi_iterator_find_subkey(REGFI_ITERATOR* i, const char* name)
[80]	1992	{
[249]	1993	const REGFI_NK* cur_key;
[207]	1994	uint32_t new_index;
[249]	1995	bool ret_val = false;
[133]	1996
[249]	1997	cur_key = regfi_iterator_cur_key(i);
	1998	if(cur_key == NULL)
[257]	1999	regfi_log_add(REGFI_LOG_ERROR, "Current key invalid in find_subkey.");
[249]	2000	return ret_val;
	2001
	2002	if(regfi_find_subkey(i->f, cur_key, name, &new_index))
[80]	2003	{
[249]	2004	i->cur->cur_subkey = new_index;
	2005	ret_val = true;
[80]	2006	}
	2007
[249]	2008	regfi_free_record(i->f, cur_key);
	2009	return ret_val;
[80]	2010	}
	2011
	2012
	2013	/******************************************************************************
	2014	*****************************************************************************/
[252]	2015	bool regfi_iterator_descend(REGFI_ITERATOR* i, const char** path)
[80]	2016	{
[168]	2017	uint32_t x;
[80]	2018	if(path == NULL)
	2019	return false;
	2020
	2021	for(x=0;
	2022	((path[x] != NULL) && regfi_iterator_find_subkey(i, path[x])
	2023	&& regfi_iterator_down(i));
	2024	x++)
	2025	{ continue; }
	2026
	2027	if(path[x] == NULL)
[215]	2028	{
[80]	2029	return true;
[215]	2030	}
	2031
[80]	2032	/* XXX: is this the right number of times? */
	2033	for(; x > 0; x--)
	2034	regfi_iterator_up(i);
	2035
	2036	return false;
	2037	}
	2038
	2039
	2040	/******************************************************************************
	2041	*****************************************************************************/
[203]	2042	const REGFI_NK* regfi_iterator_cur_key(REGFI_ITERATOR* i)
[80]	2043	{
[228]	2044	const REGFI_NK* ret_val = NULL;
	2045
[249]	2046	ret_val = regfi_load_key(i->f, i->cur->offset, i->f->string_encoding, true);
[228]	2047	return ret_val;
[80]	2048	}
	2049
	2050
	2051	/******************************************************************************
	2052	*****************************************************************************/
[206]	2053	const REGFI_SK* regfi_fetch_sk(REGFI_FILE* file, const REGFI_NK* key)
[109]	2054	{
[206]	2055	if(key == NULL \|\| key->sk_off == REGFI_OFFSET_NONE)
[109]	2056	return NULL;
	2057
[206]	2058	return regfi_load_sk(file, key->sk_off + REGFI_REGF_SIZE, true);
[109]	2059	}
	2060
	2061
	2062	/******************************************************************************
	2063	*****************************************************************************/
[253]	2064	const REGFI_SK* regfi_next_sk(REGFI_FILE* file, const REGFI_SK* sk)
	2065	{
	2066	if(sk == NULL \|\| sk->next_sk_off == REGFI_OFFSET_NONE)
	2067	return NULL;
	2068
	2069	return regfi_load_sk(file, sk->next_sk_off + REGFI_REGF_SIZE, true);
	2070	}
	2071
	2072
	2073	/******************************************************************************
	2074	*****************************************************************************/
	2075	const REGFI_SK* regfi_prev_sk(REGFI_FILE* file, const REGFI_SK* sk)
	2076	{
	2077	if(sk == NULL \|\| sk->prev_sk_off == REGFI_OFFSET_NONE)
	2078	return NULL;
	2079
	2080	return regfi_load_sk(file, sk->prev_sk_off + REGFI_REGF_SIZE, true);
	2081	}
	2082
	2083
	2084	/******************************************************************************
	2085	*****************************************************************************/
[199]	2086	bool regfi_iterator_first_subkey(REGFI_ITERATOR* i)
[80]	2087	{
[249]	2088	i->cur->cur_subkey = 0;
	2089	return (i->cur->cur_subkey < i->cur->num_subkeys);
[80]	2090	}
	2091
	2092
	2093	/******************************************************************************
	2094	*****************************************************************************/
[203]	2095	const REGFI_NK* regfi_iterator_cur_subkey(REGFI_ITERATOR* i)
[80]	2096	{
[249]	2097	const REGFI_NK* cur_key;
	2098	const REGFI_NK* ret_val;
	2099
	2100	cur_key = regfi_iterator_cur_key(i);
	2101	if(cur_key == NULL)
[257]	2102	regfi_log_add(REGFI_LOG_ERROR, "Current key invalid in cur_subkey.");
[249]	2103	return NULL;
	2104
	2105	ret_val = regfi_get_subkey(i->f, cur_key, i->cur->cur_subkey);
	2106
	2107	regfi_free_record(i->f, cur_key);
	2108	return ret_val;
[30]	2109	}
[80]	2110
	2111
	2112	/******************************************************************************
	2113	*****************************************************************************/
[199]	2114	bool regfi_iterator_next_subkey(REGFI_ITERATOR* i)
[80]	2115	{
[249]	2116	i->cur->cur_subkey++;
	2117	return (i->cur->cur_subkey < i->cur->num_subkeys);
[80]	2118	}
	2119
	2120
	2121	/******************************************************************************
	2122	*****************************************************************************/
[207]	2123	bool regfi_iterator_find_value(REGFI_ITERATOR* i, const char* name)
[80]	2124	{
[249]	2125	const REGFI_NK* cur_key;
[207]	2126	uint32_t new_index;
[249]	2127	bool ret_val = false;
[80]	2128
[249]	2129	cur_key = regfi_iterator_cur_key(i);
	2130	if(cur_key == NULL)
[257]	2131	regfi_log_add(REGFI_LOG_ERROR, "Current key invalid in find_value.");
[249]	2132	return ret_val;
	2133
	2134	if(regfi_find_value(i->f, cur_key, name, &new_index))
[80]	2135	{
[249]	2136	i->cur->cur_value = new_index;
	2137	ret_val = true;
[80]	2138	}
	2139
[249]	2140	regfi_free_record(i->f, cur_key);
	2141	return ret_val;
[80]	2142	}
	2143
	2144
	2145	/******************************************************************************
	2146	*****************************************************************************/
[199]	2147	bool regfi_iterator_first_value(REGFI_ITERATOR* i)
[80]	2148	{
[249]	2149	i->cur->cur_value = 0;
	2150	return (i->cur->cur_value < i->cur->num_values);
[80]	2151	}
	2152
	2153
	2154	/******************************************************************************
	2155	*****************************************************************************/
[203]	2156	const REGFI_VK* regfi_iterator_cur_value(REGFI_ITERATOR* i)
[80]	2157	{
[249]	2158	const REGFI_NK* cur_key;
	2159	const REGFI_VK* ret_val = NULL;
	2160
	2161	cur_key = regfi_iterator_cur_key(i);
	2162	if(cur_key == NULL)
[257]	2163	regfi_log_add(REGFI_LOG_ERROR, "Current key invalid in cur_value.");
[249]	2164	return ret_val;
	2165
	2166	ret_val = regfi_get_value(i->f, cur_key, i->cur->cur_value);
	2167
	2168	regfi_free_record(i->f, cur_key);
	2169	return ret_val;
[80]	2170	}
	2171
	2172
	2173	/******************************************************************************
	2174	*****************************************************************************/
[199]	2175	bool regfi_iterator_next_value(REGFI_ITERATOR* i)
[80]	2176	{
[249]	2177	i->cur->cur_value++;
	2178	return (i->cur->cur_value < i->cur->num_values);
[80]	2179	}
[97]	2180
	2181
[249]	2182
	2183
[159]	2184	/******************************************************************************
	2185	*****************************************************************************/
[252]	2186	const REGFI_NK** regfi_iterator_ancestry(REGFI_ITERATOR* i)
[249]	2187	{
	2188	REGFI_NK** ret_val;
	2189	void_stack_iterator* iter;
	2190	const REGFI_ITER_POSITION* cur;
[250]	2191	uint16_t k, num_keys;
[249]	2192
[250]	2193	num_keys = void_stack_size(i->key_positions)+1;
	2194	ret_val = talloc_array(NULL, REGFI_NK*, num_keys+1);
[249]	2195	if(ret_val == NULL)
	2196	return NULL;
	2197
	2198	iter = void_stack_iterator_new(i->key_positions);
	2199	if (iter == NULL)
	2200	{
	2201	talloc_free(ret_val);
	2202	return NULL;
	2203	}
[250]	2204
	2205	k=0;
	2206	for(cur=void_stack_iterator_next(iter);
	2207	cur != NULL; cur=void_stack_iterator_next(iter))
	2208	{
	2209	ret_val[k++] = regfi_load_key(i->f, cur->offset, i->f->string_encoding, true);
	2210	}
	2211	ret_val[k] = regfi_load_key(i->f, i->cur->offset, i->f->string_encoding, true);
	2212	void_stack_iterator_free(iter);
	2213
[252]	2214	if(!regfi_lock(i->f, &i->f->mem_lock, "regfi_iterator_ancestry"))
[249]	2215	{
	2216	talloc_free(ret_val);
	2217	return NULL;
	2218	}
	2219
[250]	2220	for(k=0; k<num_keys; k++)
[249]	2221	talloc_reparent(NULL, ret_val, ret_val[k]);
	2222
[252]	2223	regfi_unlock(i->f, &i->f->mem_lock, "regfi_iterator_ancestry");
[249]	2224
[250]	2225	ret_val[k] = NULL;
[249]	2226	return (const REGFI_NK**)ret_val;
	2227	}
	2228
	2229
	2230	/******************************************************************************
	2231	*****************************************************************************/
[206]	2232	const REGFI_CLASSNAME* regfi_fetch_classname(REGFI_FILE* file,
	2233	const REGFI_NK* key)
[160]	2234	{
	2235	REGFI_CLASSNAME* ret_val;
[168]	2236	uint8_t* raw;
[160]	2237	char* interpreted;
[168]	2238	uint32_t offset;
	2239	int32_t conv_size, max_size;
	2240	uint16_t parse_length;
[160]	2241
	2242	if(key->classname_off == REGFI_OFFSET_NONE \|\| key->classname_length == 0)
	2243	return NULL;
	2244
	2245	offset = key->classname_off + REGFI_REGF_SIZE;
[206]	2246	max_size = regfi_calc_maxsize(file, offset);
[160]	2247	if(max_size <= 0)
	2248	return NULL;
	2249
	2250	parse_length = key->classname_length;
[206]	2251	raw = regfi_parse_classname(file, offset, &parse_length, max_size, true);
[160]	2252
	2253	if(raw == NULL)
	2254	{
[182]	2255	regfi_log_add(REGFI_LOG_WARN, "Could not parse class"
	2256	" name at offset 0x%.8X for key record at offset 0x%.8X.",
	2257	offset, key->offset);
[160]	2258	return NULL;
	2259	}
	2260
	2261	ret_val = talloc(NULL, REGFI_CLASSNAME);
	2262	if(ret_val == NULL)
	2263	return NULL;
	2264
[206]	2265	ret_val->offset = offset;
[160]	2266	ret_val->raw = raw;
	2267	ret_val->size = parse_length;
[223]	2268	talloc_reparent(NULL, ret_val, raw);
[160]	2269
	2270	interpreted = talloc_array(NULL, char, parse_length);
	2271
[161]	2272	conv_size = regfi_conv_charset(regfi_encoding_int2str(REGFI_ENCODING_UTF16LE),
[206]	2273	regfi_encoding_int2str(file->string_encoding),
[160]	2274	raw, interpreted,
	2275	parse_length, parse_length);
	2276	if(conv_size < 0)
	2277	{
[182]	2278	regfi_log_add(REGFI_LOG_WARN, "Error occurred while"
	2279	" converting classname to charset %s. Error message: %s",
[206]	2280	file->string_encoding, strerror(-conv_size));
[160]	2281	talloc_free(interpreted);
	2282	ret_val->interpreted = NULL;
	2283	}
	2284	else
	2285	{
[223]	2286	/* XXX: check for NULL return here? */
[160]	2287	interpreted = talloc_realloc(NULL, interpreted, char, conv_size);
	2288	ret_val->interpreted = interpreted;
[223]	2289	talloc_reparent(NULL, ret_val, interpreted);
[160]	2290	}
	2291
	2292	return ret_val;
	2293	}
	2294
	2295
	2296	/******************************************************************************
	2297	*****************************************************************************/
[206]	2298	const REGFI_DATA* regfi_fetch_data(REGFI_FILE* file,
	2299	const REGFI_VK* value)
[159]	2300	{
	2301	REGFI_DATA* ret_val = NULL;
	2302	REGFI_BUFFER raw_data;
	2303
	2304	if(value->data_size != 0)
	2305	{
[206]	2306	raw_data = regfi_load_data(file, value->data_off, value->data_size,
[209]	2307	value->data_in_offset, true);
[159]	2308	if(raw_data.buf == NULL)
	2309	{
[182]	2310	regfi_log_add(REGFI_LOG_WARN, "Could not parse data record"
	2311	" while parsing VK record at offset 0x%.8X.",
	2312	value->offset);
[159]	2313	}
	2314	else
	2315	{
	2316	ret_val = regfi_buffer_to_data(raw_data);
	2317
	2318	if(ret_val == NULL)
	2319	{
[182]	2320	regfi_log_add(REGFI_LOG_WARN, "Error occurred in converting"
	2321	" data buffer to data structure while interpreting "
	2322	"data for VK record at offset 0x%.8X.",
	2323	value->offset);
[159]	2324	talloc_free(raw_data.buf);
	2325	return NULL;
	2326	}
	2327
[206]	2328	if(!regfi_interpret_data(file, file->string_encoding,
	2329	value->type, ret_val))
[159]	2330	{
[182]	2331	regfi_log_add(REGFI_LOG_INFO, "Error occurred while"
	2332	" interpreting data for VK record at offset 0x%.8X.",
	2333	value->offset);
[159]	2334	}
	2335	}
	2336	}
	2337
	2338	return ret_val;
	2339	}
	2340
	2341
[207]	2342
[159]	2343	/******************************************************************************
	2344	*****************************************************************************/
[207]	2345	bool regfi_find_subkey(REGFI_FILE* file, const REGFI_NK* key,
	2346	const char* name, uint32_t* index)
	2347	{
	2348	const REGFI_NK* cur;
	2349	uint32_t i;
	2350	uint32_t num_subkeys = regfi_fetch_num_subkeys(key);
	2351	bool found = false;
	2352
[256]	2353	/* XXX: should we allow "(default)" subkey names?
	2354	* Do realistically they exist?
[207]	2355	*/
	2356	if(name == NULL)
	2357	return false;
	2358
	2359	for(i=0; (i < num_subkeys) && (found == false); i++)
	2360	{
	2361	cur = regfi_get_subkey(file, key, i);
	2362	if(cur == NULL)
	2363	return false;
	2364
[256]	2365	/* A NULL name signifies the "(default)" value for a key */
	2366	if(cur->name != NULL && (strcasecmp(cur->name, name) == 0))
[207]	2367	{
	2368	found = true;
	2369	*index = i;
	2370	}
	2371
[228]	2372	regfi_free_record(file, cur);
[207]	2373	}
	2374
	2375	return found;
	2376	}
	2377
	2378
	2379
	2380	/******************************************************************************
	2381	*****************************************************************************/
	2382	bool regfi_find_value(REGFI_FILE* file, const REGFI_NK* key,
	2383	const char* name, uint32_t* index)
	2384	{
	2385	const REGFI_VK* cur;
	2386	uint32_t i;
	2387	uint32_t num_values = regfi_fetch_num_values(key);
	2388	bool found = false;
	2389
	2390	for(i=0; (i < num_values) && (found == false); i++)
	2391	{
	2392	cur = regfi_get_value(file, key, i);
	2393	if(cur == NULL)
	2394	return false;
	2395
[256]	2396	/* A NULL name signifies the "(default)" value for a key */
	2397	if(((name == NULL) && (cur->name == NULL))
	2398	\|\| ((name != NULL) && (cur->name != NULL)
	2399	&& (strcasecmp(cur->name, name) == 0)))
[207]	2400	{
	2401	found = true;
	2402	*index = i;
	2403	}
	2404
[228]	2405	regfi_free_record(file, cur);
[207]	2406	}
	2407
	2408	return found;
	2409	}
	2410
	2411
	2412
	2413	/******************************************************************************
	2414	*****************************************************************************/
	2415	const REGFI_NK* regfi_get_subkey(REGFI_FILE* file, const REGFI_NK* key,
	2416	uint32_t index)
	2417	{
	2418	if(index < regfi_fetch_num_subkeys(key))
	2419	{
	2420	return regfi_load_key(file,
	2421	key->subkeys->elements[index].offset+REGFI_REGF_SIZE,
	2422	file->string_encoding, true);
	2423	}
	2424
	2425	return NULL;
	2426	}
	2427
	2428
	2429	/******************************************************************************
	2430	*****************************************************************************/
	2431	const REGFI_VK* regfi_get_value(REGFI_FILE* file, const REGFI_NK* key,
	2432	uint32_t index)
	2433	{
	2434	if(index < regfi_fetch_num_values(key))
	2435	{
	2436	return regfi_load_value(file,
	2437	key->values->elements[index]+REGFI_REGF_SIZE,
	2438	file->string_encoding, true);
	2439	}
	2440
	2441	return NULL;
	2442	}
	2443
	2444
[215]	2445
[207]	2446	/******************************************************************************
	2447	*****************************************************************************/
[215]	2448	const REGFI_NK* regfi_get_parentkey(REGFI_FILE* file, const REGFI_NK* key)
	2449	{
	2450	if(key != NULL && key->parent_off != REGFI_OFFSET_NONE)
	2451	return regfi_load_key(file,
	2452	key->parent_off+REGFI_REGF_SIZE,
	2453	file->string_encoding, true);
[228]	2454
[215]	2455	return NULL;
	2456	}
	2457
	2458
	2459
	2460	/******************************************************************************
	2461	*****************************************************************************/
[159]	2462	REGFI_DATA* regfi_buffer_to_data(REGFI_BUFFER raw_data)
	2463	{
	2464	REGFI_DATA* ret_val;
	2465
	2466	if(raw_data.buf == NULL)
	2467	return NULL;
	2468
	2469	ret_val = talloc(NULL, REGFI_DATA);
	2470	if(ret_val == NULL)
	2471	return NULL;
	2472
[223]	2473	talloc_reparent(NULL, ret_val, raw_data.buf);
[159]	2474	ret_val->raw = raw_data.buf;
	2475	ret_val->size = raw_data.len;
	2476	ret_val->interpreted_size = 0;
	2477	ret_val->interpreted.qword = 0;
	2478
	2479	return ret_val;
	2480	}
	2481
	2482
	2483	/******************************************************************************
	2484	*****************************************************************************/
[161]	2485	bool regfi_interpret_data(REGFI_FILE* file, REGFI_ENCODING string_encoding,
[168]	2486	uint32_t type, REGFI_DATA* data)
[159]	2487	{
[168]	2488	uint8_t** tmp_array;
	2489	uint8_t* tmp_str;
	2490	int32_t tmp_size;
	2491	uint32_t i, j, array_size;
[159]	2492
	2493	if(data == NULL)
	2494	return false;
	2495
	2496	switch (type)
	2497	{
	2498	case REG_SZ:
	2499	case REG_EXPAND_SZ:
	2500	/* REG_LINK is a symbolic link, stored as a unicode string. */
	2501	case REG_LINK:
[168]	2502	tmp_str = talloc_array(NULL, uint8_t, data->size);
[159]	2503	if(tmp_str == NULL)
	2504	{
	2505	data->interpreted.string = NULL;
	2506	data->interpreted_size = 0;
	2507	return false;
	2508	}
	2509
[161]	2510	tmp_size = regfi_conv_charset(regfi_encoding_int2str(REGFI_ENCODING_UTF16LE),
	2511	regfi_encoding_int2str(string_encoding),
[159]	2512	data->raw, (char*)tmp_str,
	2513	data->size, data->size);
	2514	if(tmp_size < 0)
	2515	{
[182]	2516	regfi_log_add(REGFI_LOG_INFO, "Error occurred while"
[193]	2517	" converting data of type %d to %d. Error message: %s",
[182]	2518	type, string_encoding, strerror(-tmp_size));
[159]	2519	talloc_free(tmp_str);
	2520	data->interpreted.string = NULL;
	2521	data->interpreted_size = 0;
	2522	return false;
	2523	}
	2524
[168]	2525	tmp_str = talloc_realloc(NULL, tmp_str, uint8_t, tmp_size);
[257]	2526	if(tmp_str == NULL)
	2527	return false;
[159]	2528	data->interpreted.string = tmp_str;
	2529	data->interpreted_size = tmp_size;
[223]	2530	talloc_reparent(NULL, data, tmp_str);
[159]	2531	break;
	2532
	2533	case REG_DWORD:
	2534	if(data->size < 4)
	2535	{
	2536	data->interpreted.dword = 0;
	2537	data->interpreted_size = 0;
	2538	return false;
	2539	}
	2540	data->interpreted.dword = IVAL(data->raw, 0);
	2541	data->interpreted_size = 4;
	2542	break;
	2543
	2544	case REG_DWORD_BE:
	2545	if(data->size < 4)
	2546	{
	2547	data->interpreted.dword_be = 0;
	2548	data->interpreted_size = 0;
	2549	return false;
	2550	}
	2551	data->interpreted.dword_be = RIVAL(data->raw, 0);
	2552	data->interpreted_size = 4;
	2553	break;
	2554
	2555	case REG_QWORD:
	2556	if(data->size < 8)
	2557	{
	2558	data->interpreted.qword = 0;
	2559	data->interpreted_size = 0;
	2560	return false;
	2561	}
	2562	data->interpreted.qword =
[168]	2563	(uint64_t)IVAL(data->raw, 0) + (((uint64_t)IVAL(data->raw, 4))<<32);
[159]	2564	data->interpreted_size = 8;
	2565	break;
	2566
	2567	case REG_MULTI_SZ:
[168]	2568	tmp_str = talloc_array(NULL, uint8_t, data->size);
[159]	2569	if(tmp_str == NULL)
	2570	{
	2571	data->interpreted.multiple_string = NULL;
	2572	data->interpreted_size = 0;
	2573	return false;
	2574	}
	2575
	2576	/* Attempt to convert entire string from UTF-16LE to output encoding,
	2577	* then parse and quote fields individually.
	2578	*/
[161]	2579	tmp_size = regfi_conv_charset(regfi_encoding_int2str(REGFI_ENCODING_UTF16LE),
	2580	regfi_encoding_int2str(string_encoding),
[159]	2581	data->raw, (char*)tmp_str,
	2582	data->size, data->size);
	2583	if(tmp_size < 0)
	2584	{
[182]	2585	regfi_log_add(REGFI_LOG_INFO, "Error occurred while"
	2586	" converting data of type %d to %s. Error message: %s",
	2587	type, string_encoding, strerror(-tmp_size));
[159]	2588	talloc_free(tmp_str);
	2589	data->interpreted.multiple_string = NULL;
	2590	data->interpreted_size = 0;
	2591	return false;
	2592	}
	2593
	2594	array_size = tmp_size+1;
[168]	2595	tmp_array = talloc_array(NULL, uint8_t*, array_size);
[159]	2596	if(tmp_array == NULL)
	2597	{
	2598	talloc_free(tmp_str);
	2599	data->interpreted.string = NULL;
	2600	data->interpreted_size = 0;
	2601	return false;
	2602	}
	2603
	2604	tmp_array[0] = tmp_str;
	2605	for(i=0,j=1; i < tmp_size && j < array_size-1; i++)
	2606	{
[209]	2607	if(tmp_str[i] == '\0' && (i+1 < tmp_size) && tmp_str[i+1] != '\0')
[159]	2608	tmp_array[j++] = tmp_str+i+1;
	2609	}
	2610	tmp_array[j] = NULL;
[168]	2611	tmp_array = talloc_realloc(NULL, tmp_array, uint8_t*, j+1);
[159]	2612	data->interpreted.multiple_string = tmp_array;
	2613	/* XXX: how meaningful is this? should we store number of strings instead? */
	2614	data->interpreted_size = tmp_size;
[223]	2615	talloc_reparent(NULL, tmp_array, tmp_str);
	2616	talloc_reparent(NULL, data, tmp_array);
[159]	2617	break;
	2618
	2619	/* XXX: Dont know how to interpret these yet, just treat as binary */
	2620	case REG_NONE:
	2621	data->interpreted.none = data->raw;
	2622	data->interpreted_size = data->size;
	2623	break;
	2624
	2625	case REG_RESOURCE_LIST:
	2626	data->interpreted.resource_list = data->raw;
	2627	data->interpreted_size = data->size;
	2628	break;
	2629
	2630	case REG_FULL_RESOURCE_DESCRIPTOR:
	2631	data->interpreted.full_resource_descriptor = data->raw;
	2632	data->interpreted_size = data->size;
	2633	break;
	2634
	2635	case REG_RESOURCE_REQUIREMENTS_LIST:
	2636	data->interpreted.resource_requirements_list = data->raw;
	2637	data->interpreted_size = data->size;
	2638	break;
	2639
	2640	case REG_BINARY:
	2641	data->interpreted.binary = data->raw;
	2642	data->interpreted_size = data->size;
	2643	break;
	2644
	2645	default:
	2646	data->interpreted.qword = 0;
	2647	data->interpreted_size = 0;
	2648	return false;
	2649	}
	2650
	2651	data->type = type;
	2652	return true;
	2653	}
	2654
	2655
[166]	2656	/******************************************************************************
[159]	2657	* Convert from UTF-16LE to specified character set.
	2658	* On error, returns a negative errno code.
[166]	2659	*****************************************************************************/
[168]	2660	int32_t regfi_conv_charset(const char* input_charset, const char* output_charset,
[206]	2661	uint8_t* input, char* output,
	2662	uint32_t input_len, uint32_t output_max)
[159]	2663	{
	2664	iconv_t conv_desc;
	2665	char* inbuf = (char*)input;
	2666	char* outbuf = output;
	2667	size_t in_len = (size_t)input_len;
	2668	size_t out_len = (size_t)(output_max-1);
	2669	int ret;
	2670
[161]	2671	/* XXX: Consider creating a couple of conversion descriptors earlier,
	2672	* storing them on an iterator so they don't have to be recreated
	2673	* each time.
	2674	*/
	2675
[159]	2676	/* Set up conversion descriptor. */
[161]	2677	conv_desc = iconv_open(output_charset, input_charset);
[159]	2678
	2679	ret = iconv(conv_desc, &inbuf, &in_len, &outbuf, &out_len);
	2680	if(ret == -1)
	2681	{
	2682	iconv_close(conv_desc);
	2683	return -errno;
	2684	}
	2685	*outbuf = '\0';
	2686
	2687	iconv_close(conv_desc);
	2688	return output_max-out_len-1;
	2689	}
	2690
	2691
	2692
	2693	/*******************************************************************
[97]	2694	* Computes the checksum of the registry file header.
[159]	2695	* buffer must be at least the size of a regf header (4096 bytes).
[97]	2696	*******************************************************************/
[168]	2697	static uint32_t regfi_compute_header_checksum(uint8_t* buffer)
[97]	2698	{
[168]	2699	uint32_t checksum, x;
[97]	2700	int i;
	2701
	2702	/* XOR of all bytes 0x0000 - 0x01FB */
	2703
	2704	checksum = x = 0;
	2705
	2706	for ( i=0; i<0x01FB; i+=4 ) {
	2707	x = IVAL(buffer, i );
	2708	checksum ^= x;
	2709	}
	2710
	2711	return checksum;
	2712	}
	2713
	2714
	2715	/*******************************************************************
	2716	*******************************************************************/
[178]	2717	REGFI_FILE* regfi_parse_regf(REGFI_RAW_FILE* file_cb, bool strict)
[97]	2718	{
[168]	2719	uint8_t file_header[REGFI_REGF_SIZE];
	2720	uint32_t length;
[135]	2721	REGFI_FILE* ret_val;
[97]	2722
[150]	2723	ret_val = talloc(NULL, REGFI_FILE);
[97]	2724	if(ret_val == NULL)
	2725	return NULL;
	2726
[150]	2727	ret_val->sk_cache = NULL;
	2728	ret_val->hbins = NULL;
[178]	2729
[135]	2730	length = REGFI_REGF_SIZE;
[178]	2731	if((regfi_read(file_cb, file_header, &length)) != 0
	2732	\|\| length != REGFI_REGF_SIZE)
[182]	2733	{
	2734	regfi_log_add(REGFI_LOG_WARN, "Read failed while parsing REGF structure.");
[150]	2735	goto fail;
[182]	2736	}
	2737
[97]	2738	ret_val->checksum = IVAL(file_header, 0x1FC);
	2739	ret_val->computed_checksum = regfi_compute_header_checksum(file_header);
	2740	if (strict && (ret_val->checksum != ret_val->computed_checksum))
[182]	2741	{
	2742	regfi_log_add(REGFI_LOG_WARN, "Stored header checksum (%.8X) did not equal"
	2743	" computed checksum (%.8X).",
	2744	ret_val->checksum, ret_val->computed_checksum);
	2745	if(strict)
	2746	goto fail;
	2747	}
[97]	2748
[135]	2749	memcpy(ret_val->magic, file_header, REGFI_REGF_MAGIC_SIZE);
[150]	2750	if(memcmp(ret_val->magic, "regf", REGFI_REGF_MAGIC_SIZE) != 0)
[97]	2751	{
[182]	2752	regfi_log_add(REGFI_LOG_ERROR, "Magic number mismatch "
	2753	"(%.2X %.2X %.2X %.2X) while parsing hive header",
	2754	ret_val->magic[0], ret_val->magic[1],
	2755	ret_val->magic[2], ret_val->magic[3]);
	2756	goto fail;
[97]	2757	}
[178]	2758
[151]	2759	ret_val->sequence1 = IVAL(file_header, 0x4);
	2760	ret_val->sequence2 = IVAL(file_header, 0x8);
[251]	2761	ret_val->mtime = ((uint64_t)IVAL(file_header, 0x10)) << 32;
	2762	ret_val->mtime \|= IVAL(file_header, 0xC);
[151]	2763	ret_val->major_version = IVAL(file_header, 0x14);
	2764	ret_val->minor_version = IVAL(file_header, 0x18);
	2765	ret_val->type = IVAL(file_header, 0x1C);
	2766	ret_val->format = IVAL(file_header, 0x20);
	2767	ret_val->root_cell = IVAL(file_header, 0x24);
[97]	2768	ret_val->last_block = IVAL(file_header, 0x28);
[151]	2769	ret_val->cluster = IVAL(file_header, 0x2C);
[97]	2770
[151]	2771	memcpy(ret_val->file_name, file_header+0x30, REGFI_REGF_NAME_SIZE);
	2772
	2773	ret_val->rm_id = winsec_parse_uuid(ret_val, file_header+0x70, 16);
[257]	2774	if(ret_val->rm_id == NULL)
	2775	regfi_log_add(REGFI_LOG_WARN, "Hive header's rm_id failed to parse.");
	2776
[151]	2777	ret_val->log_id = winsec_parse_uuid(ret_val, file_header+0x80, 16);
[257]	2778	if(ret_val->log_id == NULL)
	2779	regfi_log_add(REGFI_LOG_WARN, "Hive header's log_id failed to parse.");
	2780
[151]	2781	ret_val->flags = IVAL(file_header, 0x90);
[257]	2782
[151]	2783	ret_val->tm_id = winsec_parse_uuid(ret_val, file_header+0x94, 16);
[257]	2784	if(ret_val->tm_id == NULL)
	2785	regfi_log_add(REGFI_LOG_WARN, "Hive header's tm_id failed to parse.");
	2786
[151]	2787	ret_val->guid_signature = IVAL(file_header, 0xa4);
	2788
	2789	memcpy(ret_val->reserved1, file_header+0xa8, REGFI_REGF_RESERVED1_SIZE);
	2790	memcpy(ret_val->reserved2, file_header+0x200, REGFI_REGF_RESERVED2_SIZE);
	2791
	2792	ret_val->thaw_tm_id = winsec_parse_uuid(ret_val, file_header+0xFC8, 16);
	2793	ret_val->thaw_rm_id = winsec_parse_uuid(ret_val, file_header+0xFD8, 16);
	2794	ret_val->thaw_log_id = winsec_parse_uuid(ret_val, file_header+0xFE8, 16);
[152]	2795	ret_val->boot_type = IVAL(file_header, 0xFF8);
	2796	ret_val->boot_recover = IVAL(file_header, 0xFFC);
[151]	2797
[97]	2798	return ret_val;
[150]	2799
	2800	fail:
	2801	talloc_free(ret_val);
	2802	return NULL;
[97]	2803	}
	2804
	2805
	2806
[148]	2807	/******************************************************************************
[97]	2808	* Given real file offset, read and parse the hbin at that location
[110]	2809	* along with it's associated cells.
[148]	2810	******************************************************************************/
[168]	2811	REGFI_HBIN* regfi_parse_hbin(REGFI_FILE* file, uint32_t offset, bool strict)
[97]	2812	{
[181]	2813	REGFI_HBIN* hbin = NULL;
[168]	2814	uint8_t hbin_header[REGFI_HBIN_HEADER_SIZE];
	2815	uint32_t length;
[99]	2816
	2817	if(offset >= file->file_length)
[180]	2818	goto fail;
	2819
[186]	2820	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_hbin"))
[180]	2821	goto fail;
[97]	2822
[178]	2823	if(regfi_seek(file->cb, offset, SEEK_SET) == -1)
[137]	2824	{
[182]	2825	regfi_log_add(REGFI_LOG_ERROR, "Seek failed"
	2826	" while parsing hbin at offset 0x%.8X.", offset);
[180]	2827	goto fail_locked;
[137]	2828	}
[97]	2829
[135]	2830	length = REGFI_HBIN_HEADER_SIZE;
[178]	2831	if((regfi_read(file->cb, hbin_header, &length) != 0)
[135]	2832	\|\| length != REGFI_HBIN_HEADER_SIZE)
[182]	2833	{
	2834	regfi_log_add(REGFI_LOG_ERROR, "Read failed"
	2835	" while parsing hbin at offset 0x%.8X.", offset);
[180]	2836	goto fail_locked;
[182]	2837	}
[97]	2838
[186]	2839	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_hbin"))
[180]	2840	goto fail;
[97]	2841
[148]	2842	hbin = talloc(NULL, REGFI_HBIN);
	2843	if(hbin == NULL)
[180]	2844	goto fail;
[99]	2845	hbin->file_off = offset;
	2846
[97]	2847	memcpy(hbin->magic, hbin_header, 4);
	2848	if(strict && (memcmp(hbin->magic, "hbin", 4) != 0))
[99]	2849	{
[182]	2850	/* This always seems to happen at the end of a file, so we make it an INFO
	2851	* message, rather than something more serious.
	2852	*/
	2853	regfi_log_add(REGFI_LOG_INFO, "Magic number mismatch "
	2854	"(%.2X %.2X %.2X %.2X) while parsing hbin at offset"
	2855	" 0x%.8X.", hbin->magic[0], hbin->magic[1],
	2856	hbin->magic[2], hbin->magic[3], offset);
[180]	2857	goto fail;
[99]	2858	}
[97]	2859
	2860	hbin->first_hbin_off = IVAL(hbin_header, 0x4);
	2861	hbin->block_size = IVAL(hbin_header, 0x8);
[182]	2862	/* this should be the same thing as hbin->block_size, but just in case */
[97]	2863	hbin->next_block = IVAL(hbin_header, 0x1C);
	2864
	2865
	2866	/* Ensure the block size is a multiple of 0x1000 and doesn't run off
	2867	* the end of the file.
	2868	*/
[116]	2869	/* XXX: This may need to be relaxed for dealing with
	2870	* partial or corrupt files.
	2871	*/
[97]	2872	if((offset + hbin->block_size > file->file_length)
	2873	\|\| (hbin->block_size & 0xFFFFF000) != hbin->block_size)
[99]	2874	{
[182]	2875	regfi_log_add(REGFI_LOG_ERROR, "The hbin offset is not aligned"
	2876	" or runs off the end of the file"
	2877	" while parsing hbin at offset 0x%.8X.", offset);
[180]	2878	goto fail;
[99]	2879	}
[97]	2880
	2881	return hbin;
[180]	2882
	2883	fail_locked:
[186]	2884	regfi_unlock(file, &file->cb_lock, "regfi_parse_hbin");
[180]	2885	fail:
	2886	talloc_free(hbin);
	2887	return NULL;
[97]	2888	}
	2889
	2890
[126]	2891	/*******************************************************************
	2892	*******************************************************************/
[203]	2893	REGFI_NK* regfi_parse_nk(REGFI_FILE* file, uint32_t offset,
	2894	uint32_t max_size, bool strict)
[99]	2895	{
[168]	2896	uint8_t nk_header[REGFI_NK_MIN_LENGTH];
[203]	2897	REGFI_NK* ret_val;
[168]	2898	uint32_t length,cell_length;
[101]	2899	bool unalloc = false;
[99]	2900
[203]	2901	ret_val = talloc(NULL, REGFI_NK);
[180]	2902	if(ret_val == NULL)
	2903	{
[182]	2904	regfi_log_add(REGFI_LOG_ERROR, "Failed to allocate memory while"
	2905	" parsing NK record at offset 0x%.8X.", offset);
[180]	2906	goto fail;
	2907	}
	2908
[186]	2909	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_nk"))
[180]	2910	goto fail;
	2911
[178]	2912	if(!regfi_parse_cell(file->cb, offset, nk_header, REGFI_NK_MIN_LENGTH,
[101]	2913	&cell_length, &unalloc))
[137]	2914	{
[182]	2915	regfi_log_add(REGFI_LOG_WARN, "Could not parse cell header"
	2916	" while parsing NK record at offset 0x%.8X.", offset);
[180]	2917	goto fail_locked;
[137]	2918	}
	2919
[101]	2920	if((nk_header[0x0] != 'n') \|\| (nk_header[0x1] != 'k'))
[135]	2921	{
[182]	2922	regfi_log_add(REGFI_LOG_WARN, "Magic number mismatch in parsing"
	2923	" NK record at offset 0x%.8X.", offset);
[180]	2924	goto fail_locked;
[135]	2925	}
[99]	2926
[150]	2927	ret_val->values = NULL;
	2928	ret_val->subkeys = NULL;
[99]	2929	ret_val->offset = offset;
[101]	2930	ret_val->cell_size = cell_length;
	2931
[99]	2932	if(ret_val->cell_size > max_size)
	2933	ret_val->cell_size = max_size & 0xFFFFFFF8;
	2934	if((ret_val->cell_size < REGFI_NK_MIN_LENGTH)
[157]	2935	\|\| (strict && (ret_val->cell_size & 0x00000007) != 0))
[99]	2936	{
[182]	2937	regfi_log_add(REGFI_LOG_WARN, "A length check failed while"
	2938	" parsing NK record at offset 0x%.8X.", offset);
[180]	2939	goto fail_locked;
[99]	2940	}
	2941
[101]	2942	ret_val->magic[0] = nk_header[0x0];
	2943	ret_val->magic[1] = nk_header[0x1];
[161]	2944	ret_val->flags = SVAL(nk_header, 0x2);
[152]	2945
[161]	2946	if((ret_val->flags & ~REGFI_NK_KNOWN_FLAGS) != 0)
[99]	2947	{
[182]	2948	regfi_log_add(REGFI_LOG_WARN, "Unknown key flags (0x%.4X) while"
	2949	" parsing NK record at offset 0x%.8X.",
	2950	(ret_val->flags & ~REGFI_NK_KNOWN_FLAGS), offset);
[99]	2951	}
[101]	2952
[251]	2953	ret_val->mtime = ((uint64_t)IVAL(nk_header, 0x8)) << 32;
	2954	ret_val->mtime \|= IVAL(nk_header, 0x4);
[116]	2955	/* If the key is unallocated and the MTIME is earlier than Jan 1, 1990
	2956	* or later than Jan 1, 2290, we consider this a bad key. This helps
	2957	* weed out some false positives during deleted data recovery.
	2958	*/
	2959	if(unalloc
[251]	2960	&& (ret_val->mtime < REGFI_MTIME_MIN
	2961	\|\| ret_val->mtime > REGFI_MTIME_MAX))
[180]	2962	{ goto fail_locked; }
[116]	2963
[101]	2964	ret_val->unknown1 = IVAL(nk_header, 0xC);
	2965	ret_val->parent_off = IVAL(nk_header, 0x10);
	2966	ret_val->num_subkeys = IVAL(nk_header, 0x14);
	2967	ret_val->unknown2 = IVAL(nk_header, 0x18);
	2968	ret_val->subkeys_off = IVAL(nk_header, 0x1C);
	2969	ret_val->unknown3 = IVAL(nk_header, 0x20);
	2970	ret_val->num_values = IVAL(nk_header, 0x24);
	2971	ret_val->values_off = IVAL(nk_header, 0x28);
	2972	ret_val->sk_off = IVAL(nk_header, 0x2C);
	2973	ret_val->classname_off = IVAL(nk_header, 0x30);
[99]	2974
[101]	2975	ret_val->max_bytes_subkeyname = IVAL(nk_header, 0x34);
	2976	ret_val->max_bytes_subkeyclassname = IVAL(nk_header, 0x38);
	2977	ret_val->max_bytes_valuename = IVAL(nk_header, 0x3C);
	2978	ret_val->max_bytes_value = IVAL(nk_header, 0x40);
	2979	ret_val->unk_index = IVAL(nk_header, 0x44);
[99]	2980
[101]	2981	ret_val->name_length = SVAL(nk_header, 0x48);
	2982	ret_val->classname_length = SVAL(nk_header, 0x4A);
[206]	2983	ret_val->name = NULL;
[99]	2984
	2985	if(ret_val->name_length + REGFI_NK_MIN_LENGTH > ret_val->cell_size)
[101]	2986	{
	2987	if(strict)
	2988	{
[182]	2989	regfi_log_add(REGFI_LOG_ERROR, "Contents too large for cell"
	2990	" while parsing NK record at offset 0x%.8X.", offset);
[180]	2991	goto fail_locked;
[101]	2992	}
	2993	else
	2994	ret_val->name_length = ret_val->cell_size - REGFI_NK_MIN_LENGTH;
	2995	}
	2996	else if (unalloc)
	2997	{ /* Truncate cell_size if it's much larger than the apparent total record length. */
	2998	/* Round up to the next multiple of 8 */
	2999	length = (ret_val->name_length + REGFI_NK_MIN_LENGTH) & 0xFFFFFFF8;
	3000	if(length < ret_val->name_length + REGFI_NK_MIN_LENGTH)
	3001	length+=8;
[99]	3002
[101]	3003	/* If cell_size is still greater, truncate. */
	3004	if(length < ret_val->cell_size)
	3005	ret_val->cell_size = length;
	3006	}
	3007
[206]	3008	/* +1 to length in case we decided to use this directly as a string later */
	3009	ret_val->name_raw = talloc_array(ret_val, uint8_t, ret_val->name_length+1);
	3010	if(ret_val->name_raw == NULL)
[180]	3011	goto fail_locked;
[99]	3012
	3013	/* Don't need to seek, should be at the right offset */
	3014	length = ret_val->name_length;
[206]	3015	if((regfi_read(file->cb, (uint8_t*)ret_val->name_raw, &length) != 0)
[99]	3016	\|\| length != ret_val->name_length)
	3017	{
[182]	3018	regfi_log_add(REGFI_LOG_ERROR, "Failed to read key name"
	3019	" while parsing NK record at offset 0x%.8X.", offset);
[180]	3020	goto fail_locked;
[99]	3021	}
	3022
[186]	3023	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_nk"))
[180]	3024	goto fail;
	3025
[126]	3026	return ret_val;
[180]	3027
	3028	fail_locked:
[186]	3029	regfi_unlock(file, &file->cb_lock, "regfi_parse_nk");
[180]	3030	fail:
	3031	talloc_free(ret_val);
	3032	return NULL;
[126]	3033	}
	3034
	3035
[168]	3036	uint8_t* regfi_parse_classname(REGFI_FILE* file, uint32_t offset,
[206]	3037	uint16_t* name_length, uint32_t max_size, bool strict)
[126]	3038	{
[168]	3039	uint8_t* ret_val = NULL;
	3040	uint32_t length;
	3041	uint32_t cell_length;
[126]	3042	bool unalloc = false;
	3043
[180]	3044	if(*name_length <= 0 \|\| offset == REGFI_OFFSET_NONE
	3045	\|\| (offset & 0x00000007) != 0)
	3046	{ goto fail; }
	3047
[186]	3048	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_classname"))
[180]	3049	goto fail;
	3050
	3051	if(!regfi_parse_cell(file->cb, offset, NULL, 0, &cell_length, &unalloc))
[131]	3052	{
[182]	3053	regfi_log_add(REGFI_LOG_WARN, "Could not parse cell header"
	3054	" while parsing class name at offset 0x%.8X.", offset);
[180]	3055	goto fail_locked;
	3056	}
	3057
	3058	if((cell_length & 0x0000007) != 0)
	3059	{
[182]	3060	regfi_log_add(REGFI_LOG_ERROR, "Cell length not a multiple of 8"
	3061	" while parsing class name at offset 0x%.8X.", offset);
[180]	3062	goto fail_locked;
	3063	}
	3064
	3065	if(cell_length > max_size)
	3066	{
[182]	3067	regfi_log_add(REGFI_LOG_WARN, "Cell stretches past hbin "
	3068	"boundary while parsing class name at offset 0x%.8X.",
	3069	offset);
[180]	3070	if(strict)
	3071	goto fail_locked;
	3072	cell_length = max_size;
	3073	}
	3074
	3075	if((cell_length - 4) < *name_length)
	3076	{
[182]	3077	regfi_log_add(REGFI_LOG_WARN, "Class name is larger than"
	3078	" cell_length while parsing class name at offset"
	3079	" 0x%.8X.", offset);
[180]	3080	if(strict)
	3081	goto fail_locked;
	3082	*name_length = cell_length - 4;
	3083	}
	3084
	3085	ret_val = talloc_array(NULL, uint8_t, *name_length);
	3086	if(ret_val != NULL)
	3087	{
	3088	length = *name_length;
	3089	if((regfi_read(file->cb, ret_val, &length) != 0)
	3090	\|\| length != *name_length)
[137]	3091	{
[182]	3092	regfi_log_add(REGFI_LOG_ERROR, "Could not read class name"
	3093	" while parsing class name at offset 0x%.8X.", offset);
[180]	3094	goto fail_locked;
[137]	3095	}
[180]	3096	}
[126]	3097
[186]	3098	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_classname"))
[180]	3099	goto fail;
[137]	3100
[180]	3101	return ret_val;
[131]	3102
[180]	3103	fail_locked:
[186]	3104	regfi_unlock(file, &file->cb_lock, "regfi_parse_classname");
[180]	3105	fail:
	3106	talloc_free(ret_val);
	3107	return NULL;
[99]	3108	}
	3109
	3110
[152]	3111	/******************************************************************************
	3112	*******************************************************************************/
[203]	3113	REGFI_VK* regfi_parse_vk(REGFI_FILE* file, uint32_t offset,
[168]	3114	uint32_t max_size, bool strict)
[97]	3115	{
[203]	3116	REGFI_VK* ret_val;
[168]	3117	uint8_t vk_header[REGFI_VK_MIN_LENGTH];
	3118	uint32_t raw_data_size, length, cell_length;
[101]	3119	bool unalloc = false;
[97]	3120
[203]	3121	ret_val = talloc(NULL, REGFI_VK);
[180]	3122	if(ret_val == NULL)
	3123	goto fail;
	3124
[186]	3125	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_nk"))
[180]	3126	goto fail;
	3127
[178]	3128	if(!regfi_parse_cell(file->cb, offset, vk_header, REGFI_VK_MIN_LENGTH,
[101]	3129	&cell_length, &unalloc))
[137]	3130	{
[182]	3131	regfi_log_add(REGFI_LOG_WARN, "Could not parse cell header"
	3132	" while parsing VK record at offset 0x%.8X.", offset);
[180]	3133	goto fail_locked;
[137]	3134	}
[111]	3135
[101]	3136	ret_val->offset = offset;
	3137	ret_val->cell_size = cell_length;
[206]	3138	ret_val->name = NULL;
	3139	ret_val->name_raw = NULL;
[150]	3140
[101]	3141	if(ret_val->cell_size > max_size)
	3142	ret_val->cell_size = max_size & 0xFFFFFFF8;
	3143	if((ret_val->cell_size < REGFI_VK_MIN_LENGTH)
[157]	3144	\|\| (ret_val->cell_size & 0x00000007) != 0)
[97]	3145	{
[182]	3146	regfi_log_add(REGFI_LOG_WARN, "Invalid cell size encountered"
	3147	" while parsing VK record at offset 0x%.8X.", offset);
[180]	3148	goto fail_locked;
[101]	3149	}
[97]	3150
[101]	3151	ret_val->magic[0] = vk_header[0x0];
	3152	ret_val->magic[1] = vk_header[0x1];
	3153	if((ret_val->magic[0] != 'v') \|\| (ret_val->magic[1] != 'k'))
	3154	{
[124]	3155	/* XXX: This does not account for deleted keys under Win2K which
	3156	* often have this (and the name length) overwritten with
	3157	* 0xFFFF.
	3158	*/
[182]	3159	regfi_log_add(REGFI_LOG_WARN, "Magic number mismatch"
	3160	" while parsing VK record at offset 0x%.8X.", offset);
[180]	3161	goto fail_locked;
[101]	3162	}
	3163
	3164	ret_val->name_length = SVAL(vk_header, 0x2);
	3165	raw_data_size = IVAL(vk_header, 0x4);
[135]	3166	ret_val->data_size = raw_data_size & ~REGFI_VK_DATA_IN_OFFSET;
[157]	3167	/* The data is typically stored in the offset if the size <= 4,
	3168	* in which case this flag is set.
	3169	*/
[135]	3170	ret_val->data_in_offset = (bool)(raw_data_size & REGFI_VK_DATA_IN_OFFSET);
[101]	3171	ret_val->data_off = IVAL(vk_header, 0x8);
	3172	ret_val->type = IVAL(vk_header, 0xC);
[162]	3173	ret_val->flags = SVAL(vk_header, 0x10);
[101]	3174	ret_val->unknown1 = SVAL(vk_header, 0x12);
	3175
[162]	3176	if(ret_val->name_length > 0)
[101]	3177	{
[113]	3178	if(ret_val->name_length + REGFI_VK_MIN_LENGTH + 4 > ret_val->cell_size)
[101]	3179	{
[182]	3180	regfi_log_add(REGFI_LOG_WARN, "Name too long for remaining cell"
	3181	" space while parsing VK record at offset 0x%.8X.",
	3182	offset);
[101]	3183	if(strict)
[180]	3184	goto fail_locked;
[101]	3185	else
[113]	3186	ret_val->name_length = ret_val->cell_size - REGFI_VK_MIN_LENGTH - 4;
[101]	3187	}
	3188
	3189	/* Round up to the next multiple of 8 */
[113]	3190	cell_length = (ret_val->name_length + REGFI_VK_MIN_LENGTH + 4) & 0xFFFFFFF8;
	3191	if(cell_length < ret_val->name_length + REGFI_VK_MIN_LENGTH + 4)
	3192	cell_length+=8;
[101]	3193
[206]	3194	/* +1 to length in case we decided to use this directly as a string later */
	3195	ret_val->name_raw = talloc_array(ret_val, uint8_t, ret_val->name_length+1);
	3196	if(ret_val->name_raw == NULL)
[180]	3197	goto fail_locked;
[113]	3198
[101]	3199	length = ret_val->name_length;
[206]	3200	if((regfi_read(file->cb, (uint8_t*)ret_val->name_raw, &length) != 0)
[101]	3201	\|\| length != ret_val->name_length)
	3202	{
[182]	3203	regfi_log_add(REGFI_LOG_ERROR, "Could not read value name"
	3204	" while parsing VK record at offset 0x%.8X.", offset);
[180]	3205	goto fail_locked;
[101]	3206	}
	3207	}
	3208	else
[113]	3209	cell_length = REGFI_VK_MIN_LENGTH + 4;
[101]	3210
[186]	3211	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_nk"))
[180]	3212	goto fail;
	3213
[101]	3214	if(unalloc)
	3215	{
	3216	/* If cell_size is still greater, truncate. */
[113]	3217	if(cell_length < ret_val->cell_size)
	3218	ret_val->cell_size = cell_length;
[101]	3219	}
	3220
	3221	return ret_val;
[180]	3222
	3223	fail_locked:
[186]	3224	regfi_unlock(file, &file->cb_lock, "regfi_parse_vk");
[180]	3225	fail:
	3226	talloc_free(ret_val);
	3227	return NULL;
[97]	3228	}
[101]	3229
	3230
[152]	3231	/******************************************************************************
[157]	3232	*
	3233	******************************************************************************/
[168]	3234	REGFI_BUFFER regfi_load_data(REGFI_FILE* file, uint32_t voffset,
	3235	uint32_t length, bool data_in_offset,
[157]	3236	bool strict)
[101]	3237	{
[151]	3238	REGFI_BUFFER ret_val;
[168]	3239	uint32_t cell_length, offset;
	3240	int32_t max_size;
[101]	3241	bool unalloc;
[151]	3242
[159]	3243	/* Microsoft's documentation indicates that "available memory" is
[165]	3244	* the limit on value sizes for the more recent registry format version.
	3245	* This is not only annoying, but it's probably also incorrect, since clearly
	3246	* value data sizes are limited to 2^31 (high bit used as a flag) and even
	3247	* with big data records, the apparent max size is:
	3248	* 16344 * 2^16 = 1071104040 (~1GB).
	3249	*
	3250	* We choose to limit it to 1M which was the limit in older versions and
	3251	* should rarely be exceeded unless the file is corrupt or malicious.
	3252	* For more info, see:
	3253	* http://msdn.microsoft.com/en-us/library/ms724872%28VS.85%29.aspx
[159]	3254	*/
[160]	3255	/* XXX: add way to skip this check at user discression. */
	3256	if(length > REGFI_VK_MAX_DATA_LENGTH)
[159]	3257	{
[182]	3258	regfi_log_add(REGFI_LOG_WARN, "Value data size %d larger than "
	3259	"%d, truncating...", length, REGFI_VK_MAX_DATA_LENGTH);
[160]	3260	length = REGFI_VK_MAX_DATA_LENGTH;
[159]	3261	}
	3262
[145]	3263	if(data_in_offset)
[157]	3264	return regfi_parse_little_data(file, voffset, length, strict);
	3265	else
[101]	3266	{
[157]	3267	offset = voffset + REGFI_REGF_SIZE;
	3268	max_size = regfi_calc_maxsize(file, offset);
	3269	if(max_size < 0)
[137]	3270	{
[182]	3271	regfi_log_add(REGFI_LOG_WARN, "Could not find HBIN for data"
	3272	" at offset 0x%.8X.", offset);
[151]	3273	goto fail;
[137]	3274	}
[157]	3275
[186]	3276	if(!regfi_lock(file, &file->cb_lock, "regfi_load_data"))
[180]	3277	goto fail;
	3278
[178]	3279	if(!regfi_parse_cell(file->cb, offset, NULL, 0,
[101]	3280	&cell_length, &unalloc))
[137]	3281	{
[182]	3282	regfi_log_add(REGFI_LOG_WARN, "Could not parse cell while"
	3283	" parsing data record at offset 0x%.8X.", offset);
[180]	3284	goto fail_locked;
[137]	3285	}
[111]	3286
[186]	3287	if(!regfi_unlock(file, &file->cb_lock, "regfi_load_data"))
[180]	3288	goto fail;
	3289
[157]	3290	if((cell_length & 0x00000007) != 0)
[137]	3291	{
[182]	3292	regfi_log_add(REGFI_LOG_WARN, "Cell length not multiple of 8"
	3293	" while parsing data record at offset 0x%.8X.",
	3294	offset);
[151]	3295	goto fail;
[137]	3296	}
[101]	3297
[131]	3298	if(cell_length > max_size)
	3299	{
[182]	3300	regfi_log_add(REGFI_LOG_WARN, "Cell extends past HBIN boundary"
	3301	" while parsing data record at offset 0x%.8X.",
	3302	offset);
[157]	3303	goto fail;
[131]	3304	}
	3305
[101]	3306	if(cell_length - 4 < length)
	3307	{
[155]	3308	/* XXX: All big data records thus far have been 16 bytes long.
	3309	* Should we check for this precise size instead of just
	3310	* relying upon the above check?
	3311	*/
[152]	3312	if (file->major_version >= 1 && file->minor_version >= 5)
	3313	{
	3314	/* Attempt to parse a big data record */
[157]	3315	return regfi_load_big_data(file, offset, length, cell_length,
	3316	NULL, strict);
[152]	3317	}
[101]	3318	else
[152]	3319	{
[182]	3320	regfi_log_add(REGFI_LOG_WARN, "Data length (0x%.8X) larger than"
	3321	" remaining cell length (0x%.8X)"
	3322	" while parsing data record at offset 0x%.8X.",
	3323	length, cell_length - 4, offset);
[152]	3324	if(strict)
	3325	goto fail;
	3326	else
	3327	length = cell_length - 4;
	3328	}
[101]	3329	}
	3330
[157]	3331	ret_val = regfi_parse_data(file, offset, length, strict);
[101]	3332	}
	3333
	3334	return ret_val;
[151]	3335
[180]	3336	fail_locked:
[186]	3337	regfi_unlock(file, &file->cb_lock, "regfi_load_data");
[151]	3338	fail:
	3339	ret_val.buf = NULL;
	3340	ret_val.len = 0;
	3341	return ret_val;
[101]	3342	}
[110]	3343
	3344
[152]	3345	/******************************************************************************
[157]	3346	* Parses the common case data records stored in a single cell.
	3347	******************************************************************************/
[168]	3348	REGFI_BUFFER regfi_parse_data(REGFI_FILE* file, uint32_t offset,
	3349	uint32_t length, bool strict)
[157]	3350	{
	3351	REGFI_BUFFER ret_val;
[168]	3352	uint32_t read_length;
[157]	3353
	3354	ret_val.buf = NULL;
	3355	ret_val.len = 0;
	3356
[180]	3357	if((ret_val.buf = talloc_array(NULL, uint8_t, length)) == NULL)
	3358	goto fail;
	3359	ret_val.len = length;
	3360
[186]	3361	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_data"))
[180]	3362	goto fail;
	3363
[178]	3364	if(regfi_seek(file->cb, offset+4, SEEK_SET) == -1)
[157]	3365	{
[182]	3366	regfi_log_add(REGFI_LOG_WARN, "Could not seek while "
	3367	"reading data at offset 0x%.8X.", offset);
[180]	3368	goto fail_locked;
[157]	3369	}
	3370
	3371	read_length = length;
[178]	3372	if((regfi_read(file->cb, ret_val.buf, &read_length) != 0)
[157]	3373	\|\| read_length != length)
	3374	{
[182]	3375	regfi_log_add(REGFI_LOG_ERROR, "Could not read data block while"
	3376	" parsing data record at offset 0x%.8X.", offset);
[180]	3377	goto fail_locked;
[157]	3378	}
	3379
[186]	3380	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_data"))
[180]	3381	goto fail;
	3382
[157]	3383	return ret_val;
[180]	3384
	3385	fail_locked:
[186]	3386	regfi_unlock(file, &file->cb_lock, "regfi_parse_data");
[180]	3387	fail:
	3388	talloc_free(ret_val.buf);
	3389	ret_val.buf = NULL;
	3390	ret_val.buf = 0;
	3391	return ret_val;
[157]	3392	}
	3393
	3394
	3395
	3396	/******************************************************************************
	3397	*
	3398	******************************************************************************/
[168]	3399	REGFI_BUFFER regfi_parse_little_data(REGFI_FILE* file, uint32_t voffset,
	3400	uint32_t length, bool strict)
[157]	3401	{
[173]	3402	uint8_t i;
[157]	3403	REGFI_BUFFER ret_val;
	3404
	3405	ret_val.buf = NULL;
	3406	ret_val.len = 0;
	3407
	3408	if(length > 4)
	3409	{
[182]	3410	regfi_log_add(REGFI_LOG_ERROR, "Data in offset but length > 4"
	3411	" while parsing data record. (voffset=0x%.8X, length=%d)",
	3412	voffset, length);
[157]	3413	return ret_val;
	3414	}
	3415
[168]	3416	if((ret_val.buf = talloc_array(NULL, uint8_t, length)) == NULL)
[157]	3417	return ret_val;
	3418	ret_val.len = length;
	3419
	3420	for(i = 0; i < length; i++)
[168]	3421	ret_val.buf[i] = (uint8_t)((voffset >> i*8) & 0xFF);
[157]	3422
	3423	return ret_val;
	3424	}
	3425
	3426	/******************************************************************************
[152]	3427	*******************************************************************************/
[168]	3428	REGFI_BUFFER regfi_parse_big_data_header(REGFI_FILE* file, uint32_t offset,
	3429	uint32_t max_size, bool strict)
[152]	3430	{
	3431	REGFI_BUFFER ret_val;
[168]	3432	uint32_t cell_length;
[152]	3433	bool unalloc;
[157]	3434
	3435	/* XXX: do something with unalloc? */
[168]	3436	ret_val.buf = (uint8_t*)talloc_array(NULL, uint8_t, REGFI_BIG_DATA_MIN_LENGTH);
[157]	3437	if(ret_val.buf == NULL)
[152]	3438	goto fail;
	3439
[157]	3440	if(REGFI_BIG_DATA_MIN_LENGTH > max_size)
	3441	{
[182]	3442	regfi_log_add(REGFI_LOG_WARN, "Big data header exceeded max_size "
	3443	"while parsing big data header at offset 0x%.8X.",offset);
[157]	3444	goto fail;
	3445	}
	3446
[186]	3447	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_big_data_header"))
[180]	3448	goto fail;
	3449
	3450
[178]	3451	if(!regfi_parse_cell(file->cb, offset, ret_val.buf, REGFI_BIG_DATA_MIN_LENGTH,
[152]	3452	&cell_length, &unalloc))
	3453	{
[182]	3454	regfi_log_add(REGFI_LOG_WARN, "Could not parse cell while"
	3455	" parsing big data header at offset 0x%.8X.", offset);
[180]	3456	goto fail_locked;
[152]	3457	}
[157]	3458
[186]	3459	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_big_data_header"))
[180]	3460	goto fail;
	3461
[157]	3462	if((ret_val.buf[0] != 'd') \|\| (ret_val.buf[1] != 'b'))
[152]	3463	{
[182]	3464	regfi_log_add(REGFI_LOG_WARN, "Unknown magic number"
	3465	" (0x%.2X, 0x%.2X) encountered while parsing"
	3466	" big data header at offset 0x%.8X.",
	3467	ret_val.buf[0], ret_val.buf[1], offset);
[152]	3468	goto fail;
	3469	}
	3470
[157]	3471	ret_val.len = REGFI_BIG_DATA_MIN_LENGTH;
	3472	return ret_val;
	3473
[180]	3474	fail_locked:
[186]	3475	regfi_unlock(file, &file->cb_lock, "regfi_parse_big_data_header");
[157]	3476	fail:
[180]	3477	talloc_free(ret_val.buf);
	3478	ret_val.buf = NULL;
[157]	3479	ret_val.len = 0;
	3480	return ret_val;
	3481	}
	3482
	3483
	3484
	3485	/******************************************************************************
	3486	*
	3487	******************************************************************************/
[168]	3488	uint32_t* regfi_parse_big_data_indirect(REGFI_FILE* file, uint32_t offset,
	3489	uint16_t num_chunks, bool strict)
[157]	3490	{
[168]	3491	uint32_t* ret_val;
	3492	uint32_t indirect_length;
	3493	int32_t max_size;
	3494	uint16_t i;
[157]	3495	bool unalloc;
	3496
	3497	/* XXX: do something with unalloc? */
	3498	max_size = regfi_calc_maxsize(file, offset);
[168]	3499	if((max_size < 0) \|\| (num_chunks*sizeof(uint32_t) + 4 > max_size))
[157]	3500	return NULL;
	3501
[168]	3502	ret_val = (uint32_t*)talloc_array(NULL, uint32_t, num_chunks);
[157]	3503	if(ret_val == NULL)
[152]	3504	goto fail;
	3505
[186]	3506	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_big_data_indirect"))
[180]	3507	goto fail;
	3508
[178]	3509	if(!regfi_parse_cell(file->cb, offset, (uint8_t*)ret_val,
[168]	3510	num_chunks*sizeof(uint32_t),
[152]	3511	&indirect_length, &unalloc))
	3512	{
[182]	3513	regfi_log_add(REGFI_LOG_WARN, "Could not parse cell while"
	3514	" parsing big data indirect record at offset 0x%.8X.",
	3515	offset);
[180]	3516	goto fail_locked;
[152]	3517	}
[157]	3518
[186]	3519	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_big_data_indirect"))
[180]	3520	goto fail;
	3521
[157]	3522	/* Convert pointers to proper endianess, verify they are aligned. */
	3523	for(i=0; i<num_chunks; i++)
[152]	3524	{
[168]	3525	ret_val[i] = IVAL(ret_val, i*sizeof(uint32_t));
[157]	3526	if((ret_val[i] & 0x00000007) != 0)
	3527	goto fail;
[152]	3528	}
[157]	3529
	3530	return ret_val;
[152]	3531
[180]	3532	fail_locked:
[186]	3533	regfi_unlock(file, &file->cb_lock, "regfi_parse_big_data_indirect");
[157]	3534	fail:
[180]	3535	talloc_free(ret_val);
[157]	3536	return NULL;
	3537	}
	3538
	3539
	3540	/******************************************************************************
	3541	* Arguments:
	3542	* file --
	3543	* offsets -- list of virtual offsets.
	3544	* num_chunks --
	3545	* strict --
	3546	*
	3547	* Returns:
	3548	* A range_list with physical offsets and complete lengths
	3549	* (including cell headers) of associated cells.
	3550	* No data in range_list elements.
	3551	******************************************************************************/
[168]	3552	range_list* regfi_parse_big_data_cells(REGFI_FILE* file, uint32_t* offsets,
	3553	uint16_t num_chunks, bool strict)
[157]	3554	{
[168]	3555	uint32_t cell_length, chunk_offset;
[157]	3556	range_list* ret_val;
[168]	3557	uint16_t i;
[157]	3558	bool unalloc;
	3559
	3560	/* XXX: do something with unalloc? */
	3561	ret_val = range_list_new();
	3562	if(ret_val == NULL)
	3563	goto fail;
	3564
[166]	3565	for(i=0; i<num_chunks; i++)
[152]	3566	{
[186]	3567	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_big_data_cells"))
[180]	3568	goto fail;
	3569
[157]	3570	chunk_offset = offsets[i]+REGFI_REGF_SIZE;
[178]	3571	if(!regfi_parse_cell(file->cb, chunk_offset, NULL, 0,
[157]	3572	&cell_length, &unalloc))
[152]	3573	{
[182]	3574	regfi_log_add(REGFI_LOG_WARN, "Could not parse cell while"
	3575	" parsing big data chunk at offset 0x%.8X.",
	3576	chunk_offset);
[180]	3577	goto fail_locked;
[152]	3578	}
	3579
[186]	3580	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_big_data_cells"))
[180]	3581	goto fail;
	3582
[157]	3583	if(!range_list_add(ret_val, chunk_offset, cell_length, NULL))
	3584	goto fail;
	3585	}
	3586
	3587	return ret_val;
	3588
[180]	3589	fail_locked:
[186]	3590	regfi_unlock(file, &file->cb_lock, "regfi_parse_big_data_cells");
[157]	3591	fail:
	3592	if(ret_val != NULL)
	3593	range_list_free(ret_val);
	3594	return NULL;
	3595	}
	3596
	3597
	3598	/******************************************************************************
	3599	*******************************************************************************/
	3600	REGFI_BUFFER regfi_load_big_data(REGFI_FILE* file,
[168]	3601	uint32_t offset, uint32_t data_length,
	3602	uint32_t cell_length, range_list* used_ranges,
[157]	3603	bool strict)
	3604	{
	3605	REGFI_BUFFER ret_val;
[168]	3606	uint16_t num_chunks, i;
	3607	uint32_t read_length, data_left, tmp_len, indirect_offset;
	3608	uint32_t* indirect_ptrs = NULL;
[157]	3609	REGFI_BUFFER bd_header;
	3610	range_list* bd_cells = NULL;
	3611	const range_list_element* cell_info;
	3612
	3613	ret_val.buf = NULL;
	3614
	3615	/* XXX: Add better error/warning messages */
	3616
	3617	bd_header = regfi_parse_big_data_header(file, offset, cell_length, strict);
	3618	if(bd_header.buf == NULL)
	3619	goto fail;
	3620
	3621	/* Keep track of used space for use by reglookup-recover */
	3622	if(used_ranges != NULL)
	3623	if(!range_list_add(used_ranges, offset, cell_length, NULL))
	3624	goto fail;
	3625
	3626	num_chunks = SVAL(bd_header.buf, 0x2);
	3627	indirect_offset = IVAL(bd_header.buf, 0x4) + REGFI_REGF_SIZE;
	3628	talloc_free(bd_header.buf);
	3629
	3630	indirect_ptrs = regfi_parse_big_data_indirect(file, indirect_offset,
	3631	num_chunks, strict);
	3632	if(indirect_ptrs == NULL)
	3633	goto fail;
	3634
	3635	if(used_ranges != NULL)
	3636	if(!range_list_add(used_ranges, indirect_offset, num_chunks*4+4, NULL))
	3637	goto fail;
	3638
	3639	if((ret_val.buf = talloc_array(NULL, uint8_t, data_length)) == NULL)
	3640	goto fail;
	3641	data_left = data_length;
	3642
	3643	bd_cells = regfi_parse_big_data_cells(file, indirect_ptrs, num_chunks, strict);
	3644	if(bd_cells == NULL)
	3645	goto fail;
	3646
	3647	talloc_free(indirect_ptrs);
	3648	indirect_ptrs = NULL;
	3649
	3650	for(i=0; (i<num_chunks) && (data_left>0); i++)
	3651	{
	3652	cell_info = range_list_get(bd_cells, i);
	3653	if(cell_info == NULL)
	3654	goto fail;
	3655
	3656	/* XXX: This should be "cell_info->length-4" to account for the 4 byte cell
[154]	3657	* length. However, it has been observed that some (all?) chunks
	3658	* have an additional 4 bytes of 0 at the end of their cells that
	3659	* isn't part of the data, so we're trimming that off too.
[157]	3660	* Perhaps it's just an 8 byte alignment requirement...
[154]	3661	*/
[157]	3662	if(cell_info->length - 8 >= data_left)
	3663	{
	3664	if(i+1 != num_chunks)
	3665	{
[182]	3666	regfi_log_add(REGFI_LOG_WARN, "Left over chunks detected "
	3667	"while constructing big data at offset 0x%.8X "
	3668	"(chunk offset 0x%.8X).", offset, cell_info->offset);
[157]	3669	}
[152]	3670	read_length = data_left;
[157]	3671	}
[152]	3672	else
[157]	3673	read_length = cell_info->length - 8;
[152]	3674
[157]	3675
	3676	if(read_length > regfi_calc_maxsize(file, cell_info->offset))
	3677	{
[182]	3678	regfi_log_add(REGFI_LOG_WARN, "A chunk exceeded the maxsize "
	3679	"while constructing big data at offset 0x%.8X "
	3680	"(chunk offset 0x%.8X).", offset, cell_info->offset);
[157]	3681	goto fail;
	3682	}
	3683
[186]	3684	if(!regfi_lock(file, &file->cb_lock, "regfi_load_big_data"))
[180]	3685	goto fail;
	3686
[178]	3687	if(regfi_seek(file->cb, cell_info->offset+sizeof(uint32_t), SEEK_SET) == -1)
[157]	3688	{
[182]	3689	regfi_log_add(REGFI_LOG_WARN, "Could not seek to chunk while "
	3690	"constructing big data at offset 0x%.8X "
	3691	"(chunk offset 0x%.8X).", offset, cell_info->offset);
[180]	3692	goto fail_locked;
[157]	3693	}
	3694
	3695	tmp_len = read_length;
[178]	3696	if(regfi_read(file->cb, ret_val.buf+(data_length-data_left),
[157]	3697	&read_length) != 0 \|\| (read_length != tmp_len))
[152]	3698	{
[182]	3699	regfi_log_add(REGFI_LOG_WARN, "Could not read data chunk while"
	3700	" constructing big data at offset 0x%.8X"
	3701	" (chunk offset 0x%.8X).", offset, cell_info->offset);
[180]	3702	goto fail_locked;
[152]	3703	}
	3704
[186]	3705	if(!regfi_unlock(file, &file->cb_lock, "regfi_load_big_data"))
[180]	3706	goto fail;
	3707
[157]	3708	if(used_ranges != NULL)
	3709	if(!range_list_add(used_ranges, cell_info->offset,cell_info->length,NULL))
	3710	goto fail;
	3711
[152]	3712	data_left -= read_length;
	3713	}
[157]	3714	range_list_free(bd_cells);
	3715
[152]	3716	ret_val.len = data_length-data_left;
	3717	return ret_val;
	3718
[180]	3719	fail_locked:
[186]	3720	regfi_unlock(file, &file->cb_lock, "regfi_load_big_data");
[152]	3721	fail:
[180]	3722	talloc_free(ret_val.buf);
	3723	talloc_free(indirect_ptrs);
[157]	3724	if(bd_cells != NULL)
	3725	range_list_free(bd_cells);
[152]	3726	ret_val.buf = NULL;
	3727	ret_val.len = 0;
	3728	return ret_val;
	3729	}
	3730
	3731
[135]	3732	range_list* regfi_parse_unalloc_cells(REGFI_FILE* file)
[110]	3733	{
	3734	range_list* ret_val;
[135]	3735	REGFI_HBIN* hbin;
[110]	3736	const range_list_element* hbins_elem;
[168]	3737	uint32_t i, num_hbins, curr_off, cell_len;
[110]	3738	bool is_unalloc;
	3739
	3740	ret_val = range_list_new();
	3741	if(ret_val == NULL)
	3742	return NULL;
	3743
[186]	3744	if(!regfi_read_lock(file, &file->hbins_lock, "regfi_parse_unalloc_cells"))
[180]	3745	{
	3746	range_list_free(ret_val);
	3747	return NULL;
	3748	}
	3749
[110]	3750	num_hbins = range_list_size(file->hbins);
	3751	for(i=0; i<num_hbins; i++)
	3752	{
	3753	hbins_elem = range_list_get(file->hbins, i);
	3754	if(hbins_elem == NULL)
	3755	break;
[135]	3756	hbin = (REGFI_HBIN*)hbins_elem->data;
[110]	3757
[135]	3758	curr_off = REGFI_HBIN_HEADER_SIZE;
[110]	3759	while(curr_off < hbin->block_size)
	3760	{
[186]	3761	if(!regfi_lock(file, &file->cb_lock, "regfi_parse_unalloc_cells"))
[180]	3762	break;
	3763
[178]	3764	if(!regfi_parse_cell(file->cb, hbin->file_off+curr_off, NULL, 0,
[110]	3765	&cell_len, &is_unalloc))
[180]	3766	{
[186]	3767	regfi_unlock(file, &file->cb_lock, "regfi_parse_unalloc_cells");
[110]	3768	break;
[180]	3769	}
	3770
[186]	3771	if(!regfi_unlock(file, &file->cb_lock, "regfi_parse_unalloc_cells"))
[180]	3772	break;
	3773
[157]	3774	if((cell_len == 0) \|\| ((cell_len & 0x00000007) != 0))
[140]	3775	{
[182]	3776	regfi_log_add(REGFI_LOG_ERROR, "Bad cell length encountered"
	3777	" while parsing unallocated cells at offset 0x%.8X.",
	3778	hbin->file_off+curr_off);
[110]	3779	break;
[140]	3780	}
	3781
[110]	3782	/* for some reason the record_size of the last record in
	3783	an hbin block can extend past the end of the block
	3784	even though the record fits within the remaining
	3785	space....aaarrrgggghhhhhh */
	3786	if(curr_off + cell_len >= hbin->block_size)
	3787	cell_len = hbin->block_size - curr_off;
	3788
	3789	if(is_unalloc)
	3790	range_list_add(ret_val, hbin->file_off+curr_off,
	3791	cell_len, NULL);
	3792
	3793	curr_off = curr_off+cell_len;
	3794	}
	3795	}
	3796
[186]	3797	if(!regfi_rw_unlock(file, &file->hbins_lock, "regfi_parse_unalloc_cells"))
[180]	3798	{
	3799	range_list_free(ret_val);
	3800	return NULL;
	3801	}
	3802
[110]	3803	return ret_val;
	3804	}
[168]	3805
	3806
	3807	/* From lib/time.c */
	3808
	3809	/****************************************************************************
[251]	3810	Returns an 8 byte filetime from a time_t
[168]	3811	This takes real GMT as input and converts to kludge-GMT
	3812	****************************************************************************/
[251]	3813	REGFI_NTTIME regfi_unix2nt_time(time_t t)
[168]	3814	{
	3815	double d;
[251]	3816
	3817	if (t==0)
	3818	return 0L;
[168]	3819
	3820	if (t == TIME_T_MAX)
[251]	3821	return 0x7fffffffffffffffL;
[168]	3822
	3823	if (t == -1)
[251]	3824	return 0xffffffffffffffffL;
[168]	3825
	3826	/* this converts GMT to kludge-GMT */
	3827	/* XXX: This was removed due to difficult dependency requirements.
	3828	* So far, times appear to be correct without this adjustment, but
	3829	* that may be proven wrong with adequate testing.
	3830	*/
	3831	/* t -= TimeDiff(t) - get_serverzone(); */
	3832
[251]	3833	d = (double)(t) + REGFI_TIME_FIXUP;
[168]	3834	d *= 1.0e7;
[251]	3835	/*
	3836	nt->high = (uint32_t)(d * (1.0/c));
	3837	nt->low = (uint32_t)(d - ((double)nt->high) * c);
	3838	*/
	3839
	3840	return (REGFI_NTTIME) d;
[168]	3841	}
	3842
	3843
	3844	/****************************************************************************
	3845	Interpret an 8 byte "filetime" structure to a time_t
	3846	It's originally in "100ns units since jan 1st 1601"
	3847
	3848	An 8 byte value of 0xffffffffffffffff will be returned as (time_t)0.
	3849
	3850	It appears to be kludge-GMT (at least for file listings). This means
	3851	its the GMT you get by taking a localtime and adding the
	3852	serverzone. This is NOT the same as GMT in some cases. This routine
	3853	converts this to real GMT.
	3854	****************************************************************************/
[251]	3855	double regfi_nt2unix_time(REGFI_NTTIME nt)
[168]	3856	{
[219]	3857	double ret_val;
[168]	3858
[251]	3859	if (nt == 0 \|\| nt == 0xffffffffffffffffL)
	3860	return 0;
[168]	3861
[251]	3862	ret_val = (double)(nt) * 1.0e-7;
[168]	3863
	3864	/* now adjust by 369 years to make the secs since 1970 */
[251]	3865	ret_val -= REGFI_TIME_FIXUP;
[168]	3866
	3867	/* this takes us from kludge-GMT to real GMT */
	3868	/* XXX: This was removed due to difficult dependency requirements.
	3869	* So far, times appear to be correct without this adjustment, but
	3870	* that may be proven wrong with adequate testing.
	3871	*/
	3872	/*
	3873	ret -= get_serverzone();
	3874	ret += LocTimeDiff(ret);
	3875	*/
	3876
[219]	3877	return ret_val;
[168]	3878	}
	3879
	3880	/* End of stuff from lib/time.c */

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