| blob | 3aac5c917afe73b02f2ca5a6f63f347ffb69f629 |
1 // SPDX-License-Identifier: GPL-2.0-or-later
2 /**
3 * mft.c - NTFS kernel mft record operations. Part of the Linux-NTFS project.
4 *
5 * Copyright (c) 2001-2012 Anton Altaparmakov and Tuxera Inc.
6 * Copyright (c) 2002 Richard Russon
7 */
9 #include <linux/buffer_head.h>
10 #include <linux/slab.h>
11 #include <linux/swap.h>
12 #include <linux/bio.h>
24 #define MAX_BHS (PAGE_SIZE / NTFS_BLOCK_SIZE)
26 /**
27 * map_mft_record_page - map the page in which a specific mft record resides
28 * @ni: ntfs inode whose mft record page to map
29 *
30 * This maps the page in which the mft record of the ntfs inode @ni is situated
31 * and returns a pointer to the mft record within the mapped page.
32 *
33 * Return value needs to be checked with IS_ERR() and if that is true PTR_ERR()
34 * contains the negative error code returned.
35 */
37 {
38 loff_t i_size;
46 /*
47 * The index into the page cache and the offset within the page cache
48 * page of the wanted mft record. FIXME: We need to check for
49 * overflowing the unsigned long, but I don't think we would ever get
50 * here if the volume was that big...
51 */
53 PAGE_SHIFT;
57 /* The maximum valid index into the page cache for $MFT's data. */
60 /* If the wanted index is out of bounds the mft record doesn't exist. */
66 "which is beyond the end of the mft. "
67 "This is probably a bug in the ntfs "
70 }
71 }
72 /* Read, map, and pin the page. */
75 /* Catch multi sector transfer fixup errors. */
77 ofs)))) {
81 }
87 }
88 err_out:
92 }
94 /**
95 * map_mft_record - map, pin and lock an mft record
96 * @ni: ntfs inode whose MFT record to map
97 *
98 * First, take the mrec_lock mutex. We might now be sleeping, while waiting
99 * for the mutex if it was already locked by someone else.
100 *
101 * The page of the record is mapped using map_mft_record_page() before being
102 * returned to the caller.
103 *
104 * This in turn uses ntfs_map_page() to get the page containing the wanted mft
105 * record (it in turn calls read_cache_page() which reads it in from disk if
106 * necessary, increments the use count on the page so that it cannot disappear
107 * under us and returns a reference to the page cache page).
108 *
109 * If read_cache_page() invokes ntfs_readpage() to load the page from disk, it
110 * sets PG_locked and clears PG_uptodate on the page. Once I/O has completed
111 * and the post-read mst fixups on each mft record in the page have been
112 * performed, the page gets PG_uptodate set and PG_locked cleared (this is done
113 * in our asynchronous I/O completion handler end_buffer_read_mft_async()).
114 * ntfs_map_page() waits for PG_locked to become clear and checks if
115 * PG_uptodate is set and returns an error code if not. This provides
116 * sufficient protection against races when reading/using the page.
117 *
118 * However there is the write mapping to think about. Doing the above described
119 * checking here will be fine, because when initiating the write we will set
120 * PG_locked and clear PG_uptodate making sure nobody is touching the page
121 * contents. Doing the locking this way means that the commit to disk code in
122 * the page cache code paths is automatically sufficiently locked with us as
123 * we will not touch a page that has been locked or is not uptodate. The only
124 * locking problem then is them locking the page while we are accessing it.
125 *
126 * So that code will end up having to own the mrec_lock of all mft
127 * records/inodes present in the page before I/O can proceed. In that case we
128 * wouldn't need to bother with PG_locked and PG_uptodate as nobody will be
129 * accessing anything without owning the mrec_lock mutex. But we do need to
130 * use them because of the read_cache_page() invocation and the code becomes so
131 * much simpler this way that it is well worth it.
132 *
133 * The mft record is now ours and we return a pointer to it. You need to check
134 * the returned pointer with IS_ERR() and if that is true, PTR_ERR() will return
135 * the error code.
136 *
137 * NOTE: Caller is responsible for setting the mft record dirty before calling
138 * unmap_mft_record(). This is obviously only necessary if the caller really
139 * modified the mft record...
140 * Q: Do we want to recycle one of the VFS inode state bits instead?
141 * A: No, the inode ones mean we want to change the mft record, not we want to
142 * write it out.
143 */
145 {
150 /* Make sure the ntfs inode doesn't go away. */
153 /* Serialize access to this mft record. */
164 }
166 /**
167 * unmap_mft_record_page - unmap the page in which a specific mft record resides
168 * @ni: ntfs inode whose mft record page to unmap
169 *
170 * This unmaps the page in which the mft record of the ntfs inode @ni is
171 * situated and returns. This is a NOOP if highmem is not configured.
172 *
173 * The unmap happens via ntfs_unmap_page() which in turn decrements the use
174 * count on the page thus releasing it from the pinned state.
175 *
176 * We do not actually unmap the page from memory of course, as that will be
177 * done by the page cache code itself when memory pressure increases or
178 * whatever.
179 */
181 {
184 // TODO: If dirty, blah...
189 }
191 /**
192 * unmap_mft_record - release a mapped mft record
193 * @ni: ntfs inode whose MFT record to unmap
194 *
195 * We release the page mapping and the mrec_lock mutex which unmaps the mft
196 * record and releases it for others to get hold of. We also release the ntfs
197 * inode by decrementing the ntfs inode reference count.
198 *
199 * NOTE: If caller has modified the mft record, it is imperative to set the mft
200 * record dirty BEFORE calling unmap_mft_record().
201 */
203 {
213 /*
214 * If pure ntfs_inode, i.e. no vfs inode attached, we leave it to
215 * ntfs_clear_extent_inode() in the extent inode case, and to the
216 * caller in the non-extent, yet pure ntfs inode case, to do the actual
217 * tear down of all structures and freeing of all allocated memory.
218 */
220 }
222 /**
223 * map_extent_mft_record - load an extent inode and attach it to its base
224 * @base_ni: base ntfs inode
225 * @mref: mft reference of the extent inode to load
226 * @ntfs_ino: on successful return, pointer to the ntfs_inode structure
227 *
228 * Load the extent mft record @mref and attach it to its base inode @base_ni.
229 * Return the mapped extent mft record if IS_ERR(result) is false. Otherwise
230 * PTR_ERR(result) gives the negative error code.
231 *
232 * On successful return, @ntfs_ino contains a pointer to the ntfs_inode
233 * structure of the mapped extent inode.
234 */
237 {
248 /* Make sure the base ntfs inode doesn't go away. */
250 /*
251 * Check if this extent inode has already been added to the base inode,
252 * in which case just return it. If not found, add it to the base
253 * inode before returning it.
254 */
262 /* Make sure the ntfs inode doesn't go away. */
265 }
266 }
270 /* We found the record; just have to map and return it. */
272 /* map_mft_record() has incremented this on success. */
275 /* Verify the sequence number. */
280 }
283 "reference! Corrupt filesystem. "
286 }
287 map_err_out:
291 }
292 /* Record wasn't there. Get a new ntfs inode and initialize it. */
298 }
303 /* Now map the record. */
310 }
311 /* Verify the sequence number if it is present. */
318 }
319 /* Attach extent inode to base inode, reallocating memory if needed. */
331 }
337 }
339 }
346 unm_err_out:
350 /*
351 * If the extent inode was not attached to the base inode we need to
352 * release it or we will leak memory.
353 */
357 }
359 #ifdef NTFS_RW
361 /**
362 * __mark_mft_record_dirty - set the mft record and the page containing it dirty
363 * @ni: ntfs inode describing the mapped mft record
364 *
365 * Internal function. Users should call mark_mft_record_dirty() instead.
366 *
367 * Set the mapped (extent) mft record of the (base or extent) ntfs inode @ni,
368 * as well as the page containing the mft record, dirty. Also, mark the base
369 * vfs inode dirty. This ensures that any changes to the mft record are
370 * written out to disk.
371 *
372 * NOTE: We only set I_DIRTY_DATASYNC (and not I_DIRTY_PAGES)
373 * on the base vfs inode, because even though file data may have been modified,
374 * it is dirty in the inode meta data rather than the data page cache of the
375 * inode, and thus there are no data pages that need writing out. Therefore, a
376 * full mark_inode_dirty() is overkill. A mark_inode_dirty_sync(), on the
377 * other hand, is not sufficient, because ->write_inode needs to be called even
378 * in case of fdatasync. This needs to happen or the file data would not
379 * necessarily hit the device synchronously, even though the vfs inode has the
380 * O_SYNC flag set. Also, I_DIRTY_DATASYNC simply "feels" better than just
381 * I_DIRTY_SYNC, since the file data has not actually hit the block device yet,
382 * which is not what I_DIRTY_SYNC on its own would suggest.
383 */
385 {
391 /* Determine the base vfs inode and mark it dirty, too. */
395 else
399 }
402 "linux-ntfs-dev@lists.sourceforge.net and say that you saw "
405 /**
406 * ntfs_sync_mft_mirror_umount - synchronise an mft record to the mft mirror
407 * @vol: ntfs volume on which the mft record to synchronize resides
408 * @mft_no: mft record number of mft record to synchronize
409 * @m: mapped, mst protected (extent) mft record to synchronize
410 *
411 * Write the mapped, mst protected (extent) mft record @m with mft record
412 * number @mft_no to the mft mirror ($MFTMirr) of the ntfs volume @vol,
413 * bypassing the page cache and the $MFTMirr inode itself.
414 *
415 * This function is only for use at umount time when the mft mirror inode has
416 * already been disposed off. We BUG() if we are called while the mft mirror
417 * inode is still attached to the volume.
418 *
419 * On success return 0. On error return -errno.
420 *
421 * NOTE: This function is not implemented yet as I am not convinced it can
422 * actually be triggered considering the sequence of commits we do in super.c::
423 * ntfs_put_super(). But just in case we provide this place holder as the
424 * alternative would be either to BUG() or to get a NULL pointer dereference
425 * and Oops.
426 */
429 {
434 }
436 /**
437 * ntfs_sync_mft_mirror - synchronize an mft record to the mft mirror
438 * @vol: ntfs volume on which the mft record to synchronize resides
439 * @mft_no: mft record number of mft record to synchronize
440 * @m: mapped, mst protected (extent) mft record to synchronize
441 * @sync: if true, wait for i/o completion
442 *
443 * Write the mapped, mst protected (extent) mft record @m with mft record
444 * number @mft_no to the mft mirror ($MFTMirr) of the ntfs volume @vol.
445 *
446 * On success return 0. On error return -errno and set the volume errors flag
447 * in the ntfs volume @vol.
448 *
449 * NOTE: We always perform synchronous i/o and ignore the @sync parameter.
450 *
451 * TODO: If @sync is false, want to do truly asynchronous i/o, i.e. just
452 * schedule i/o via ->writepage or do it via kntfsd or whatever.
453 */
456 {
473 /* This could happen during umount... */
478 }
479 /* Get the page containing the mirror copy of the mft record @m. */
486 }
490 /* Offset of the mft mirror record inside the page. */
492 /* The address in the page of the mirror copy of the mft record @m. */
494 /* Copy the mst protected mft record to the mirror. */
496 /* Create uptodate buffers if not present. */
508 }
518 /* If the buffer is outside the mft record, skip it. */
523 /* Need to map the buffer if it is not mapped already. */
525 VCN vcn;
526 LCN lcn;
530 /* Obtain the vcn and offset of the current block. */
539 /*
540 * $MFTMirr always has the whole of its runlist
541 * in memory.
542 */
544 }
545 /* Seek to element containing target vcn. */
547 rl++;
549 /* For $MFTMirr, only lcn >= 0 is a successful remap. */
551 /* Setup buffer head to correct block. */
559 "record 0x%lx because its "
560 "location on disk could not "
561 "be determined (error code "
565 }
566 }
576 /* Lock buffers and start synchronous write i/o on them. */
587 }
588 /* Wait on i/o completion of buffers. */
595 /*
596 * Set the buffer uptodate so the page and
597 * buffer states do not become out of sync.
598 */
600 }
601 }
603 /* Clean the buffers. */
606 }
607 /* Current state: all buffers are clean, unlocked, and uptodate. */
608 /* Remove the mst protection fixups again. */
619 err_out:
621 "code %i). Volume will be left marked dirty "
622 "on umount. Run ntfsfix on the partition "
625 }
627 }
629 /**
630 * write_mft_record_nolock - write out a mapped (extent) mft record
631 * @ni: ntfs inode describing the mapped (extent) mft record
632 * @m: mapped (extent) mft record to write
633 * @sync: if true, wait for i/o completion
634 *
635 * Write the mapped (extent) mft record @m described by the (regular or extent)
636 * ntfs inode @ni to backing store. If the mft record @m has a counterpart in
637 * the mft mirror, that is also updated.
638 *
639 * We only write the mft record if the ntfs inode @ni is dirty and the first
640 * buffer belonging to its mft record is dirty, too. We ignore the dirty state
641 * of subsequent buffers because we could have raced with
642 * fs/ntfs/aops.c::mark_ntfs_record_dirty().
643 *
644 * On success, clean the mft record and return 0. On error, leave the mft
645 * record dirty and return -errno.
646 *
647 * NOTE: We always perform synchronous i/o and ignore the @sync parameter.
648 * However, if the mft record has a counterpart in the mft mirror and @sync is
649 * true, we write the mft record, wait for i/o completion, and only then write
650 * the mft mirror copy. This ensures that if the system crashes either the mft
651 * or the mft mirror will contain a self-consistent mft record @m. If @sync is
652 * false on the other hand, we start i/o on both and then wait for completion
653 * on them. This provides a speedup but no longer guarantees that you will end
654 * up with a self-consistent mft record in the case of a crash but if you asked
655 * for asynchronous writing you probably do not care about that anyway.
656 *
657 * TODO: If @sync is false, want to do truly asynchronous i/o, i.e. just
658 * schedule i/o via ->writepage or do it via kntfsd or whatever.
659 */
661 {
680 }
681 /*
682 * If the ntfs_inode is clean no need to do anything. If it is dirty,
683 * mark it as clean now so that it can be redirtied later on if needed.
684 * There is no danger of races since the caller is holding the locks
685 * for the mft record @m and the page it is in.
686 */
698 /* If the buffer is outside the mft record, skip it. */
703 /*
704 * If this block is not the first one in the record, we ignore
705 * the buffer's dirty state because we could have raced with a
706 * parallel mark_ntfs_record_dirty().
707 */
709 /* This block is the first one in the record. */
712 /* Clean records are not written out. */
714 }
715 }
716 /* Need to map the buffer if it is not mapped already. */
718 VCN vcn;
719 LCN lcn;
723 /* Obtain the vcn and offset of the current block. */
732 }
733 /* Seek to element containing target vcn. */
735 rl++;
737 /* For $MFT, only lcn >= 0 is a successful remap. */
739 /* Setup buffer head to correct block. */
747 "0x%lx because its location "
748 "on disk could not be "
752 }
753 }
766 /* Apply the mst protection fixups. */
771 }
773 /* Lock buffers and start synchronous write i/o on them. */
784 }
785 /* Synchronize the mft mirror now if not @sync. */
788 /* Wait on i/o completion of buffers. */
795 /*
796 * Set the buffer uptodate so the page and buffer
797 * states do not become out of sync.
798 */
801 }
802 }
803 /* If @sync, now synchronize the mft mirror. */
806 /* Remove the mst protection fixups again. */
810 /* I/O error during writing. This is really bad! */
812 "0x%lx! Marking base inode as bad. You "
816 }
817 done:
820 cleanup_out:
821 /* Clean the buffers. */
824 err_out:
825 /*
826 * Current state: all buffers are clean, unlocked, and uptodate.
827 * The caller should mark the base inode as bad so that no more i/o
828 * happens. ->clear_inode() will still be invoked so all extent inodes
829 * and other allocated memory will be freed.
830 */
839 }
841 /**
842 * ntfs_may_write_mft_record - check if an mft record may be written out
843 * @vol: [IN] ntfs volume on which the mft record to check resides
844 * @mft_no: [IN] mft record number of the mft record to check
845 * @m: [IN] mapped mft record to check
846 * @locked_ni: [OUT] caller has to unlock this ntfs inode if one is returned
847 *
848 * Check if the mapped (base or extent) mft record @m with mft record number
849 * @mft_no belonging to the ntfs volume @vol may be written out. If necessary
850 * and possible the ntfs inode of the mft record is locked and the base vfs
851 * inode is pinned. The locked ntfs inode is then returned in @locked_ni. The
852 * caller is responsible for unlocking the ntfs inode and unpinning the base
853 * vfs inode.
854 *
855 * Return 'true' if the mft record may be written out and 'false' if not.
856 *
857 * The caller has locked the page and cleared the uptodate flag on it which
858 * means that we can safely write out any dirty mft records that do not have
859 * their inodes in icache as determined by ilookup5() as anyone
860 * opening/creating such an inode would block when attempting to map the mft
861 * record in read_cache_page() until we are finished with the write out.
862 *
863 * Here is a description of the tests we perform:
864 *
865 * If the inode is found in icache we know the mft record must be a base mft
866 * record. If it is dirty, we do not write it and return 'false' as the vfs
867 * inode write paths will result in the access times being updated which would
868 * cause the base mft record to be redirtied and written out again. (We know
869 * the access time update will modify the base mft record because Windows
870 * chkdsk complains if the standard information attribute is not in the base
871 * mft record.)
872 *
873 * If the inode is in icache and not dirty, we attempt to lock the mft record
874 * and if we find the lock was already taken, it is not safe to write the mft
875 * record and we return 'false'.
876 *
877 * If we manage to obtain the lock we have exclusive access to the mft record,
878 * which also allows us safe writeout of the mft record. We then set
879 * @locked_ni to the locked ntfs inode and return 'true'.
880 *
881 * Note we cannot just lock the mft record and sleep while waiting for the lock
882 * because this would deadlock due to lock reversal (normally the mft record is
883 * locked before the page is locked but we already have the page locked here
884 * when we try to lock the mft record).
885 *
886 * If the inode is not in icache we need to perform further checks.
887 *
888 * If the mft record is not a FILE record or it is a base mft record, we can
889 * safely write it and return 'true'.
890 *
891 * We now know the mft record is an extent mft record. We check if the inode
892 * corresponding to its base mft record is in icache and obtain a reference to
893 * it if it is. If it is not, we can safely write it and return 'true'.
894 *
895 * We now have the base inode for the extent mft record. We check if it has an
896 * ntfs inode for the extent mft record attached and if not it is safe to write
897 * the extent mft record and we return 'true'.
898 *
899 * The ntfs inode for the extent mft record is attached to the base inode so we
900 * attempt to lock the extent mft record and if we find the lock was already
901 * taken, it is not safe to write the extent mft record and we return 'false'.
902 *
903 * If we manage to obtain the lock we have exclusive access to the extent mft
904 * record, which also allows us safe writeout of the extent mft record. We
905 * set the ntfs inode of the extent mft record clean and then set @locked_ni to
906 * the now locked ntfs inode and return 'true'.
907 *
908 * Note, the reason for actually writing dirty mft records here and not just
909 * relying on the vfs inode dirty code paths is that we can have mft records
910 * modified without them ever having actual inodes in memory. Also we can have
911 * dirty mft records with clean ntfs inodes in memory. None of the described
912 * cases would result in the dirty mft records being written out if we only
913 * relied on the vfs inode dirty code paths. And these cases can really occur
914 * during allocation of new mft records and in particular when the
915 * initialized_size of the $MFT/$DATA attribute is extended and the new space
916 * is initialized using ntfs_mft_record_format(). The clean inode can then
917 * appear if the mft record is reused for a new inode before it got written
918 * out.
919 */
922 {
928 ntfs_attr na;
931 /*
932 * Normally we do not return a locked inode so set @locked_ni to NULL.
933 */
936 /*
937 * Check if the inode corresponding to this mft record is in the VFS
938 * inode cache and obtain a reference to it if it is.
939 */
945 /*
946 * Optimize inode 0, i.e. $MFT itself, since we have it in memory and
947 * we get here for it rather often.
948 */
950 /* Balance the below iput(). */
954 /*
955 * Have to use ilookup5_nowait() since ilookup5() waits for the
956 * inode lock which causes ntfs to deadlock when a concurrent
957 * inode write via the inode dirty code paths and the page
958 * dirty code path of the inode dirty code path when writing
959 * $MFT occurs.
960 */
962 }
965 /* The inode is in icache. */
967 /* Take a reference to the ntfs inode. */
969 /* If the inode is dirty, do not write this record. */
972 mft_no);
976 }
978 /* The inode is not dirty, try to take the mft record lock. */
985 }
987 mft_no);
988 /*
989 * The write has to occur while we hold the mft record lock so
990 * return the locked ntfs inode.
991 */
994 }
996 /* The inode is not in icache. */
997 /* Write the record if it is not a mft record (type "FILE"). */
1000 mft_no);
1002 }
1003 /* Write the mft record if it is a base inode. */
1006 mft_no);
1008 }
1009 /*
1010 * This is an extent mft record. Check if the inode corresponding to
1011 * its base mft record is in icache and obtain a reference to it if it
1012 * is.
1013 */
1018 /* Balance the below iput(). */
1025 /*
1026 * The base inode is not in icache, write this extent mft
1027 * record.
1028 */
1032 }
1034 /*
1035 * The base inode is in icache. Check if it has the extent inode
1036 * corresponding to this extent mft record attached.
1037 */
1041 /*
1042 * The base inode has no attached extent inodes, write this
1043 * extent mft record.
1044 */
1050 }
1051 /* Iterate over the attached extent inodes. */
1055 /*
1056 * Found the extent inode corresponding to this extent
1057 * mft record.
1058 */
1061 }
1062 }
1063 /*
1064 * If the extent inode was not attached to the base inode, write this
1065 * extent mft record.
1066 */
1074 }
1077 /* Take a reference to the extent ntfs inode. */
1080 /*
1081 * Found the extent inode coresponding to this extent mft record.
1082 * Try to take the mft record lock.
1083 */
1090 }
1092 mft_no);
1095 mft_no);
1096 /*
1097 * The write has to occur while we hold the mft record lock so return
1098 * the locked extent ntfs inode.
1099 */
1102 }
1107 /**
1108 * ntfs_mft_bitmap_find_and_alloc_free_rec_nolock - see name
1109 * @vol: volume on which to search for a free mft record
1110 * @base_ni: open base inode if allocating an extent mft record or NULL
1111 *
1112 * Search for a free mft record in the mft bitmap attribute on the ntfs volume
1113 * @vol.
1114 *
1115 * If @base_ni is NULL start the search at the default allocator position.
1116 *
1117 * If @base_ni is not NULL start the search at the mft record after the base
1118 * mft record @base_ni.
1119 *
1120 * Return the free mft record on success and -errno on error. An error code of
1121 * -ENOSPC means that there are no free mft records in the currently
1122 * initialized mft bitmap.
1123 *
1124 * Locking: Caller must hold vol->mftbmp_lock for writing.
1125 */
1128 {
1140 /*
1141 * Set the end of the pass making sure we do not overflow the mft
1142 * bitmap.
1143 */
1156 else
1163 /* This happens on a freshly formatted volume. */
1166 }
1172 /* Loop until a free mft record is found. */
1174 /* Cap size to pass_end. */
1182 /*
1183 * If we are still within the active pass, search the next page
1184 * for a zero bit.
1185 */
1193 }
1211 }
1217 "allocated mft record "
1221 }
1222 }
1228 /*
1229 * If the end of the pass has not been reached yet,
1230 * continue searching the mft bitmap for a zero bit.
1231 */
1234 }
1235 /* Do the next pass. */
1237 /*
1238 * Starting the second pass, in which we scan the first
1239 * part of the zone which we omitted earlier.
1240 */
1248 }
1249 }
1250 /* No free mft records in currently initialized mft bitmap. */
1254 }
1256 /**
1257 * ntfs_mft_bitmap_extend_allocation_nolock - extend mft bitmap by a cluster
1258 * @vol: volume on which to extend the mft bitmap attribute
1259 *
1260 * Extend the mft bitmap attribute on the ntfs volume @vol by one cluster.
1261 *
1262 * Note: Only changes allocated_size, i.e. does not touch initialized_size or
1263 * data_size.
1264 *
1265 * Return 0 on success and -errno on error.
1266 *
1267 * Locking: - Caller must hold vol->mftbmp_lock for writing.
1268 * - This function takes NTFS_I(vol->mftbmp_ino)->runlist.lock for
1269 * writing and releases it before returning.
1270 * - This function takes vol->lcnbmp_lock for writing and releases it
1271 * before returning.
1272 */
1274 {
1275 LCN lcn;
1276 s64 ll;
1296 /*
1297 * Determine the last lcn of the mft bitmap. The allocated size of the
1298 * mft bitmap cannot be zero so we are ok to do this.
1299 */
1312 else
1315 }
1319 /*
1320 * Attempt to get the cluster following the last allocated cluster by
1321 * hand as it may be in the MFT zone so the allocator would not give it
1322 * to us.
1323 */
1331 }
1336 /* Next cluster is free, allocate it. */
1342 /* Update the mft bitmap runlist. */
1350 /* Allocate a cluster from the DATA_ZONE. */
1358 }
1368 }
1371 }
1375 /* Find the last run in the new runlist. */
1377 ;
1378 }
1379 /*
1380 * Update the attribute record as well. Note: @rl is the last
1381 * (non-terminator) runlist element of mft bitmap.
1382 */
1388 }
1394 }
1404 }
1407 /* Search back for the previous last allocated cluster of mft bitmap. */
1411 }
1414 /* Get the size for the new mapping pairs array for this extent. */
1423 }
1424 /* Expand the attribute record if necessary. */
1433 }
1434 // TODO: Deal with this by moving this extent to a new mft
1435 // record or by starting a new extent in a new mft record or by
1436 // moving other attributes out of this mft record.
1437 // Note: It will need to be a special mft record and if none of
1438 // those are available it gets rather complicated...
1440 "accommodate extended mft bitmap attribute "
1444 }
1446 /* Generate the mapping pairs array directly into the attr record. */
1454 }
1455 /* Update the highest_vcn. */
1457 /*
1458 * We now have extended the mft bitmap allocated_size by one cluster.
1459 * Reflect this in the ntfs_inode structure and the attribute record.
1460 */
1462 /*
1463 * We are not in the first attribute extent, switch to it, but
1464 * first ensure the changes will make it to disk later.
1465 */
1476 }
1478 }
1484 /* Ensure the changes make it to disk. */
1492 restore_undo_alloc:
1505 /*
1506 * The only thing that is now wrong is ->allocated_size of the
1507 * base attribute extent which chkdsk should be able to fix.
1508 */
1511 }
1514 undo_alloc:
1516 /* Truncate the last run in the runlist by one cluster. */
1521 /* Remove the last run from the runlist. */
1524 }
1525 /* Deallocate the cluster. */
1530 }
1541 }
1546 }
1549 }
1556 }
1558 /**
1559 * ntfs_mft_bitmap_extend_initialized_nolock - extend mftbmp initialized data
1560 * @vol: volume on which to extend the mft bitmap attribute
1561 *
1562 * Extend the initialized portion of the mft bitmap attribute on the ntfs
1563 * volume @vol by 8 bytes.
1564 *
1565 * Note: Only changes initialized_size and data_size, i.e. requires that
1566 * allocated_size is big enough to fit the new initialized_size.
1567 *
1568 * Return 0 on success and -error on error.
1569 *
1570 * Locking: Caller must hold vol->mftbmp_lock for writing.
1571 */
1573 {
1587 /* Get the attribute record. */
1592 }
1598 }
1607 }
1612 /*
1613 * We can simply update the initialized_size before filling the space
1614 * with zeroes because the caller is holding the mft bitmap lock for
1615 * writing which ensures that no one else is trying to access the data.
1616 */
1624 }
1626 /* Ensure the changes make it to disk. */
1631 /* Initialize the mft bitmap attribute value with zeroes. */
1637 }
1639 /* Try to recover from the error. */
1645 }
1651 }
1657 put_err_out:
1659 unm_err_out:
1662 }
1671 }
1677 #ifdef DEBUG
1686 err_out:
1688 }
1690 /**
1691 * ntfs_mft_data_extend_allocation_nolock - extend mft data attribute
1692 * @vol: volume on which to extend the mft data attribute
1693 *
1694 * Extend the mft data attribute on the ntfs volume @vol by 16 mft records
1695 * worth of clusters or if not enough space for this by one mft record worth
1696 * of clusters.
1697 *
1698 * Note: Only changes allocated_size, i.e. does not touch initialized_size or
1699 * data_size.
1700 *
1701 * Return 0 on success and -errno on error.
1702 *
1703 * Locking: - Caller must hold vol->mftbmp_lock for writing.
1704 * - This function takes NTFS_I(vol->mft_ino)->runlist.lock for
1705 * writing and releases it before returning.
1706 * - This function calls functions which take vol->lcnbmp_lock for
1707 * writing and release it before returning.
1708 */
1710 {
1711 LCN lcn;
1712 VCN old_last_vcn;
1726 /*
1727 * Determine the preferred allocation location, i.e. the last lcn of
1728 * the mft data attribute. The allocated size of the mft data
1729 * attribute cannot be zero so we are ok to do this.
1730 */
1743 else
1746 }
1749 /* Minimum allocation is one mft record worth of clusters. */
1753 /* Want to allocate 16 mft records worth of clusters. */
1757 /* Ensure we do not go above 2^32-1 mft records. */
1767 "because the maximum number of inodes "
1771 }
1772 }
1783 "number of clusters (%lli) for the "
1787 }
1788 /*
1789 * There is not enough space to do the allocation, but there
1790 * might be enough space to do a minimal allocation so try that
1791 * before failing.
1792 */
1806 }
1809 }
1812 /* Find the last run in the new runlist. */
1814 ;
1815 /* Update the attribute record as well. */
1821 }
1827 }
1836 }
1839 /* Search back for the previous last allocated cluster of mft bitmap. */
1843 }
1846 /* Get the size for the new mapping pairs array for this extent. */
1855 }
1856 /* Expand the attribute record if necessary. */
1865 }
1866 // TODO: Deal with this by moving this extent to a new mft
1867 // record or by starting a new extent in a new mft record or by
1868 // moving other attributes out of this mft record.
1869 // Note: Use the special reserved mft records and ensure that
1870 // this extent is not required to find the mft record in
1871 // question. If no free special records left we would need to
1872 // move an existing record away, insert ours in its place, and
1873 // then place the moved record into the newly allocated space
1874 // and we would then need to update all references to this mft
1875 // record appropriately. This is rather complicated...
1877 "accommodate extended mft data attribute "
1881 }
1883 /* Generate the mapping pairs array directly into the attr record. */
1891 }
1892 /* Update the highest_vcn. */
1894 /*
1895 * We now have extended the mft data allocated_size by nr clusters.
1896 * Reflect this in the ntfs_inode structure and the attribute record.
1897 * @rl is the last (non-terminator) runlist element of mft data
1898 * attribute.
1899 */
1901 /*
1902 * We are not in the first attribute extent, switch to it, but
1903 * first ensure the changes will make it to disk later.
1904 */
1910 ctx);
1915 }
1917 }
1923 /* Ensure the changes make it to disk. */
1931 restore_undo_alloc:
1943 /*
1944 * The only thing that is now wrong is ->allocated_size of the
1945 * base attribute extent which chkdsk should be able to fix.
1946 */
1949 }
1952 undo_alloc:
1957 }
1963 }
1973 }
1978 }
1985 }
1992 }
1994 /**
1995 * ntfs_mft_record_layout - layout an mft record into a memory buffer
1996 * @vol: volume to which the mft record will belong
1997 * @mft_no: mft reference specifying the mft record number
1998 * @m: destination buffer of size >= @vol->mft_record_size bytes
1999 *
2000 * Layout an empty, unused mft record with the mft record number @mft_no into
2001 * the buffer @m. The volume @vol is needed because the mft record structure
2002 * was modified in NTFS 3.1 so we need to know which volume version this mft
2003 * record will be used on.
2004 *
2005 * Return 0 on success and -errno on error.
2006 */
2009 {
2017 }
2018 /* Start by clearing the whole mft record to gives us a clean slate. */
2020 /* Aligned to 2-byte boundary. */
2025 /*
2026 * Set the NTFS 3.1+ specific fields while we know that the
2027 * volume version is 3.1+.
2028 */
2031 }
2039 "size. Setting usa_count to 1. If chkdsk "
2040 "reports this as corruption, please email "
2041 "linux-ntfs-dev@lists.sourceforge.net stating "
2042 "that you saw this message and that the "
2043 "modified filesystem created was corrupt. "
2045 }
2046 /* Set the update sequence number to 1. */
2051 /*
2052 * Place the attributes straight after the update sequence array,
2053 * aligned to 8-byte boundary.
2054 */
2058 /*
2059 * Using attrs_offset plus eight bytes (for the termination attribute).
2060 * attrs_offset is already aligned to 8-byte boundary, so no need to
2061 * align again.
2062 */
2067 /* Add the termination attribute. */
2073 }
2075 /**
2076 * ntfs_mft_record_format - format an mft record on an ntfs volume
2077 * @vol: volume on which to format the mft record
2078 * @mft_no: mft record number to format
2079 *
2080 * Format the mft record @mft_no in $MFT/$DATA, i.e. lay out an empty, unused
2081 * mft record into the appropriate place of the mft data attribute. This is
2082 * used when extending the mft data attribute.
2083 *
2084 * Return 0 on success and -errno on error.
2085 */
2087 {
2088 loff_t i_size;
2097 /*
2098 * The index into the page cache and the offset within the page cache
2099 * page of the wanted mft record.
2100 */
2103 /* The maximum valid index into the page cache for $MFT's data. */
2112 }
2113 }
2114 /* Read, map, and pin the page containing the mft record. */
2120 }
2133 }
2137 /*
2138 * Make sure the mft record is written out to disk. We could use
2139 * ilookup5() to check if an inode is in icache and so on but this is
2140 * unnecessary as ntfs_writepage() will write the dirty record anyway.
2141 */
2146 }
2148 /**
2149 * ntfs_mft_record_alloc - allocate an mft record on an ntfs volume
2150 * @vol: [IN] volume on which to allocate the mft record
2151 * @mode: [IN] mode if want a file or directory, i.e. base inode or 0
2152 * @base_ni: [IN] open base inode if allocating an extent mft record or NULL
2153 * @mrec: [OUT] on successful return this is the mapped mft record
2154 *
2155 * Allocate an mft record in $MFT/$DATA of an open ntfs volume @vol.
2156 *
2157 * If @base_ni is NULL make the mft record a base mft record, i.e. a file or
2158 * direvctory inode, and allocate it at the default allocator position. In
2159 * this case @mode is the file mode as given to us by the caller. We in
2160 * particular use @mode to distinguish whether a file or a directory is being
2161 * created (S_IFDIR(mode) and S_IFREG(mode), respectively).
2162 *
2163 * If @base_ni is not NULL make the allocated mft record an extent record,
2164 * allocate it starting at the mft record after the base mft record and attach
2165 * the allocated and opened ntfs inode to the base inode @base_ni. In this
2166 * case @mode must be 0 as it is meaningless for extent inodes.
2167 *
2168 * You need to check the return value with IS_ERR(). If false, the function
2169 * was successful and the return value is the now opened ntfs inode of the
2170 * allocated mft record. *@mrec is then set to the allocated, mapped, pinned,
2171 * and locked mft record. If IS_ERR() is true, the function failed and the
2172 * error code is obtained from PTR_ERR(return value). *@mrec is undefined in
2173 * this case.
2174 *
2175 * Allocation strategy:
2176 *
2177 * To find a free mft record, we scan the mft bitmap for a zero bit. To
2178 * optimize this we start scanning at the place specified by @base_ni or if
2179 * @base_ni is NULL we start where we last stopped and we perform wrap around
2180 * when we reach the end. Note, we do not try to allocate mft records below
2181 * number 24 because numbers 0 to 15 are the defined system files anyway and 16
2182 * to 24 are special in that they are used for storing extension mft records
2183 * for the $DATA attribute of $MFT. This is required to avoid the possibility
2184 * of creating a runlist with a circular dependency which once written to disk
2185 * can never be read in again. Windows will only use records 16 to 24 for
2186 * normal files if the volume is completely out of space. We never use them
2187 * which means that when the volume is really out of space we cannot create any
2188 * more files while Windows can still create up to 8 small files. We can start
2189 * doing this at some later time, it does not matter much for now.
2190 *
2191 * When scanning the mft bitmap, we only search up to the last allocated mft
2192 * record. If there are no free records left in the range 24 to number of
2193 * allocated mft records, then we extend the $MFT/$DATA attribute in order to
2194 * create free mft records. We extend the allocated size of $MFT/$DATA by 16
2195 * records at a time or one cluster, if cluster size is above 16kiB. If there
2196 * is not sufficient space to do this, we try to extend by a single mft record
2197 * or one cluster, if cluster size is above the mft record size.
2198 *
2199 * No matter how many mft records we allocate, we initialize only the first
2200 * allocated mft record, incrementing mft data size and initialized size
2201 * accordingly, open an ntfs_inode for it and return it to the caller, unless
2202 * there are less than 24 mft records, in which case we allocate and initialize
2203 * mft records until we reach record 24 which we consider as the first free mft
2204 * record for use by normal files.
2205 *
2206 * If during any stage we overflow the initialized data in the mft bitmap, we
2207 * extend the initialized size (and data size) by 8 bytes, allocating another
2208 * cluster if required. The bitmap data size has to be at least equal to the
2209 * number of mft records in the mft, but it can be bigger, in which case the
2210 * superflous bits are padded with zeroes.
2211 *
2212 * Thus, when we return successfully (IS_ERR() is false), we will have:
2213 * - initialized / extended the mft bitmap if necessary,
2214 * - initialized / extended the mft data if necessary,
2215 * - set the bit corresponding to the mft record being allocated in the
2216 * mft bitmap,
2217 * - opened an ntfs_inode for the allocated mft record, and we will have
2218 * - returned the ntfs_inode as well as the allocated mapped, pinned, and
2219 * locked mft record.
2220 *
2221 * On error, the volume will be left in a consistent state and no record will
2222 * be allocated. If rolling back a partial operation fails, we may leave some
2223 * inconsistent metadata in which case we set NVolErrors() so the volume is
2224 * left dirty when unmounted.
2225 *
2226 * Note, this function cannot make use of most of the normal functions, like
2227 * for example for attribute resizing, etc, because when the run list overflows
2228 * the base mft record and an attribute list is used, it is very important that
2229 * the extension mft records used to store the $DATA attribute of $MFT can be
2230 * reached without having to read the information contained inside them, as
2231 * this would make it impossible to find them in the first place after the
2232 * volume is unmounted. $MFT/$BITMAP probably does not need to follow this
2233 * rule because the bitmap is not essential for finding the mft records, but on
2234 * the other hand, handling the bitmap in this special way would make life
2235 * easier because otherwise there might be circular invocations of functions
2236 * when reading the bitmap.
2237 */
2240 {
2249 pgoff_t index;
2259 /* @mode and @base_ni are mutually exclusive. */
2264 /* @mode and @base_ni are mutually exclusive. */
2266 /* We only support creation of normal files and directories. */
2269 }
2279 }
2283 }
2284 /*
2285 * No free mft records left. If the mft bitmap already covers more
2286 * than the currently used mft records, the next records are all free,
2287 * so we can simply allocate the first unused mft record.
2288 * Note: We also have to make sure that the mft bitmap at least covers
2289 * the first 24 mft records as they are special and whilst they may not
2290 * be in use, we do not allocate from them.
2291 */
2307 }
2308 /*
2309 * The mft bitmap needs to be expanded until it covers the first unused
2310 * mft record that we can allocate.
2311 * Note: The smallest mft record we allocate is mft record 24.
2312 */
2325 /* Need to extend bitmap by one more cluster. */
2331 }
2332 #ifdef DEBUG
2335 "allocated_size 0x%llx, data_size 0x%llx, "
2342 }
2343 /*
2344 * We now have sufficient allocated space, extend the initialized_size
2345 * as well as the data_size if necessary and fill the new space with
2346 * zeroes.
2347 */
2352 }
2353 #ifdef DEBUG
2356 "allocated_size 0x%llx, data_size 0x%llx, "
2364 found_free_rec:
2365 /* @bit is the found free mft record, allocate it in the mft bitmap. */
2372 }
2374 have_alloc_rec:
2375 /*
2376 * The mft bitmap is now uptodate. Deal with mft data attribute now.
2377 * Note, we keep hold of the mft bitmap lock for writing until all
2378 * modifications to the mft data attribute are complete, too, as they
2379 * will impact decisions for mft bitmap and mft record allocation done
2380 * by a parallel allocation and if the lock is not maintained a
2381 * parallel allocation could allocate the same mft record as this one.
2382 */
2390 }
2392 /*
2393 * The mft record is outside the initialized data. Extend the mft data
2394 * attribute until it covers the allocated record. The loop is only
2395 * actually traversed more than once when a freshly formatted volume is
2396 * first written to so it optimizes away nicely in the common case.
2397 */
2400 "allocated_size 0x%llx, data_size 0x%llx, "
2412 }
2415 "allocated_size 0x%llx, data_size 0x%llx, "
2420 }
2422 /*
2423 * Extend mft data initialized size (and data size of course) to reach
2424 * the allocated mft record, formatting the mft records allong the way.
2425 * Note: We only modify the ntfs_inode structure as that is all that is
2426 * needed by ntfs_mft_record_format(). We will update the attribute
2427 * record itself in one fell swoop later on.
2428 */
2447 }
2450 }
2453 /* Update the mft data attribute record to reflect the new sizes. */
2459 }
2466 }
2475 }
2483 /* Ensure the changes make it to disk. */
2490 "allocated_size 0x%llx, data_size 0x%llx, "
2498 mft_rec_already_initialized:
2499 /*
2500 * We can finally drop the mft bitmap lock as the mft data attribute
2501 * has been fully updated. The only disparity left is that the
2502 * allocated mft record still needs to be marked as in use to match the
2503 * set bit in the mft bitmap but this is actually not a problem since
2504 * this mft record is not referenced from anywhere yet and the fact
2505 * that it is allocated in the mft bitmap means that no-one will try to
2506 * allocate it either.
2507 */
2509 /*
2510 * We now have allocated and initialized the mft record. Calculate the
2511 * index of and the offset within the page cache page the record is in.
2512 */
2515 /* Read, map, and pin the page containing the mft record. */
2522 }
2527 /* If we just formatted the mft record no need to do it again. */
2529 /* Sanity check that the mft record is really not in use. */
2533 "free in mft bitmap but is marked "
2534 "used itself. Corrupt filesystem. "
2543 }
2544 /*
2545 * We need to (re-)format the mft record, preserving the
2546 * sequence number if it is not zero as well as the update
2547 * sequence number if it is not zero or -1 (0xffff). This
2548 * means we do not need to care whether or not something went
2549 * wrong with the previous mft record.
2550 */
2561 }
2566 }
2567 /* Set the mft record itself in use. */
2576 /*
2577 * Setup the base mft record in the extent mft record. This
2578 * completes initialization of the allocated extent mft record
2579 * and we can simply use it with map_extent_mft_record().
2580 */
2583 /*
2584 * Allocate an extent inode structure for the new mft record,
2585 * attach it to the base inode @base_ni and map, pin, and lock
2586 * its, i.e. the allocated, mft record.
2587 */
2593 /* Set the mft record itself not in use. */
2597 /* Make sure the mft record is written out to disk. */
2602 }
2604 /*
2605 * Make sure the allocated mft record is written out to disk.
2606 * No need to set the inode dirty because the caller is going
2607 * to do that anyway after finishing with the new extent mft
2608 * record (e.g. at a minimum a new attribute will be added to
2609 * the mft record.
2610 */
2613 /*
2614 * Need to unmap the page since map_extent_mft_record() mapped
2615 * it as well so we have it mapped twice at the moment.
2616 */
2619 /*
2620 * Allocate a new VFS inode and set it up. NOTE: @vi->i_nlink
2621 * is set to 1 but the mft record->link_count is 0. The caller
2622 * needs to bear this in mind.
2623 */
2627 /* Set the mft record itself not in use. */
2631 /* Make sure the mft record is written out to disk. */
2636 }
2639 /* The owner and group come from the ntfs volume. */
2643 /* Initialize the ntfs specific part of @vi. */
2646 /*
2647 * Set the appropriate mode, attribute type, and name. For
2648 * directories, also setup the index values to the defaults.
2649 */
2670 }
2678 }
2682 /* Set the inode times to the current time. */
2685 /*
2686 * Set the file size to 0, the ntfs inode sizes are set to 0 by
2687 * the call to ntfs_init_big_inode() below.
2688 */
2692 /* Set the sequence number. */
2694 /*
2695 * Manually map, pin, and lock the mft record as we already
2696 * have its page mapped and it is very easy to do.
2697 */
2702 /*
2703 * Make sure the allocated mft record is written out to disk.
2704 * NOTE: We do not set the ntfs inode dirty because this would
2705 * fail in ntfs_write_inode() because the inode does not have a
2706 * standard information attribute yet. Also, there is no need
2707 * to set the inode dirty because the caller is going to do
2708 * that anyway after finishing with the new mft record (e.g. at
2709 * a minimum some new attributes will be added to the mft
2710 * record.
2711 */
2715 /* Add the inode to the inode hash for the superblock. */
2718 /* Update the default mft allocation position. */
2720 }
2721 /*
2722 * Return the opened, allocated inode of the allocated mft record as
2723 * well as the mapped, pinned, and locked mft record.
2724 */
2729 undo_data_init:
2735 undo_mftbmp_alloc:
2737 undo_mftbmp_alloc_nolock:
2741 }
2743 err_out:
2745 max_err_out:
2750 }
2752 /**
2753 * ntfs_extent_mft_record_free - free an extent mft record on an ntfs volume
2754 * @ni: ntfs inode of the mapped extent mft record to free
2755 * @m: mapped extent mft record of the ntfs inode @ni
2756 *
2757 * Free the mapped extent mft record @m of the extent ntfs inode @ni.
2758 *
2759 * Note that this function unmaps the mft record and closes and destroys @ni
2760 * internally and hence you cannot use either @ni nor @m any more after this
2761 * function returns success.
2762 *
2763 * On success return 0 and on error return -errno. @ni and @m are still valid
2764 * in this case and have not been freed.
2765 *
2766 * For some errors an error message is displayed and the success code 0 is
2767 * returned and the volume is then left dirty on umount. This makes sense in
2768 * case we could not rollback the changes that were already done since the
2769 * caller no longer wants to reference this mft record so it does not matter to
2770 * the caller if something is wrong with it as long as it is properly detached
2771 * from the base inode.
2772 */
2774 {
2780 le16 old_seq_no;
2781 u16 seq_no;
2797 /* Make sure we are holding the only reference to the extent inode. */
2803 }
2805 /* Dissociate the ntfs inode from the base inode. */
2817 }
2826 }
2828 /*
2829 * The extent inode is no longer attached to the base inode so no one
2830 * can get a reference to it any more.
2831 */
2833 /* Mark the mft record as not in use. */
2836 /* Increment the sequence number, skipping zero, if it is not zero. */
2842 seq_no++;
2845 /*
2846 * Set the ntfs inode dirty and write it out. We do not need to worry
2847 * about the base inode here since whatever caused the extent mft
2848 * record to be freed is guaranteed to do it already.
2849 */
2856 }
2857 rollback_error:
2858 /* Unmap and throw away the now freed extent inode. */
2862 /* Clear the bit in the $MFT/$BITMAP corresponding to this record. */
2867 /*
2868 * The extent inode is gone but we failed to deallocate it in
2869 * the mft bitmap. Just emit a warning and leave the volume
2870 * dirty on umount.
2871 */
2874 }
2876 rollback:
2877 /* Rollback what we did... */
2890 }
2896 }
2898 }
2905 }