| blob | 5a9e34475e37951eb03be7ae62d8c55666b53c48 |
1 /**
2 * dir.c - NTFS kernel directory operations. Part of the Linux-NTFS project.
3 *
4 * Copyright (c) 2001-2007 Anton Altaparmakov
5 * Copyright (c) 2002 Richard Russon
6 *
7 * This program/include file is free software; you can redistribute it and/or
8 * modify it under the terms of the GNU General Public License as published
9 * by the Free Software Foundation; either version 2 of the License, or
10 * (at your option) any later version.
11 *
12 * This program/include file is distributed in the hope that it will be
13 * useful, but WITHOUT ANY WARRANTY; without even the implied warranty
14 * of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 * GNU General Public License for more details.
16 *
17 * You should have received a copy of the GNU General Public License
18 * along with this program (in the main directory of the Linux-NTFS
19 * distribution in the file COPYING); if not, write to the Free Software
20 * Foundation,Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
21 */
23 #include <linux/buffer_head.h>
32 /**
33 * The little endian Unicode string $I30 as a global constant.
34 */
38 /**
39 * ntfs_lookup_inode_by_name - find an inode in a directory given its name
40 * @dir_ni: ntfs inode of the directory in which to search for the name
41 * @uname: Unicode name for which to search in the directory
42 * @uname_len: length of the name @uname in Unicode characters
43 * @res: return the found file name if necessary (see below)
44 *
45 * Look for an inode with name @uname in the directory with inode @dir_ni.
46 * ntfs_lookup_inode_by_name() walks the contents of the directory looking for
47 * the Unicode name. If the name is found in the directory, the corresponding
48 * inode number (>= 0) is returned as a mft reference in cpu format, i.e. it
49 * is a 64-bit number containing the sequence number.
50 *
51 * On error, a negative value is returned corresponding to the error code. In
52 * particular if the inode is not found -ENOENT is returned. Note that you
53 * can't just check the return value for being negative, you have to check the
54 * inode number for being negative which you can extract using MREC(return
55 * value).
56 *
57 * Note, @uname_len does not include the (optional) terminating NULL character.
58 *
59 * Note, we look for a case sensitive match first but we also look for a case
60 * insensitive match at the same time. If we find a case insensitive match, we
61 * save that for the case that we don't find an exact match, where we return
62 * the case insensitive match and setup @res (which we allocate!) with the mft
63 * reference, the file name type, length and with a copy of the little endian
64 * Unicode file name itself. If we match a file name which is in the DOS name
65 * space, we only return the mft reference and file name type in @res.
66 * ntfs_lookup() then uses this to find the long file name in the inode itself.
67 * This is to avoid polluting the dcache with short file names. We want them to
68 * work but we don't care for how quickly one can access them. This also fixes
69 * the dcache aliasing issues.
70 *
71 * Locking: - Caller must hold i_mutex on the directory.
72 * - Each page cache page in the index allocation mapping must be
73 * locked whilst being accessed otherwise we may find a corrupt
74 * page due to it being under ->writepage at the moment which
75 * applies the mst protection fixups before writing out and then
76 * removes them again after the write is complete after which it
77 * unlocks the page.
78 */
81 {
89 u64 mref;
100 /* Get hold of the mft record for the directory. */
106 }
111 }
112 /* Find the index root attribute in the mft record. */
121 }
123 }
124 /* Get to the index root value (it's been verified in read_inode). */
128 /* The first index entry. */
131 /*
132 * Loop until we exceed valid memory (corruption case) or until we
133 * reach the last entry.
134 */
136 /* Bounds checks. */
140 index_end)
142 /*
143 * The last entry cannot contain a name. It can however contain
144 * a pointer to a child node in the B+tree so we just break out.
145 */
148 /*
149 * We perform a case sensitive comparison and if that matches
150 * we are done and return the mft reference of the inode (i.e.
151 * the inode number together with the sequence number for
152 * consistency checking). We convert it to cpu format before
153 * returning.
154 */
159 found_it:
160 /*
161 * We have a perfect match, so we don't need to care
162 * about having matched imperfectly before, so we can
163 * free name and set *res to NULL.
164 * However, if the perfect match is a short file name,
165 * we need to signal this through *res, so that
166 * ntfs_lookup() can fix dcache aliasing issues.
167 * As an optimization we just reuse an existing
168 * allocation of *res.
169 */
173 GFP_NOFS);
177 }
178 }
187 }
192 }
193 /*
194 * For a case insensitive mount, we also perform a case
195 * insensitive comparison (provided the file name is not in the
196 * POSIX namespace). If the comparison matches, and the name is
197 * in the WIN32 namespace, we cache the filename in *res so
198 * that the caller, ntfs_lookup(), can work on it. If the
199 * comparison matches, and the name is in the DOS namespace, we
200 * only cache the mft reference and the file name type (we set
201 * the name length to zero for simplicity).
202 */
213 /* Only one case insensitive matching name allowed. */
216 "in phase 1. Please run chkdsk "
217 "and if that doesn't find any "
218 "errors please report you saw "
219 "this message to "
220 "linux-ntfs-dev@lists."
223 }
231 }
241 }
242 /*
243 * Not a perfect match, need to do full blown collation so we
244 * know which way in the B+tree we have to go.
245 */
250 /*
251 * If uname collates before the name of the current entry, there
252 * is definitely no such name in this index but we might need to
253 * descend into the B+tree so we just break out of the loop.
254 */
257 /* The names are not equal, continue the search. */
260 /*
261 * Names match with case insensitive comparison, now try the
262 * case sensitive comparison, which is required for proper
263 * collation.
264 */
273 /*
274 * Perfect match, this will never happen as the
275 * ntfs_are_names_equal() call will have gotten a match but we
276 * still treat it correctly.
277 */
279 }
280 /*
281 * We have finished with this index without success. Check for the
282 * presence of a child node and if not present return -ENOENT, unless
283 * we have got a matching name cached in name in which case return the
284 * mft reference associated with it.
285 */
291 }
296 /* Consistency check: Verify that an index allocation exists. */
299 "requires one. Directory inode 0x%lx is "
302 }
303 /* Get the starting vcn of the index_block holding the child node. */
306 /*
307 * We are done with the index root and the mft record. Release them,
308 * otherwise we deadlock with ntfs_map_page().
309 */
314 descend_into_child_node:
315 /*
316 * Convert vcn to index into the index allocation attribute in units
317 * of PAGE_CACHE_SIZE and map the page cache page, reading it from
318 * disk if necessary.
319 */
327 }
330 fast_descend_into_child_node:
331 /* Get to the index allocation block. */
334 /* Bounds checks. */
339 }
340 /* Catch multi sector transfer fixup errors. */
346 }
349 "different from expected VCN (0x%llx). "
350 "Directory inode 0x%lx is corrupt or driver "
355 }
359 "0x%lx has a size (%u) differing from the "
360 "directory specified size (%u). Directory "
366 }
370 "0x%lx crosses page boundary. Impossible! "
371 "Cannot access! This is probably a bug in the "
375 }
382 }
383 /* The first index entry. */
386 /*
387 * Iterate similar to above big loop but applied to index buffer, thus
388 * loop until we exceed valid memory (corruption case) or until we
389 * reach the last entry.
390 */
392 /* Bounds check. */
396 index_end) {
401 }
402 /*
403 * The last entry cannot contain a name. It can however contain
404 * a pointer to a child node in the B+tree so we just break out.
405 */
408 /*
409 * We perform a case sensitive comparison and if that matches
410 * we are done and return the mft reference of the inode (i.e.
411 * the inode number together with the sequence number for
412 * consistency checking). We convert it to cpu format before
413 * returning.
414 */
419 found_it2:
420 /*
421 * We have a perfect match, so we don't need to care
422 * about having matched imperfectly before, so we can
423 * free name and set *res to NULL.
424 * However, if the perfect match is a short file name,
425 * we need to signal this through *res, so that
426 * ntfs_lookup() can fix dcache aliasing issues.
427 * As an optimization we just reuse an existing
428 * allocation of *res.
429 */
433 GFP_NOFS);
437 }
438 }
447 }
452 }
453 /*
454 * For a case insensitive mount, we also perform a case
455 * insensitive comparison (provided the file name is not in the
456 * POSIX namespace). If the comparison matches, and the name is
457 * in the WIN32 namespace, we cache the filename in *res so
458 * that the caller, ntfs_lookup(), can work on it. If the
459 * comparison matches, and the name is in the DOS namespace, we
460 * only cache the mft reference and the file name type (we set
461 * the name length to zero for simplicity).
462 */
473 /* Only one case insensitive matching name allowed. */
476 "in phase 2. Please run chkdsk "
477 "and if that doesn't find any "
478 "errors please report you saw "
479 "this message to "
480 "linux-ntfs-dev@lists."
485 }
493 }
503 }
504 /*
505 * Not a perfect match, need to do full blown collation so we
506 * know which way in the B+tree we have to go.
507 */
512 /*
513 * If uname collates before the name of the current entry, there
514 * is definitely no such name in this index but we might need to
515 * descend into the B+tree so we just break out of the loop.
516 */
519 /* The names are not equal, continue the search. */
522 /*
523 * Names match with case insensitive comparison, now try the
524 * case sensitive comparison, which is required for proper
525 * collation.
526 */
535 /*
536 * Perfect match, this will never happen as the
537 * ntfs_are_names_equal() call will have gotten a match but we
538 * still treat it correctly.
539 */
541 }
542 /*
543 * We have finished with this index buffer without success. Check for
544 * the presence of a child node.
545 */
552 }
553 /* Child node present, descend into it. */
558 /* If vcn is in the same page cache page as old_vcn we
559 * recycle the mapped page. */
563 PAGE_CACHE_SHIFT)
568 }
572 }
573 /*
574 * No child node present, return -ENOENT, unless we have got a matching
575 * name cached in name in which case return the mft reference
576 * associated with it.
577 */
582 }
585 unm_err_out:
588 err_out:
598 }
600 dir_err_out:
603 }
605 #if 0
607 // TODO: (AIA)
608 // The algorithm embedded in this code will be required for the time when we
609 // want to support adding of entries to directories, where we require correct
610 // collation of file names in order not to cause corruption of the filesystem.
612 /**
613 * ntfs_lookup_inode_by_name - find an inode in a directory given its name
614 * @dir_ni: ntfs inode of the directory in which to search for the name
615 * @uname: Unicode name for which to search in the directory
616 * @uname_len: length of the name @uname in Unicode characters
617 *
618 * Look for an inode with name @uname in the directory with inode @dir_ni.
619 * ntfs_lookup_inode_by_name() walks the contents of the directory looking for
620 * the Unicode name. If the name is found in the directory, the corresponding
621 * inode number (>= 0) is returned as a mft reference in cpu format, i.e. it
622 * is a 64-bit number containing the sequence number.
623 *
624 * On error, a negative value is returned corresponding to the error code. In
625 * particular if the inode is not found -ENOENT is returned. Note that you
626 * can't just check the return value for being negative, you have to check the
627 * inode number for being negative which you can extract using MREC(return
628 * value).
629 *
630 * Note, @uname_len does not include the (optional) terminating NULL character.
631 */
634 {
642 u64 mref;
645 IGNORE_CASE_BOOL ic;
651 /* Get hold of the mft record for the directory. */
657 }
662 }
663 /* Find the index root attribute in the mft record. */
672 }
674 }
675 /* Get to the index root value (it's been verified in read_inode). */
679 /* The first index entry. */
682 /*
683 * Loop until we exceed valid memory (corruption case) or until we
684 * reach the last entry.
685 */
687 /* Bounds checks. */
691 index_end)
693 /*
694 * The last entry cannot contain a name. It can however contain
695 * a pointer to a child node in the B+tree so we just break out.
696 */
699 /*
700 * If the current entry has a name type of POSIX, the name is
701 * case sensitive and not otherwise. This has the effect of us
702 * not being able to access any POSIX file names which collate
703 * after the non-POSIX one when they only differ in case, but
704 * anyone doing screwy stuff like that deserves to burn in
705 * hell... Doing that kind of stuff on NT4 actually causes
706 * corruption on the partition even when using SP6a and Linux
707 * is not involved at all.
708 */
710 CASE_SENSITIVE;
711 /*
712 * If the names match perfectly, we are done and return the
713 * mft reference of the inode (i.e. the inode number together
714 * with the sequence number for consistency checking. We
715 * convert it to cpu format before returning.
716 */
721 found_it:
726 }
727 /*
728 * Not a perfect match, need to do full blown collation so we
729 * know which way in the B+tree we have to go.
730 */
735 /*
736 * If uname collates before the name of the current entry, there
737 * is definitely no such name in this index but we might need to
738 * descend into the B+tree so we just break out of the loop.
739 */
742 /* The names are not equal, continue the search. */
745 /*
746 * Names match with case insensitive comparison, now try the
747 * case sensitive comparison, which is required for proper
748 * collation.
749 */
758 /*
759 * Perfect match, this will never happen as the
760 * ntfs_are_names_equal() call will have gotten a match but we
761 * still treat it correctly.
762 */
764 }
765 /*
766 * We have finished with this index without success. Check for the
767 * presence of a child node.
768 */
770 /* No child node, return -ENOENT. */
774 /* Consistency check: Verify that an index allocation exists. */
777 "requires one. Directory inode 0x%lx is "
780 }
781 /* Get the starting vcn of the index_block holding the child node. */
784 /*
785 * We are done with the index root and the mft record. Release them,
786 * otherwise we deadlock with ntfs_map_page().
787 */
792 descend_into_child_node:
793 /*
794 * Convert vcn to index into the index allocation attribute in units
795 * of PAGE_CACHE_SIZE and map the page cache page, reading it from
796 * disk if necessary.
797 */
805 }
808 fast_descend_into_child_node:
809 /* Get to the index allocation block. */
812 /* Bounds checks. */
817 }
818 /* Catch multi sector transfer fixup errors. */
824 }
827 "different from expected VCN (0x%llx). "
828 "Directory inode 0x%lx is corrupt or driver "
833 }
837 "0x%lx has a size (%u) differing from the "
838 "directory specified size (%u). Directory "
844 }
848 "0x%lx crosses page boundary. Impossible! "
849 "Cannot access! This is probably a bug in the "
853 }
860 }
861 /* The first index entry. */
864 /*
865 * Iterate similar to above big loop but applied to index buffer, thus
866 * loop until we exceed valid memory (corruption case) or until we
867 * reach the last entry.
868 */
870 /* Bounds check. */
874 index_end) {
879 }
880 /*
881 * The last entry cannot contain a name. It can however contain
882 * a pointer to a child node in the B+tree so we just break out.
883 */
886 /*
887 * If the current entry has a name type of POSIX, the name is
888 * case sensitive and not otherwise. This has the effect of us
889 * not being able to access any POSIX file names which collate
890 * after the non-POSIX one when they only differ in case, but
891 * anyone doing screwy stuff like that deserves to burn in
892 * hell... Doing that kind of stuff on NT4 actually causes
893 * corruption on the partition even when using SP6a and Linux
894 * is not involved at all.
895 */
897 CASE_SENSITIVE;
898 /*
899 * If the names match perfectly, we are done and return the
900 * mft reference of the inode (i.e. the inode number together
901 * with the sequence number for consistency checking. We
902 * convert it to cpu format before returning.
903 */
908 found_it2:
913 }
914 /*
915 * Not a perfect match, need to do full blown collation so we
916 * know which way in the B+tree we have to go.
917 */
922 /*
923 * If uname collates before the name of the current entry, there
924 * is definitely no such name in this index but we might need to
925 * descend into the B+tree so we just break out of the loop.
926 */
929 /* The names are not equal, continue the search. */
932 /*
933 * Names match with case insensitive comparison, now try the
934 * case sensitive comparison, which is required for proper
935 * collation.
936 */
945 /*
946 * Perfect match, this will never happen as the
947 * ntfs_are_names_equal() call will have gotten a match but we
948 * still treat it correctly.
949 */
951 }
952 /*
953 * We have finished with this index buffer without success. Check for
954 * the presence of a child node.
955 */
962 }
963 /* Child node present, descend into it. */
967 /* If vcn is in the same page cache page as old_vcn we
968 * recycle the mapped page. */
972 PAGE_CACHE_SHIFT)
977 }
981 }
982 /* No child node, return -ENOENT. */
985 unm_err_out:
988 err_out:
996 dir_err_out:
999 }
1001 #endif
1003 /**
1004 * ntfs_filldir - ntfs specific filldir method
1005 * @vol: current ntfs volume
1006 * @fpos: position in the directory
1007 * @ndir: ntfs inode of current directory
1008 * @ia_page: page in which the index allocation buffer @ie is in resides
1009 * @ie: current index entry
1010 * @name: buffer to use for the converted name
1011 * @dirent: vfs filldir callback context
1012 * @filldir: vfs filldir callback
1013 *
1014 * Convert the Unicode @name to the loaded NLS and pass it to the @filldir
1015 * callback.
1016 *
1017 * If @ia_page is not NULL it is the locked page containing the index
1018 * allocation block containing the index entry @ie.
1019 *
1020 * Note, we drop (and then reacquire) the page lock on @ia_page across the
1021 * @filldir() call otherwise we would deadlock with NFSd when it calls ->lookup
1022 * since ntfs_lookup() will lock the same page. As an optimization, we do not
1023 * retake the lock if we are returning a non-zero value as ntfs_readdir()
1024 * would need to drop the lock immediately anyway.
1025 */
1029 {
1033 FILE_NAME_TYPE_FLAGS name_type;
1039 }
1043 }
1048 }
1056 }
1058 FILE_ATTR_DUP_FILE_NAME_INDEX_PRESENT)
1060 else
1063 /*
1064 * Drop the page lock otherwise we deadlock with NFS when it calls
1065 * ->lookup since ntfs_lookup() will lock the same page.
1066 */
1073 /* Relock the page but not if we are aborting ->readdir. */
1077 }
1079 /*
1080 * We use the same basic approach as the old NTFS driver, i.e. we parse the
1081 * index root entries and then the index allocation entries that are marked
1082 * as in use in the index bitmap.
1083 *
1084 * While this will return the names in random order this doesn't matter for
1085 * ->readdir but OTOH results in a faster ->readdir.
1086 *
1087 * VFS calls ->readdir without BKL but with i_mutex held. This protects the VFS
1088 * parts (e.g. ->f_pos and ->i_size, and it also protects against directory
1089 * modifications).
1090 *
1091 * Locking: - Caller must hold i_mutex on the directory.
1092 * - Each page cache page in the index allocation mapping must be
1093 * locked whilst being accessed otherwise we may find a corrupt
1094 * page due to it being under ->writepage at the moment which
1095 * applies the mst protection fixups before writing out and then
1096 * removes them again after the write is complete after which it
1097 * unlocks the page.
1098 */
1100 {
1122 /* Are we at end of dir yet? */
1126 /* Emulate . and .. for all directories. */
1133 fpos++;
1134 }
1143 fpos++;
1144 }
1147 /*
1148 * Allocate a buffer to store the current name being processed
1149 * converted to format determined by current NLS.
1150 */
1155 }
1156 /* Are we jumping straight into the index allocation attribute? */
1159 /* Get hold of the mft record for the directory. */
1165 }
1170 }
1171 /* Get the offset into the index root attribute. */
1173 /* Find the index root attribute in the mft record. */
1180 }
1181 /*
1182 * Copy the index root attribute value to a buffer so that we can put
1183 * the search context and unmap the mft record before calling the
1184 * filldir() callback. We need to do this because of NFSd which calls
1185 * ->lookup() from its filldir callback() and this causes NTFS to
1186 * deadlock as ntfs_lookup() maps the mft record of the directory and
1187 * we have got it mapped here already. The only solution is for us to
1188 * unmap the mft record here so that a call to ntfs_lookup() is able to
1189 * map the mft record without deadlocking.
1190 */
1196 }
1197 /* Copy the index root value (it has been verified in read_inode). */
1205 /* The first index entry. */
1208 /*
1209 * Loop until we exceed valid memory (corruption case) or until we
1210 * reach the last entry or until filldir tells us it has had enough
1211 * or signals an error (both covered by the rc test).
1212 */
1215 /* Bounds checks. */
1219 index_end))
1221 /* The last entry cannot contain a name. */
1224 /* Skip index root entry if continuing previous readdir. */
1227 /* Advance the position even if going to skip the entry. */
1229 /* Submit the name to the filldir callback. */
1231 filldir);
1235 }
1236 }
1237 /* We are done with the index root and can free the buffer. */
1240 /* If there is no index allocation attribute we are finished. */
1243 /* Advance fpos to the beginning of the index allocation. */
1245 skip_index_root:
1248 /* Get the offset into the index allocation attribute. */
1257 }
1259 /* Get the starting bitmap bit position and sanity check it. */
1265 }
1266 /* Get the starting bit position in the current bitmap page. */
1269 get_next_bmp_page:
1281 }
1283 /* Find next index block in use. */
1285 find_next_index_buffer:
1286 cur_bmp_pos++;
1287 /*
1288 * If we have reached the end of the bitmap page, get the next
1289 * page, and put away the old one.
1290 */
1296 }
1297 /* If we have reached the end of the bitmap, we are done. */
1302 }
1305 /* If the current index buffer is in the same page we reuse the page. */
1312 }
1313 /*
1314 * Map the page cache page containing the current ia_pos,
1315 * reading it from disk if necessary.
1316 */
1323 }
1326 }
1327 /* Get the current index buffer. */
1330 /* Bounds checks. */
1335 }
1336 /* Catch multi sector transfer fixup errors. */
1343 }
1348 "different from expected VCN (0x%llx). "
1349 "Directory inode 0x%lx is corrupt or driver "
1355 }
1359 "0x%lx has a size (%u) differing from the "
1360 "directory specified size (%u). Directory "
1367 }
1371 "0x%lx crosses page boundary. Impossible! "
1372 "Cannot access! This is probably a bug in the "
1376 }
1385 }
1386 /* The first index entry in this index buffer. */
1389 /*
1390 * Loop until we exceed valid memory (corruption case) or until we
1391 * reach the last entry or until filldir tells us it has had enough
1392 * or signals an error (both covered by the rc test).
1393 */
1398 /* Bounds checks. */
1402 index_end))
1404 /* The last entry cannot contain a name. */
1407 /* Skip index block entry if continuing previous readdir. */
1410 /* Advance the position even if going to skip the entry. */
1415 /*
1416 * Submit the name to the @filldir callback. Note,
1417 * ntfs_filldir() drops the lock on @ia_page but it retakes it
1418 * before returning, unless a non-zero value is returned in
1419 * which case the page is left unlocked.
1420 */
1422 filldir);
1424 /* @ia_page is already unlocked in this case. */
1429 }
1430 }
1432 unm_EOD:
1436 }
1439 EOD:
1440 /* We are finished, set fpos to EOD. */
1442 abort:
1444 done:
1445 #ifdef DEBUG
1448 else
1451 #endif
1454 err_out:
1457 iput_err_out:
1459 }
1463 }
1475 }
1477 /**
1478 * ntfs_dir_open - called when an inode is about to be opened
1479 * @vi: inode to be opened
1480 * @filp: file structure describing the inode
1481 *
1482 * Limit directory size to the page cache limit on architectures where unsigned
1483 * long is 32-bits. This is the most we can do for now without overflowing the
1484 * page cache page index. Doing it this way means we don't run into problems
1485 * because of existing too large directories. It would be better to allow the
1486 * user to read the accessible part of the directory but I doubt very much
1487 * anyone is going to hit this check on a 32-bit architecture, so there is no
1488 * point in adding the extra complexity required to support this.
1489 *
1490 * On 64-bit architectures, the check is hopefully optimized away by the
1491 * compiler.
1492 */
1494 {
1498 }
1500 }
1502 #ifdef NTFS_RW
1504 /**
1505 * ntfs_dir_fsync - sync a directory to disk
1506 * @filp: directory to be synced
1507 * @dentry: dentry describing the directory to sync
1508 * @datasync: if non-zero only flush user data and not metadata
1509 *
1510 * Data integrity sync of a directory to disk. Used for fsync, fdatasync, and
1511 * msync system calls. This function is based on file.c::ntfs_file_fsync().
1512 *
1513 * Write the mft record and all associated extent mft records as well as the
1514 * $INDEX_ALLOCATION and $BITMAP attributes and then sync the block device.
1515 *
1516 * If @datasync is true, we do not wait on the inode(s) to be written out
1517 * but we always wait on the page cache pages to be written out.
1518 *
1519 * Note: In the past @filp could be NULL so we ignore it as we don't need it
1520 * anyway.
1521 *
1522 * Locking: Caller must hold i_mutex on the inode.
1523 *
1524 * TODO: We should probably also write all attribute/index inodes associated
1525 * with this inode but since we have no simple way of getting to them we ignore
1526 * this problem for now. We do write the $BITMAP attribute if it is present
1527 * which is the important one for a directory so things are not too bad.
1528 */
1531 {
1534 ntfs_attr na;
1538 /* If the bitmap attribute inode is in memory sync it, too. */
1547 }
1555 else
1559 }
1567 #ifdef NTFS_RW
1570 i/o operations on a kiocb. */
1573 mounted filesystem. */
1575 };