4 * Read and write the per-WIM-image table of security descriptors.
8 * Copyright (C) 2012, 2013 Eric Biggers
10 * This file is part of wimlib, a library for working with WIM files.
12 * wimlib is free software; you can redistribute it and/or modify it under the
13 * terms of the GNU General Public License as published by the Free
14 * Software Foundation; either version 3 of the License, or (at your option)
17 * wimlib is distributed in the hope that it will be useful, but WITHOUT ANY
18 * WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
19 * A PARTICULAR PURPOSE. See the GNU General Public License for more
22 * You should have received a copy of the GNU General Public License
23 * along with wimlib; if not, see http://www.gnu.org/licenses/.
30 #include "wimlib/assert.h"
31 #include "wimlib/endianness.h"
32 #include "wimlib/error.h"
33 #include "wimlib/security.h"
34 #include "wimlib/security_descriptor.h"
35 #include "wimlib/sha1.h"
36 #include "wimlib/util.h"
38 struct wim_security_data_disk {
44 struct wim_security_data *
45 new_wim_security_data(void)
47 return CALLOC(1, sizeof(struct wim_security_data));
51 * Reads the security data from the metadata resource of a WIM image.
53 * @metadata_resource: An array that contains the uncompressed metadata
54 * resource for the WIM image.
55 * @metadata_resource_len: The length of @metadata_resource.
56 * @sd_ret: A pointer to a pointer to a wim_security_data structure that
57 * will be filled in with a pointer to a new wim_security_data
58 * structure containing the security data on success.
60 * Note: There is no `offset' argument because the security data is located at
61 * the beginning of the metadata resource.
64 * WIMLIB_ERR_SUCCESS (0)
65 * WIMLIB_ERR_INVALID_METADATA_RESOURCE
69 read_wim_security_data(const u8 metadata_resource[], size_t metadata_resource_len,
70 struct wim_security_data **sd_ret)
72 struct wim_security_data *sd;
76 u64 size_no_descriptors;
77 const struct wim_security_data_disk *sd_disk;
80 if (metadata_resource_len < 8)
81 return WIMLIB_ERR_INVALID_METADATA_RESOURCE;
83 sd = new_wim_security_data();
87 sd_disk = (const struct wim_security_data_disk*)metadata_resource;
88 sd->total_length = le32_to_cpu(sd_disk->total_length);
89 sd->num_entries = le32_to_cpu(sd_disk->num_entries);
91 DEBUG("Reading security data: num_entries=%u, total_length=%u",
92 sd->num_entries, sd->total_length);
94 /* Length field of 0 is a special case that really means length
96 if (sd->total_length == 0)
99 /* The security_id field of each dentry is a signed 32-bit integer, so
100 * the possible indices into the security descriptors table are 0
101 * through 0x7fffffff. Which means 0x80000000 security descriptors
102 * maximum. Not like you should ever have anywhere close to that many
103 * security descriptors! */
104 if (sd->num_entries > 0x80000000)
107 /* Verify the listed total length of the security data is big enough to
108 * include the sizes array, verify that the file data is big enough to
109 * include it as well, then allocate the array of sizes.
111 * Note: The total length of the security data must fit in a 32-bit
112 * integer, even though each security descriptor size is a 64-bit
113 * integer. This is stupid, and we need to be careful not to actually
114 * let the security descriptor sizes be over 0xffffffff. */
115 if (sd->total_length > metadata_resource_len)
118 sizes_size = (u64)sd->num_entries * sizeof(u64);
119 size_no_descriptors = 8 + sizes_size;
120 if (size_no_descriptors > sd->total_length)
123 total_len = size_no_descriptors;
125 /* Return immediately if no security descriptors. */
126 if (sd->num_entries == 0)
127 goto out_align_total_length;
129 /* Allocate a new buffer for the sizes array */
130 sd->sizes = MALLOC(sizes_size);
134 /* Copy the sizes array into the new buffer */
135 for (u32 i = 0; i < sd->num_entries; i++) {
136 sd->sizes[i] = le64_to_cpu(sd_disk->sizes[i]);
137 if (sd->sizes[i] > 0xffffffff)
141 p = (const u8*)sd_disk + size_no_descriptors;
143 /* Allocate the array of pointers to the security descriptors, then read
144 * them into separate buffers. */
145 sd->descriptors = CALLOC(sd->num_entries, sizeof(sd->descriptors[0]));
146 if (!sd->descriptors)
149 for (u32 i = 0; i < sd->num_entries; i++) {
150 if (sd->sizes[i] == 0)
152 total_len += sd->sizes[i];
153 if (total_len > (u64)sd->total_length)
155 sd->descriptors[i] = memdup(p, sd->sizes[i]);
156 if (!sd->descriptors[i])
160 out_align_total_length:
161 total_len = (total_len + 7) & ~7;
162 sd->total_length = (sd->total_length + 7) & ~7;
163 if (total_len != sd->total_length) {
164 WARNING("Expected WIM security data total length of "
165 "%u bytes, but calculated %u bytes",
166 sd->total_length, (unsigned)total_len);
172 ERROR("WIM security data is invalid!");
173 ret = WIMLIB_ERR_INVALID_METADATA_RESOURCE;
176 ERROR("Out of memory while reading WIM security data!");
177 ret = WIMLIB_ERR_NOMEM;
179 free_wim_security_data(sd);
185 * Writes the security data for a WIM image to an in-memory buffer.
188 write_wim_security_data(const struct wim_security_data * restrict sd,
191 DEBUG("Writing security data (total_length = %"PRIu32", num_entries "
192 "= %"PRIu32")", sd->total_length, sd->num_entries);
195 struct wim_security_data_disk *sd_disk = (struct wim_security_data_disk*)p;
196 u32 num_entries = sd->num_entries;
198 sd_disk->total_length = cpu_to_le32(sd->total_length);
199 sd_disk->num_entries = cpu_to_le32(num_entries);
201 for (u32 i = 0; i < num_entries; i++)
202 sd_disk->sizes[i] = cpu_to_le64(sd->sizes[i]);
204 p = (u8*)&sd_disk->sizes[num_entries];
206 for (u32 i = 0; i < num_entries; i++)
207 p = mempcpy(p, sd->descriptors[i], sd->sizes[i]);
209 while ((uintptr_t)p & 7)
212 wimlib_assert(p - orig_p == sd->total_length);
214 DEBUG("Successfully wrote security data.");
219 print_acl(const wimlib_ACL *acl, const tchar *type, size_t max_size)
223 if (max_size < sizeof(wimlib_ACL))
226 u8 revision = acl->revision;
227 u16 acl_size = le16_to_cpu(acl->acl_size);
228 u16 ace_count = le16_to_cpu(acl->ace_count);
230 tprintf(T(" [%"TS" ACL]\n"), type);
231 tprintf(T(" Revision = %u\n"), revision);
232 tprintf(T(" ACL Size = %u\n"), acl_size);
233 tprintf(T(" ACE Count = %u\n"), ace_count);
235 p = (const u8*)acl + sizeof(wimlib_ACL);
236 for (u16 i = 0; i < ace_count; i++) {
237 if (max_size < p + sizeof(wimlib_ACCESS_ALLOWED_ACE) - (const u8*)acl)
239 const wimlib_ACCESS_ALLOWED_ACE *aaa = (const wimlib_ACCESS_ALLOWED_ACE*)p;
240 tprintf(T(" [ACE]\n"));
241 tprintf(T(" ACE type = %d\n"), aaa->hdr.type);
242 tprintf(T(" ACE flags = 0x%x\n"), aaa->hdr.flags);
243 tprintf(T(" ACE size = %u\n"), le16_to_cpu(aaa->hdr.size));
244 tprintf(T(" ACE mask = %x\n"), le32_to_cpu(aaa->mask));
245 tprintf(T(" SID start = %u\n"), le32_to_cpu(aaa->sid_start));
246 p += le16_to_cpu(aaa->hdr.size);
252 print_sid(const wimlib_SID *sid, const tchar *type, size_t max_size)
254 if (max_size < sizeof(wimlib_SID))
257 tprintf(T(" [%"TS" SID]\n"), type);
258 tprintf(T(" Revision = %u\n"), sid->revision);
259 tprintf(T(" Subauthority count = %u\n"), sid->sub_authority_count);
260 tprintf(T(" Identifier authority = "));
261 print_byte_field(sid->identifier_authority,
262 sizeof(sid->identifier_authority), stdout);
264 if (max_size < sizeof(wimlib_SID) + (size_t)sid->sub_authority_count * sizeof(u32))
266 for (u8 i = 0; i < sid->sub_authority_count; i++) {
267 tprintf(T(" Subauthority %u = %u\n"),
268 i, le32_to_cpu(sid->sub_authority[i]));
274 print_security_descriptor(const wimlib_SECURITY_DESCRIPTOR_RELATIVE *descr,
277 u8 revision = descr->revision;
278 u16 control = le16_to_cpu(descr->control);
279 u32 owner_offset = le32_to_cpu(descr->owner_offset);
280 u32 group_offset = le32_to_cpu(descr->group_offset);
281 u32 dacl_offset = le32_to_cpu(descr->dacl_offset);
282 u32 sacl_offset = le32_to_cpu(descr->sacl_offset);
284 tprintf(T("Revision = %u\n"), revision);
285 tprintf(T("Security Descriptor Control = %#x\n"), control);
286 tprintf(T("Owner offset = %u\n"), owner_offset);
287 tprintf(T("Group offset = %u\n"), group_offset);
288 tprintf(T("Discretionary ACL offset = %u\n"), dacl_offset);
289 tprintf(T("System ACL offset = %u\n"), sacl_offset);
291 if (owner_offset != 0 && owner_offset <= size)
292 print_sid((const wimlib_SID*)((const u8*)descr + owner_offset),
293 T("Owner"), size - owner_offset);
295 if (group_offset != 0 && group_offset <= size)
296 print_sid((const wimlib_SID*)((const u8*)descr + group_offset),
297 T("Group"), size - group_offset);
299 if (dacl_offset != 0 && dacl_offset <= size)
300 print_acl((const wimlib_ACL*)((const u8*)descr + dacl_offset),
301 T("Discretionary"), size - dacl_offset);
303 if (sacl_offset != 0 && sacl_offset <= size)
304 print_acl((const wimlib_ACL*)((const u8*)descr + sacl_offset),
305 T("System"), size - sacl_offset);
309 * Prints the security data for a WIM file.
312 print_wim_security_data(const struct wim_security_data *sd)
314 tputs(T("[SECURITY DATA]"));
315 tprintf(T("Length = %"PRIu32" bytes\n"), sd->total_length);
316 tprintf(T("Number of Entries = %"PRIu32"\n"), sd->num_entries);
318 for (u32 i = 0; i < sd->num_entries; i++) {
319 tprintf(T("[SECURITY_DESCRIPTOR_RELATIVE %"PRIu32", length = %"PRIu64"]\n"),
321 print_security_descriptor((const wimlib_SECURITY_DESCRIPTOR_RELATIVE*)sd->descriptors[i],
329 free_wim_security_data(struct wim_security_data *sd)
332 u8 **descriptors = sd->descriptors;
333 u32 num_entries = sd->num_entries;
335 while (num_entries--)
336 FREE(*descriptors++);
338 FREE(sd->descriptors);
345 u8 hash[SHA1_HASH_SIZE];
346 struct rb_node rb_node;
350 free_sd_tree(struct rb_node *node)
353 free_sd_tree(node->rb_left);
354 free_sd_tree(node->rb_right);
355 FREE(container_of(node, struct sd_node, rb_node));
359 /* Frees a security descriptor index set. */
361 destroy_sd_set(struct wim_sd_set *sd_set, bool rollback)
364 struct wim_security_data *sd = sd_set->sd;
365 u8 **descriptors = sd->descriptors + sd_set->orig_num_entries;
366 u32 num_entries = sd->num_entries - sd_set->orig_num_entries;
367 while (num_entries--)
368 FREE(*descriptors++);
369 sd->num_entries = sd_set->orig_num_entries;
371 free_sd_tree(sd_set->rb_root.rb_node);
374 /* Inserts a a new node into the security descriptor index tree. */
376 insert_sd_node(struct wim_sd_set *set, struct sd_node *new)
378 struct rb_root *root = &set->rb_root;
379 struct rb_node **p = &(root->rb_node);
380 struct rb_node *rb_parent = NULL;
383 struct sd_node *this = container_of(*p, struct sd_node, rb_node);
384 int cmp = hashes_cmp(new->hash, this->hash);
388 p = &((*p)->rb_left);
390 p = &((*p)->rb_right);
392 return false; /* Duplicate security descriptor */
394 rb_link_node(&new->rb_node, rb_parent, p);
395 rb_insert_color(&new->rb_node, root);
399 /* Returns the index of the security descriptor having a SHA1 message digest of
400 * @hash. If not found, return -1. */
402 lookup_sd(struct wim_sd_set *set, const u8 hash[SHA1_HASH_SIZE])
404 struct rb_node *node = set->rb_root.rb_node;
407 struct sd_node *sd_node = container_of(node, struct sd_node, rb_node);
408 int cmp = hashes_cmp(hash, sd_node->hash);
410 node = node->rb_left;
412 node = node->rb_right;
414 return sd_node->security_id;
420 * Adds a security descriptor to the indexed security descriptor set as well as
421 * the corresponding `struct wim_security_data', and returns the new security
422 * ID; or, if there is an existing security descriptor that is the same, return
423 * the security ID for it. If a new security descriptor cannot be allocated,
427 sd_set_add_sd(struct wim_sd_set *sd_set, const char *descriptor, size_t size)
429 u8 hash[SHA1_HASH_SIZE];
435 struct wim_security_data *sd;
438 sha1_buffer(descriptor, size, hash);
440 security_id = lookup_sd(sd_set, hash);
441 if (security_id >= 0) /* Identical descriptor already exists */
444 /* Need to add a new security descriptor */
447 new = MALLOC(sizeof(*new));
451 descr_copy = memdup(descriptor, size);
456 new->security_id = sd->num_entries;
457 copy_hash(new->hash, hash);
459 /* There typically are only a few dozen security descriptors in a
460 * directory tree, so expanding the array of security descriptors by
461 * only 1 extra space each time should not be a problem. */
462 descriptors = REALLOC(sd->descriptors,
463 (sd->num_entries + 1) * sizeof(sd->descriptors[0]));
466 sd->descriptors = descriptors;
467 sizes = REALLOC(sd->sizes,
468 (sd->num_entries + 1) * sizeof(sd->sizes[0]));
472 sd->descriptors[sd->num_entries] = descr_copy;
473 sd->sizes[sd->num_entries] = size;
475 DEBUG("There are now %u security descriptors", sd->num_entries);
476 bret = insert_sd_node(sd_set, new);
478 security_id = new->security_id;
488 /* Initialize a `struct sd_set' mapping from SHA1 message digests of security
489 * descriptors to indices into the security descriptors table of the WIM image
492 init_sd_set(struct wim_sd_set *sd_set, struct wim_security_data *sd)
497 sd_set->rb_root.rb_node = NULL;
499 /* Remember the original number of security descriptors so that newly
500 * added ones can be rolled back if needed. */
501 sd_set->orig_num_entries = sd->num_entries;
502 for (u32 i = 0; i < sd->num_entries; i++) {
505 new = MALLOC(sizeof(struct sd_node));
507 ret = WIMLIB_ERR_NOMEM;
508 goto out_destroy_sd_set;
510 sha1_buffer(sd->descriptors[i], sd->sizes[i], new->hash);
511 new->security_id = i;
512 if (!insert_sd_node(sd_set, new))
513 FREE(new); /* Ignore duplicate security descriptor */
518 destroy_sd_set(sd_set, false);