1/* SPDX-License-Identifier: GPL-2.0-or-later */ 2/* 3 * layout.h - All NTFS associated on-disk structures. Part of the Linux-NTFS 4 * project. 5 * 6 * Copyright (c) 2001-2005 Anton Altaparmakov 7 * Copyright (c) 2002 Richard Russon 8 */ 9 10#ifndef _LINUX_NTFS_LAYOUT_H 11#define _LINUX_NTFS_LAYOUT_H 12 13#include <linux/types.h> 14#include <linux/bitops.h> 15#include <linux/list.h> 16#include <asm/byteorder.h> 17 18#include "types.h" 19 20/* The NTFS oem_id "NTFS " */ 21#define magicNTFS cpu_to_le64(0x202020205346544eULL) 22 23/* 24 * Location of bootsector on partition: 25 * The standard NTFS_BOOT_SECTOR is on sector 0 of the partition. 26 * On NT4 and above there is one backup copy of the boot sector to 27 * be found on the last sector of the partition (not normally accessible 28 * from within Windows as the bootsector contained number of sectors 29 * value is one less than the actual value!). 30 * On versions of NT 3.51 and earlier, the backup copy was located at 31 * number of sectors/2 (integer divide), i.e. in the middle of the volume. 32 */ 33 34/* 35 * BIOS parameter block (bpb) structure. 36 */ 37typedef struct { 38 le16 bytes_per_sector; /* Size of a sector in bytes. */ 39 u8 sectors_per_cluster; /* Size of a cluster in sectors. */ 40 le16 reserved_sectors; /* zero */ 41 u8 fats; /* zero */ 42 le16 root_entries; /* zero */ 43 le16 sectors; /* zero */ 44 u8 media_type; /* 0xf8 = hard disk */ 45 le16 sectors_per_fat; /* zero */ 46 le16 sectors_per_track; /* irrelevant */ 47 le16 heads; /* irrelevant */ 48 le32 hidden_sectors; /* zero */ 49 le32 large_sectors; /* zero */ 50} __attribute__ ((__packed__)) BIOS_PARAMETER_BLOCK; 51 52/* 53 * NTFS boot sector structure. 54 */ 55typedef struct { 56 u8 jump[3]; /* Irrelevant (jump to boot up code).*/ 57 le64 oem_id; /* Magic "NTFS ". */ 58 BIOS_PARAMETER_BLOCK bpb; /* See BIOS_PARAMETER_BLOCK. */ 59 u8 unused[4]; /* zero, NTFS diskedit.exe states that 60 this is actually: 61 __u8 physical_drive; // 0x80 62 __u8 current_head; // zero 63 __u8 extended_boot_signature; 64 // 0x80 65 __u8 unused; // zero 66 */ 67/*0x28*/sle64 number_of_sectors; /* Number of sectors in volume. Gives 68 maximum volume size of 2^63 sectors. 69 Assuming standard sector size of 512 70 bytes, the maximum byte size is 71 approx. 4.7x10^21 bytes. (-; */ 72 sle64 mft_lcn; /* Cluster location of mft data. */ 73 sle64 mftmirr_lcn; /* Cluster location of copy of mft. */ 74 s8 clusters_per_mft_record; /* Mft record size in clusters. */ 75 u8 reserved0[3]; /* zero */ 76 s8 clusters_per_index_record; /* Index block size in clusters. */ 77 u8 reserved1[3]; /* zero */ 78 le64 volume_serial_number; /* Irrelevant (serial number). */ 79 le32 checksum; /* Boot sector checksum. */ 80/*0x54*/u8 bootstrap[426]; /* Irrelevant (boot up code). */ 81 le16 end_of_sector_marker; /* End of bootsector magic. Always is 82 0xaa55 in little endian. */ 83/* sizeof() = 512 (0x200) bytes */ 84} __attribute__ ((__packed__)) NTFS_BOOT_SECTOR; 85 86/* 87 * Magic identifiers present at the beginning of all ntfs record containing 88 * records (like mft records for example). 89 */ 90enum { 91 /* Found in $MFT/$DATA. */ 92 magic_FILE = cpu_to_le32(0x454c4946), /* Mft entry. */ 93 magic_INDX = cpu_to_le32(0x58444e49), /* Index buffer. */ 94 magic_HOLE = cpu_to_le32(0x454c4f48), /* ? (NTFS 3.0+?) */ 95 96 /* Found in $LogFile/$DATA. */ 97 magic_RSTR = cpu_to_le32(0x52545352), /* Restart page. */ 98 magic_RCRD = cpu_to_le32(0x44524352), /* Log record page. */ 99 100 /* Found in $LogFile/$DATA. (May be found in $MFT/$DATA, also?) */ 101 magic_CHKD = cpu_to_le32(0x444b4843), /* Modified by chkdsk. */ 102 103 /* Found in all ntfs record containing records. */ 104 magic_BAAD = cpu_to_le32(0x44414142), /* Failed multi sector 105 transfer was detected. */ 106 /* 107 * Found in $LogFile/$DATA when a page is full of 0xff bytes and is 108 * thus not initialized. Page must be initialized before using it. 109 */ 110 magic_empty = cpu_to_le32(0xffffffff) /* Record is empty. */ 111}; 112 113typedef le32 NTFS_RECORD_TYPE; 114 115/* 116 * Generic magic comparison macros. Finally found a use for the ## preprocessor 117 * operator! (-8 118 */ 119 120static inline bool __ntfs_is_magic(le32 x, NTFS_RECORD_TYPE r) 121{ 122 return (x == r); 123} 124#define ntfs_is_magic(x, m) __ntfs_is_magic(x, magic_##m) 125 126static inline bool __ntfs_is_magicp(le32 *p, NTFS_RECORD_TYPE r) 127{ 128 return (*p == r); 129} 130#define ntfs_is_magicp(p, m) __ntfs_is_magicp(p, magic_##m) 131 132/* 133 * Specialised magic comparison macros for the NTFS_RECORD_TYPEs defined above. 134 */ 135#define ntfs_is_file_record(x) ( ntfs_is_magic (x, FILE) ) 136#define ntfs_is_file_recordp(p) ( ntfs_is_magicp(p, FILE) ) 137#define ntfs_is_mft_record(x) ( ntfs_is_file_record (x) ) 138#define ntfs_is_mft_recordp(p) ( ntfs_is_file_recordp(p) ) 139#define ntfs_is_indx_record(x) ( ntfs_is_magic (x, INDX) ) 140#define ntfs_is_indx_recordp(p) ( ntfs_is_magicp(p, INDX) ) 141#define ntfs_is_hole_record(x) ( ntfs_is_magic (x, HOLE) ) 142#define ntfs_is_hole_recordp(p) ( ntfs_is_magicp(p, HOLE) ) 143 144#define ntfs_is_rstr_record(x) ( ntfs_is_magic (x, RSTR) ) 145#define ntfs_is_rstr_recordp(p) ( ntfs_is_magicp(p, RSTR) ) 146#define ntfs_is_rcrd_record(x) ( ntfs_is_magic (x, RCRD) ) 147#define ntfs_is_rcrd_recordp(p) ( ntfs_is_magicp(p, RCRD) ) 148 149#define ntfs_is_chkd_record(x) ( ntfs_is_magic (x, CHKD) ) 150#define ntfs_is_chkd_recordp(p) ( ntfs_is_magicp(p, CHKD) ) 151 152#define ntfs_is_baad_record(x) ( ntfs_is_magic (x, BAAD) ) 153#define ntfs_is_baad_recordp(p) ( ntfs_is_magicp(p, BAAD) ) 154 155#define ntfs_is_empty_record(x) ( ntfs_is_magic (x, empty) ) 156#define ntfs_is_empty_recordp(p) ( ntfs_is_magicp(p, empty) ) 157 158/* 159 * The Update Sequence Array (usa) is an array of the le16 values which belong 160 * to the end of each sector protected by the update sequence record in which 161 * this array is contained. Note that the first entry is the Update Sequence 162 * Number (usn), a cyclic counter of how many times the protected record has 163 * been written to disk. The values 0 and -1 (ie. 0xffff) are not used. All 164 * last le16's of each sector have to be equal to the usn (during reading) or 165 * are set to it (during writing). If they are not, an incomplete multi sector 166 * transfer has occurred when the data was written. 167 * The maximum size for the update sequence array is fixed to: 168 * maximum size = usa_ofs + (usa_count * 2) = 510 bytes 169 * The 510 bytes comes from the fact that the last le16 in the array has to 170 * (obviously) finish before the last le16 of the first 512-byte sector. 171 * This formula can be used as a consistency check in that usa_ofs + 172 * (usa_count * 2) has to be less than or equal to 510. 173 */ 174typedef struct { 175 NTFS_RECORD_TYPE magic; /* A four-byte magic identifying the record 176 type and/or status. */ 177 le16 usa_ofs; /* Offset to the Update Sequence Array (usa) 178 from the start of the ntfs record. */ 179 le16 usa_count; /* Number of le16 sized entries in the usa 180 including the Update Sequence Number (usn), 181 thus the number of fixups is the usa_count 182 minus 1. */ 183} __attribute__ ((__packed__)) NTFS_RECORD; 184 185/* 186 * System files mft record numbers. All these files are always marked as used 187 * in the bitmap attribute of the mft; presumably in order to avoid accidental 188 * allocation for random other mft records. Also, the sequence number for each 189 * of the system files is always equal to their mft record number and it is 190 * never modified. 191 */ 192typedef enum { 193 FILE_MFT = 0, /* Master file table (mft). Data attribute 194 contains the entries and bitmap attribute 195 records which ones are in use (bit==1). */ 196 FILE_MFTMirr = 1, /* Mft mirror: copy of first four mft records 197 in data attribute. If cluster size > 4kiB, 198 copy of first N mft records, with 199 N = cluster_size / mft_record_size. */ 200 FILE_LogFile = 2, /* Journalling log in data attribute. */ 201 FILE_Volume = 3, /* Volume name attribute and volume information 202 attribute (flags and ntfs version). Windows 203 refers to this file as volume DASD (Direct 204 Access Storage Device). */ 205 FILE_AttrDef = 4, /* Array of attribute definitions in data 206 attribute. */ 207 FILE_root = 5, /* Root directory. */ 208 FILE_Bitmap = 6, /* Allocation bitmap of all clusters (lcns) in 209 data attribute. */ 210 FILE_Boot = 7, /* Boot sector (always at cluster 0) in data 211 attribute. */ 212 FILE_BadClus = 8, /* Contains all bad clusters in the non-resident 213 data attribute. */ 214 FILE_Secure = 9, /* Shared security descriptors in data attribute 215 and two indexes into the descriptors. 216 Appeared in Windows 2000. Before that, this 217 file was named $Quota but was unused. */ 218 FILE_UpCase = 10, /* Uppercase equivalents of all 65536 Unicode 219 characters in data attribute. */ 220 FILE_Extend = 11, /* Directory containing other system files (eg. 221 $ObjId, $Quota, $Reparse and $UsnJrnl). This 222 is new to NTFS3.0. */ 223 FILE_reserved12 = 12, /* Reserved for future use (records 12-15). */ 224 FILE_reserved13 = 13, 225 FILE_reserved14 = 14, 226 FILE_reserved15 = 15, 227 FILE_first_user = 16, /* First user file, used as test limit for 228 whether to allow opening a file or not. */ 229} NTFS_SYSTEM_FILES; 230 231/* 232 * These are the so far known MFT_RECORD_* flags (16-bit) which contain 233 * information about the mft record in which they are present. 234 */ 235enum { 236 MFT_RECORD_IN_USE = cpu_to_le16(0x0001), 237 MFT_RECORD_IS_DIRECTORY = cpu_to_le16(0x0002), 238} __attribute__ ((__packed__)); 239 240typedef le16 MFT_RECORD_FLAGS; 241 242/* 243 * mft references (aka file references or file record segment references) are 244 * used whenever a structure needs to refer to a record in the mft. 245 * 246 * A reference consists of a 48-bit index into the mft and a 16-bit sequence 247 * number used to detect stale references. 248 * 249 * For error reporting purposes we treat the 48-bit index as a signed quantity. 250 * 251 * The sequence number is a circular counter (skipping 0) describing how many 252 * times the referenced mft record has been (re)used. This has to match the 253 * sequence number of the mft record being referenced, otherwise the reference 254 * is considered stale and removed (FIXME: only ntfsck or the driver itself?). 255 * 256 * If the sequence number is zero it is assumed that no sequence number 257 * consistency checking should be performed. 258 * 259 * FIXME: Since inodes are 32-bit as of now, the driver needs to always check 260 * for high_part being 0 and if not either BUG(), cause a panic() or handle 261 * the situation in some other way. This shouldn't be a problem as a volume has 262 * to become HUGE in order to need more than 32-bits worth of mft records. 263 * Assuming the standard mft record size of 1kb only the records (never mind 264 * the non-resident attributes, etc.) would require 4Tb of space on their own 265 * for the first 32 bits worth of records. This is only if some strange person 266 * doesn't decide to foul play and make the mft sparse which would be a really 267 * horrible thing to do as it would trash our current driver implementation. )-: 268 * Do I hear screams "we want 64-bit inodes!" ?!? (-; 269 * 270 * FIXME: The mft zone is defined as the first 12% of the volume. This space is 271 * reserved so that the mft can grow contiguously and hence doesn't become 272 * fragmented. Volume free space includes the empty part of the mft zone and 273 * when the volume's free 88% are used up, the mft zone is shrunk by a factor 274 * of 2, thus making more space available for more files/data. This process is 275 * repeated every time there is no more free space except for the mft zone until 276 * there really is no more free space. 277 */ 278 279/* 280 * Typedef the MFT_REF as a 64-bit value for easier handling. 281 * Also define two unpacking macros to get to the reference (MREF) and 282 * sequence number (MSEQNO) respectively. 283 * The _LE versions are to be applied on little endian MFT_REFs. 284 * Note: The _LE versions will return a CPU endian formatted value! 285 */ 286#define MFT_REF_MASK_CPU 0x0000ffffffffffffULL 287#define MFT_REF_MASK_LE cpu_to_le64(MFT_REF_MASK_CPU) 288 289typedef u64 MFT_REF; 290typedef le64 leMFT_REF; 291 292#define MK_MREF(m, s) ((MFT_REF)(((MFT_REF)(s) << 48) | \ 293 ((MFT_REF)(m) & MFT_REF_MASK_CPU))) 294#define MK_LE_MREF(m, s) cpu_to_le64(MK_MREF(m, s)) 295 296#define MREF(x) ((unsigned long)((x) & MFT_REF_MASK_CPU)) 297#define MSEQNO(x) ((u16)(((x) >> 48) & 0xffff)) 298#define MREF_LE(x) ((unsigned long)(le64_to_cpu(x) & MFT_REF_MASK_CPU)) 299#define MSEQNO_LE(x) ((u16)((le64_to_cpu(x) >> 48) & 0xffff)) 300 301#define IS_ERR_MREF(x) (((x) & 0x0000800000000000ULL) ? true : false) 302#define ERR_MREF(x) ((u64)((s64)(x))) 303#define MREF_ERR(x) ((int)((s64)(x))) 304 305/* 306 * The mft record header present at the beginning of every record in the mft. 307 * This is followed by a sequence of variable length attribute records which 308 * is terminated by an attribute of type AT_END which is a truncated attribute 309 * in that it only consists of the attribute type code AT_END and none of the 310 * other members of the attribute structure are present. 311 */ 312typedef struct { 313/*Ofs*/ 314/* 0 NTFS_RECORD; -- Unfolded here as gcc doesn't like unnamed structs. */ 315 NTFS_RECORD_TYPE magic; /* Usually the magic is "FILE". */ 316 le16 usa_ofs; /* See NTFS_RECORD definition above. */ 317 le16 usa_count; /* See NTFS_RECORD definition above. */ 318 319/* 8*/ le64 lsn; /* $LogFile sequence number for this record. 320 Changed every time the record is modified. */ 321/* 16*/ le16 sequence_number; /* Number of times this mft record has been 322 reused. (See description for MFT_REF 323 above.) NOTE: The increment (skipping zero) 324 is done when the file is deleted. NOTE: If 325 this is zero it is left zero. */ 326/* 18*/ le16 link_count; /* Number of hard links, i.e. the number of 327 directory entries referencing this record. 328 NOTE: Only used in mft base records. 329 NOTE: When deleting a directory entry we 330 check the link_count and if it is 1 we 331 delete the file. Otherwise we delete the 332 FILE_NAME_ATTR being referenced by the 333 directory entry from the mft record and 334 decrement the link_count. 335 FIXME: Careful with Win32 + DOS names! */ 336/* 20*/ le16 attrs_offset; /* Byte offset to the first attribute in this 337 mft record from the start of the mft record. 338 NOTE: Must be aligned to 8-byte boundary. */ 339/* 22*/ MFT_RECORD_FLAGS flags; /* Bit array of MFT_RECORD_FLAGS. When a file 340 is deleted, the MFT_RECORD_IN_USE flag is 341 set to zero. */ 342/* 24*/ le32 bytes_in_use; /* Number of bytes used in this mft record. 343 NOTE: Must be aligned to 8-byte boundary. */ 344/* 28*/ le32 bytes_allocated; /* Number of bytes allocated for this mft 345 record. This should be equal to the mft 346 record size. */ 347/* 32*/ leMFT_REF base_mft_record;/* This is zero for base mft records. 348 When it is not zero it is a mft reference 349 pointing to the base mft record to which 350 this record belongs (this is then used to 351 locate the attribute list attribute present 352 in the base record which describes this 353 extension record and hence might need 354 modification when the extension record 355 itself is modified, also locating the 356 attribute list also means finding the other 357 potential extents, belonging to the non-base 358 mft record). */ 359/* 40*/ le16 next_attr_instance;/* The instance number that will be assigned to 360 the next attribute added to this mft record. 361 NOTE: Incremented each time after it is used. 362 NOTE: Every time the mft record is reused 363 this number is set to zero. NOTE: The first 364 instance number is always 0. */ 365/* The below fields are specific to NTFS 3.1+ (Windows XP and above): */ 366/* 42*/ le16 reserved; /* Reserved/alignment. */ 367/* 44*/ le32 mft_record_number; /* Number of this mft record. */ 368/* sizeof() = 48 bytes */ 369/* 370 * When (re)using the mft record, we place the update sequence array at this 371 * offset, i.e. before we start with the attributes. This also makes sense, 372 * otherwise we could run into problems with the update sequence array 373 * containing in itself the last two bytes of a sector which would mean that 374 * multi sector transfer protection wouldn't work. As you can't protect data 375 * by overwriting it since you then can't get it back... 376 * When reading we obviously use the data from the ntfs record header. 377 */ 378} __attribute__ ((__packed__)) MFT_RECORD; 379 380/* This is the version without the NTFS 3.1+ specific fields. */ 381typedef struct { 382/*Ofs*/ 383/* 0 NTFS_RECORD; -- Unfolded here as gcc doesn't like unnamed structs. */ 384 NTFS_RECORD_TYPE magic; /* Usually the magic is "FILE". */ 385 le16 usa_ofs; /* See NTFS_RECORD definition above. */ 386 le16 usa_count; /* See NTFS_RECORD definition above. */ 387 388/* 8*/ le64 lsn; /* $LogFile sequence number for this record. 389 Changed every time the record is modified. */ 390/* 16*/ le16 sequence_number; /* Number of times this mft record has been 391 reused. (See description for MFT_REF 392 above.) NOTE: The increment (skipping zero) 393 is done when the file is deleted. NOTE: If 394 this is zero it is left zero. */ 395/* 18*/ le16 link_count; /* Number of hard links, i.e. the number of 396 directory entries referencing this record. 397 NOTE: Only used in mft base records. 398 NOTE: When deleting a directory entry we 399 check the link_count and if it is 1 we 400 delete the file. Otherwise we delete the 401 FILE_NAME_ATTR being referenced by the 402 directory entry from the mft record and 403 decrement the link_count. 404 FIXME: Careful with Win32 + DOS names! */ 405/* 20*/ le16 attrs_offset; /* Byte offset to the first attribute in this 406 mft record from the start of the mft record. 407 NOTE: Must be aligned to 8-byte boundary. */ 408/* 22*/ MFT_RECORD_FLAGS flags; /* Bit array of MFT_RECORD_FLAGS. When a file 409 is deleted, the MFT_RECORD_IN_USE flag is 410 set to zero. */ 411/* 24*/ le32 bytes_in_use; /* Number of bytes used in this mft record. 412 NOTE: Must be aligned to 8-byte boundary. */ 413/* 28*/ le32 bytes_allocated; /* Number of bytes allocated for this mft 414 record. This should be equal to the mft 415 record size. */ 416/* 32*/ leMFT_REF base_mft_record;/* This is zero for base mft records. 417 When it is not zero it is a mft reference 418 pointing to the base mft record to which 419 this record belongs (this is then used to 420 locate the attribute list attribute present 421 in the base record which describes this 422 extension record and hence might need 423 modification when the extension record 424 itself is modified, also locating the 425 attribute list also means finding the other 426 potential extents, belonging to the non-base 427 mft record). */ 428/* 40*/ le16 next_attr_instance;/* The instance number that will be assigned to 429 the next attribute added to this mft record. 430 NOTE: Incremented each time after it is used. 431 NOTE: Every time the mft record is reused 432 this number is set to zero. NOTE: The first 433 instance number is always 0. */ 434/* sizeof() = 42 bytes */ 435/* 436 * When (re)using the mft record, we place the update sequence array at this 437 * offset, i.e. before we start with the attributes. This also makes sense, 438 * otherwise we could run into problems with the update sequence array 439 * containing in itself the last two bytes of a sector which would mean that 440 * multi sector transfer protection wouldn't work. As you can't protect data 441 * by overwriting it since you then can't get it back... 442 * When reading we obviously use the data from the ntfs record header. 443 */ 444} __attribute__ ((__packed__)) MFT_RECORD_OLD; 445 446/* 447 * System defined attributes (32-bit). Each attribute type has a corresponding 448 * attribute name (Unicode string of maximum 64 character length) as described 449 * by the attribute definitions present in the data attribute of the $AttrDef 450 * system file. On NTFS 3.0 volumes the names are just as the types are named 451 * in the below defines exchanging AT_ for the dollar sign ($). If that is not 452 * a revealing choice of symbol I do not know what is... (-; 453 */ 454enum { 455 AT_UNUSED = cpu_to_le32( 0), 456 AT_STANDARD_INFORMATION = cpu_to_le32( 0x10), 457 AT_ATTRIBUTE_LIST = cpu_to_le32( 0x20), 458 AT_FILE_NAME = cpu_to_le32( 0x30), 459 AT_OBJECT_ID = cpu_to_le32( 0x40), 460 AT_SECURITY_DESCRIPTOR = cpu_to_le32( 0x50), 461 AT_VOLUME_NAME = cpu_to_le32( 0x60), 462 AT_VOLUME_INFORMATION = cpu_to_le32( 0x70), 463 AT_DATA = cpu_to_le32( 0x80), 464 AT_INDEX_ROOT = cpu_to_le32( 0x90), 465 AT_INDEX_ALLOCATION = cpu_to_le32( 0xa0), 466 AT_BITMAP = cpu_to_le32( 0xb0), 467 AT_REPARSE_POINT = cpu_to_le32( 0xc0), 468 AT_EA_INFORMATION = cpu_to_le32( 0xd0), 469 AT_EA = cpu_to_le32( 0xe0), 470 AT_PROPERTY_SET = cpu_to_le32( 0xf0), 471 AT_LOGGED_UTILITY_STREAM = cpu_to_le32( 0x100), 472 AT_FIRST_USER_DEFINED_ATTRIBUTE = cpu_to_le32( 0x1000), 473 AT_END = cpu_to_le32(0xffffffff) 474}; 475 476typedef le32 ATTR_TYPE; 477 478/* 479 * The collation rules for sorting views/indexes/etc (32-bit). 480 * 481 * COLLATION_BINARY - Collate by binary compare where the first byte is most 482 * significant. 483 * COLLATION_UNICODE_STRING - Collate Unicode strings by comparing their binary 484 * Unicode values, except that when a character can be uppercased, the 485 * upper case value collates before the lower case one. 486 * COLLATION_FILE_NAME - Collate file names as Unicode strings. The collation 487 * is done very much like COLLATION_UNICODE_STRING. In fact I have no idea 488 * what the difference is. Perhaps the difference is that file names 489 * would treat some special characters in an odd way (see 490 * unistr.c::ntfs_collate_names() and unistr.c::legal_ansi_char_array[] 491 * for what I mean but COLLATION_UNICODE_STRING would not give any special 492 * treatment to any characters at all, but this is speculation. 493 * COLLATION_NTOFS_ULONG - Sorting is done according to ascending le32 key 494 * values. E.g. used for $SII index in FILE_Secure, which sorts by 495 * security_id (le32). 496 * COLLATION_NTOFS_SID - Sorting is done according to ascending SID values. 497 * E.g. used for $O index in FILE_Extend/$Quota. 498 * COLLATION_NTOFS_SECURITY_HASH - Sorting is done first by ascending hash 499 * values and second by ascending security_id values. E.g. used for $SDH 500 * index in FILE_Secure. 501 * COLLATION_NTOFS_ULONGS - Sorting is done according to a sequence of ascending 502 * le32 key values. E.g. used for $O index in FILE_Extend/$ObjId, which 503 * sorts by object_id (16-byte), by splitting up the object_id in four 504 * le32 values and using them as individual keys. E.g. take the following 505 * two security_ids, stored as follows on disk: 506 * 1st: a1 61 65 b7 65 7b d4 11 9e 3d 00 e0 81 10 42 59 507 * 2nd: 38 14 37 d2 d2 f3 d4 11 a5 21 c8 6b 79 b1 97 45 508 * To compare them, they are split into four le32 values each, like so: 509 * 1st: 0xb76561a1 0x11d47b65 0xe0003d9e 0x59421081 510 * 2nd: 0xd2371438 0x11d4f3d2 0x6bc821a5 0x4597b179 511 * Now, it is apparent why the 2nd object_id collates after the 1st: the 512 * first le32 value of the 1st object_id is less than the first le32 of 513 * the 2nd object_id. If the first le32 values of both object_ids were 514 * equal then the second le32 values would be compared, etc. 515 */ 516enum { 517 COLLATION_BINARY = cpu_to_le32(0x00), 518 COLLATION_FILE_NAME = cpu_to_le32(0x01), 519 COLLATION_UNICODE_STRING = cpu_to_le32(0x02), 520 COLLATION_NTOFS_ULONG = cpu_to_le32(0x10), 521 COLLATION_NTOFS_SID = cpu_to_le32(0x11), 522 COLLATION_NTOFS_SECURITY_HASH = cpu_to_le32(0x12), 523 COLLATION_NTOFS_ULONGS = cpu_to_le32(0x13), 524}; 525 526typedef le32 COLLATION_RULE; 527 528/* 529 * The flags (32-bit) describing attribute properties in the attribute 530 * definition structure. FIXME: This information is based on Regis's 531 * information and, according to him, it is not certain and probably 532 * incomplete. The INDEXABLE flag is fairly certainly correct as only the file 533 * name attribute has this flag set and this is the only attribute indexed in 534 * NT4. 535 */ 536enum { 537 ATTR_DEF_INDEXABLE = cpu_to_le32(0x02), /* Attribute can be 538 indexed. */ 539 ATTR_DEF_MULTIPLE = cpu_to_le32(0x04), /* Attribute type 540 can be present multiple times in the 541 mft records of an inode. */ 542 ATTR_DEF_NOT_ZERO = cpu_to_le32(0x08), /* Attribute value 543 must contain at least one non-zero 544 byte. */ 545 ATTR_DEF_INDEXED_UNIQUE = cpu_to_le32(0x10), /* Attribute must be 546 indexed and the attribute value must be 547 unique for the attribute type in all of 548 the mft records of an inode. */ 549 ATTR_DEF_NAMED_UNIQUE = cpu_to_le32(0x20), /* Attribute must be 550 named and the name must be unique for 551 the attribute type in all of the mft 552 records of an inode. */ 553 ATTR_DEF_RESIDENT = cpu_to_le32(0x40), /* Attribute must be 554 resident. */ 555 ATTR_DEF_ALWAYS_LOG = cpu_to_le32(0x80), /* Always log 556 modifications to this attribute, 557 regardless of whether it is resident or 558 non-resident. Without this, only log 559 modifications if the attribute is 560 resident. */ 561}; 562 563typedef le32 ATTR_DEF_FLAGS; 564 565/* 566 * The data attribute of FILE_AttrDef contains a sequence of attribute 567 * definitions for the NTFS volume. With this, it is supposed to be safe for an 568 * older NTFS driver to mount a volume containing a newer NTFS version without 569 * damaging it (that's the theory. In practice it's: not damaging it too much). 570 * Entries are sorted by attribute type. The flags describe whether the 571 * attribute can be resident/non-resident and possibly other things, but the 572 * actual bits are unknown. 573 */ 574typedef struct { 575/*hex ofs*/ 576/* 0*/ ntfschar name[0x40]; /* Unicode name of the attribute. Zero 577 terminated. */ 578/* 80*/ ATTR_TYPE type; /* Type of the attribute. */ 579/* 84*/ le32 display_rule; /* Default display rule. 580 FIXME: What does it mean? (AIA) */ 581/* 88*/ COLLATION_RULE collation_rule; /* Default collation rule. */ 582/* 8c*/ ATTR_DEF_FLAGS flags; /* Flags describing the attribute. */ 583/* 90*/ sle64 min_size; /* Optional minimum attribute size. */ 584/* 98*/ sle64 max_size; /* Maximum size of attribute. */ 585/* sizeof() = 0xa0 or 160 bytes */ 586} __attribute__ ((__packed__)) ATTR_DEF; 587 588/* 589 * Attribute flags (16-bit). 590 */ 591enum { 592 ATTR_IS_COMPRESSED = cpu_to_le16(0x0001), 593 ATTR_COMPRESSION_MASK = cpu_to_le16(0x00ff), /* Compression method 594 mask. Also, first 595 illegal value. */ 596 ATTR_IS_ENCRYPTED = cpu_to_le16(0x4000), 597 ATTR_IS_SPARSE = cpu_to_le16(0x8000), 598} __attribute__ ((__packed__)); 599 600typedef le16 ATTR_FLAGS; 601 602/* 603 * Attribute compression. 604 * 605 * Only the data attribute is ever compressed in the current ntfs driver in 606 * Windows. Further, compression is only applied when the data attribute is 607 * non-resident. Finally, to use compression, the maximum allowed cluster size 608 * on a volume is 4kib. 609 * 610 * The compression method is based on independently compressing blocks of X 611 * clusters, where X is determined from the compression_unit value found in the 612 * non-resident attribute record header (more precisely: X = 2^compression_unit 613 * clusters). On Windows NT/2k, X always is 16 clusters (compression_unit = 4). 614 * 615 * There are three different cases of how a compression block of X clusters 616 * can be stored: 617 * 618 * 1) The data in the block is all zero (a sparse block): 619 * This is stored as a sparse block in the runlist, i.e. the runlist 620 * entry has length = X and lcn = -1. The mapping pairs array actually 621 * uses a delta_lcn value length of 0, i.e. delta_lcn is not present at 622 * all, which is then interpreted by the driver as lcn = -1. 623 * NOTE: Even uncompressed files can be sparse on NTFS 3.0 volumes, then 624 * the same principles apply as above, except that the length is not 625 * restricted to being any particular value. 626 * 627 * 2) The data in the block is not compressed: 628 * This happens when compression doesn't reduce the size of the block 629 * in clusters. I.e. if compression has a small effect so that the 630 * compressed data still occupies X clusters, then the uncompressed data 631 * is stored in the block. 632 * This case is recognised by the fact that the runlist entry has 633 * length = X and lcn >= 0. The mapping pairs array stores this as 634 * normal with a run length of X and some specific delta_lcn, i.e. 635 * delta_lcn has to be present. 636 * 637 * 3) The data in the block is compressed: 638 * The common case. This case is recognised by the fact that the run 639 * list entry has length L < X and lcn >= 0. The mapping pairs array 640 * stores this as normal with a run length of X and some specific 641 * delta_lcn, i.e. delta_lcn has to be present. This runlist entry is 642 * immediately followed by a sparse entry with length = X - L and 643 * lcn = -1. The latter entry is to make up the vcn counting to the 644 * full compression block size X. 645 * 646 * In fact, life is more complicated because adjacent entries of the same type 647 * can be coalesced. This means that one has to keep track of the number of 648 * clusters handled and work on a basis of X clusters at a time being one 649 * block. An example: if length L > X this means that this particular runlist 650 * entry contains a block of length X and part of one or more blocks of length 651 * L - X. Another example: if length L < X, this does not necessarily mean that 652 * the block is compressed as it might be that the lcn changes inside the block 653 * and hence the following runlist entry describes the continuation of the 654 * potentially compressed block. The block would be compressed if the 655 * following runlist entry describes at least X - L sparse clusters, thus 656 * making up the compression block length as described in point 3 above. (Of 657 * course, there can be several runlist entries with small lengths so that the 658 * sparse entry does not follow the first data containing entry with 659 * length < X.) 660 * 661 * NOTE: At the end of the compressed attribute value, there most likely is not 662 * just the right amount of data to make up a compression block, thus this data 663 * is not even attempted to be compressed. It is just stored as is, unless 664 * the number of clusters it occupies is reduced when compressed in which case 665 * it is stored as a compressed compression block, complete with sparse 666 * clusters at the end. 667 */ 668 669/* 670 * Flags of resident attributes (8-bit). 671 */ 672enum { 673 RESIDENT_ATTR_IS_INDEXED = 0x01, /* Attribute is referenced in an index 674 (has implications for deleting and 675 modifying the attribute). */ 676} __attribute__ ((__packed__)); 677 678typedef u8 RESIDENT_ATTR_FLAGS; 679 680/* 681 * Attribute record header. Always aligned to 8-byte boundary. 682 */ 683typedef struct { 684/*Ofs*/ 685/* 0*/ ATTR_TYPE type; /* The (32-bit) type of the attribute. */ 686/* 4*/ le32 length; /* Byte size of the resident part of the 687 attribute (aligned to 8-byte boundary). 688 Used to get to the next attribute. */ 689/* 8*/ u8 non_resident; /* If 0, attribute is resident. 690 If 1, attribute is non-resident. */ 691/* 9*/ u8 name_length; /* Unicode character size of name of attribute. 692 0 if unnamed. */ 693/* 10*/ le16 name_offset; /* If name_length != 0, the byte offset to the 694 beginning of the name from the attribute 695 record. Note that the name is stored as a 696 Unicode string. When creating, place offset 697 just at the end of the record header. Then, 698 follow with attribute value or mapping pairs 699 array, resident and non-resident attributes 700 respectively, aligning to an 8-byte 701 boundary. */ 702/* 12*/ ATTR_FLAGS flags; /* Flags describing the attribute. */ 703/* 14*/ le16 instance; /* The instance of this attribute record. This 704 number is unique within this mft record (see 705 MFT_RECORD/next_attribute_instance notes in 706 in mft.h for more details). */ 707/* 16*/ union { 708 /* Resident attributes. */ 709 struct { 710/* 16 */ le32 value_length;/* Byte size of attribute value. */ 711/* 20 */ le16 value_offset;/* Byte offset of the attribute 712 value from the start of the 713 attribute record. When creating, 714 align to 8-byte boundary if we 715 have a name present as this might 716 not have a length of a multiple 717 of 8-bytes. */ 718/* 22 */ RESIDENT_ATTR_FLAGS flags; /* See above. */ 719/* 23 */ s8 reserved; /* Reserved/alignment to 8-byte 720 boundary. */ 721 } __attribute__ ((__packed__)) resident; 722 /* Non-resident attributes. */ 723 struct { 724/* 16*/ leVCN lowest_vcn;/* Lowest valid virtual cluster number 725 for this portion of the attribute value or 726 0 if this is the only extent (usually the 727 case). - Only when an attribute list is used 728 does lowest_vcn != 0 ever occur. */ 729/* 24*/ leVCN highest_vcn;/* Highest valid vcn of this extent of 730 the attribute value. - Usually there is only one 731 portion, so this usually equals the attribute 732 value size in clusters minus 1. Can be -1 for 733 zero length files. Can be 0 for "single extent" 734 attributes. */ 735/* 32*/ le16 mapping_pairs_offset; /* Byte offset from the 736 beginning of the structure to the mapping pairs 737 array which contains the mappings between the 738 vcns and the logical cluster numbers (lcns). 739 When creating, place this at the end of this 740 record header aligned to 8-byte boundary. */ 741/* 34*/ u8 compression_unit; /* The compression unit expressed 742 as the log to the base 2 of the number of 743 clusters in a compression unit. 0 means not 744 compressed. (This effectively limits the 745 compression unit size to be a power of two 746 clusters.) WinNT4 only uses a value of 4. 747 Sparse files have this set to 0 on XPSP2. */ 748/* 35*/ u8 reserved[5]; /* Align to 8-byte boundary. */ 749/* The sizes below are only used when lowest_vcn is zero, as otherwise it would 750 be difficult to keep them up-to-date.*/ 751/* 40*/ sle64 allocated_size; /* Byte size of disk space 752 allocated to hold the attribute value. Always 753 is a multiple of the cluster size. When a file 754 is compressed, this field is a multiple of the 755 compression block size (2^compression_unit) and 756 it represents the logically allocated space 757 rather than the actual on disk usage. For this 758 use the compressed_size (see below). */ 759/* 48*/ sle64 data_size; /* Byte size of the attribute 760 value. Can be larger than allocated_size if 761 attribute value is compressed or sparse. */ 762/* 56*/ sle64 initialized_size; /* Byte size of initialized 763 portion of the attribute value. Usually equals 764 data_size. */ 765/* sizeof(uncompressed attr) = 64*/ 766/* 64*/ sle64 compressed_size; /* Byte size of the attribute 767 value after compression. Only present when 768 compressed or sparse. Always is a multiple of 769 the cluster size. Represents the actual amount 770 of disk space being used on the disk. */ 771/* sizeof(compressed attr) = 72*/ 772 } __attribute__ ((__packed__)) non_resident; 773 } __attribute__ ((__packed__)) data; 774} __attribute__ ((__packed__)) ATTR_RECORD; 775 776typedef ATTR_RECORD ATTR_REC; 777 778/* 779 * File attribute flags (32-bit) appearing in the file_attributes fields of the 780 * STANDARD_INFORMATION attribute of MFT_RECORDs and the FILENAME_ATTR 781 * attributes of MFT_RECORDs and directory index entries. 782 * 783 * All of the below flags appear in the directory index entries but only some 784 * appear in the STANDARD_INFORMATION attribute whilst only some others appear 785 * in the FILENAME_ATTR attribute of MFT_RECORDs. Unless otherwise stated the 786 * flags appear in all of the above. 787 */ 788enum { 789 FILE_ATTR_READONLY = cpu_to_le32(0x00000001), 790 FILE_ATTR_HIDDEN = cpu_to_le32(0x00000002), 791 FILE_ATTR_SYSTEM = cpu_to_le32(0x00000004), 792 /* Old DOS volid. Unused in NT. = cpu_to_le32(0x00000008), */ 793 794 FILE_ATTR_DIRECTORY = cpu_to_le32(0x00000010), 795 /* Note, FILE_ATTR_DIRECTORY is not considered valid in NT. It is 796 reserved for the DOS SUBDIRECTORY flag. */ 797 FILE_ATTR_ARCHIVE = cpu_to_le32(0x00000020), 798 FILE_ATTR_DEVICE = cpu_to_le32(0x00000040), 799 FILE_ATTR_NORMAL = cpu_to_le32(0x00000080), 800 801 FILE_ATTR_TEMPORARY = cpu_to_le32(0x00000100), 802 FILE_ATTR_SPARSE_FILE = cpu_to_le32(0x00000200), 803 FILE_ATTR_REPARSE_POINT = cpu_to_le32(0x00000400), 804 FILE_ATTR_COMPRESSED = cpu_to_le32(0x00000800), 805 806 FILE_ATTR_OFFLINE = cpu_to_le32(0x00001000), 807 FILE_ATTR_NOT_CONTENT_INDEXED = cpu_to_le32(0x00002000), 808 FILE_ATTR_ENCRYPTED = cpu_to_le32(0x00004000), 809 810 FILE_ATTR_VALID_FLAGS = cpu_to_le32(0x00007fb7), 811 /* Note, FILE_ATTR_VALID_FLAGS masks out the old DOS VolId and the 812 FILE_ATTR_DEVICE and preserves everything else. This mask is used 813 to obtain all flags that are valid for reading. */ 814 FILE_ATTR_VALID_SET_FLAGS = cpu_to_le32(0x000031a7), 815 /* Note, FILE_ATTR_VALID_SET_FLAGS masks out the old DOS VolId, the 816 F_A_DEVICE, F_A_DIRECTORY, F_A_SPARSE_FILE, F_A_REPARSE_POINT, 817 F_A_COMPRESSED, and F_A_ENCRYPTED and preserves the rest. This mask 818 is used to obtain all flags that are valid for setting. */ 819 /* 820 * The flag FILE_ATTR_DUP_FILENAME_INDEX_PRESENT is present in all 821 * FILENAME_ATTR attributes but not in the STANDARD_INFORMATION 822 * attribute of an mft record. 823 */ 824 FILE_ATTR_DUP_FILE_NAME_INDEX_PRESENT = cpu_to_le32(0x10000000), 825 /* Note, this is a copy of the corresponding bit from the mft record, 826 telling us whether this is a directory or not, i.e. whether it has 827 an index root attribute or not. */ 828 FILE_ATTR_DUP_VIEW_INDEX_PRESENT = cpu_to_le32(0x20000000), 829 /* Note, this is a copy of the corresponding bit from the mft record, 830 telling us whether this file has a view index present (eg. object id 831 index, quota index, one of the security indexes or the encrypting 832 filesystem related indexes). */ 833}; 834 835typedef le32 FILE_ATTR_FLAGS; 836 837/* 838 * NOTE on times in NTFS: All times are in MS standard time format, i.e. they 839 * are the number of 100-nanosecond intervals since 1st January 1601, 00:00:00 840 * universal coordinated time (UTC). (In Linux time starts 1st January 1970, 841 * 00:00:00 UTC and is stored as the number of 1-second intervals since then.) 842 */ 843 844/* 845 * Attribute: Standard information (0x10). 846 * 847 * NOTE: Always resident. 848 * NOTE: Present in all base file records on a volume. 849 * NOTE: There is conflicting information about the meaning of each of the time 850 * fields but the meaning as defined below has been verified to be 851 * correct by practical experimentation on Windows NT4 SP6a and is hence 852 * assumed to be the one and only correct interpretation. 853 */ 854typedef struct { 855/*Ofs*/ 856/* 0*/ sle64 creation_time; /* Time file was created. Updated when 857 a filename is changed(?). */ 858/* 8*/ sle64 last_data_change_time; /* Time the data attribute was last 859 modified. */ 860/* 16*/ sle64 last_mft_change_time; /* Time this mft record was last 861 modified. */ 862/* 24*/ sle64 last_access_time; /* Approximate time when the file was 863 last accessed (obviously this is not 864 updated on read-only volumes). In 865 Windows this is only updated when 866 accessed if some time delta has 867 passed since the last update. Also, 868 last access time updates can be 869 disabled altogether for speed. */ 870/* 32*/ FILE_ATTR_FLAGS file_attributes; /* Flags describing the file. */ 871/* 36*/ union { 872 /* NTFS 1.2 */ 873 struct { 874 /* 36*/ u8 reserved12[12]; /* Reserved/alignment to 8-byte 875 boundary. */ 876 } __attribute__ ((__packed__)) v1; 877 /* sizeof() = 48 bytes */ 878 /* NTFS 3.x */ 879 struct { 880/* 881 * If a volume has been upgraded from a previous NTFS version, then these 882 * fields are present only if the file has been accessed since the upgrade. 883 * Recognize the difference by comparing the length of the resident attribute 884 * value. If it is 48, then the following fields are missing. If it is 72 then 885 * the fields are present. Maybe just check like this: 886 * if (resident.ValueLength < sizeof(STANDARD_INFORMATION)) { 887 * Assume NTFS 1.2- format. 888 * If (volume version is 3.x) 889 * Upgrade attribute to NTFS 3.x format. 890 * else 891 * Use NTFS 1.2- format for access. 892 * } else 893 * Use NTFS 3.x format for access. 894 * Only problem is that it might be legal to set the length of the value to 895 * arbitrarily large values thus spoiling this check. - But chkdsk probably 896 * views that as a corruption, assuming that it behaves like this for all 897 * attributes. 898 */ 899 /* 36*/ le32 maximum_versions; /* Maximum allowed versions for 900 file. Zero if version numbering is disabled. */ 901 /* 40*/ le32 version_number; /* This file's version (if any). 902 Set to zero if maximum_versions is zero. */ 903 /* 44*/ le32 class_id; /* Class id from bidirectional 904 class id index (?). */ 905 /* 48*/ le32 owner_id; /* Owner_id of the user owning 906 the file. Translate via $Q index in FILE_Extend 907 /$Quota to the quota control entry for the user 908 owning the file. Zero if quotas are disabled. */ 909 /* 52*/ le32 security_id; /* Security_id for the file. 910 Translate via $SII index and $SDS data stream 911 in FILE_Secure to the security descriptor. */ 912 /* 56*/ le64 quota_charged; /* Byte size of the charge to 913 the quota for all streams of the file. Note: Is 914 zero if quotas are disabled. */ 915 /* 64*/ leUSN usn; /* Last update sequence number 916 of the file. This is a direct index into the 917 transaction log file ($UsnJrnl). It is zero if 918 the usn journal is disabled or this file has 919 not been subject to logging yet. See usnjrnl.h 920 for details. */ 921 } __attribute__ ((__packed__)) v3; 922 /* sizeof() = 72 bytes (NTFS 3.x) */ 923 } __attribute__ ((__packed__)) ver; 924} __attribute__ ((__packed__)) STANDARD_INFORMATION; 925 926/* 927 * Attribute: Attribute list (0x20). 928 * 929 * - Can be either resident or non-resident. 930 * - Value consists of a sequence of variable length, 8-byte aligned, 931 * ATTR_LIST_ENTRY records. 932 * - The list is not terminated by anything at all! The only way to know when 933 * the end is reached is to keep track of the current offset and compare it to 934 * the attribute value size. 935 * - The attribute list attribute contains one entry for each attribute of 936 * the file in which the list is located, except for the list attribute 937 * itself. The list is sorted: first by attribute type, second by attribute 938 * name (if present), third by instance number. The extents of one 939 * non-resident attribute (if present) immediately follow after the initial 940 * extent. They are ordered by lowest_vcn and have their instace set to zero. 941 * It is not allowed to have two attributes with all sorting keys equal. 942 * - Further restrictions: 943 * - If not resident, the vcn to lcn mapping array has to fit inside the 944 * base mft record. 945 * - The attribute list attribute value has a maximum size of 256kb. This 946 * is imposed by the Windows cache manager. 947 * - Attribute lists are only used when the attributes of mft record do not 948 * fit inside the mft record despite all attributes (that can be made 949 * non-resident) having been made non-resident. This can happen e.g. when: 950 * - File has a large number of hard links (lots of file name 951 * attributes present). 952 * - The mapping pairs array of some non-resident attribute becomes so 953 * large due to fragmentation that it overflows the mft record. 954 * - The security descriptor is very complex (not applicable to 955 * NTFS 3.0 volumes). 956 * - There are many named streams. 957 */ 958typedef struct { 959/*Ofs*/ 960/* 0*/ ATTR_TYPE type; /* Type of referenced attribute. */ 961/* 4*/ le16 length; /* Byte size of this entry (8-byte aligned). */ 962/* 6*/ u8 name_length; /* Size in Unicode chars of the name of the 963 attribute or 0 if unnamed. */ 964/* 7*/ u8 name_offset; /* Byte offset to beginning of attribute name 965 (always set this to where the name would 966 start even if unnamed). */ 967/* 8*/ leVCN lowest_vcn; /* Lowest virtual cluster number of this portion 968 of the attribute value. This is usually 0. It 969 is non-zero for the case where one attribute 970 does not fit into one mft record and thus 971 several mft records are allocated to hold 972 this attribute. In the latter case, each mft 973 record holds one extent of the attribute and 974 there is one attribute list entry for each 975 extent. NOTE: This is DEFINITELY a signed 976 value! The windows driver uses cmp, followed 977 by jg when comparing this, thus it treats it 978 as signed. */ 979/* 16*/ leMFT_REF mft_reference;/* The reference of the mft record holding 980 the ATTR_RECORD for this portion of the 981 attribute value. */ 982/* 24*/ le16 instance; /* If lowest_vcn = 0, the instance of the 983 attribute being referenced; otherwise 0. */ 984/* 26*/ ntfschar name[0]; /* Use when creating only. When reading use 985 name_offset to determine the location of the 986 name. */ 987/* sizeof() = 26 + (attribute_name_length * 2) bytes */ 988} __attribute__ ((__packed__)) ATTR_LIST_ENTRY; 989 990/* 991 * The maximum allowed length for a file name. 992 */ 993#define MAXIMUM_FILE_NAME_LENGTH 255 994 995/* 996 * Possible namespaces for filenames in ntfs (8-bit). 997 */ 998enum { 999 FILE_NAME_POSIX = 0x00, 1000 /* This is the largest namespace. It is case sensitive and allows all
1001 Unicode characters except for: '\0' and '/'. Beware that in 1002 WinNT/2k/2003 by default files which eg have the same name except 1003 for their case will not be distinguished by the standard utilities 1004 and thus a "del filename" will delete both "filename" and "fileName" 1005 without warning. However if for example Services For Unix (SFU) are 1006 installed and the case sensitive option was enabled at installation 1007 time, then you can create/access/delete such files. 1008 Note that even SFU places restrictions on the filenames beyond the 1009 '\0' and '/' and in particular the following set of characters is 1010 not allowed: '"', '/', '<', '>', '\'. All other characters, 1011 including the ones no allowed in WIN32 namespace are allowed. 1012 Tested with SFU 3.5 (this is now free) running on Windows XP. */ 1013 FILE_NAME_WIN32 = 0x01, 1014 /* The standard WinNT/2k NTFS long filenames. Case insensitive. All 1015 Unicode chars except: '\0', '"', '*', '/', ':', '<', '>', '?', '\', 1016 and '|'. Further, names cannot end with a '.' or a space. */ 1017 FILE_NAME_DOS = 0x02, 1018 /* The standard DOS filenames (8.3 format). Uppercase only. All 8-bit 1019 characters greater space, except: '"', '*', '+', ',', '/', ':', ';', 1020 '<', '=', '>', '?', and '\'. */ 1021 FILE_NAME_WIN32_AND_DOS = 0x03, 1022 /* 3 means that both the Win32 and the DOS filenames are identical and 1023 hence have been saved in this single filename record. */ 1024} __attribute__ ((__packed__)); 1025 1026typedef u8 FILE_NAME_TYPE_FLAGS; 1027 1028/* 1029 * Attribute: Filename (0x30). 1030 * 1031 * NOTE: Always resident. 1032 * NOTE: All fields, except the parent_directory, are only updated when the 1033 * filename is changed. Until then, they just become out of sync with 1034 * reality and the more up to date values are present in the standard 1035 * information attribute. 1036 * NOTE: There is conflicting information about the meaning of each of the time 1037 * fields but the meaning as defined below has been verified to be 1038 * correct by practical experimentation on Windows NT4 SP6a and is hence 1039 * assumed to be the one and only correct interpretation. 1040 */ 1041typedef struct { 1042/*hex ofs*/ 1043/* 0*/ leMFT_REF parent_directory; /* Directory this filename is 1044 referenced from. */ 1045/* 8*/ sle64 creation_time; /* Time file was created. */ 1046/* 10*/ sle64 last_data_change_time; /* Time the data attribute was last 1047 modified. */ 1048/* 18*/ sle64 last_mft_change_time; /* Time this mft record was last 1049 modified. */ 1050/* 20*/ sle64 last_access_time; /* Time this mft record was last 1051 accessed. */ 1052/* 28*/ sle64 allocated_size; /* Byte size of on-disk allocated space 1053 for the unnamed data attribute. So 1054 for normal $DATA, this is the 1055 allocated_size from the unnamed 1056 $DATA attribute and for compressed 1057 and/or sparse $DATA, this is the 1058 compressed_size from the unnamed 1059 $DATA attribute. For a directory or 1060 other inode without an unnamed $DATA 1061 attribute, this is always 0. NOTE: 1062 This is a multiple of the cluster 1063 size. */ 1064/* 30*/ sle64 data_size; /* Byte size of actual data in unnamed 1065 data attribute. For a directory or 1066 other inode without an unnamed $DATA 1067 attribute, this is always 0. */ 1068/* 38*/ FILE_ATTR_FLAGS file_attributes; /* Flags describing the file. */ 1069/* 3c*/ union { 1070 /* 3c*/ struct { 1071 /* 3c*/ le16 packed_ea_size; /* Size of the buffer needed to 1072 pack the extended attributes 1073 (EAs), if such are present.*/ 1074 /* 3e*/ le16 reserved; /* Reserved for alignment. */ 1075 } __attribute__ ((__packed__)) ea; 1076 /* 3c*/ struct { 1077 /* 3c*/ le32 reparse_point_tag; /* Type of reparse point, 1078 present only in reparse 1079 points and only if there are 1080 no EAs. */ 1081 } __attribute__ ((__packed__)) rp; 1082 } __attribute__ ((__packed__)) type; 1083/* 40*/ u8 file_name_length; /* Length of file name in 1084 (Unicode) characters. */ 1085/* 41*/ FILE_NAME_TYPE_FLAGS file_name_type; /* Namespace of the file name.*/ 1086/* 42*/ ntfschar file_name[0]; /* File name in Unicode. */ 1087} __attribute__ ((__packed__)) FILE_NAME_ATTR; 1088 1089/* 1090 * GUID structures store globally unique identifiers (GUID). A GUID is a 1091 * 128-bit value consisting of one group of eight hexadecimal digits, followed 1092 * by three groups of four hexadecimal digits each, followed by one group of 1093 * twelve hexadecimal digits. GUIDs are Microsoft's implementation of the 1094 * distributed computing environment (DCE) universally unique identifier (UUID). 1095 * Example of a GUID: 1096 * 1F010768-5A73-BC91-0010A52216A7 1097 */ 1098typedef struct { 1099 le32 data1; /* The first eight hexadecimal digits of the GUID. */ 1100 le16 data2; /* The first group of four hexadecimal digits. */ 1101 le16 data3; /* The second group of four hexadecimal digits. */ 1102 u8 data4[8]; /* The first two bytes are the third group of four 1103 hexadecimal digits. The remaining six bytes are the 1104 final 12 hexadecimal digits. */ 1105} __attribute__ ((__packed__)) GUID; 1106 1107/* 1108 * FILE_Extend/$ObjId contains an index named $O. This index contains all 1109 * object_ids present on the volume as the index keys and the corresponding 1110 * mft_record numbers as the index entry data parts. The data part (defined 1111 * below) also contains three other object_ids: 1112 * birth_volume_id - object_id of FILE_Volume on which the file was first 1113 * created. Optional (i.e. can be zero). 1114 * birth_object_id - object_id of file when it was first created. Usually 1115 * equals the object_id. Optional (i.e. can be zero). 1116 * domain_id - Reserved (always zero). 1117 */ 1118typedef struct { 1119 leMFT_REF mft_reference;/* Mft record containing the object_id in 1120 the index entry key. */ 1121 union { 1122 struct { 1123 GUID birth_volume_id; 1124 GUID birth_object_id; 1125 GUID domain_id; 1126 } __attribute__ ((__packed__)) origin; 1127 u8 extended_info[48]; 1128 } __attribute__ ((__packed__)) opt; 1129} __attribute__ ((__packed__)) OBJ_ID_INDEX_DATA; 1130 1131/* 1132 * Attribute: Object id (NTFS 3.0+) (0x40). 1133 * 1134 * NOTE: Always resident. 1135 */ 1136typedef struct { 1137 GUID object_id; /* Unique id assigned to the 1138 file.*/ 1139 /* The following fields are optional. The attribute value size is 16 1140 bytes, i.e. sizeof(GUID), if these are not present at all. Note, 1141 the entries can be present but one or more (or all) can be zero 1142 meaning that that particular value(s) is(are) not defined. */ 1143 union { 1144 struct { 1145 GUID birth_volume_id; /* Unique id of volume on which 1146 the file was first created.*/ 1147 GUID birth_object_id; /* Unique id of file when it was 1148 first created. */ 1149 GUID domain_id; /* Reserved, zero. */ 1150 } __attribute__ ((__packed__)) origin; 1151 u8 extended_info[48]; 1152 } __attribute__ ((__packed__)) opt; 1153} __attribute__ ((__packed__)) OBJECT_ID_ATTR; 1154 1155/* 1156 * The pre-defined IDENTIFIER_AUTHORITIES used as SID_IDENTIFIER_AUTHORITY in 1157 * the SID structure (see below). 1158 */ 1159//typedef enum { /* SID string prefix. */ 1160// SECURITY_NULL_SID_AUTHORITY = {0, 0, 0, 0, 0, 0}, /* S-1-0 */ 1161// SECURITY_WORLD_SID_AUTHORITY = {0, 0, 0, 0, 0, 1}, /* S-1-1 */ 1162// SECURITY_LOCAL_SID_AUTHORITY = {0, 0, 0, 0, 0, 2}, /* S-1-2 */ 1163// SECURITY_CREATOR_SID_AUTHORITY = {0, 0, 0, 0, 0, 3}, /* S-1-3 */ 1164// SECURITY_NON_UNIQUE_AUTHORITY = {0, 0, 0, 0, 0, 4}, /* S-1-4 */ 1165// SECURITY_NT_SID_AUTHORITY = {0, 0, 0, 0, 0, 5}, /* S-1-5 */ 1166//} IDENTIFIER_AUTHORITIES; 1167 1168/* 1169 * These relative identifiers (RIDs) are used with the above identifier 1170 * authorities to make up universal well-known SIDs. 1171 * 1172 * Note: The relative identifier (RID) refers to the portion of a SID, which 1173 * identifies a user or group in relation to the authority that issued the SID. 1174 * For example, the universal well-known SID Creator Owner ID (S-1-3-0) is 1175 * made up of the identifier authority SECURITY_CREATOR_SID_AUTHORITY (3) and 1176 * the relative identifier SECURITY_CREATOR_OWNER_RID (0). 1177 */ 1178typedef enum { /* Identifier authority. */ 1179 SECURITY_NULL_RID = 0, /* S-1-0 */ 1180 SECURITY_WORLD_RID = 0, /* S-1-1 */ 1181 SECURITY_LOCAL_RID = 0, /* S-1-2 */ 1182 1183 SECURITY_CREATOR_OWNER_RID = 0, /* S-1-3 */ 1184 SECURITY_CREATOR_GROUP_RID = 1, /* S-1-3 */ 1185 1186 SECURITY_CREATOR_OWNER_SERVER_RID = 2, /* S-1-3 */ 1187 SECURITY_CREATOR_GROUP_SERVER_RID = 3, /* S-1-3 */ 1188 1189 SECURITY_DIALUP_RID = 1, 1190 SECURITY_NETWORK_RID = 2, 1191 SECURITY_BATCH_RID = 3, 1192 SECURITY_INTERACTIVE_RID = 4, 1193 SECURITY_SERVICE_RID = 6, 1194 SECURITY_ANONYMOUS_LOGON_RID = 7, 1195 SECURITY_PROXY_RID = 8, 1196 SECURITY_ENTERPRISE_CONTROLLERS_RID=9, 1197 SECURITY_SERVER_LOGON_RID = 9, 1198 SECURITY_PRINCIPAL_SELF_RID = 0xa, 1199 SECURITY_AUTHENTICATED_USER_RID = 0xb, 1200 SECURITY_RESTRICTED_CODE_RID = 0xc, 1201 SECURITY_TERMINAL_SERVER_RID = 0xd, 1202 1203 SECURITY_LOGON_IDS_RID = 5, 1204 SECURITY_LOGON_IDS_RID_COUNT = 3, 1205 1206 SECURITY_LOCAL_SYSTEM_RID = 0x12, 1207 1208 SECURITY_NT_NON_UNIQUE = 0x15, 1209 1210 SECURITY_BUILTIN_DOMAIN_RID = 0x20, 1211 1212 /* 1213 * Well-known domain relative sub-authority values (RIDs). 1214 */ 1215 1216 /* Users. */ 1217 DOMAIN_USER_RID_ADMIN = 0x1f4, 1218 DOMAIN_USER_RID_GUEST = 0x1f5, 1219 DOMAIN_USER_RID_KRBTGT = 0x1f6, 1220 1221 /* Groups. */ 1222 DOMAIN_GROUP_RID_ADMINS = 0x200, 1223 DOMAIN_GROUP_RID_USERS = 0x201, 1224 DOMAIN_GROUP_RID_GUESTS = 0x202, 1225 DOMAIN_GROUP_RID_COMPUTERS = 0x203, 1226 DOMAIN_GROUP_RID_CONTROLLERS = 0x204, 1227 DOMAIN_GROUP_RID_CERT_ADMINS = 0x205, 1228 DOMAIN_GROUP_RID_SCHEMA_ADMINS = 0x206, 1229 DOMAIN_GROUP_RID_ENTERPRISE_ADMINS= 0x207, 1230 DOMAIN_GROUP_RID_POLICY_ADMINS = 0x208, 1231 1232 /* Aliases. */ 1233 DOMAIN_ALIAS_RID_ADMINS = 0x220, 1234 DOMAIN_ALIAS_RID_USERS = 0x221, 1235 DOMAIN_ALIAS_RID_GUESTS = 0x222, 1236 DOMAIN_ALIAS_RID_POWER_USERS = 0x223, 1237 1238 DOMAIN_ALIAS_RID_ACCOUNT_OPS = 0x224, 1239 DOMAIN_ALIAS_RID_SYSTEM_OPS = 0x225, 1240 DOMAIN_ALIAS_RID_PRINT_OPS = 0x226, 1241 DOMAIN_ALIAS_RID_BACKUP_OPS = 0x227, 1242 1243 DOMAIN_ALIAS_RID_REPLICATOR = 0x228, 1244 DOMAIN_ALIAS_RID_RAS_SERVERS = 0x229, 1245 DOMAIN_ALIAS_RID_PREW2KCOMPACCESS = 0x22a, 1246} RELATIVE_IDENTIFIERS; 1247 1248/* 1249 * The universal well-known SIDs: 1250 * 1251 * NULL_SID S-1-0-0 1252 * WORLD_SID S-1-1-0 1253 * LOCAL_SID S-1-2-0 1254 * CREATOR_OWNER_SID S-1-3-0 1255 * CREATOR_GROUP_SID S-1-3-1 1256 * CREATOR_OWNER_SERVER_SID S-1-3-2 1257 * CREATOR_GROUP_SERVER_SID S-1-3-3 1258 * 1259 * (Non-unique IDs) S-1-4 1260 * 1261 * NT well-known SIDs: 1262 * 1263 * NT_AUTHORITY_SID S-1-5 1264 * DIALUP_SID S-1-5-1 1265 * 1266 * NETWORD_SID S-1-5-2 1267 * BATCH_SID S-1-5-3 1268 * INTERACTIVE_SID S-1-5-4 1269 * SERVICE_SID S-1-5-6 1270 * ANONYMOUS_LOGON_SID S-1-5-7 (aka null logon session) 1271 * PROXY_SID S-1-5-8 1272 * SERVER_LOGON_SID S-1-5-9 (aka domain controller account) 1273 * SELF_SID S-1-5-10 (self RID) 1274 * AUTHENTICATED_USER_SID S-1-5-11 1275 * RESTRICTED_CODE_SID S-1-5-12 (running restricted code) 1276 * TERMINAL_SERVER_SID S-1-5-13 (running on terminal server) 1277 * 1278 * (Logon IDs) S-1-5-5-X-Y 1279 * 1280 * (NT non-unique IDs) S-1-5-0x15-... 1281 * 1282 * (Built-in domain) S-1-5-0x20 1283 */ 1284 1285/* 1286 * The SID_IDENTIFIER_AUTHORITY is a 48-bit value used in the SID structure. 1287 * 1288 * NOTE: This is stored as a big endian number, hence the high_part comes 1289 * before the low_part. 1290 */ 1291typedef union { 1292 struct { 1293 u16 high_part; /* High 16-bits. */ 1294 u32 low_part; /* Low 32-bits. */ 1295 } __attribute__ ((__packed__)) parts; 1296 u8 value[6]; /* Value as individual bytes. */ 1297} __attribute__ ((__packed__)) SID_IDENTIFIER_AUTHORITY; 1298 1299/* 1300 * The SID structure is a variable-length structure used to uniquely identify 1301 * users or groups. SID stands for security identifier. 1302 * 1303 * The standard textual representation of the SID is of the form: 1304 * S-R-I-S-S... 1305 * Where: 1306 * - The first "S" is the literal character 'S' identifying the following 1307 * digits as a SID. 1308 * - R is the revision level of the SID expressed as a sequence of digits 1309 * either in decimal or hexadecimal (if the later, prefixed by "0x"). 1310 * - I is the 48-bit identifier_authority, expressed as digits as R above. 1311 * - S... is one or more sub_authority values, expressed as digits as above. 1312 * 1313 * Example SID; the domain-relative SID of the local Administrators group on 1314 * Windows NT/2k: 1315 * S-1-5-32-544 1316 * This translates to a SID with: 1317 * revision = 1, 1318 * sub_authority_count = 2, 1319 * identifier_authority = {0,0,0,0,0,5}, // SECURITY_NT_AUTHORITY 1320 * sub_authority[0] = 32, // SECURITY_BUILTIN_DOMAIN_RID 1321 * sub_authority[1] = 544 // DOMAIN_ALIAS_RID_ADMINS 1322 */ 1323typedef struct { 1324 u8 revision; 1325 u8 sub_authority_count; 1326 SID_IDENTIFIER_AUTHORITY identifier_authority; 1327 le32 sub_authority[1]; /* At least one sub_authority. */ 1328} __attribute__ ((__packed__)) SID; 1329 1330/* 1331 * Current constants for SIDs. 1332 */ 1333typedef enum { 1334 SID_REVISION = 1, /* Current revision level. */ 1335 SID_MAX_SUB_AUTHORITIES = 15, /* Maximum number of those. */ 1336 SID_RECOMMENDED_SUB_AUTHORITIES = 1, /* Will change to around 6 in 1337 a future revision. */ 1338} SID_CONSTANTS; 1339 1340/* 1341 * The predefined ACE types (8-bit, see below). 1342 */ 1343enum { 1344 ACCESS_MIN_MS_ACE_TYPE = 0, 1345 ACCESS_ALLOWED_ACE_TYPE = 0, 1346 ACCESS_DENIED_ACE_TYPE = 1, 1347 SYSTEM_AUDIT_ACE_TYPE = 2, 1348 SYSTEM_ALARM_ACE_TYPE = 3, /* Not implemented as of Win2k. */ 1349 ACCESS_MAX_MS_V2_ACE_TYPE = 3, 1350 1351 ACCESS_ALLOWED_COMPOUND_ACE_TYPE= 4, 1352 ACCESS_MAX_MS_V3_ACE_TYPE = 4, 1353 1354 /* The following are Win2k only. */ 1355 ACCESS_MIN_MS_OBJECT_ACE_TYPE = 5, 1356 ACCESS_ALLOWED_OBJECT_ACE_TYPE = 5, 1357 ACCESS_DENIED_OBJECT_ACE_TYPE = 6, 1358 SYSTEM_AUDIT_OBJECT_ACE_TYPE = 7, 1359 SYSTEM_ALARM_OBJECT_ACE_TYPE = 8, 1360 ACCESS_MAX_MS_OBJECT_ACE_TYPE = 8, 1361 1362 ACCESS_MAX_MS_V4_ACE_TYPE = 8, 1363 1364 /* This one is for WinNT/2k. */ 1365 ACCESS_MAX_MS_ACE_TYPE = 8, 1366} __attribute__ ((__packed__)); 1367 1368typedef u8 ACE_TYPES; 1369 1370/* 1371 * The ACE flags (8-bit) for audit and inheritance (see below). 1372 * 1373 * SUCCESSFUL_ACCESS_ACE_FLAG is only used with system audit and alarm ACE 1374 * types to indicate that a message is generated (in Windows!) for successful 1375 * accesses. 1376 * 1377 * FAILED_ACCESS_ACE_FLAG is only used with system audit and alarm ACE types 1378 * to indicate that a message is generated (in Windows!) for failed accesses. 1379 */ 1380enum { 1381 /* The inheritance flags. */ 1382 OBJECT_INHERIT_ACE = 0x01, 1383 CONTAINER_INHERIT_ACE = 0x02, 1384 NO_PROPAGATE_INHERIT_ACE = 0x04, 1385 INHERIT_ONLY_ACE = 0x08, 1386 INHERITED_ACE = 0x10, /* Win2k only. */ 1387 VALID_INHERIT_FLAGS = 0x1f, 1388 1389 /* The audit flags. */ 1390 SUCCESSFUL_ACCESS_ACE_FLAG = 0x40, 1391 FAILED_ACCESS_ACE_FLAG = 0x80, 1392} __attribute__ ((__packed__)); 1393 1394typedef u8 ACE_FLAGS; 1395 1396/* 1397 * An ACE is an access-control entry in an access-control list (ACL). 1398 * An ACE defines access to an object for a specific user or group or defines 1399 * the types of access that generate system-administration messages or alarms 1400 * for a specific user or group. The user or group is identified by a security 1401 * identifier (SID). 1402 * 1403 * Each ACE starts with an ACE_HEADER structure (aligned on 4-byte boundary), 1404 * which specifies the type and size of the ACE. The format of the subsequent 1405 * data depends on the ACE type. 1406 */ 1407typedef struct { 1408/*Ofs*/ 1409/* 0*/ ACE_TYPES type; /* Type of the ACE. */ 1410/* 1*/ ACE_FLAGS flags; /* Flags describing the ACE. */ 1411/* 2*/ le16 size; /* Size in bytes of the ACE. */ 1412} __attribute__ ((__packed__)) ACE_HEADER; 1413 1414/* 1415 * The access mask (32-bit). Defines the access rights. 1416 * 1417 * The specific rights (bits 0 to 15). These depend on the type of the object 1418 * being secured by the ACE. 1419 */ 1420enum { 1421 /* Specific rights for files and directories are as follows: */ 1422 1423 /* Right to read data from the file. (FILE) */ 1424 FILE_READ_DATA = cpu_to_le32(0x00000001), 1425 /* Right to list contents of a directory. (DIRECTORY) */ 1426 FILE_LIST_DIRECTORY = cpu_to_le32(0x00000001), 1427 1428 /* Right to write data to the file. (FILE) */ 1429 FILE_WRITE_DATA = cpu_to_le32(0x00000002), 1430 /* Right to create a file in the directory. (DIRECTORY) */ 1431 FILE_ADD_FILE = cpu_to_le32(0x00000002), 1432 1433 /* Right to append data to the file. (FILE) */ 1434 FILE_APPEND_DATA = cpu_to_le32(0x00000004), 1435 /* Right to create a subdirectory. (DIRECTORY) */ 1436 FILE_ADD_SUBDIRECTORY = cpu_to_le32(0x00000004), 1437 1438 /* Right to read extended attributes. (FILE/DIRECTORY) */ 1439 FILE_READ_EA = cpu_to_le32(0x00000008), 1440 1441 /* Right to write extended attributes. (FILE/DIRECTORY) */ 1442 FILE_WRITE_EA = cpu_to_le32(0x00000010), 1443 1444 /* Right to execute a file. (FILE) */ 1445 FILE_EXECUTE = cpu_to_le32(0x00000020), 1446 /* Right to traverse the directory. (DIRECTORY) */ 1447 FILE_TRAVERSE = cpu_to_le32(0x00000020), 1448 1449 /* 1450 * Right to delete a directory and all the files it contains (its 1451 * children), even if the files are read-only. (DIRECTORY) 1452 */ 1453 FILE_DELETE_CHILD = cpu_to_le32(0x00000040), 1454 1455 /* Right to read file attributes. (FILE/DIRECTORY) */ 1456 FILE_READ_ATTRIBUTES = cpu_to_le32(0x00000080), 1457 1458 /* Right to change file attributes. (FILE/DIRECTORY) */ 1459 FILE_WRITE_ATTRIBUTES = cpu_to_le32(0x00000100), 1460 1461 /* 1462 * The standard rights (bits 16 to 23). These are independent of the 1463 * type of object being secured. 1464 */ 1465 1466 /* Right to delete the object. */ 1467 DELETE = cpu_to_le32(0x00010000), 1468 1469 /* 1470 * Right to read the information in the object's security descriptor, 1471 * not including the information in the SACL, i.e. right to read the 1472 * security descriptor and owner. 1473 */ 1474 READ_CONTROL = cpu_to_le32(0x00020000), 1475 1476 /* Right to modify the DACL in the object's security descriptor. */ 1477 WRITE_DAC = cpu_to_le32(0x00040000), 1478 1479 /* Right to change the owner in the object's security descriptor. */ 1480 WRITE_OWNER = cpu_to_le32(0x00080000), 1481 1482 /* 1483 * Right to use the object for synchronization. Enables a process to 1484 * wait until the object is in the signalled state. Some object types 1485 * do not support this access right. 1486 */ 1487 SYNCHRONIZE = cpu_to_le32(0x00100000), 1488 1489 /* 1490 * The following STANDARD_RIGHTS_* are combinations of the above for 1491 * convenience and are defined by the Win32 API. 1492 */ 1493 1494 /* These are currently defined to READ_CONTROL. */ 1495 STANDARD_RIGHTS_READ = cpu_to_le32(0x00020000), 1496 STANDARD_RIGHTS_WRITE = cpu_to_le32(0x00020000), 1497 STANDARD_RIGHTS_EXECUTE = cpu_to_le32(0x00020000), 1498 1499 /* Combines DELETE, READ_CONTROL, WRITE_DAC, and WRITE_OWNER access. */ 1500 STANDARD_RIGHTS_REQUIRED = cpu_to_le32(0x000f0000), 1501 1502 /* 1503 * Combines DELETE, READ_CONTROL, WRITE_DAC, WRITE_OWNER, and 1504 * SYNCHRONIZE access. 1505 */ 1506 STANDARD_RIGHTS_ALL = cpu_to_le32(0x001f0000), 1507 1508 /* 1509 * The access system ACL and maximum allowed access types (bits 24 to 1510 * 25, bits 26 to 27 are reserved). 1511 */ 1512 ACCESS_SYSTEM_SECURITY = cpu_to_le32(0x01000000), 1513 MAXIMUM_ALLOWED = cpu_to_le32(0x02000000), 1514 1515 /* 1516 * The generic rights (bits 28 to 31). These map onto the standard and 1517 * specific rights. 1518 */ 1519 1520 /* Read, write, and execute access. */ 1521 GENERIC_ALL = cpu_to_le32(0x10000000), 1522 1523 /* Execute access. */ 1524 GENERIC_EXECUTE = cpu_to_le32(0x20000000), 1525 1526 /* 1527 * Write access. For files, this maps onto: 1528 * FILE_APPEND_DATA | FILE_WRITE_ATTRIBUTES | FILE_WRITE_DATA | 1529 * FILE_WRITE_EA | STANDARD_RIGHTS_WRITE | SYNCHRONIZE 1530 * For directories, the mapping has the same numerical value. See 1531 * above for the descriptions of the rights granted. 1532 */ 1533 GENERIC_WRITE = cpu_to_le32(0x40000000), 1534 1535 /* 1536 * Read access. For files, this maps onto: 1537 * FILE_READ_ATTRIBUTES | FILE_READ_DATA | FILE_READ_EA | 1538 * STANDARD_RIGHTS_READ | SYNCHRONIZE 1539 * For directories, the mapping has the same numberical value. See 1540 * above for the descriptions of the rights granted. 1541 */ 1542 GENERIC_READ = cpu_to_le32(0x80000000), 1543}; 1544 1545typedef le32 ACCESS_MASK; 1546 1547/* 1548 * The generic mapping array. Used to denote the mapping of each generic 1549 * access right to a specific access mask. 1550 * 1551 * FIXME: What exactly is this and what is it for? (AIA) 1552 */ 1553typedef struct { 1554 ACCESS_MASK generic_read; 1555 ACCESS_MASK generic_write; 1556 ACCESS_MASK generic_execute; 1557 ACCESS_MASK generic_all; 1558} __attribute__ ((__packed__)) GENERIC_MAPPING; 1559 1560/* 1561 * The predefined ACE type structures are as defined below. 1562 */ 1563 1564/* 1565 * ACCESS_ALLOWED_ACE, ACCESS_DENIED_ACE, SYSTEM_AUDIT_ACE, SYSTEM_ALARM_ACE 1566 */ 1567typedef struct { 1568/* 0 ACE_HEADER; -- Unfolded here as gcc doesn't like unnamed structs. */ 1569 ACE_TYPES type; /* Type of the ACE. */ 1570 ACE_FLAGS flags; /* Flags describing the ACE. */ 1571 le16 size; /* Size in bytes of the ACE. */ 1572/* 4*/ ACCESS_MASK mask; /* Access mask associated with the ACE. */ 1573 1574/* 8*/ SID sid; /* The SID associated with the ACE. */ 1575} __attribute__ ((__packed__)) ACCESS_ALLOWED_ACE, ACCESS_DENIED_ACE, 1576 SYSTEM_AUDIT_ACE, SYSTEM_ALARM_ACE; 1577 1578/* 1579 * The object ACE flags (32-bit). 1580 */ 1581enum { 1582 ACE_OBJECT_TYPE_PRESENT = cpu_to_le32(1), 1583 ACE_INHERITED_OBJECT_TYPE_PRESENT = cpu_to_le32(2), 1584}; 1585 1586typedef le32 OBJECT_ACE_FLAGS; 1587 1588typedef struct { 1589/* 0 ACE_HEADER; -- Unfolded here as gcc doesn't like unnamed structs. */ 1590 ACE_TYPES type; /* Type of the ACE. */ 1591 ACE_FLAGS flags; /* Flags describing the ACE. */ 1592 le16 size; /* Size in bytes of the ACE. */ 1593/* 4*/ ACCESS_MASK mask; /* Access mask associated with the ACE. */ 1594 1595/* 8*/ OBJECT_ACE_FLAGS object_flags; /* Flags describing the object ACE. */ 1596/* 12*/ GUID object_type; 1597/* 28*/ GUID inherited_object_type; 1598 1599/* 44*/ SID sid; /* The SID associated with the ACE. */ 1600} __attribute__ ((__packed__)) ACCESS_ALLOWED_OBJECT_ACE, 1601 ACCESS_DENIED_OBJECT_ACE, 1602 SYSTEM_AUDIT_OBJECT_ACE, 1603 SYSTEM_ALARM_OBJECT_ACE; 1604 1605/* 1606 * An ACL is an access-control list (ACL). 1607 * An ACL starts with an ACL header structure, which specifies the size of 1608 * the ACL and the number of ACEs it contains. The ACL header is followed by 1609 * zero or more access control entries (ACEs). The ACL as well as each ACE 1610 * are aligned on 4-byte boundaries. 1611 */ 1612typedef struct { 1613 u8 revision; /* Revision of this ACL. */ 1614 u8 alignment1; 1615 le16 size; /* Allocated space in bytes for ACL. Includes this 1616 header, the ACEs and the remaining free space. */ 1617 le16 ace_count; /* Number of ACEs in the ACL. */ 1618 le16 alignment2; 1619/* sizeof() = 8 bytes */ 1620} __attribute__ ((__packed__)) ACL; 1621 1622/* 1623 * Current constants for ACLs. 1624 */ 1625typedef enum { 1626 /* Current revision. */ 1627 ACL_REVISION = 2, 1628 ACL_REVISION_DS = 4, 1629 1630 /* History of revisions. */ 1631 ACL_REVISION1 = 1, 1632 MIN_ACL_REVISION = 2, 1633 ACL_REVISION2 = 2, 1634 ACL_REVISION3 = 3, 1635 ACL_REVISION4 = 4, 1636 MAX_ACL_REVISION = 4, 1637} ACL_CONSTANTS; 1638 1639/* 1640 * The security descriptor control flags (16-bit). 1641 * 1642 * SE_OWNER_DEFAULTED - This boolean flag, when set, indicates that the SID 1643 * pointed to by the Owner field was provided by a defaulting mechanism 1644 * rather than explicitly provided by the original provider of the 1645 * security descriptor. This may affect the treatment of the SID with 1646 * respect to inheritance of an owner. 1647 * 1648 * SE_GROUP_DEFAULTED - This boolean flag, when set, indicates that the SID in 1649 * the Group field was provided by a defaulting mechanism rather than 1650 * explicitly provided by the original provider of the security 1651 * descriptor. This may affect the treatment of the SID with respect to 1652 * inheritance of a primary group. 1653 * 1654 * SE_DACL_PRESENT - This boolean flag, when set, indicates that the security 1655 * descriptor contains a discretionary ACL. If this flag is set and the 1656 * Dacl field of the SECURITY_DESCRIPTOR is null, then a null ACL is 1657 * explicitly being specified. 1658 * 1659 * SE_DACL_DEFAULTED - This boolean flag, when set, indicates that the ACL 1660 * pointed to by the Dacl field was provided by a defaulting mechanism 1661 * rather than explicitly provided by the original provider of the 1662 * security descriptor. This may affect the treatment of the ACL with 1663 * respect to inheritance of an ACL. This flag is ignored if the 1664 * DaclPresent flag is not set. 1665 * 1666 * SE_SACL_PRESENT - This boolean flag, when set, indicates that the security 1667 * descriptor contains a system ACL pointed to by the Sacl field. If this 1668 * flag is set and the Sacl field of the SECURITY_DESCRIPTOR is null, then 1669 * an empty (but present) ACL is being specified. 1670 * 1671 * SE_SACL_DEFAULTED - This boolean flag, when set, indicates that the ACL 1672 * pointed to by the Sacl field was provided by a defaulting mechanism 1673 * rather than explicitly provided by the original provider of the 1674 * security descriptor. This may affect the treatment of the ACL with 1675 * respect to inheritance of an ACL. This flag is ignored if the 1676 * SaclPresent flag is not set. 1677 * 1678 * SE_SELF_RELATIVE - This boolean flag, when set, indicates that the security 1679 * descriptor is in self-relative form. In this form, all fields of the 1680 * security descriptor are contiguous in memory and all pointer fields are 1681 * expressed as offsets from the beginning of the security descriptor. 1682 */ 1683enum { 1684 SE_OWNER_DEFAULTED = cpu_to_le16(0x0001), 1685 SE_GROUP_DEFAULTED = cpu_to_le16(0x0002), 1686 SE_DACL_PRESENT = cpu_to_le16(0x0004), 1687 SE_DACL_DEFAULTED = cpu_to_le16(0x0008), 1688 1689 SE_SACL_PRESENT = cpu_to_le16(0x0010), 1690 SE_SACL_DEFAULTED = cpu_to_le16(0x0020), 1691 1692 SE_DACL_AUTO_INHERIT_REQ = cpu_to_le16(0x0100), 1693 SE_SACL_AUTO_INHERIT_REQ = cpu_to_le16(0x0200), 1694 SE_DACL_AUTO_INHERITED = cpu_to_le16(0x0400), 1695 SE_SACL_AUTO_INHERITED = cpu_to_le16(0x0800), 1696 1697 SE_DACL_PROTECTED = cpu_to_le16(0x1000), 1698 SE_SACL_PROTECTED = cpu_to_le16(0x2000), 1699 SE_RM_CONTROL_VALID = cpu_to_le16(0x4000), 1700 SE_SELF_RELATIVE = cpu_to_le16(0x8000) 1701} __attribute__ ((__packed__)); 1702 1703typedef le16 SECURITY_DESCRIPTOR_CONTROL; 1704 1705/* 1706 * Self-relative security descriptor. Contains the owner and group SIDs as well 1707 * as the sacl and dacl ACLs inside the security descriptor itself. 1708 */ 1709typedef struct { 1710 u8 revision; /* Revision level of the security descriptor. */ 1711 u8 alignment; 1712 SECURITY_DESCRIPTOR_CONTROL control; /* Flags qualifying the type of 1713 the descriptor as well as the following fields. */ 1714 le32 owner; /* Byte offset to a SID representing an object's 1715 owner. If this is NULL, no owner SID is present in 1716 the descriptor. */ 1717 le32 group; /* Byte offset to a SID representing an object's 1718 primary group. If this is NULL, no primary group 1719 SID is present in the descriptor. */ 1720 le32 sacl; /* Byte offset to a system ACL. Only valid, if 1721 SE_SACL_PRESENT is set in the control field. If 1722 SE_SACL_PRESENT is set but sacl is NULL, a NULL ACL 1723 is specified. */ 1724 le32 dacl; /* Byte offset to a discretionary ACL. Only valid, if 1725 SE_DACL_PRESENT is set in the control field. If 1726 SE_DACL_PRESENT is set but dacl is NULL, a NULL ACL 1727 (unconditionally granting access) is specified. */ 1728/* sizeof() = 0x14 bytes */ 1729} __attribute__ ((__packed__)) SECURITY_DESCRIPTOR_RELATIVE; 1730 1731/* 1732 * Absolute security descriptor. Does not contain the owner and group SIDs, nor 1733 * the sacl and dacl ACLs inside the security descriptor. Instead, it contains 1734 * pointers to these structures in memory. Obviously, absolute security 1735 * descriptors are only useful for in memory representations of security 1736 * descriptors. On disk, a self-relative security descriptor is used. 1737 */ 1738typedef struct { 1739 u8 revision; /* Revision level of the security descriptor. */ 1740 u8 alignment; 1741 SECURITY_DESCRIPTOR_CONTROL control; /* Flags qualifying the type of 1742 the descriptor as well as the following fields. */ 1743 SID *owner; /* Points to a SID representing an object's owner. If 1744 this is NULL, no owner SID is present in the 1745 descriptor. */ 1746 SID *group; /* Points to a SID representing an object's primary 1747 group. If this is NULL, no primary group SID is 1748 present in the descriptor. */ 1749 ACL *sacl; /* Points to a system ACL. Only valid, if 1750 SE_SACL_PRESENT is set in the control field. If 1751 SE_SACL_PRESENT is set but sacl is NULL, a NULL ACL 1752 is specified. */ 1753 ACL *dacl; /* Points to a discretionary ACL. Only valid, if 1754 SE_DACL_PRESENT is set in the control field. If 1755 SE_DACL_PRESENT is set but dacl is NULL, a NULL ACL 1756 (unconditionally granting access) is specified. */ 1757} __attribute__ ((__packed__)) SECURITY_DESCRIPTOR; 1758 1759/* 1760 * Current constants for security descriptors. 1761 */ 1762typedef enum { 1763 /* Current revision. */ 1764 SECURITY_DESCRIPTOR_REVISION = 1, 1765 SECURITY_DESCRIPTOR_REVISION1 = 1, 1766 1767 /* The sizes of both the absolute and relative security descriptors is 1768 the same as pointers, at least on ia32 architecture are 32-bit. */ 1769 SECURITY_DESCRIPTOR_MIN_LENGTH = sizeof(SECURITY_DESCRIPTOR), 1770} SECURITY_DESCRIPTOR_CONSTANTS; 1771 1772/* 1773 * Attribute: Security descriptor (0x50). A standard self-relative security 1774 * descriptor. 1775 * 1776 * NOTE: Can be resident or non-resident. 1777 * NOTE: Not used in NTFS 3.0+, as security descriptors are stored centrally 1778 * in FILE_Secure and the correct descriptor is found using the security_id 1779 * from the standard information attribute. 1780 */ 1781typedef SECURITY_DESCRIPTOR_RELATIVE SECURITY_DESCRIPTOR_ATTR; 1782 1783/* 1784 * On NTFS 3.0+, all security descriptors are stored in FILE_Secure. Only one 1785 * referenced instance of each unique security descriptor is stored. 1786 * 1787 * FILE_Secure contains no unnamed data attribute, i.e. it has zero length. It 1788 * does, however, contain two indexes ($SDH and $SII) as well as a named data 1789 * stream ($SDS). 1790 * 1791 * Every unique security descriptor is assigned a unique security identifier 1792 * (security_id, not to be confused with a SID). The security_id is unique for 1793 * the NTFS volume and is used as an index into the $SII index, which maps 1794 * security_ids to the security descriptor's storage location within the $SDS 1795 * data attribute. The $SII index is sorted by ascending security_id. 1796 * 1797 * A simple hash is computed from each security descriptor. This hash is used 1798 * as an index into the $SDH index, which maps security descriptor hashes to 1799 * the security descriptor's storage location within the $SDS data attribute. 1800 * The $SDH index is sorted by security descriptor hash and is stored in a B+ 1801 * tree. When searching $SDH (with the intent of determining whether or not a 1802 * new security descriptor is already present in the $SDS data stream), if a 1803 * matching hash is found, but the security descriptors do not match, the 1804 * search in the $SDH index is continued, searching for a next matching hash. 1805 * 1806 * When a precise match is found, the security_id coresponding to the security 1807 * descriptor in the $SDS attribute is read from the found $SDH index entry and 1808 * is stored in the $STANDARD_INFORMATION attribute of the file/directory to 1809 * which the security descriptor is being applied. The $STANDARD_INFORMATION 1810 * attribute is present in all base mft records (i.e. in all files and 1811 * directories). 1812 * 1813 * If a match is not found, the security descriptor is assigned a new unique 1814 * security_id and is added to the $SDS data attribute. Then, entries 1815 * referencing the this security descriptor in the $SDS data attribute are 1816 * added to the $SDH and $SII indexes. 1817 * 1818 * Note: Entries are never deleted from FILE_Secure, even if nothing 1819 * references an entry any more. 1820 */ 1821 1822/* 1823 * This header precedes each security descriptor in the $SDS data stream. 1824 * This is also the index entry data part of both the $SII and $SDH indexes. 1825 */ 1826typedef struct { 1827 le32 hash; /* Hash of the security descriptor. */ 1828 le32 security_id; /* The security_id assigned to the descriptor. */ 1829 le64 offset; /* Byte offset of this entry in the $SDS stream. */ 1830 le32 length; /* Size in bytes of this entry in $SDS stream. */ 1831} __attribute__ ((__packed__)) SECURITY_DESCRIPTOR_HEADER; 1832 1833/* 1834 * The $SDS data stream contains the security descriptors, aligned on 16-byte 1835 * boundaries, sorted by security_id in a B+ tree. Security descriptors cannot 1836 * cross 256kib boundaries (this restriction is imposed by the Windows cache 1837 * manager). Each security descriptor is contained in a SDS_ENTRY structure. 1838 * Also, each security descriptor is stored twice in the $SDS stream with a 1839 * fixed offset of 0x40000 bytes (256kib, the Windows cache manager's max size) 1840 * between them; i.e. if a SDS_ENTRY specifies an offset of 0x51d0, then the 1841 * the first copy of the security descriptor will be at offset 0x51d0 in the 1842 * $SDS data stream and the second copy will be at offset 0x451d0. 1843 */ 1844typedef struct { 1845/*Ofs*/ 1846/* 0 SECURITY_DESCRIPTOR_HEADER; -- Unfolded here as gcc doesn't like 1847 unnamed structs. */ 1848 le32 hash; /* Hash of the security descriptor. */ 1849 le32 security_id; /* The security_id assigned to the descriptor. */ 1850 le64 offset; /* Byte offset of this entry in the $SDS stream. */ 1851 le32 length; /* Size in bytes of this entry in $SDS stream. */ 1852/* 20*/ SECURITY_DESCRIPTOR_RELATIVE sid; /* The self-relative security 1853 descriptor. */ 1854} __attribute__ ((__packed__)) SDS_ENTRY; 1855 1856/* 1857 * The index entry key used in the $SII index. The collation type is 1858 * COLLATION_NTOFS_ULONG. 1859 */ 1860typedef struct { 1861 le32 security_id; /* The security_id assigned to the descriptor. */ 1862} __attribute__ ((__packed__)) SII_INDEX_KEY; 1863 1864/* 1865 * The index entry key used in the $SDH index. The keys are sorted first by 1866 * hash and then by security_id. The collation rule is 1867 * COLLATION_NTOFS_SECURITY_HASH. 1868 */ 1869typedef struct { 1870 le32 hash; /* Hash of the security descriptor. */ 1871 le32 security_id; /* The security_id assigned to the descriptor. */ 1872} __attribute__ ((__packed__)) SDH_INDEX_KEY; 1873 1874/* 1875 * Attribute: Volume name (0x60). 1876 * 1877 * NOTE: Always resident. 1878 * NOTE: Present only in FILE_Volume. 1879 */ 1880typedef struct { 1881 ntfschar name[0]; /* The name of the volume in Unicode. */ 1882} __attribute__ ((__packed__)) VOLUME_NAME; 1883 1884/* 1885 * Possible flags for the volume (16-bit). 1886 */ 1887enum { 1888 VOLUME_IS_DIRTY = cpu_to_le16(0x0001), 1889 VOLUME_RESIZE_LOG_FILE = cpu_to_le16(0x0002), 1890 VOLUME_UPGRADE_ON_MOUNT = cpu_to_le16(0x0004), 1891 VOLUME_MOUNTED_ON_NT4 = cpu_to_le16(0x0008), 1892 1893 VOLUME_DELETE_USN_UNDERWAY = cpu_to_le16(0x0010), 1894 VOLUME_REPAIR_OBJECT_ID = cpu_to_le16(0x0020), 1895 1896 VOLUME_CHKDSK_UNDERWAY = cpu_to_le16(0x4000), 1897 VOLUME_MODIFIED_BY_CHKDSK = cpu_to_le16(0x8000), 1898 1899 VOLUME_FLAGS_MASK = cpu_to_le16(0xc03f), 1900 1901 /* To make our life easier when checking if we must mount read-only. */ 1902 VOLUME_MUST_MOUNT_RO_MASK = cpu_to_le16(0xc027), 1903} __attribute__ ((__packed__)); 1904 1905typedef le16 VOLUME_FLAGS; 1906 1907/* 1908 * Attribute: Volume information (0x70). 1909 * 1910 * NOTE: Always resident. 1911 * NOTE: Present only in FILE_Volume. 1912 * NOTE: Windows 2000 uses NTFS 3.0 while Windows NT4 service pack 6a uses 1913 * NTFS 1.2. I haven't personally seen other values yet. 1914 */ 1915typedef struct { 1916 le64 reserved; /* Not used (yet?). */ 1917 u8 major_ver; /* Major version of the ntfs format. */ 1918 u8 minor_ver; /* Minor version of the ntfs format. */ 1919 VOLUME_FLAGS flags; /* Bit array of VOLUME_* flags. */ 1920} __attribute__ ((__packed__)) VOLUME_INFORMATION; 1921 1922/* 1923 * Attribute: Data attribute (0x80). 1924 * 1925 * NOTE: Can be resident or non-resident. 1926 * 1927 * Data contents of a file (i.e. the unnamed stream) or of a named stream. 1928 */ 1929typedef struct { 1930 u8 data[0]; /* The file's data contents. */ 1931} __attribute__ ((__packed__)) DATA_ATTR; 1932 1933/* 1934 * Index header flags (8-bit). 1935 */ 1936enum { 1937 /* 1938 * When index header is in an index root attribute: 1939 */ 1940 SMALL_INDEX = 0, /* The index is small enough to fit inside the index 1941 root attribute and there is no index allocation 1942 attribute present. */ 1943 LARGE_INDEX = 1, /* The index is too large to fit in the index root 1944 attribute and/or an index allocation attribute is 1945 present. */ 1946 /* 1947 * When index header is in an index block, i.e. is part of index 1948 * allocation attribute: 1949 */ 1950 LEAF_NODE = 0, /* This is a leaf node, i.e. there are no more nodes 1951 branching off it. */ 1952 INDEX_NODE = 1, /* This node indexes other nodes, i.e. it is not a leaf 1953 node. */ 1954 NODE_MASK = 1, /* Mask for accessing the *_NODE bits. */ 1955} __attribute__ ((__packed__)); 1956 1957typedef u8 INDEX_HEADER_FLAGS; 1958 1959/* 1960 * This is the header for indexes, describing the INDEX_ENTRY records, which 1961 * follow the INDEX_HEADER. Together the index header and the index entries 1962 * make up a complete index. 1963 * 1964 * IMPORTANT NOTE: The offset, length and size structure members are counted 1965 * relative to the start of the index header structure and not relative to the 1966 * start of the index root or index allocation structures themselves. 1967 */ 1968typedef struct { 1969 le32 entries_offset; /* Byte offset to first INDEX_ENTRY 1970 aligned to 8-byte boundary. */ 1971 le32 index_length; /* Data size of the index in bytes, 1972 i.e. bytes used from allocated 1973 size, aligned to 8-byte boundary. */ 1974 le32 allocated_size; /* Byte size of this index (block), 1975 multiple of 8 bytes. */ 1976 /* NOTE: For the index root attribute, the above two numbers are always 1977 equal, as the attribute is resident and it is resized as needed. In 1978 the case of the index allocation attribute the attribute is not 1979 resident and hence the allocated_size is a fixed value and must 1980 equal the index_block_size specified by the INDEX_ROOT attribute 1981 corresponding to the INDEX_ALLOCATION attribute this INDEX_BLOCK 1982 belongs to. */ 1983 INDEX_HEADER_FLAGS flags; /* Bit field of INDEX_HEADER_FLAGS. */ 1984 u8 reserved[3]; /* Reserved/align to 8-byte boundary. */ 1985} __attribute__ ((__packed__)) INDEX_HEADER; 1986 1987/* 1988 * Attribute: Index root (0x90). 1989 * 1990 * NOTE: Always resident. 1991 * 1992 * This is followed by a sequence of index entries (INDEX_ENTRY structures) 1993 * as described by the index header. 1994 * 1995 * When a directory is small enough to fit inside the index root then this 1996 * is the only attribute describing the directory. When the directory is too 1997 * large to fit in the index root, on the other hand, two additional attributes 1998 * are present: an index allocation attribute, containing sub-nodes of the B+ 1999 * directory tree (see below), and a bitmap attribute, describing which virtual 2000 * cluster numbers (vcns) in the index allocation attribute are in use by an
2001 * index block. 2002 * 2003 * NOTE: The root directory (FILE_root) contains an entry for itself. Other 2004 * directories do not contain entries for themselves, though. 2005 */ 2006typedef struct { 2007 ATTR_TYPE type; /* Type of the indexed attribute. Is 2008 $FILE_NAME for directories, zero 2009 for view indexes. No other values 2010 allowed. */ 2011 COLLATION_RULE collation_rule; /* Collation rule used to sort the 2012 index entries. If type is $FILE_NAME, 2013 this must be COLLATION_FILE_NAME. */ 2014 le32 index_block_size; /* Size of each index block in bytes (in 2015 the index allocation attribute). */ 2016 u8 clusters_per_index_block; /* Cluster size of each index block (in 2017 the index allocation attribute), when 2018 an index block is >= than a cluster, 2019 otherwise this will be the log of 2020 the size (like how the encoding of 2021 the mft record size and the index 2022 record size found in the boot sector 2023 work). Has to be a power of 2. */ 2024 u8 reserved[3]; /* Reserved/align to 8-byte boundary. */ 2025 INDEX_HEADER index; /* Index header describing the 2026 following index entries. */ 2027} __attribute__ ((__packed__)) INDEX_ROOT; 2028 2029/* 2030 * Attribute: Index allocation (0xa0). 2031 * 2032 * NOTE: Always non-resident (doesn't make sense to be resident anyway!). 2033 * 2034 * This is an array of index blocks. Each index block starts with an 2035 * INDEX_BLOCK structure containing an index header, followed by a sequence of 2036 * index entries (INDEX_ENTRY structures), as described by the INDEX_HEADER. 2037 */ 2038typedef struct { 2039/* 0 NTFS_RECORD; -- Unfolded here as gcc doesn't like unnamed structs. */ 2040 NTFS_RECORD_TYPE magic; /* Magic is "INDX". */ 2041 le16 usa_ofs; /* See NTFS_RECORD definition. */ 2042 le16 usa_count; /* See NTFS_RECORD definition. */ 2043 2044/* 8*/ sle64 lsn; /* $LogFile sequence number of the last 2045 modification of this index block. */ 2046/* 16*/ leVCN index_block_vcn; /* Virtual cluster number of the index block. 2047 If the cluster_size on the volume is <= the 2048 index_block_size of the directory, 2049 index_block_vcn counts in units of clusters, 2050 and in units of sectors otherwise. */ 2051/* 24*/ INDEX_HEADER index; /* Describes the following index entries. */ 2052/* sizeof()= 40 (0x28) bytes */ 2053/* 2054 * When creating the index block, we place the update sequence array at this 2055 * offset, i.e. before we start with the index entries. This also makes sense, 2056 * otherwise we could run into problems with the update sequence array 2057 * containing in itself the last two bytes of a sector which would mean that 2058 * multi sector transfer protection wouldn't work. As you can't protect data 2059 * by overwriting it since you then can't get it back... 2060 * When reading use the data from the ntfs record header. 2061 */ 2062} __attribute__ ((__packed__)) INDEX_BLOCK; 2063 2064typedef INDEX_BLOCK INDEX_ALLOCATION; 2065 2066/* 2067 * The system file FILE_Extend/$Reparse contains an index named $R listing 2068 * all reparse points on the volume. The index entry keys are as defined 2069 * below. Note, that there is no index data associated with the index entries. 2070 * 2071 * The index entries are sorted by the index key file_id. The collation rule is 2072 * COLLATION_NTOFS_ULONGS. FIXME: Verify whether the reparse_tag is not the 2073 * primary key / is not a key at all. (AIA) 2074 */ 2075typedef struct { 2076 le32 reparse_tag; /* Reparse point type (inc. flags). */ 2077 leMFT_REF file_id; /* Mft record of the file containing the 2078 reparse point attribute. */ 2079} __attribute__ ((__packed__)) REPARSE_INDEX_KEY; 2080 2081/* 2082 * Quota flags (32-bit). 2083 * 2084 * The user quota flags. Names explain meaning. 2085 */ 2086enum { 2087 QUOTA_FLAG_DEFAULT_LIMITS = cpu_to_le32(0x00000001), 2088 QUOTA_FLAG_LIMIT_REACHED = cpu_to_le32(0x00000002), 2089 QUOTA_FLAG_ID_DELETED = cpu_to_le32(0x00000004), 2090 2091 QUOTA_FLAG_USER_MASK = cpu_to_le32(0x00000007), 2092 /* This is a bit mask for the user quota flags. */ 2093 2094 /* 2095 * These flags are only present in the quota defaults index entry, i.e. 2096 * in the entry where owner_id = QUOTA_DEFAULTS_ID. 2097 */ 2098 QUOTA_FLAG_TRACKING_ENABLED = cpu_to_le32(0x00000010), 2099 QUOTA_FLAG_ENFORCEMENT_ENABLED = cpu_to_le32(0x00000020), 2100 QUOTA_FLAG_TRACKING_REQUESTED = cpu_to_le32(0x00000040), 2101 QUOTA_FLAG_LOG_THRESHOLD = cpu_to_le32(0x00000080), 2102 2103 QUOTA_FLAG_LOG_LIMIT = cpu_to_le32(0x00000100), 2104 QUOTA_FLAG_OUT_OF_DATE = cpu_to_le32(0x00000200), 2105 QUOTA_FLAG_CORRUPT = cpu_to_le32(0x00000400), 2106 QUOTA_FLAG_PENDING_DELETES = cpu_to_le32(0x00000800), 2107}; 2108 2109typedef le32 QUOTA_FLAGS; 2110 2111/* 2112 * The system file FILE_Extend/$Quota contains two indexes $O and $Q. Quotas 2113 * are on a per volume and per user basis. 2114 * 2115 * The $Q index contains one entry for each existing user_id on the volume. The 2116 * index key is the user_id of the user/group owning this quota control entry, 2117 * i.e. the key is the owner_id. The user_id of the owner of a file, i.e. the 2118 * owner_id, is found in the standard information attribute. The collation rule 2119 * for $Q is COLLATION_NTOFS_ULONG. 2120 * 2121 * The $O index contains one entry for each user/group who has been assigned 2122 * a quota on that volume. The index key holds the SID of the user_id the 2123 * entry belongs to, i.e. the owner_id. The collation rule for $O is 2124 * COLLATION_NTOFS_SID. 2125 * 2126 * The $O index entry data is the user_id of the user corresponding to the SID. 2127 * This user_id is used as an index into $Q to find the quota control entry 2128 * associated with the SID. 2129 * 2130 * The $Q index entry data is the quota control entry and is defined below. 2131 */ 2132typedef struct { 2133 le32 version; /* Currently equals 2. */ 2134 QUOTA_FLAGS flags; /* Flags describing this quota entry. */ 2135 le64 bytes_used; /* How many bytes of the quota are in use. */ 2136 sle64 change_time; /* Last time this quota entry was changed. */ 2137 sle64 threshold; /* Soft quota (-1 if not limited). */ 2138 sle64 limit; /* Hard quota (-1 if not limited). */ 2139 sle64 exceeded_time; /* How long the soft quota has been exceeded. */ 2140 SID sid; /* The SID of the user/object associated with 2141 this quota entry. Equals zero for the quota 2142 defaults entry (and in fact on a WinXP 2143 volume, it is not present at all). */ 2144} __attribute__ ((__packed__)) QUOTA_CONTROL_ENTRY; 2145 2146/* 2147 * Predefined owner_id values (32-bit). 2148 */ 2149enum { 2150 QUOTA_INVALID_ID = cpu_to_le32(0x00000000), 2151 QUOTA_DEFAULTS_ID = cpu_to_le32(0x00000001), 2152 QUOTA_FIRST_USER_ID = cpu_to_le32(0x00000100), 2153}; 2154 2155/* 2156 * Current constants for quota control entries. 2157 */ 2158typedef enum { 2159 /* Current version. */ 2160 QUOTA_VERSION = 2, 2161} QUOTA_CONTROL_ENTRY_CONSTANTS; 2162 2163/* 2164 * Index entry flags (16-bit). 2165 */ 2166enum { 2167 INDEX_ENTRY_NODE = cpu_to_le16(1), /* This entry contains a 2168 sub-node, i.e. a reference to an index block in form of 2169 a virtual cluster number (see below). */ 2170 INDEX_ENTRY_END = cpu_to_le16(2), /* This signifies the last 2171 entry in an index block. The index entry does not 2172 represent a file but it can point to a sub-node. */ 2173 2174 INDEX_ENTRY_SPACE_FILLER = cpu_to_le16(0xffff), /* gcc: Force 2175 enum bit width to 16-bit. */ 2176} __attribute__ ((__packed__)); 2177 2178typedef le16 INDEX_ENTRY_FLAGS; 2179 2180/* 2181 * This the index entry header (see below). 2182 */ 2183typedef struct { 2184/* 0*/ union { 2185 struct { /* Only valid when INDEX_ENTRY_END is not set. */ 2186 leMFT_REF indexed_file; /* The mft reference of the file 2187 described by this index 2188 entry. Used for directory 2189 indexes. */ 2190 } __attribute__ ((__packed__)) dir; 2191 struct { /* Used for views/indexes to find the entry's data. */ 2192 le16 data_offset; /* Data byte offset from this 2193 INDEX_ENTRY. Follows the 2194 index key. */ 2195 le16 data_length; /* Data length in bytes. */ 2196 le32 reservedV; /* Reserved (zero). */ 2197 } __attribute__ ((__packed__)) vi; 2198 } __attribute__ ((__packed__)) data; 2199/* 8*/ le16 length; /* Byte size of this index entry, multiple of 2200 8-bytes. */ 2201/* 10*/ le16 key_length; /* Byte size of the key value, which is in the 2202 index entry. It follows field reserved. Not 2203 multiple of 8-bytes. */ 2204/* 12*/ INDEX_ENTRY_FLAGS flags; /* Bit field of INDEX_ENTRY_* flags. */ 2205/* 14*/ le16 reserved; /* Reserved/align to 8-byte boundary. */ 2206/* sizeof() = 16 bytes */ 2207} __attribute__ ((__packed__)) INDEX_ENTRY_HEADER; 2208 2209/* 2210 * This is an index entry. A sequence of such entries follows each INDEX_HEADER 2211 * structure. Together they make up a complete index. The index follows either 2212 * an index root attribute or an index allocation attribute. 2213 * 2214 * NOTE: Before NTFS 3.0 only filename attributes were indexed. 2215 */ 2216typedef struct { 2217/*Ofs*/ 2218/* 0 INDEX_ENTRY_HEADER; -- Unfolded here as gcc dislikes unnamed structs. */ 2219 union { 2220 struct { /* Only valid when INDEX_ENTRY_END is not set. */ 2221 leMFT_REF indexed_file; /* The mft reference of the file 2222 described by this index 2223 entry. Used for directory 2224 indexes. */ 2225 } __attribute__ ((__packed__)) dir; 2226 struct { /* Used for views/indexes to find the entry's data. */ 2227 le16 data_offset; /* Data byte offset from this 2228 INDEX_ENTRY. Follows the 2229 index key. */ 2230 le16 data_length; /* Data length in bytes. */ 2231 le32 reservedV; /* Reserved (zero). */ 2232 } __attribute__ ((__packed__)) vi; 2233 } __attribute__ ((__packed__)) data; 2234 le16 length; /* Byte size of this index entry, multiple of 2235 8-bytes. */ 2236 le16 key_length; /* Byte size of the key value, which is in the 2237 index entry. It follows field reserved. Not 2238 multiple of 8-bytes. */ 2239 INDEX_ENTRY_FLAGS flags; /* Bit field of INDEX_ENTRY_* flags. */ 2240 le16 reserved; /* Reserved/align to 8-byte boundary. */ 2241 2242/* 16*/ union { /* The key of the indexed attribute. NOTE: Only present 2243 if INDEX_ENTRY_END bit in flags is not set. NOTE: On 2244 NTFS versions before 3.0 the only valid key is the 2245 FILE_NAME_ATTR. On NTFS 3.0+ the following 2246 additional index keys are defined: */ 2247 FILE_NAME_ATTR file_name;/* $I30 index in directories. */ 2248 SII_INDEX_KEY sii; /* $SII index in $Secure. */ 2249 SDH_INDEX_KEY sdh; /* $SDH index in $Secure. */ 2250 GUID object_id; /* $O index in FILE_Extend/$ObjId: The 2251 object_id of the mft record found in 2252 the data part of the index. */ 2253 REPARSE_INDEX_KEY reparse; /* $R index in 2254 FILE_Extend/$Reparse. */ 2255 SID sid; /* $O index in FILE_Extend/$Quota: 2256 SID of the owner of the user_id. */ 2257 le32 owner_id; /* $Q index in FILE_Extend/$Quota: 2258 user_id of the owner of the quota 2259 control entry in the data part of 2260 the index. */ 2261 } __attribute__ ((__packed__)) key; 2262 /* The (optional) index data is inserted here when creating. */ 2263 // leVCN vcn; /* If INDEX_ENTRY_NODE bit in flags is set, the last 2264 // eight bytes of this index entry contain the virtual 2265 // cluster number of the index block that holds the 2266 // entries immediately preceding the current entry (the 2267 // vcn references the corresponding cluster in the data 2268 // of the non-resident index allocation attribute). If 2269 // the key_length is zero, then the vcn immediately 2270 // follows the INDEX_ENTRY_HEADER. Regardless of 2271 // key_length, the address of the 8-byte boundary 2272 // aligned vcn of INDEX_ENTRY{_HEADER} *ie is given by 2273 // (char*)ie + le16_to_cpu(ie*)->length) - sizeof(VCN), 2274 // where sizeof(VCN) can be hardcoded as 8 if wanted. */ 2275} __attribute__ ((__packed__)) INDEX_ENTRY; 2276 2277/* 2278 * Attribute: Bitmap (0xb0). 2279 * 2280 * Contains an array of bits (aka a bitfield). 2281 * 2282 * When used in conjunction with the index allocation attribute, each bit 2283 * corresponds to one index block within the index allocation attribute. Thus 2284 * the number of bits in the bitmap * index block size / cluster size is the 2285 * number of clusters in the index allocation attribute. 2286 */ 2287typedef struct { 2288 u8 bitmap[0]; /* Array of bits. */ 2289} __attribute__ ((__packed__)) BITMAP_ATTR; 2290 2291/* 2292 * The reparse point tag defines the type of the reparse point. It also 2293 * includes several flags, which further describe the reparse point. 2294 * 2295 * The reparse point tag is an unsigned 32-bit value divided in three parts: 2296 * 2297 * 1. The least significant 16 bits (i.e. bits 0 to 15) specifiy the type of 2298 * the reparse point. 2299 * 2. The 13 bits after this (i.e. bits 16 to 28) are reserved for future use. 2300 * 3. The most significant three bits are flags describing the reparse point. 2301 * They are defined as follows: 2302 * bit 29: Name surrogate bit. If set, the filename is an alias for 2303 * another object in the system. 2304 * bit 30: High-latency bit. If set, accessing the first byte of data will 2305 * be slow. (E.g. the data is stored on a tape drive.) 2306 * bit 31: Microsoft bit. If set, the tag is owned by Microsoft. User 2307 * defined tags have to use zero here. 2308 * 2309 * These are the predefined reparse point tags: 2310 */ 2311enum { 2312 IO_REPARSE_TAG_IS_ALIAS = cpu_to_le32(0x20000000), 2313 IO_REPARSE_TAG_IS_HIGH_LATENCY = cpu_to_le32(0x40000000), 2314 IO_REPARSE_TAG_IS_MICROSOFT = cpu_to_le32(0x80000000), 2315 2316 IO_REPARSE_TAG_RESERVED_ZERO = cpu_to_le32(0x00000000), 2317 IO_REPARSE_TAG_RESERVED_ONE = cpu_to_le32(0x00000001), 2318 IO_REPARSE_TAG_RESERVED_RANGE = cpu_to_le32(0x00000001), 2319 2320 IO_REPARSE_TAG_NSS = cpu_to_le32(0x68000005), 2321 IO_REPARSE_TAG_NSS_RECOVER = cpu_to_le32(0x68000006), 2322 IO_REPARSE_TAG_SIS = cpu_to_le32(0x68000007), 2323 IO_REPARSE_TAG_DFS = cpu_to_le32(0x68000008), 2324 2325 IO_REPARSE_TAG_MOUNT_POINT = cpu_to_le32(0x88000003), 2326 2327 IO_REPARSE_TAG_HSM = cpu_to_le32(0xa8000004), 2328 2329 IO_REPARSE_TAG_SYMBOLIC_LINK = cpu_to_le32(0xe8000000), 2330 2331 IO_REPARSE_TAG_VALID_VALUES = cpu_to_le32(0xe000ffff), 2332}; 2333 2334/* 2335 * Attribute: Reparse point (0xc0). 2336 * 2337 * NOTE: Can be resident or non-resident. 2338 */ 2339typedef struct { 2340 le32 reparse_tag; /* Reparse point type (inc. flags). */ 2341 le16 reparse_data_length; /* Byte size of reparse data. */ 2342 le16 reserved; /* Align to 8-byte boundary. */ 2343 u8 reparse_data[0]; /* Meaning depends on reparse_tag. */ 2344} __attribute__ ((__packed__)) REPARSE_POINT; 2345 2346/* 2347 * Attribute: Extended attribute (EA) information (0xd0). 2348 * 2349 * NOTE: Always resident. (Is this true???) 2350 */ 2351typedef struct { 2352 le16 ea_length; /* Byte size of the packed extended 2353 attributes. */ 2354 le16 need_ea_count; /* The number of extended attributes which have 2355 the NEED_EA bit set. */ 2356 le32 ea_query_length; /* Byte size of the buffer required to query 2357 the extended attributes when calling 2358 ZwQueryEaFile() in Windows NT/2k. I.e. the 2359 byte size of the unpacked extended 2360 attributes. */ 2361} __attribute__ ((__packed__)) EA_INFORMATION; 2362 2363/* 2364 * Extended attribute flags (8-bit). 2365 */ 2366enum { 2367 NEED_EA = 0x80 /* If set the file to which the EA belongs 2368 cannot be interpreted without understanding 2369 the associates extended attributes. */ 2370} __attribute__ ((__packed__)); 2371 2372typedef u8 EA_FLAGS; 2373 2374/* 2375 * Attribute: Extended attribute (EA) (0xe0). 2376 * 2377 * NOTE: Can be resident or non-resident. 2378 * 2379 * Like the attribute list and the index buffer list, the EA attribute value is 2380 * a sequence of EA_ATTR variable length records. 2381 */ 2382typedef struct { 2383 le32 next_entry_offset; /* Offset to the next EA_ATTR. */ 2384 EA_FLAGS flags; /* Flags describing the EA. */ 2385 u8 ea_name_length; /* Length of the name of the EA in bytes 2386 excluding the '\0' byte terminator. */ 2387 le16 ea_value_length; /* Byte size of the EA's value. */ 2388 u8 ea_name[0]; /* Name of the EA. Note this is ASCII, not 2389 Unicode and it is zero terminated. */ 2390 u8 ea_value[0]; /* The value of the EA. Immediately follows 2391 the name. */ 2392} __attribute__ ((__packed__)) EA_ATTR; 2393 2394/* 2395 * Attribute: Property set (0xf0). 2396 * 2397 * Intended to support Native Structure Storage (NSS) - a feature removed from 2398 * NTFS 3.0 during beta testing. 2399 */ 2400typedef struct { 2401 /* Irrelevant as feature unused. */ 2402} __attribute__ ((__packed__)) PROPERTY_SET; 2403 2404/* 2405 * Attribute: Logged utility stream (0x100). 2406 * 2407 * NOTE: Can be resident or non-resident. 2408 * 2409 * Operations on this attribute are logged to the journal ($LogFile) like 2410 * normal metadata changes. 2411 * 2412 * Used by the Encrypting File System (EFS). All encrypted files have this 2413 * attribute with the name $EFS. 2414 */ 2415typedef struct { 2416 /* Can be anything the creator chooses. */ 2417 /* EFS uses it as follows: */ 2418 // FIXME: Type this info, verifying it along the way. (AIA) 2419} __attribute__ ((__packed__)) LOGGED_UTILITY_STREAM, EFS_ATTR; 2420 2421#endif /* _LINUX_NTFS_LAYOUT_H */ 2422