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|
/* hivex - Windows Registry "hive" extraction library.
* Copyright (C) 2009-2010 Red Hat Inc.
* Derived from code by Petter Nordahl-Hagen under a compatible license:
* Copyright (c) 1997-2007 Petter Nordahl-Hagen.
* Derived from code by Markus Stephany under a compatible license:
* Copyright (c) 2000-2004, Markus Stephany.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation;
* version 2.1 of the License.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* See file LICENSE for the full license.
*/
#include <config.h>
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include <stddef.h>
#include <inttypes.h>
#include <string.h>
#include <fcntl.h>
#include <unistd.h>
#include <errno.h>
#include <iconv.h>
#include <sys/mman.h>
#include <sys/stat.h>
#include <assert.h>
#include "c-ctype.h"
#include "full-read.h"
#include "full-write.h"
#ifndef O_CLOEXEC
#define O_CLOEXEC 0
#endif
#define STREQ(a,b) (strcmp((a),(b)) == 0)
#define STRCASEEQ(a,b) (strcasecmp((a),(b)) == 0)
//#define STRNEQ(a,b) (strcmp((a),(b)) != 0)
//#define STRCASENEQ(a,b) (strcasecmp((a),(b)) != 0)
#define STREQLEN(a,b,n) (strncmp((a),(b),(n)) == 0)
//#define STRCASEEQLEN(a,b,n) (strncasecmp((a),(b),(n)) == 0)
//#define STRNEQLEN(a,b,n) (strncmp((a),(b),(n)) != 0)
//#define STRCASENEQLEN(a,b,n) (strncasecmp((a),(b),(n)) != 0)
#define STRPREFIX(a,b) (strncmp((a),(b),strlen((b))) == 0)
#include "hivex.h"
#include "byte_conversions.h"
/* These limits are in place to stop really stupid stuff and/or exploits. */
#define HIVEX_MAX_SUBKEYS 15000
#define HIVEX_MAX_VALUES 10000
#define HIVEX_MAX_VALUE_LEN 1000000
#define HIVEX_MAX_ALLOCATION 1000000
static char *windows_utf16_to_utf8 (/* const */ char *input, size_t len);
static size_t utf16_string_len_in_bytes (const char *str);
static size_t utf16_string_len_in_bytes_max (const char *str, size_t len);
struct hive_h {
char *filename;
int fd;
size_t size;
int msglvl;
int writable;
/* Registry file, memory mapped if read-only, or malloc'd if writing. */
union {
char *addr;
struct ntreg_header *hdr;
};
/* Use a bitmap to store which file offsets are valid (point to a
* used block). We only need to store 1 bit per 32 bits of the file
* (because blocks are 4-byte aligned). We found that the average
* block size in a registry file is ~50 bytes. So roughly 1 in 12
* bits in the bitmap will be set, making it likely a more efficient
* structure than a hash table.
*/
char *bitmap;
#define BITMAP_SET(bitmap,off) (bitmap[(off)>>5] |= 1 << (((off)>>2)&7))
#define BITMAP_CLR(bitmap,off) (bitmap[(off)>>5] &= ~ (1 << (((off)>>2)&7)))
#define BITMAP_TST(bitmap,off) (bitmap[(off)>>5] & (1 << (((off)>>2)&7)))
#define IS_VALID_BLOCK(h,off) \
(((off) & 3) == 0 && \
(off) >= 0x1000 && \
(off) < (h)->size && \
BITMAP_TST((h)->bitmap,(off)))
/* Fields from the header, extracted from little-endianness hell. */
size_t rootoffs; /* Root key offset (always an nk-block). */
size_t endpages; /* Offset of end of pages. */
/* For writing. */
size_t endblocks; /* Offset to next block allocation (0
if not allocated anything yet). */
};
/* NB. All fields are little endian. */
struct ntreg_header {
char magic[4]; /* "regf" */
uint32_t sequence1;
uint32_t sequence2;
char last_modified[8];
uint32_t major_ver; /* 1 */
uint32_t minor_ver; /* 3 */
uint32_t unknown5; /* 0 */
uint32_t unknown6; /* 1 */
uint32_t offset; /* offset of root key record - 4KB */
uint32_t blocks; /* pointer AFTER last hbin in file - 4KB */
uint32_t unknown7; /* 1 */
/* 0x30 */
char name[64]; /* original file name of hive */
char unknown_guid1[16];
char unknown_guid2[16];
/* 0x90 */
uint32_t unknown8;
char unknown_guid3[16];
uint32_t unknown9;
/* 0xa8 */
char unknown10[340];
/* 0x1fc */
uint32_t csum; /* checksum: xor of dwords 0-0x1fb. */
/* 0x200 */
char unknown11[3528];
/* 0xfc8 */
char unknown_guid4[16];
char unknown_guid5[16];
char unknown_guid6[16];
uint32_t unknown12;
uint32_t unknown13;
/* 0x1000 */
} __attribute__((__packed__));
struct ntreg_hbin_page {
char magic[4]; /* "hbin" */
uint32_t offset_first; /* offset from 1st block */
uint32_t page_size; /* size of this page (multiple of 4KB) */
char unknown[20];
/* Linked list of blocks follows here. */
} __attribute__((__packed__));
struct ntreg_hbin_block {
int32_t seg_len; /* length of this block (-ve for used block) */
char id[2]; /* the block type (eg. "nk" for nk record) */
/* Block data follows here. */
} __attribute__((__packed__));
#define BLOCK_ID_EQ(h,offs,eqid) \
(STREQLEN (((struct ntreg_hbin_block *)((h)->addr + (offs)))->id, (eqid), 2))
static size_t
block_len (hive_h *h, size_t blkoff, int *used)
{
struct ntreg_hbin_block *block;
block = (struct ntreg_hbin_block *) (h->addr + blkoff);
int32_t len = le32toh (block->seg_len);
if (len < 0) {
if (used) *used = 1;
len = -len;
} else {
if (used) *used = 0;
}
return (size_t) len;
}
struct ntreg_nk_record {
int32_t seg_len; /* length (always -ve because used) */
char id[2]; /* "nk" */
uint16_t flags;
char timestamp[8];
uint32_t unknown1;
uint32_t parent; /* offset of owner/parent */
uint32_t nr_subkeys; /* number of subkeys */
uint32_t nr_subkeys_volatile;
uint32_t subkey_lf; /* lf record containing list of subkeys */
uint32_t subkey_lf_volatile;
uint32_t nr_values; /* number of values */
uint32_t vallist; /* value-list record */
uint32_t sk; /* offset of sk-record */
uint32_t classname; /* offset of classname record */
uint16_t max_subkey_name_len; /* maximum length of a subkey name in bytes
if the subkey was reencoded as UTF-16LE */
uint16_t unknown2;
uint32_t unknown3;
uint32_t max_vk_name_len; /* maximum length of any vk name in bytes
if the name was reencoded as UTF-16LE */
uint32_t max_vk_data_len; /* maximum length of any vk data in bytes */
uint32_t unknown6;
uint16_t name_len; /* length of name */
uint16_t classname_len; /* length of classname */
char name[1]; /* name follows here */
} __attribute__((__packed__));
struct ntreg_lf_record {
int32_t seg_len;
char id[2]; /* "lf"|"lh" */
uint16_t nr_keys; /* number of keys in this record */
struct {
uint32_t offset; /* offset of nk-record for this subkey */
char hash[4]; /* hash of subkey name */
} keys[1];
} __attribute__((__packed__));
struct ntreg_ri_record {
int32_t seg_len;
char id[2]; /* "ri" */
uint16_t nr_offsets; /* number of pointers to lh records */
uint32_t offset[1]; /* list of pointers to lh records */
} __attribute__((__packed__));
/* This has no ID header. */
struct ntreg_value_list {
int32_t seg_len;
uint32_t offset[1]; /* list of pointers to vk records */
} __attribute__((__packed__));
struct ntreg_vk_record {
int32_t seg_len; /* length (always -ve because used) */
char id[2]; /* "vk" */
uint16_t name_len; /* length of name */
/* length of the data:
* If data_len is <= 4, then it's stored inline.
* Top bit is set to indicate inline.
*/
uint32_t data_len;
uint32_t data_offset; /* pointer to the data (or data if inline) */
uint32_t data_type; /* type of the data */
uint16_t flags; /* bit 0 set => key name ASCII,
bit 0 clr => key name UTF-16.
Only seen ASCII here in the wild.
NB: this is CLEAR for default key. */
uint16_t unknown2;
char name[1]; /* key name follows here */
} __attribute__((__packed__));
struct ntreg_sk_record {
int32_t seg_len; /* length (always -ve because used) */
char id[2]; /* "sk" */
uint16_t unknown1;
uint32_t sk_next; /* linked into a circular list */
uint32_t sk_prev;
uint32_t refcount; /* reference count */
uint32_t sec_len; /* length of security info */
char sec_desc[1]; /* security info follows */
} __attribute__((__packed__));
static uint32_t
header_checksum (const hive_h *h)
{
uint32_t *daddr = (uint32_t *) h->addr;
size_t i;
uint32_t sum = 0;
for (i = 0; i < 0x1fc / 4; ++i) {
sum ^= le32toh (*daddr);
daddr++;
}
return sum;
}
#define HIVEX_OPEN_MSGLVL_MASK (HIVEX_OPEN_VERBOSE|HIVEX_OPEN_DEBUG)
hive_h *
hivex_open (const char *filename, int flags)
{
hive_h *h = NULL;
assert (sizeof (struct ntreg_header) == 0x1000);
assert (offsetof (struct ntreg_header, csum) == 0x1fc);
h = calloc (1, sizeof *h);
if (h == NULL)
goto error;
h->msglvl = flags & HIVEX_OPEN_MSGLVL_MASK;
const char *debug = getenv ("HIVEX_DEBUG");
if (debug && STREQ (debug, "1"))
h->msglvl = 2;
if (h->msglvl >= 2)
fprintf (stderr, "hivex_open: created handle %p\n", h);
h->writable = !!(flags & HIVEX_OPEN_WRITE);
h->filename = strdup (filename);
if (h->filename == NULL)
goto error;
h->fd = open (filename, O_RDONLY | O_CLOEXEC);
if (h->fd == -1)
goto error;
struct stat statbuf;
if (fstat (h->fd, &statbuf) == -1)
goto error;
h->size = statbuf.st_size;
if (!h->writable) {
h->addr = mmap (NULL, h->size, PROT_READ, MAP_SHARED, h->fd, 0);
if (h->addr == MAP_FAILED)
goto error;
if (h->msglvl >= 2)
fprintf (stderr, "hivex_open: mapped file at %p\n", h->addr);
} else {
h->addr = malloc (h->size);
if (h->addr == NULL)
goto error;
if (full_read (h->fd, h->addr, h->size) < h->size)
goto error;
}
/* Check header. */
if (h->hdr->magic[0] != 'r' ||
h->hdr->magic[1] != 'e' ||
h->hdr->magic[2] != 'g' ||
h->hdr->magic[3] != 'f') {
fprintf (stderr, "hivex: %s: not a Windows NT Registry hive file\n",
filename);
errno = ENOTSUP;
goto error;
}
/* Check major version. */
uint32_t major_ver = le32toh (h->hdr->major_ver);
if (major_ver != 1) {
fprintf (stderr,
"hivex: %s: hive file major version %" PRIu32 " (expected 1)\n",
filename, major_ver);
errno = ENOTSUP;
goto error;
}
h->bitmap = calloc (1 + h->size / 32, 1);
if (h->bitmap == NULL)
goto error;
/* Header checksum. */
uint32_t sum = header_checksum (h);
if (sum != le32toh (h->hdr->csum)) {
fprintf (stderr, "hivex: %s: bad checksum in hive header\n", filename);
errno = EINVAL;
goto error;
}
if (h->msglvl >= 2) {
char *name = windows_utf16_to_utf8 (h->hdr->name, 64);
fprintf (stderr,
"hivex_open: header fields:\n"
" file version %" PRIu32 ".%" PRIu32 "\n"
" sequence nos %" PRIu32 " %" PRIu32 "\n"
" (sequences nos should match if hive was synched at shutdown)\n"
" original file name %s\n"
" (only 32 chars are stored, name is probably truncated)\n"
" root offset 0x%x + 0x1000\n"
" end of last page 0x%x + 0x1000 (total file size 0x%zx)\n"
" checksum 0x%x (calculated 0x%x)\n",
major_ver, le32toh (h->hdr->minor_ver),
le32toh (h->hdr->sequence1), le32toh (h->hdr->sequence2),
name ? name : "(conversion failed)",
le32toh (h->hdr->offset),
le32toh (h->hdr->blocks), h->size,
le32toh (h->hdr->csum), sum);
free (name);
}
h->rootoffs = le32toh (h->hdr->offset) + 0x1000;
h->endpages = le32toh (h->hdr->blocks) + 0x1000;
if (h->msglvl >= 2)
fprintf (stderr, "hivex_open: root offset = 0x%zx\n", h->rootoffs);
/* We'll set this flag when we see a block with the root offset (ie.
* the root block).
*/
int seen_root_block = 0, bad_root_block = 0;
/* Collect some stats. */
size_t pages = 0; /* Number of hbin pages read. */
size_t smallest_page = SIZE_MAX, largest_page = 0;
size_t blocks = 0; /* Total number of blocks found. */
size_t smallest_block = SIZE_MAX, largest_block = 0, blocks_bytes = 0;
size_t used_blocks = 0; /* Total number of used blocks found. */
size_t used_size = 0; /* Total size (bytes) of used blocks. */
/* Read the pages and blocks. The aim here is to be robust against
* corrupt or malicious registries. So we make sure the loops
* always make forward progress. We add the address of each block
* we read to a hash table so pointers will only reference the start
* of valid blocks.
*/
size_t off;
struct ntreg_hbin_page *page;
for (off = 0x1000; off < h->size; off += le32toh (page->page_size)) {
if (off >= h->endpages)
break;
page = (struct ntreg_hbin_page *) (h->addr + off);
if (page->magic[0] != 'h' ||
page->magic[1] != 'b' ||
page->magic[2] != 'i' ||
page->magic[3] != 'n') {
fprintf (stderr, "hivex: %s: trailing garbage at end of file (at 0x%zx, after %zu pages)\n",
filename, off, pages);
errno = ENOTSUP;
goto error;
}
size_t page_size = le32toh (page->page_size);
if (h->msglvl >= 2)
fprintf (stderr, "hivex_open: page at 0x%zx, size %zu\n", off, page_size);
pages++;
if (page_size < smallest_page) smallest_page = page_size;
if (page_size > largest_page) largest_page = page_size;
if (page_size <= sizeof (struct ntreg_hbin_page) ||
(page_size & 0x0fff) != 0) {
fprintf (stderr, "hivex: %s: page size %zu at 0x%zx, bad registry\n",
filename, page_size, off);
errno = ENOTSUP;
goto error;
}
/* Read the blocks in this page. */
size_t blkoff;
struct ntreg_hbin_block *block;
size_t seg_len;
for (blkoff = off + 0x20;
blkoff < off + page_size;
blkoff += seg_len) {
blocks++;
int is_root = blkoff == h->rootoffs;
if (is_root)
seen_root_block = 1;
block = (struct ntreg_hbin_block *) (h->addr + blkoff);
int used;
seg_len = block_len (h, blkoff, &used);
if (seg_len <= 4 || (seg_len & 3) != 0) {
fprintf (stderr, "hivex: %s: block size %" PRIu32 " at 0x%zx, bad registry\n",
filename, le32toh (block->seg_len), blkoff);
errno = ENOTSUP;
goto error;
}
if (h->msglvl >= 2)
fprintf (stderr, "hivex_open: %s block id %d,%d at 0x%zx size %zu%s\n",
used ? "used" : "free", block->id[0], block->id[1], blkoff,
seg_len, is_root ? " (root)" : "");
blocks_bytes += seg_len;
if (seg_len < smallest_block) smallest_block = seg_len;
if (seg_len > largest_block) largest_block = seg_len;
if (is_root && !used)
bad_root_block = 1;
if (used) {
used_blocks++;
used_size += seg_len;
/* Root block must be an nk-block. */
if (is_root && (block->id[0] != 'n' || block->id[1] != 'k'))
bad_root_block = 1;
/* Note this blkoff is a valid address. */
BITMAP_SET (h->bitmap, blkoff);
}
}
}
if (!seen_root_block) {
fprintf (stderr, "hivex: %s: no root block found\n", filename);
errno = ENOTSUP;
goto error;
}
if (bad_root_block) {
fprintf (stderr, "hivex: %s: bad root block (free or not nk)\n", filename);
errno = ENOTSUP;
goto error;
}
if (h->msglvl >= 1)
fprintf (stderr,
"hivex_open: successfully read Windows Registry hive file:\n"
" pages: %zu [sml: %zu, lge: %zu]\n"
" blocks: %zu [sml: %zu, avg: %zu, lge: %zu]\n"
" blocks used: %zu\n"
" bytes used: %zu\n",
pages, smallest_page, largest_page,
blocks, smallest_block, blocks_bytes / blocks, largest_block,
used_blocks, used_size);
return h;
error:;
int err = errno;
if (h) {
free (h->bitmap);
if (h->addr && h->size && h->addr != MAP_FAILED) {
if (!h->writable)
munmap (h->addr, h->size);
else
free (h->addr);
}
if (h->fd >= 0)
close (h->fd);
free (h->filename);
free (h);
}
errno = err;
return NULL;
}
int
hivex_close (hive_h *h)
{
int r;
free (h->bitmap);
if (!h->writable)
munmap (h->addr, h->size);
else
free (h->addr);
r = close (h->fd);
free (h->filename);
free (h);
if (h->msglvl >= 1)
fprintf (stderr, "hivex_close\n");
return r;
}
/*----------------------------------------------------------------------
* Reading.
*/
hive_node_h
hivex_root (hive_h *h)
{
hive_node_h ret = h->rootoffs;
if (!IS_VALID_BLOCK (h, ret)) {
errno = ENOKEY;
return 0;
}
return ret;
}
char *
hivex_node_name (hive_h *h, hive_node_h node)
{
if (!IS_VALID_BLOCK (h, node) || !BLOCK_ID_EQ (h, node, "nk")) {
errno = EINVAL;
return NULL;
}
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + node);
/* AFAIK the node name is always plain ASCII, so no conversion
* to UTF-8 is necessary. However we do need to nul-terminate
* the string.
*/
/* nk->name_len is unsigned, 16 bit, so this is safe ... However
* we have to make sure the length doesn't exceed the block length.
*/
size_t len = le16toh (nk->name_len);
size_t seg_len = block_len (h, node, NULL);
if (sizeof (struct ntreg_nk_record) + len - 1 > seg_len) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_name: returning EFAULT because node name is too long (%zu, %zu)\n",
len, seg_len);
errno = EFAULT;
return NULL;
}
char *ret = malloc (len + 1);
if (ret == NULL)
return NULL;
memcpy (ret, nk->name, len);
ret[len] = '\0';
return ret;
}
#if 0
/* I think the documentation for the sk and classname fields in the nk
* record is wrong, or else the offset field is in the wrong place.
* Otherwise this makes no sense. Disabled this for now -- it's not
* useful for reading the registry anyway.
*/
hive_security_h
hivex_node_security (hive_h *h, hive_node_h node)
{
if (!IS_VALID_BLOCK (h, node) || !BLOCK_ID_EQ (h, node, "nk")) {
errno = EINVAL;
return 0;
}
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + node);
hive_node_h ret = le32toh (nk->sk);
ret += 0x1000;
if (!IS_VALID_BLOCK (h, ret)) {
errno = EFAULT;
return 0;
}
return ret;
}
hive_classname_h
hivex_node_classname (hive_h *h, hive_node_h node)
{
if (!IS_VALID_BLOCK (h, node) || !BLOCK_ID_EQ (h, node, "nk")) {
errno = EINVAL;
return 0;
}
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + node);
hive_node_h ret = le32toh (nk->classname);
ret += 0x1000;
if (!IS_VALID_BLOCK (h, ret)) {
errno = EFAULT;
return 0;
}
return ret;
}
#endif
/* Structure for returning 0-terminated lists of offsets (nodes,
* values, etc).
*/
struct offset_list {
size_t *offsets;
size_t len;
size_t alloc;
};
static void
init_offset_list (struct offset_list *list)
{
list->len = 0;
list->alloc = 0;
list->offsets = NULL;
}
#define INIT_OFFSET_LIST(name) \
struct offset_list name; \
init_offset_list (&name)
/* Preallocates the offset_list, but doesn't make the contents longer. */
static int
grow_offset_list (struct offset_list *list, size_t alloc)
{
assert (alloc >= list->len);
size_t *p = realloc (list->offsets, alloc * sizeof (size_t));
if (p == NULL)
return -1;
list->offsets = p;
list->alloc = alloc;
return 0;
}
static int
add_to_offset_list (struct offset_list *list, size_t offset)
{
if (list->len >= list->alloc) {
if (grow_offset_list (list, list->alloc ? list->alloc * 2 : 4) == -1)
return -1;
}
list->offsets[list->len] = offset;
list->len++;
return 0;
}
static void
free_offset_list (struct offset_list *list)
{
free (list->offsets);
}
static size_t *
return_offset_list (struct offset_list *list)
{
if (add_to_offset_list (list, 0) == -1)
return NULL;
return list->offsets; /* caller frees */
}
/* Iterate over children, returning child nodes and intermediate blocks. */
#define GET_CHILDREN_NO_CHECK_NK 1
static int
get_children (hive_h *h, hive_node_h node,
hive_node_h **children_ret, size_t **blocks_ret,
int flags)
{
if (!IS_VALID_BLOCK (h, node) || !BLOCK_ID_EQ (h, node, "nk")) {
errno = EINVAL;
return -1;
}
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + node);
size_t nr_subkeys_in_nk = le32toh (nk->nr_subkeys);
INIT_OFFSET_LIST (children);
INIT_OFFSET_LIST (blocks);
/* Deal with the common "no subkeys" case quickly. */
if (nr_subkeys_in_nk == 0)
goto ok;
/* Arbitrarily limit the number of subkeys we will ever deal with. */
if (nr_subkeys_in_nk > HIVEX_MAX_SUBKEYS) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex: get_children: returning ERANGE because nr_subkeys_in_nk > HIVEX_MAX_SUBKEYS (%zu > %d)\n",
nr_subkeys_in_nk, HIVEX_MAX_SUBKEYS);
errno = ERANGE;
goto error;
}
/* Preallocate space for the children. */
if (grow_offset_list (&children, nr_subkeys_in_nk) == -1)
goto error;
/* The subkey_lf field can point either to an lf-record, which is
* the common case, or if there are lots of subkeys, to an
* ri-record.
*/
size_t subkey_lf = le32toh (nk->subkey_lf);
subkey_lf += 0x1000;
if (!IS_VALID_BLOCK (h, subkey_lf)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_children: returning EFAULT because subkey_lf is not a valid block (0x%zx)\n",
subkey_lf);
errno = EFAULT;
goto error;
}
if (add_to_offset_list (&blocks, subkey_lf) == -1)
goto error;
struct ntreg_hbin_block *block =
(struct ntreg_hbin_block *) (h->addr + subkey_lf);
/* Points to lf-record? (Note, also "lh" but that is basically the
* same as "lf" as far as we are concerned here).
*/
if (block->id[0] == 'l' && (block->id[1] == 'f' || block->id[1] == 'h')) {
struct ntreg_lf_record *lf = (struct ntreg_lf_record *) block;
/* Check number of subkeys in the nk-record matches number of subkeys
* in the lf-record.
*/
size_t nr_subkeys_in_lf = le16toh (lf->nr_keys);
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_children: nr_subkeys_in_nk = %zu, nr_subkeys_in_lf = %zu\n",
nr_subkeys_in_nk, nr_subkeys_in_lf);
if (nr_subkeys_in_nk != nr_subkeys_in_lf) {
errno = ENOTSUP;
goto error;
}
size_t len = block_len (h, subkey_lf, NULL);
if (8 + nr_subkeys_in_lf * 8 > len) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_children: returning EFAULT because too many subkeys (%zu, %zu)\n",
nr_subkeys_in_lf, len);
errno = EFAULT;
goto error;
}
size_t i;
for (i = 0; i < nr_subkeys_in_lf; ++i) {
hive_node_h subkey = le32toh (lf->keys[i].offset);
subkey += 0x1000;
if (!(flags & GET_CHILDREN_NO_CHECK_NK)) {
if (!IS_VALID_BLOCK (h, subkey)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_children: returning EFAULT because subkey is not a valid block (0x%zx)\n",
subkey);
errno = EFAULT;
goto error;
}
}
if (add_to_offset_list (&children, subkey) == -1)
goto error;
}
goto ok;
}
/* Points to ri-record? */
else if (block->id[0] == 'r' && block->id[1] == 'i') {
struct ntreg_ri_record *ri = (struct ntreg_ri_record *) block;
size_t nr_offsets = le16toh (ri->nr_offsets);
/* Count total number of children. */
size_t i, count = 0;
for (i = 0; i < nr_offsets; ++i) {
hive_node_h offset = le32toh (ri->offset[i]);
offset += 0x1000;
if (!IS_VALID_BLOCK (h, offset)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_children: returning EFAULT because ri-offset is not a valid block (0x%zx)\n",
offset);
errno = EFAULT;
goto error;
}
if (!BLOCK_ID_EQ (h, offset, "lf") && !BLOCK_ID_EQ (h, offset, "lh")) {
if (h->msglvl >= 2)
fprintf (stderr, "get_children: returning ENOTSUP because ri-record offset does not point to lf/lh (0x%zx)\n",
offset);
errno = ENOTSUP;
goto error;
}
if (add_to_offset_list (&blocks, offset) == -1)
goto error;
struct ntreg_lf_record *lf =
(struct ntreg_lf_record *) (h->addr + offset);
count += le16toh (lf->nr_keys);
}
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_children: nr_subkeys_in_nk = %zu, counted = %zu\n",
nr_subkeys_in_nk, count);
if (nr_subkeys_in_nk != count) {
errno = ENOTSUP;
goto error;
}
/* Copy list of children. Note nr_subkeys_in_nk is limited to
* something reasonable above.
*/
for (i = 0; i < nr_offsets; ++i) {
hive_node_h offset = le32toh (ri->offset[i]);
offset += 0x1000;
if (!IS_VALID_BLOCK (h, offset)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_children: returning EFAULT because ri-offset is not a valid block (0x%zx)\n",
offset);
errno = EFAULT;
goto error;
}
if (!BLOCK_ID_EQ (h, offset, "lf") && !BLOCK_ID_EQ (h, offset, "lh")) {
if (h->msglvl >= 2)
fprintf (stderr, "get_children: returning ENOTSUP because ri-record offset does not point to lf/lh (0x%zx)\n",
offset);
errno = ENOTSUP;
goto error;
}
struct ntreg_lf_record *lf =
(struct ntreg_lf_record *) (h->addr + offset);
size_t j;
for (j = 0; j < le16toh (lf->nr_keys); ++j) {
hive_node_h subkey = le32toh (lf->keys[j].offset);
subkey += 0x1000;
if (!(flags & GET_CHILDREN_NO_CHECK_NK)) {
if (!IS_VALID_BLOCK (h, subkey)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_children: returning EFAULT because indirect subkey is not a valid block (0x%zx)\n",
subkey);
errno = EFAULT;
goto error;
}
}
if (add_to_offset_list (&children, subkey) == -1)
goto error;
}
}
goto ok;
}
/* else not supported, set errno and fall through */
if (h->msglvl >= 2)
fprintf (stderr, "get_children: returning ENOTSUP because subkey block is not lf/lh/ri (0x%zx, %d, %d)\n",
subkey_lf, block->id[0], block->id[1]);
errno = ENOTSUP;
error:
free_offset_list (&children);
free_offset_list (&blocks);
return -1;
ok:
*children_ret = return_offset_list (&children);
*blocks_ret = return_offset_list (&blocks);
if (!*children_ret || !*blocks_ret)
goto error;
return 0;
}
hive_node_h *
hivex_node_children (hive_h *h, hive_node_h node)
{
hive_node_h *children;
size_t *blocks;
if (get_children (h, node, &children, &blocks, 0) == -1)
return NULL;
free (blocks);
return children;
}
/* Very inefficient, but at least having a separate API call
* allows us to make it more efficient in future.
*/
hive_node_h
hivex_node_get_child (hive_h *h, hive_node_h node, const char *nname)
{
hive_node_h *children = NULL;
char *name = NULL;
hive_node_h ret = 0;
children = hivex_node_children (h, node);
if (!children) goto error;
size_t i;
for (i = 0; children[i] != 0; ++i) {
name = hivex_node_name (h, children[i]);
if (!name) goto error;
if (STRCASEEQ (name, nname)) {
ret = children[i];
break;
}
free (name); name = NULL;
}
error:
free (children);
free (name);
return ret;
}
hive_node_h
hivex_node_parent (hive_h *h, hive_node_h node)
{
if (!IS_VALID_BLOCK (h, node) || !BLOCK_ID_EQ (h, node, "nk")) {
errno = EINVAL;
return 0;
}
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + node);
hive_node_h ret = le32toh (nk->parent);
ret += 0x1000;
if (!IS_VALID_BLOCK (h, ret)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_parent: returning EFAULT because parent is not a valid block (0x%zx)\n",
ret);
errno = EFAULT;
return 0;
}
return ret;
}
static int
get_values (hive_h *h, hive_node_h node,
hive_value_h **values_ret, size_t **blocks_ret)
{
if (!IS_VALID_BLOCK (h, node) || !BLOCK_ID_EQ (h, node, "nk")) {
errno = EINVAL;
return -1;
}
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + node);
size_t nr_values = le32toh (nk->nr_values);
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_values: nr_values = %zu\n", nr_values);
INIT_OFFSET_LIST (values);
INIT_OFFSET_LIST (blocks);
/* Deal with the common "no values" case quickly. */
if (nr_values == 0)
goto ok;
/* Arbitrarily limit the number of values we will ever deal with. */
if (nr_values > HIVEX_MAX_VALUES) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex: get_values: returning ERANGE because nr_values > HIVEX_MAX_VALUES (%zu > %d)\n",
nr_values, HIVEX_MAX_VALUES);
errno = ERANGE;
goto error;
}
/* Preallocate space for the values. */
if (grow_offset_list (&values, nr_values) == -1)
goto error;
/* Get the value list and check it looks reasonable. */
size_t vlist_offset = le32toh (nk->vallist);
vlist_offset += 0x1000;
if (!IS_VALID_BLOCK (h, vlist_offset)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_values: returning EFAULT because value list is not a valid block (0x%zx)\n",
vlist_offset);
errno = EFAULT;
goto error;
}
if (add_to_offset_list (&blocks, vlist_offset) == -1)
goto error;
struct ntreg_value_list *vlist =
(struct ntreg_value_list *) (h->addr + vlist_offset);
size_t len = block_len (h, vlist_offset, NULL);
if (4 + nr_values * 4 > len) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_values: returning EFAULT because value list is too long (%zu, %zu)\n",
nr_values, len);
errno = EFAULT;
goto error;
}
size_t i;
for (i = 0; i < nr_values; ++i) {
hive_node_h value = vlist->offset[i];
value += 0x1000;
if (!IS_VALID_BLOCK (h, value)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_values: returning EFAULT because value is not a valid block (0x%zx)\n",
value);
errno = EFAULT;
goto error;
}
if (add_to_offset_list (&values, value) == -1)
goto error;
}
ok:
*values_ret = return_offset_list (&values);
*blocks_ret = return_offset_list (&blocks);
if (!*values_ret || !*blocks_ret)
goto error;
return 0;
error:
free_offset_list (&values);
free_offset_list (&blocks);
return -1;
}
hive_value_h *
hivex_node_values (hive_h *h, hive_node_h node)
{
hive_value_h *values;
size_t *blocks;
if (get_values (h, node, &values, &blocks) == -1)
return NULL;
free (blocks);
return values;
}
/* Very inefficient, but at least having a separate API call
* allows us to make it more efficient in future.
*/
hive_value_h
hivex_node_get_value (hive_h *h, hive_node_h node, const char *key)
{
hive_value_h *values = NULL;
char *name = NULL;
hive_value_h ret = 0;
values = hivex_node_values (h, node);
if (!values) goto error;
size_t i;
for (i = 0; values[i] != 0; ++i) {
name = hivex_value_key (h, values[i]);
if (!name) goto error;
if (STRCASEEQ (name, key)) {
ret = values[i];
break;
}
free (name); name = NULL;
}
error:
free (values);
free (name);
return ret;
}
char *
hivex_value_key (hive_h *h, hive_value_h value)
{
if (!IS_VALID_BLOCK (h, value) || !BLOCK_ID_EQ (h, value, "vk")) {
errno = EINVAL;
return 0;
}
struct ntreg_vk_record *vk = (struct ntreg_vk_record *) (h->addr + value);
/* AFAIK the key is always plain ASCII, so no conversion to UTF-8 is
* necessary. However we do need to nul-terminate the string.
*/
/* vk->name_len is unsigned, 16 bit, so this is safe ... However
* we have to make sure the length doesn't exceed the block length.
*/
size_t len = le16toh (vk->name_len);
size_t seg_len = block_len (h, value, NULL);
if (sizeof (struct ntreg_vk_record) + len - 1 > seg_len) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_value_key: returning EFAULT because key length is too long (%zu, %zu)\n",
len, seg_len);
errno = EFAULT;
return NULL;
}
char *ret = malloc (len + 1);
if (ret == NULL)
return NULL;
memcpy (ret, vk->name, len);
ret[len] = '\0';
return ret;
}
int
hivex_value_type (hive_h *h, hive_value_h value, hive_type *t, size_t *len)
{
if (!IS_VALID_BLOCK (h, value) || !BLOCK_ID_EQ (h, value, "vk")) {
errno = EINVAL;
return -1;
}
struct ntreg_vk_record *vk = (struct ntreg_vk_record *) (h->addr + value);
if (t)
*t = le32toh (vk->data_type);
if (len) {
*len = le32toh (vk->data_len);
*len &= 0x7fffffff; /* top bit indicates if data is stored inline */
}
return 0;
}
char *
hivex_value_value (hive_h *h, hive_value_h value,
hive_type *t_rtn, size_t *len_rtn)
{
if (!IS_VALID_BLOCK (h, value) || !BLOCK_ID_EQ (h, value, "vk")) {
errno = EINVAL;
return NULL;
}
struct ntreg_vk_record *vk = (struct ntreg_vk_record *) (h->addr + value);
hive_type t;
size_t len;
int is_inline;
t = le32toh (vk->data_type);
len = le32toh (vk->data_len);
is_inline = !!(len & 0x80000000);
len &= 0x7fffffff;
if (h->msglvl >= 2)
fprintf (stderr, "hivex_value_value: value=0x%zx, t=%d, len=%zu, inline=%d\n",
value, t, len, is_inline);
if (t_rtn)
*t_rtn = t;
if (len_rtn)
*len_rtn = len;
if (is_inline && len > 4) {
errno = ENOTSUP;
return NULL;
}
/* Arbitrarily limit the length that we will read. */
if (len > HIVEX_MAX_VALUE_LEN) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_value_value: returning ERANGE because data length > HIVEX_MAX_VALUE_LEN (%zu > %d)\n",
len, HIVEX_MAX_SUBKEYS);
errno = ERANGE;
return NULL;
}
char *ret = malloc (len);
if (ret == NULL)
return NULL;
if (is_inline) {
memcpy (ret, (char *) &vk->data_offset, len);
return ret;
}
size_t data_offset = le32toh (vk->data_offset);
data_offset += 0x1000;
if (!IS_VALID_BLOCK (h, data_offset)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_value_value: returning EFAULT because data offset is not a valid block (0x%zx)\n",
data_offset);
errno = EFAULT;
free (ret);
return NULL;
}
/* Check that the declared size isn't larger than the block its in.
*
* XXX Some apparently valid registries are seen to have this,
* so turn this into a warning and substitute the smaller length
* instead.
*/
size_t blen = block_len (h, data_offset, NULL);
if (len > blen - 4 /* subtract 4 for block header */) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_value_value: warning: declared data length is longer than the block it is in (data 0x%zx, data len %zu, block len %zu)\n",
data_offset, len, blen);
len = blen - 4;
}
char *data = h->addr + data_offset + 4;
memcpy (ret, data, len);
return ret;
}
static char *
windows_utf16_to_utf8 (/* const */ char *input, size_t len)
{
iconv_t ic = iconv_open ("UTF-8", "UTF-16");
if (ic == (iconv_t) -1)
return NULL;
/* iconv(3) has an insane interface ... */
/* Mostly UTF-8 will be smaller, so this is a good initial guess. */
size_t outalloc = len;
again:;
size_t inlen = len;
size_t outlen = outalloc;
char *out = malloc (outlen + 1);
if (out == NULL) {
int err = errno;
iconv_close (ic);
errno = err;
return NULL;
}
char *inp = input;
char *outp = out;
size_t r = iconv (ic, &inp, &inlen, &outp, &outlen);
if (r == (size_t) -1) {
if (errno == E2BIG) {
int err = errno;
size_t prev = outalloc;
/* Try again with a larger output buffer. */
free (out);
outalloc *= 2;
if (outalloc < prev) {
iconv_close (ic);
errno = err;
return NULL;
}
goto again;
}
else {
/* Else some conversion failure, eg. EILSEQ, EINVAL. */
int err = errno;
iconv_close (ic);
free (out);
errno = err;
return NULL;
}
}
*outp = '\0';
iconv_close (ic);
return out;
}
char *
hivex_value_string (hive_h *h, hive_value_h value)
{
hive_type t;
size_t len;
char *data = hivex_value_value (h, value, &t, &len);
if (data == NULL)
return NULL;
if (t != hive_t_string && t != hive_t_expand_string && t != hive_t_link) {
free (data);
errno = EINVAL;
return NULL;
}
/* Deal with the case where Windows has allocated a large buffer
* full of random junk, and only the first few bytes of the buffer
* contain a genuine UTF-16 string.
*
* In this case, iconv would try to process the junk bytes as UTF-16
* and inevitably find an illegal sequence (EILSEQ). Instead, stop
* after we find the first \0\0.
*
* (Found by Hilko Bengen in a fresh Windows XP SOFTWARE hive).
*/
size_t slen = utf16_string_len_in_bytes_max (data, len);
if (slen > len)
len = slen;
char *ret = windows_utf16_to_utf8 (data, len);
free (data);
if (ret == NULL)
return NULL;
return ret;
}
static void
free_strings (char **argv)
{
if (argv) {
size_t i;
for (i = 0; argv[i] != NULL; ++i)
free (argv[i]);
free (argv);
}
}
/* Get the length of a UTF-16 format string. Handle the string as
* pairs of bytes, looking for the first \0\0 pair.
*/
static size_t
utf16_string_len_in_bytes (const char *str)
{
size_t ret = 0;
while (str[0] || str[1]) {
str += 2;
ret += 2;
}
return ret;
}
/* As for utf16_string_len_in_bytes but only read up to a maximum length. */
static size_t
utf16_string_len_in_bytes_max (const char *str, size_t len)
{
size_t ret = 0;
while (len > 0 && (str[0] || str[1])) {
str += 2;
ret += 2;
len -= 2;
}
return ret;
}
/* http://blogs.msdn.com/oldnewthing/archive/2009/10/08/9904646.aspx */
char **
hivex_value_multiple_strings (hive_h *h, hive_value_h value)
{
hive_type t;
size_t len;
char *data = hivex_value_value (h, value, &t, &len);
if (data == NULL)
return NULL;
if (t != hive_t_multiple_strings) {
free (data);
errno = EINVAL;
return NULL;
}
size_t nr_strings = 0;
char **ret = malloc ((1 + nr_strings) * sizeof (char *));
if (ret == NULL) {
free (data);
return NULL;
}
ret[0] = NULL;
char *p = data;
size_t plen;
while (p < data + len && (plen = utf16_string_len_in_bytes (p)) > 0) {
nr_strings++;
char **ret2 = realloc (ret, (1 + nr_strings) * sizeof (char *));
if (ret2 == NULL) {
free_strings (ret);
free (data);
return NULL;
}
ret = ret2;
ret[nr_strings-1] = windows_utf16_to_utf8 (p, plen);
ret[nr_strings] = NULL;
if (ret[nr_strings-1] == NULL) {
free_strings (ret);
free (data);
return NULL;
}
p += plen + 2 /* skip over UTF-16 \0\0 at the end of this string */;
}
free (data);
return ret;
}
int32_t
hivex_value_dword (hive_h *h, hive_value_h value)
{
hive_type t;
size_t len;
char *data = hivex_value_value (h, value, &t, &len);
if (data == NULL)
return -1;
if ((t != hive_t_dword && t != hive_t_dword_be) || len != 4) {
free (data);
errno = EINVAL;
return -1;
}
int32_t ret = *(int32_t*)data;
free (data);
if (t == hive_t_dword) /* little endian */
ret = le32toh (ret);
else
ret = be32toh (ret);
return ret;
}
int64_t
hivex_value_qword (hive_h *h, hive_value_h value)
{
hive_type t;
size_t len;
char *data = hivex_value_value (h, value, &t, &len);
if (data == NULL)
return -1;
if (t != hive_t_qword || len != 8) {
free (data);
errno = EINVAL;
return -1;
}
int64_t ret = *(int64_t*)data;
free (data);
ret = le64toh (ret); /* always little endian */
return ret;
}
/*----------------------------------------------------------------------
* Visiting.
*/
int
hivex_visit (hive_h *h, const struct hivex_visitor *visitor, size_t len,
void *opaque, int flags)
{
return hivex_visit_node (h, hivex_root (h), visitor, len, opaque, flags);
}
static int hivex__visit_node (hive_h *h, hive_node_h node, const struct hivex_visitor *vtor, char *unvisited, void *opaque, int flags);
int
hivex_visit_node (hive_h *h, hive_node_h node,
const struct hivex_visitor *visitor, size_t len, void *opaque,
int flags)
{
struct hivex_visitor vtor;
memset (&vtor, 0, sizeof vtor);
/* Note that len might be larger *or smaller* than the expected size. */
size_t copysize = len <= sizeof vtor ? len : sizeof vtor;
memcpy (&vtor, visitor, copysize);
/* This bitmap records unvisited nodes, so we don't loop if the
* registry contains cycles.
*/
char *unvisited = malloc (1 + h->size / 32);
if (unvisited == NULL)
return -1;
memcpy (unvisited, h->bitmap, 1 + h->size / 32);
int r = hivex__visit_node (h, node, &vtor, unvisited, opaque, flags);
free (unvisited);
return r;
}
static int
hivex__visit_node (hive_h *h, hive_node_h node,
const struct hivex_visitor *vtor, char *unvisited,
void *opaque, int flags)
{
int skip_bad = flags & HIVEX_VISIT_SKIP_BAD;
char *name = NULL;
hive_value_h *values = NULL;
hive_node_h *children = NULL;
char *key = NULL;
char *str = NULL;
char **strs = NULL;
int i;
/* Return -1 on all callback errors. However on internal errors,
* check if skip_bad is set and suppress those errors if so.
*/
int ret = -1;
if (!BITMAP_TST (unvisited, node)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex__visit_node: contains cycle: visited node 0x%zx already\n",
node);
errno = ELOOP;
return skip_bad ? 0 : -1;
}
BITMAP_CLR (unvisited, node);
name = hivex_node_name (h, node);
if (!name) return skip_bad ? 0 : -1;
if (vtor->node_start && vtor->node_start (h, opaque, node, name) == -1)
goto error;
values = hivex_node_values (h, node);
if (!values) {
ret = skip_bad ? 0 : -1;
goto error;
}
for (i = 0; values[i] != 0; ++i) {
hive_type t;
size_t len;
if (hivex_value_type (h, values[i], &t, &len) == -1) {
ret = skip_bad ? 0 : -1;
goto error;
}
key = hivex_value_key (h, values[i]);
if (key == NULL) {
ret = skip_bad ? 0 : -1;
goto error;
}
if (vtor->value_any) {
str = hivex_value_value (h, values[i], &t, &len);
if (str == NULL) {
ret = skip_bad ? 0 : -1;
goto error;
}
if (vtor->value_any (h, opaque, node, values[i], t, len, key, str) == -1)
goto error;
free (str); str = NULL;
}
else {
switch (t) {
case hive_t_none:
str = hivex_value_value (h, values[i], &t, &len);
if (str == NULL) {
ret = skip_bad ? 0 : -1;
goto error;
}
if (t != hive_t_none) {
ret = skip_bad ? 0 : -1;
goto error;
}
if (vtor->value_none &&
vtor->value_none (h, opaque, node, values[i], t, len, key, str) == -1)
goto error;
free (str); str = NULL;
break;
case hive_t_string:
case hive_t_expand_string:
case hive_t_link:
str = hivex_value_string (h, values[i]);
if (str == NULL) {
if (errno != EILSEQ && errno != EINVAL) {
ret = skip_bad ? 0 : -1;
goto error;
}
if (vtor->value_string_invalid_utf16) {
str = hivex_value_value (h, values[i], &t, &len);
if (vtor->value_string_invalid_utf16 (h, opaque, node, values[i], t, len, key, str) == -1)
goto error;
free (str); str = NULL;
}
break;
}
if (vtor->value_string &&
vtor->value_string (h, opaque, node, values[i], t, len, key, str) == -1)
goto error;
free (str); str = NULL;
break;
case hive_t_dword:
case hive_t_dword_be: {
int32_t i32 = hivex_value_dword (h, values[i]);
if (vtor->value_dword &&
vtor->value_dword (h, opaque, node, values[i], t, len, key, i32) == -1)
goto error;
break;
}
case hive_t_qword: {
int64_t i64 = hivex_value_qword (h, values[i]);
if (vtor->value_qword &&
vtor->value_qword (h, opaque, node, values[i], t, len, key, i64) == -1)
goto error;
break;
}
case hive_t_binary:
str = hivex_value_value (h, values[i], &t, &len);
if (str == NULL) {
ret = skip_bad ? 0 : -1;
goto error;
}
if (t != hive_t_binary) {
ret = skip_bad ? 0 : -1;
goto error;
}
if (vtor->value_binary &&
vtor->value_binary (h, opaque, node, values[i], t, len, key, str) == -1)
goto error;
free (str); str = NULL;
break;
case hive_t_multiple_strings:
strs = hivex_value_multiple_strings (h, values[i]);
if (strs == NULL) {
if (errno != EILSEQ && errno != EINVAL) {
ret = skip_bad ? 0 : -1;
goto error;
}
if (vtor->value_string_invalid_utf16) {
str = hivex_value_value (h, values[i], &t, &len);
if (vtor->value_string_invalid_utf16 (h, opaque, node, values[i], t, len, key, str) == -1)
goto error;
free (str); str = NULL;
}
break;
}
if (vtor->value_multiple_strings &&
vtor->value_multiple_strings (h, opaque, node, values[i], t, len, key, strs) == -1)
goto error;
free_strings (strs); strs = NULL;
break;
case hive_t_resource_list:
case hive_t_full_resource_description:
case hive_t_resource_requirements_list:
default:
str = hivex_value_value (h, values[i], &t, &len);
if (str == NULL) {
ret = skip_bad ? 0 : -1;
goto error;
}
if (vtor->value_other &&
vtor->value_other (h, opaque, node, values[i], t, len, key, str) == -1)
goto error;
free (str); str = NULL;
break;
}
}
free (key); key = NULL;
}
children = hivex_node_children (h, node);
if (children == NULL) {
ret = skip_bad ? 0 : -1;
goto error;
}
for (i = 0; children[i] != 0; ++i) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex__visit_node: %s: visiting subkey %d (0x%zx)\n",
name, i, children[i]);
if (hivex__visit_node (h, children[i], vtor, unvisited, opaque, flags) == -1)
goto error;
}
if (vtor->node_end && vtor->node_end (h, opaque, node, name) == -1)
goto error;
ret = 0;
error:
free (name);
free (values);
free (children);
free (key);
free (str);
free_strings (strs);
return ret;
}
/*----------------------------------------------------------------------
* Writing.
*/
/* Allocate an hbin (page), extending the malloc'd space if necessary,
* and updating the hive handle fields (but NOT the hive disk header
* -- the hive disk header is updated when we commit). This function
* also extends the bitmap if necessary.
*
* 'allocation_hint' is the size of the block allocation we would like
* to make. Normally registry blocks are very small (avg 50 bytes)
* and are contained in standard-sized pages (4KB), but the registry
* can support blocks which are larger than a standard page, in which
* case it creates a page of 8KB, 12KB etc.
*
* Returns:
* > 0 : offset of first usable byte of new page (after page header)
* 0 : error (errno set)
*/
static size_t
allocate_page (hive_h *h, size_t allocation_hint)
{
/* In almost all cases this will be 1. */
size_t nr_4k_pages =
1 + (allocation_hint + sizeof (struct ntreg_hbin_page) - 1) / 4096;
assert (nr_4k_pages >= 1);
/* 'extend' is the number of bytes to extend the file by. Note that
* hives found in the wild often contain slack between 'endpages'
* and the actual end of the file, so we don't always need to make
* the file larger.
*/
ssize_t extend = h->endpages + nr_4k_pages * 4096 - h->size;
if (h->msglvl >= 2) {
fprintf (stderr, "allocate_page: current endpages = 0x%zx, current size = 0x%zx\n",
h->endpages, h->size);
fprintf (stderr, "allocate_page: extending file by %zd bytes (<= 0 if no extension)\n",
extend);
}
if (extend > 0) {
size_t oldsize = h->size;
size_t newsize = h->size + extend;
char *newaddr = realloc (h->addr, newsize);
if (newaddr == NULL)
return 0;
size_t oldbitmapsize = 1 + oldsize / 32;
size_t newbitmapsize = 1 + newsize / 32;
char *newbitmap = realloc (h->bitmap, newbitmapsize);
if (newbitmap == NULL) {
free (newaddr);
return 0;
}
h->addr = newaddr;
h->size = newsize;
h->bitmap = newbitmap;
memset (h->addr + oldsize, 0, newsize - oldsize);
memset (h->bitmap + oldbitmapsize, 0, newbitmapsize - oldbitmapsize);
}
size_t offset = h->endpages;
h->endpages += nr_4k_pages * 4096;
if (h->msglvl >= 2)
fprintf (stderr, "allocate_page: new endpages = 0x%zx, new size = 0x%zx\n",
h->endpages, h->size);
/* Write the hbin header. */
struct ntreg_hbin_page *page =
(struct ntreg_hbin_page *) (h->addr + offset);
page->magic[0] = 'h';
page->magic[1] = 'b';
page->magic[2] = 'i';
page->magic[3] = 'n';
page->offset_first = htole32 (offset - 0x1000);
page->page_size = htole32 (nr_4k_pages * 4096);
memset (page->unknown, 0, sizeof (page->unknown));
if (h->msglvl >= 2)
fprintf (stderr, "allocate_page: new page at 0x%zx\n", offset);
/* Offset of first usable byte after the header. */
return offset + sizeof (struct ntreg_hbin_page);
}
/* Allocate a single block, first allocating an hbin (page) at the end
* of the current file if necessary. NB. To keep the implementation
* simple and more likely to be correct, we do not reuse existing free
* blocks.
*
* seg_len is the size of the block (this INCLUDES the block header).
* The header of the block is initialized to -seg_len (negative to
* indicate used). id[2] is the block ID (type), eg. "nk" for nk-
* record. The block bitmap is updated to show this block as valid.
* The rest of the contents of the block will be zero.
*
* **NB** Because allocate_block may reallocate the memory, all
* pointers into the memory become potentially invalid. I really
* love writing in C, can't you tell?
*
* Returns:
* > 0 : offset of new block
* 0 : error (errno set)
*/
static size_t
allocate_block (hive_h *h, size_t seg_len, const char id[2])
{
if (!h->writable) {
errno = EROFS;
return 0;
}
if (seg_len < 4) {
/* The caller probably forgot to include the header. Note that
* value lists have no ID field, so seg_len == 4 would be possible
* for them, albeit unusual.
*/
if (h->msglvl >= 2)
fprintf (stderr, "allocate_block: refusing too small allocation (%zu), returning ERANGE\n",
seg_len);
errno = ERANGE;
return 0;
}
/* Refuse really large allocations. */
if (seg_len > HIVEX_MAX_ALLOCATION) {
if (h->msglvl >= 2)
fprintf (stderr, "allocate_block: refusing large allocation (%zu), returning ERANGE\n",
seg_len);
errno = ERANGE;
return 0;
}
/* Round up allocation to multiple of 8 bytes. All blocks must be
* on an 8 byte boundary.
*/
seg_len = (seg_len + 7) & ~7;
/* Allocate a new page if necessary. */
if (h->endblocks == 0 || h->endblocks + seg_len > h->endpages) {
size_t newendblocks = allocate_page (h, seg_len);
if (newendblocks == 0)
return 0;
h->endblocks = newendblocks;
}
size_t offset = h->endblocks;
if (h->msglvl >= 2)
fprintf (stderr, "allocate_block: new block at 0x%zx, size %zu\n",
offset, seg_len);
struct ntreg_hbin_block *blockhdr =
(struct ntreg_hbin_block *) (h->addr + offset);
memset (blockhdr, 0, seg_len);
blockhdr->seg_len = htole32 (- (int32_t) seg_len);
if (id[0] && id[1] && seg_len >= sizeof (struct ntreg_hbin_block)) {
blockhdr->id[0] = id[0];
blockhdr->id[1] = id[1];
}
BITMAP_SET (h->bitmap, offset);
h->endblocks += seg_len;
/* If there is space after the last block in the last page, then we
* have to put a dummy free block header here to mark the rest of
* the page as free.
*/
ssize_t rem = h->endpages - h->endblocks;
if (rem > 0) {
if (h->msglvl >= 2)
fprintf (stderr, "allocate_block: marking remainder of page free starting at 0x%zx, size %zd\n",
h->endblocks, rem);
assert (rem >= 4);
blockhdr = (struct ntreg_hbin_block *) (h->addr + h->endblocks);
blockhdr->seg_len = htole32 ((int32_t) rem);
}
return offset;
}
/* 'offset' must point to a valid, used block. This function marks
* the block unused (by updating the seg_len field) and invalidates
* the bitmap. It does NOT do this recursively, so to avoid creating
* unreachable used blocks, callers may have to recurse over the hive
* structures. Also callers must ensure there are no references to
* this block from other parts of the hive.
*/
static void
mark_block_unused (hive_h *h, size_t offset)
{
assert (h->writable);
assert (IS_VALID_BLOCK (h, offset));
if (h->msglvl >= 2)
fprintf (stderr, "mark_block_unused: marking 0x%zx unused\n", offset);
struct ntreg_hbin_block *blockhdr =
(struct ntreg_hbin_block *) (h->addr + offset);
size_t seg_len = block_len (h, offset, NULL);
blockhdr->seg_len = htole32 (seg_len);
BITMAP_CLR (h->bitmap, offset);
}
/* Delete all existing values at this node. */
static int
delete_values (hive_h *h, hive_node_h node)
{
assert (h->writable);
hive_value_h *values;
size_t *blocks;
if (get_values (h, node, &values, &blocks) == -1)
return -1;
size_t i;
for (i = 0; blocks[i] != 0; ++i)
mark_block_unused (h, blocks[i]);
free (blocks);
for (i = 0; values[i] != 0; ++i) {
struct ntreg_vk_record *vk =
(struct ntreg_vk_record *) (h->addr + values[i]);
size_t len;
int is_inline;
len = le32toh (vk->data_len);
is_inline = !!(len & 0x80000000); /* top bit indicates is inline */
len &= 0x7fffffff;
if (!is_inline) { /* non-inline, so remove data block */
size_t data_offset = le32toh (vk->data_offset);
data_offset += 0x1000;
mark_block_unused (h, data_offset);
}
/* remove vk record */
mark_block_unused (h, values[i]);
}
free (values);
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + node);
nk->nr_values = htole32 (0);
nk->vallist = htole32 (0xffffffff);
return 0;
}
int
hivex_commit (hive_h *h, const char *filename, int flags)
{
if (flags != 0) {
errno = EINVAL;
return -1;
}
if (!h->writable) {
errno = EROFS;
return -1;
}
filename = filename ? : h->filename;
int fd = open (filename, O_WRONLY|O_CREAT|O_TRUNC|O_NOCTTY, 0666);
if (fd == -1)
return -1;
/* Update the header fields. */
uint32_t sequence = le32toh (h->hdr->sequence1);
sequence++;
h->hdr->sequence1 = htole32 (sequence);
h->hdr->sequence2 = htole32 (sequence);
/* XXX Ought to update h->hdr->last_modified. */
h->hdr->blocks = htole32 (h->endpages - 0x1000);
/* Recompute header checksum. */
uint32_t sum = header_checksum (h);
h->hdr->csum = htole32 (sum);
if (h->msglvl >= 2)
fprintf (stderr, "hivex_commit: new header checksum: 0x%x\n", sum);
if (full_write (fd, h->addr, h->size) != h->size) {
int err = errno;
close (fd);
errno = err;
return -1;
}
if (close (fd) == -1)
return -1;
return 0;
}
/* Calculate the hash for a lf or lh record offset.
*/
static void
calc_hash (const char *type, const char *name, char *ret)
{
size_t len = strlen (name);
if (STRPREFIX (type, "lf"))
/* Old-style, not used in current registries. */
memcpy (ret, name, len < 4 ? len : 4);
else {
/* New-style for lh-records. */
size_t i, c;
uint32_t h = 0;
for (i = 0; i < len; ++i) {
c = c_toupper (name[i]);
h *= 37;
h += c;
}
*((uint32_t *) ret) = htole32 (h);
}
}
/* Create a completely new lh-record containing just the single node. */
static size_t
new_lh_record (hive_h *h, const char *name, hive_node_h node)
{
static const char id[2] = { 'l', 'h' };
size_t seg_len = sizeof (struct ntreg_lf_record);
size_t offset = allocate_block (h, seg_len, id);
if (offset == 0)
return 0;
struct ntreg_lf_record *lh = (struct ntreg_lf_record *) (h->addr + offset);
lh->nr_keys = htole16 (1);
lh->keys[0].offset = htole32 (node - 0x1000);
calc_hash ("lh", name, lh->keys[0].hash);
return offset;
}
/* Insert node into existing lf/lh-record at position.
* This allocates a new record and marks the old one as unused.
*/
static size_t
insert_lf_record (hive_h *h, size_t old_offs, size_t posn,
const char *name, hive_node_h node)
{
assert (IS_VALID_BLOCK (h, old_offs));
/* Work around C stupidity.
* http://www.redhat.com/archives/libguestfs/2010-February/msg00056.html
*/
int test = BLOCK_ID_EQ (h, old_offs, "lf") || BLOCK_ID_EQ (h, old_offs, "lh");
assert (test);
struct ntreg_lf_record *old_lf =
(struct ntreg_lf_record *) (h->addr + old_offs);
size_t nr_keys = le16toh (old_lf->nr_keys);
nr_keys++; /* in new record ... */
size_t seg_len = sizeof (struct ntreg_lf_record) + (nr_keys-1) * 8;
/* Copy the old_lf->id in case it moves during allocate_block. */
char id[2];
memcpy (id, old_lf->id, sizeof id);
size_t new_offs = allocate_block (h, seg_len, id);
if (new_offs == 0)
return 0;
/* old_lf could have been invalidated by allocate_block. */
old_lf = (struct ntreg_lf_record *) (h->addr + old_offs);
struct ntreg_lf_record *new_lf =
(struct ntreg_lf_record *) (h->addr + new_offs);
new_lf->nr_keys = htole16 (nr_keys);
/* Copy the keys until we reach posn, insert the new key there, then
* copy the remaining keys.
*/
size_t i;
for (i = 0; i < posn; ++i)
new_lf->keys[i] = old_lf->keys[i];
new_lf->keys[i].offset = htole32 (node - 0x1000);
calc_hash (new_lf->id, name, new_lf->keys[i].hash);
for (i = posn+1; i < nr_keys; ++i)
new_lf->keys[i] = old_lf->keys[i-1];
/* Old block is unused, return new block. */
mark_block_unused (h, old_offs);
return new_offs;
}
/* Compare name with name in nk-record. */
static int
compare_name_with_nk_name (hive_h *h, const char *name, hive_node_h nk_offs)
{
assert (IS_VALID_BLOCK (h, nk_offs));
assert (BLOCK_ID_EQ (h, nk_offs, "nk"));
/* Name in nk is not necessarily nul-terminated. */
char *nname = hivex_node_name (h, nk_offs);
/* Unfortunately we don't have a way to return errors here. */
if (!nname) {
perror ("compare_name_with_nk_name");
return 0;
}
int r = strcasecmp (name, nname);
free (nname);
return r;
}
hive_node_h
hivex_node_add_child (hive_h *h, hive_node_h parent, const char *name)
{
if (!h->writable) {
errno = EROFS;
return 0;
}
if (!IS_VALID_BLOCK (h, parent) || !BLOCK_ID_EQ (h, parent, "nk")) {
errno = EINVAL;
return 0;
}
if (name == NULL || strlen (name) == 0) {
errno = EINVAL;
return 0;
}
if (hivex_node_get_child (h, parent, name) != 0) {
errno = EEXIST;
return 0;
}
/* Create the new nk-record. */
static const char nk_id[2] = { 'n', 'k' };
size_t seg_len = sizeof (struct ntreg_nk_record) + strlen (name);
hive_node_h node = allocate_block (h, seg_len, nk_id);
if (node == 0)
return 0;
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_add_child: allocated new nk-record for child at 0x%zx\n", node);
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + node);
nk->flags = htole16 (0x0020); /* key is ASCII. */
nk->parent = htole32 (parent - 0x1000);
nk->subkey_lf = htole32 (0xffffffff);
nk->subkey_lf_volatile = htole32 (0xffffffff);
nk->vallist = htole32 (0xffffffff);
nk->classname = htole32 (0xffffffff);
nk->name_len = htole16 (strlen (name));
strcpy (nk->name, name);
/* Inherit parent sk. */
struct ntreg_nk_record *parent_nk =
(struct ntreg_nk_record *) (h->addr + parent);
size_t parent_sk_offset = le32toh (parent_nk->sk);
parent_sk_offset += 0x1000;
if (!IS_VALID_BLOCK (h, parent_sk_offset) ||
!BLOCK_ID_EQ (h, parent_sk_offset, "sk")) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_add_child: returning EFAULT because parent sk is not a valid block (%zu)\n",
parent_sk_offset);
errno = EFAULT;
return 0;
}
struct ntreg_sk_record *sk =
(struct ntreg_sk_record *) (h->addr + parent_sk_offset);
sk->refcount = htole32 (le32toh (sk->refcount) + 1);
nk->sk = htole32 (parent_sk_offset - 0x1000);
/* Inherit parent timestamp. */
memcpy (nk->timestamp, parent_nk->timestamp, sizeof (parent_nk->timestamp));
/* What I found out the hard way (not documented anywhere): the
* subkeys in lh-records must be kept sorted. If you just add a
* subkey in a non-sorted position (eg. just add it at the end) then
* Windows won't see the subkey _and_ Windows will corrupt the hive
* itself when it modifies or saves it.
*
* So use get_children() to get a list of intermediate
* lf/lh-records. get_children() returns these in reading order
* (which is sorted), so we look for the lf/lh-records in sequence
* until we find the key name just after the one we are inserting,
* and we insert the subkey just before it.
*
* The only other case is the no-subkeys case, where we have to
* create a brand new lh-record.
*/
hive_node_h *unused;
size_t *blocks;
if (get_children (h, parent, &unused, &blocks, 0) == -1)
return 0;
free (unused);
size_t i, j;
size_t nr_subkeys_in_parent_nk = le32toh (parent_nk->nr_subkeys);
if (nr_subkeys_in_parent_nk == 0) { /* No subkeys case. */
/* Free up any existing intermediate blocks. */
for (i = 0; blocks[i] != 0; ++i)
mark_block_unused (h, blocks[i]);
size_t lh_offs = new_lh_record (h, name, node);
if (lh_offs == 0) {
free (blocks);
return 0;
}
/* Recalculate pointers that could have been invalidated by
* previous call to allocate_block (via new_lh_record).
*/
nk = (struct ntreg_nk_record *) (h->addr + node);
parent_nk = (struct ntreg_nk_record *) (h->addr + parent);
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_add_child: no keys, allocated new lh-record at 0x%zx\n", lh_offs);
parent_nk->subkey_lf = htole32 (lh_offs - 0x1000);
}
else { /* Insert subkeys case. */
size_t old_offs = 0, new_offs = 0;
struct ntreg_lf_record *old_lf = NULL;
/* Find lf/lh key name just after the one we are inserting. */
for (i = 0; blocks[i] != 0; ++i) {
if (BLOCK_ID_EQ (h, blocks[i], "lf") ||
BLOCK_ID_EQ (h, blocks[i], "lh")) {
old_offs = blocks[i];
old_lf = (struct ntreg_lf_record *) (h->addr + old_offs);
for (j = 0; j < le16toh (old_lf->nr_keys); ++j) {
hive_node_h nk_offs = le32toh (old_lf->keys[j].offset);
nk_offs += 0x1000;
if (compare_name_with_nk_name (h, name, nk_offs) < 0)
goto insert_it;
}
}
}
/* Insert it at the end.
* old_offs points to the last lf record, set j.
*/
assert (old_offs != 0); /* should never happen if nr_subkeys > 0 */
j = le16toh (old_lf->nr_keys);
/* Insert it. */
insert_it:
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_add_child: insert key in existing lh-record at 0x%zx, posn %zu\n", old_offs, j);
new_offs = insert_lf_record (h, old_offs, j, name, node);
if (new_offs == 0) {
free (blocks);
return 0;
}
/* Recalculate pointers that could have been invalidated by
* previous call to allocate_block (via insert_lf_record).
*/
nk = (struct ntreg_nk_record *) (h->addr + node);
parent_nk = (struct ntreg_nk_record *) (h->addr + parent);
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_add_child: new lh-record at 0x%zx\n",
new_offs);
/* If the lf/lh-record was directly referenced by the parent nk,
* then update the parent nk.
*/
if (le32toh (parent_nk->subkey_lf) + 0x1000 == old_offs)
parent_nk->subkey_lf = htole32 (new_offs - 0x1000);
/* Else we have to look for the intermediate ri-record and update
* that in-place.
*/
else {
for (i = 0; blocks[i] != 0; ++i) {
if (BLOCK_ID_EQ (h, blocks[i], "ri")) {
struct ntreg_ri_record *ri =
(struct ntreg_ri_record *) (h->addr + blocks[i]);
for (j = 0; j < le16toh (ri->nr_offsets); ++j)
if (le32toh (ri->offset[j] + 0x1000) == old_offs) {
ri->offset[j] = htole32 (new_offs - 0x1000);
goto found_it;
}
}
}
/* Not found .. This is an internal error. */
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_add_child: returning ENOTSUP because could not find ri->lf link\n");
errno = ENOTSUP;
free (blocks);
return 0;
found_it:
;
}
}
free (blocks);
/* Update nr_subkeys in parent nk. */
nr_subkeys_in_parent_nk++;
parent_nk->nr_subkeys = htole32 (nr_subkeys_in_parent_nk);
/* Update max_subkey_name_len in parent nk. */
uint16_t max = le16toh (parent_nk->max_subkey_name_len);
if (max < strlen (name) * 2) /* *2 because "recoded" in UTF16-LE. */
parent_nk->max_subkey_name_len = htole16 (strlen (name) * 2);
return node;
}
/* Decrement the refcount of an sk-record, and if it reaches zero,
* unlink it from the chain and delete it.
*/
static int
delete_sk (hive_h *h, size_t sk_offset)
{
if (!IS_VALID_BLOCK (h, sk_offset) || !BLOCK_ID_EQ (h, sk_offset, "sk")) {
if (h->msglvl >= 2)
fprintf (stderr, "delete_sk: not an sk record: 0x%zx\n", sk_offset);
errno = EFAULT;
return -1;
}
struct ntreg_sk_record *sk = (struct ntreg_sk_record *) (h->addr + sk_offset);
if (sk->refcount == 0) {
if (h->msglvl >= 2)
fprintf (stderr, "delete_sk: sk record already has refcount 0: 0x%zx\n",
sk_offset);
errno = EINVAL;
return -1;
}
sk->refcount--;
if (sk->refcount == 0) {
size_t sk_prev_offset = sk->sk_prev;
sk_prev_offset += 0x1000;
size_t sk_next_offset = sk->sk_next;
sk_next_offset += 0x1000;
/* Update sk_prev/sk_next SKs, unless they both point back to this
* cell in which case we are deleting the last SK.
*/
if (sk_prev_offset != sk_offset && sk_next_offset != sk_offset) {
struct ntreg_sk_record *sk_prev =
(struct ntreg_sk_record *) (h->addr + sk_prev_offset);
struct ntreg_sk_record *sk_next =
(struct ntreg_sk_record *) (h->addr + sk_next_offset);
sk_prev->sk_next = htole32 (sk_next_offset - 0x1000);
sk_next->sk_prev = htole32 (sk_prev_offset - 0x1000);
}
/* Refcount is zero so really delete this block. */
mark_block_unused (h, sk_offset);
}
return 0;
}
/* Callback from hivex_node_delete_child which is called to delete a
* node AFTER its subnodes have been visited. The subnodes have been
* deleted but we still have to delete any lf/lh/li/ri records and the
* value list block and values, followed by deleting the node itself.
*/
static int
delete_node (hive_h *h, void *opaque, hive_node_h node, const char *name)
{
/* Get the intermediate blocks. The subkeys have already been
* deleted by this point, so tell get_children() not to check for
* validity of the nk-records.
*/
hive_node_h *unused;
size_t *blocks;
if (get_children (h, node, &unused, &blocks, GET_CHILDREN_NO_CHECK_NK) == -1)
return -1;
free (unused);
/* We don't care what's in these intermediate blocks, so we can just
* delete them unconditionally.
*/
size_t i;
for (i = 0; blocks[i] != 0; ++i)
mark_block_unused (h, blocks[i]);
free (blocks);
/* Delete the values in the node. */
if (delete_values (h, node) == -1)
return -1;
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + node);
/* If the NK references an SK, delete it. */
size_t sk_offs = le32toh (nk->sk);
if (sk_offs != 0xffffffff) {
sk_offs += 0x1000;
if (delete_sk (h, sk_offs) == -1)
return -1;
nk->sk = htole32 (0xffffffff);
}
/* If the NK references a classname, delete it. */
size_t cl_offs = le32toh (nk->classname);
if (cl_offs != 0xffffffff) {
cl_offs += 0x1000;
mark_block_unused (h, cl_offs);
nk->classname = htole32 (0xffffffff);
}
/* Delete the node itself. */
mark_block_unused (h, node);
return 0;
}
int
hivex_node_delete_child (hive_h *h, hive_node_h node)
{
if (!h->writable) {
errno = EROFS;
return -1;
}
if (!IS_VALID_BLOCK (h, node) || !BLOCK_ID_EQ (h, node, "nk")) {
errno = EINVAL;
return -1;
}
if (node == hivex_root (h)) {
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_delete_child: cannot delete root node\n");
errno = EINVAL;
return -1;
}
hive_node_h parent = hivex_node_parent (h, node);
if (parent == 0)
return -1;
/* Delete node and all its children and values recursively. */
static const struct hivex_visitor visitor = { .node_end = delete_node };
if (hivex_visit_node (h, node, &visitor, sizeof visitor, NULL, 0) == -1)
return -1;
/* Delete the link from parent to child. We need to find the lf/lh
* record which contains the offset and remove the offset from that
* record, then decrement the element count in that record, and
* decrement the overall number of subkeys stored in the parent
* node.
*/
hive_node_h *unused;
size_t *blocks;
if (get_children (h, parent, &unused, &blocks, GET_CHILDREN_NO_CHECK_NK)== -1)
return -1;
free (unused);
size_t i, j;
for (i = 0; blocks[i] != 0; ++i) {
struct ntreg_hbin_block *block =
(struct ntreg_hbin_block *) (h->addr + blocks[i]);
if (block->id[0] == 'l' && (block->id[1] == 'f' || block->id[1] == 'h')) {
struct ntreg_lf_record *lf = (struct ntreg_lf_record *) block;
size_t nr_subkeys_in_lf = le16toh (lf->nr_keys);
for (j = 0; j < nr_subkeys_in_lf; ++j)
if (le32toh (lf->keys[j].offset) + 0x1000 == node) {
for (; j < nr_subkeys_in_lf - 1; ++j)
memcpy (&lf->keys[j], &lf->keys[j+1], sizeof (lf->keys[j]));
lf->nr_keys = htole16 (nr_subkeys_in_lf - 1);
goto found;
}
}
}
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_delete_child: could not find parent to child link\n");
errno = ENOTSUP;
return -1;
found:;
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + parent);
size_t nr_subkeys_in_nk = le32toh (nk->nr_subkeys);
nk->nr_subkeys = htole32 (nr_subkeys_in_nk - 1);
if (h->msglvl >= 2)
fprintf (stderr, "hivex_node_delete_child: updating nr_subkeys in parent 0x%zx to %zu\n",
parent, nr_subkeys_in_nk);
return 0;
}
int
hivex_node_set_values (hive_h *h, hive_node_h node,
size_t nr_values, const hive_set_value *values,
int flags)
{
if (!h->writable) {
errno = EROFS;
return -1;
}
if (!IS_VALID_BLOCK (h, node) || !BLOCK_ID_EQ (h, node, "nk")) {
errno = EINVAL;
return -1;
}
/* Delete all existing values. */
if (delete_values (h, node) == -1)
return -1;
if (nr_values == 0)
return 0;
/* Allocate value list node. Value lists have no id field. */
static const char nul_id[2] = { 0, 0 };
size_t seg_len =
sizeof (struct ntreg_value_list) + (nr_values - 1) * sizeof (uint32_t);
size_t vallist_offs = allocate_block (h, seg_len, nul_id);
if (vallist_offs == 0)
return -1;
struct ntreg_nk_record *nk = (struct ntreg_nk_record *) (h->addr + node);
nk->nr_values = htole32 (nr_values);
nk->vallist = htole32 (vallist_offs - 0x1000);
struct ntreg_value_list *vallist =
(struct ntreg_value_list *) (h->addr + vallist_offs);
size_t i;
for (i = 0; i < nr_values; ++i) {
/* Allocate vk record to store this (key, value) pair. */
static const char vk_id[2] = { 'v', 'k' };
seg_len = sizeof (struct ntreg_vk_record) + strlen (values[i].key);
size_t vk_offs = allocate_block (h, seg_len, vk_id);
if (vk_offs == 0)
return -1;
/* Recalculate pointers that could have been invalidated by
* previous call to allocate_block.
*/
nk = (struct ntreg_nk_record *) (h->addr + node);
vallist = (struct ntreg_value_list *) (h->addr + vallist_offs);
vallist->offset[i] = htole32 (vk_offs - 0x1000);
struct ntreg_vk_record *vk = (struct ntreg_vk_record *) (h->addr + vk_offs);
size_t name_len = strlen (values[i].key);
vk->name_len = htole16 (name_len);
strcpy (vk->name, values[i].key);
vk->data_type = htole32 (values[i].t);
uint32_t len = values[i].len;
if (len <= 4) /* store it inline => set MSB flag */
len |= 0x80000000;
vk->data_len = htole32 (len);
vk->flags = name_len == 0 ? 0 : 1;
if (values[i].len <= 4) /* store it inline */
memcpy (&vk->data_offset, values[i].value, values[i].len);
else {
size_t offs = allocate_block (h, values[i].len + 4, nul_id);
if (offs == 0)
return -1;
/* Recalculate pointers that could have been invalidated by
* previous call to allocate_block.
*/
nk = (struct ntreg_nk_record *) (h->addr + node);
vallist = (struct ntreg_value_list *) (h->addr + vallist_offs);
vk = (struct ntreg_vk_record *) (h->addr + vk_offs);
memcpy (h->addr + offs + 4, values[i].value, values[i].len);
vk->data_offset = htole32 (offs - 0x1000);
}
if (name_len * 2 > le32toh (nk->max_vk_name_len))
/* * 2 for UTF16-LE "reencoding" */
nk->max_vk_name_len = htole32 (name_len * 2);
if (values[i].len > le32toh (nk->max_vk_data_len))
nk->max_vk_data_len = htole32 (values[i].len);
}
return 0;
}
int
hivex_node_set_value (hive_h *h, hive_node_h node,
const hive_set_value *val, int flags)
{
hive_value_h *prev_values = hivex_node_values (h, node);
if (prev_values == NULL)
return -1;
int retval = -1;
size_t nr_values = 0;
for (hive_value_h *itr = prev_values; *itr != 0; ++itr)
++nr_values;
hive_set_value *values = malloc ((nr_values + 1) * (sizeof (hive_set_value)));
if (values == NULL)
goto leave_prev_values;
int alloc_ct = 0;
int idx_of_val = -1;
hive_value_h *prev_val;
for (prev_val = prev_values; *prev_val != 0; ++prev_val) {
size_t len;
hive_type t;
hive_set_value *value = &values[prev_val - prev_values];
char *valval = hivex_value_value (h, *prev_val, &t, &len);
if (valval == NULL) goto leave_partial;
++alloc_ct;
value->value = valval;
value->t = t;
value->len = len;
char *valkey = hivex_value_key (h, *prev_val);
if (valkey == NULL) goto leave_partial;
++alloc_ct;
value->key = valkey;
if (STRCASEEQ (valkey, val->key))
idx_of_val = prev_val - prev_values;
}
if (idx_of_val > -1) {
free (values[idx_of_val].key);
free (values[idx_of_val].value);
} else {
idx_of_val = nr_values;
++nr_values;
}
hive_set_value *value = &values[idx_of_val];
*value = (hive_set_value){
.key = strdup (val->key),
.value = malloc (val->len),
.len = val->len,
.t = val->t
};
if (value->key == NULL || value->value == NULL) goto leave_partial;
memcpy (value->value, val->value, val->len);
retval = hivex_node_set_values (h, node, nr_values, values, 0);
leave_partial:
for (int i = 0; i < alloc_ct; i += 2) {
if (values[i / 2].value != NULL)
free (values[i / 2].value);
if (i + 1 < alloc_ct && values[i / 2].key != NULL)
free (values[i / 2].key);
}
free (values);
leave_prev_values:
free (prev_values);
return retval;
}
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