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mft.c
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mft.c
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/**
* mft.c - NTFS kernel mft record operations. Part of the Linux-NTFS project.
*
* Copyright (c) 2001-2006 Anton Altaparmakov
* Copyright (c) 2002 Richard Russon
*
* This program/include file is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as published
* by the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program/include file is distributed in the hope that it will be
* useful, but WITHOUT ANY WARRANTY; without even the implied warranty
* of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program (in the main directory of the Linux-NTFS
* distribution in the file COPYING); if not, write to the Free Software
* Foundation,Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include <linux/buffer_head.h>
#include <linux/swap.h>
#include "attrib.h"
#include "aops.h"
#include "bitmap.h"
#include "debug.h"
#include "dir.h"
#include "lcnalloc.h"
#include "malloc.h"
#include "mft.h"
#include "ntfs.h"
/**
* map_mft_record_page - map the page in which a specific mft record resides
* @ni: ntfs inode whose mft record page to map
*
* This maps the page in which the mft record of the ntfs inode @ni is situated
* and returns a pointer to the mft record within the mapped page.
*
* Return value needs to be checked with IS_ERR() and if that is true PTR_ERR()
* contains the negative error code returned.
*/
static inline MFT_RECORD *map_mft_record_page(ntfs_inode *ni)
{
loff_t i_size;
ntfs_volume *vol = ni->vol;
struct inode *mft_vi = vol->mft_ino;
struct page *page;
unsigned long index, end_index;
unsigned ofs;
BUG_ON(ni->page);
/*
* The index into the page cache and the offset within the page cache
* page of the wanted mft record. FIXME: We need to check for
* overflowing the unsigned long, but I don't think we would ever get
* here if the volume was that big...
*/
index = (u64)ni->mft_no << vol->mft_record_size_bits >>
PAGE_CACHE_SHIFT;
ofs = (ni->mft_no << vol->mft_record_size_bits) & ~PAGE_CACHE_MASK;
i_size = i_size_read(mft_vi);
/* The maximum valid index into the page cache for $MFT's data. */
end_index = i_size >> PAGE_CACHE_SHIFT;
/* If the wanted index is out of bounds the mft record doesn't exist. */
if (unlikely(index >= end_index)) {
if (index > end_index || (i_size & ~PAGE_CACHE_MASK) < ofs +
vol->mft_record_size) {
page = ERR_PTR(-ENOENT);
ntfs_error(vol->sb, "Attemt to read mft record 0x%lx, "
"which is beyond the end of the mft. "
"This is probably a bug in the ntfs "
"driver.", ni->mft_no);
goto err_out;
}
}
/* Read, map, and pin the page. */
page = ntfs_map_page(mft_vi->i_mapping, index);
if (likely(!IS_ERR(page))) {
/* Catch multi sector transfer fixup errors. */
if (likely(ntfs_is_mft_recordp((le32*)(page_address(page) +
ofs)))) {
ni->page = page;
ni->page_ofs = ofs;
return page_address(page) + ofs;
}
ntfs_error(vol->sb, "Mft record 0x%lx is corrupt. "
"Run chkdsk.", ni->mft_no);
ntfs_unmap_page(page);
page = ERR_PTR(-EIO);
NVolSetErrors(vol);
}
err_out:
ni->page = NULL;
ni->page_ofs = 0;
return (void*)page;
}
/**
* map_mft_record - map, pin and lock an mft record
* @ni: ntfs inode whose MFT record to map
*
* First, take the mrec_lock mutex. We might now be sleeping, while waiting
* for the mutex if it was already locked by someone else.
*
* The page of the record is mapped using map_mft_record_page() before being
* returned to the caller.
*
* This in turn uses ntfs_map_page() to get the page containing the wanted mft
* record (it in turn calls read_cache_page() which reads it in from disk if
* necessary, increments the use count on the page so that it cannot disappear
* under us and returns a reference to the page cache page).
*
* If read_cache_page() invokes ntfs_readpage() to load the page from disk, it
* sets PG_locked and clears PG_uptodate on the page. Once I/O has completed
* and the post-read mst fixups on each mft record in the page have been
* performed, the page gets PG_uptodate set and PG_locked cleared (this is done
* in our asynchronous I/O completion handler end_buffer_read_mft_async()).
* ntfs_map_page() waits for PG_locked to become clear and checks if
* PG_uptodate is set and returns an error code if not. This provides
* sufficient protection against races when reading/using the page.
*
* However there is the write mapping to think about. Doing the above described
* checking here will be fine, because when initiating the write we will set
* PG_locked and clear PG_uptodate making sure nobody is touching the page
* contents. Doing the locking this way means that the commit to disk code in
* the page cache code paths is automatically sufficiently locked with us as
* we will not touch a page that has been locked or is not uptodate. The only
* locking problem then is them locking the page while we are accessing it.
*
* So that code will end up having to own the mrec_lock of all mft
* records/inodes present in the page before I/O can proceed. In that case we
* wouldn't need to bother with PG_locked and PG_uptodate as nobody will be
* accessing anything without owning the mrec_lock mutex. But we do need to
* use them because of the read_cache_page() invocation and the code becomes so
* much simpler this way that it is well worth it.
*
* The mft record is now ours and we return a pointer to it. You need to check
* the returned pointer with IS_ERR() and if that is true, PTR_ERR() will return
* the error code.
*
* NOTE: Caller is responsible for setting the mft record dirty before calling
* unmap_mft_record(). This is obviously only necessary if the caller really
* modified the mft record...
* Q: Do we want to recycle one of the VFS inode state bits instead?
* A: No, the inode ones mean we want to change the mft record, not we want to
* write it out.
*/
MFT_RECORD *map_mft_record(ntfs_inode *ni)
{
MFT_RECORD *m;
ntfs_debug("Entering for mft_no 0x%lx.", ni->mft_no);
/* Make sure the ntfs inode doesn't go away. */
atomic_inc(&ni->count);
/* Serialize access to this mft record. */
mutex_lock(&ni->mrec_lock);
m = map_mft_record_page(ni);
if (likely(!IS_ERR(m)))
return m;
mutex_unlock(&ni->mrec_lock);
atomic_dec(&ni->count);
ntfs_error(ni->vol->sb, "Failed with error code %lu.", -PTR_ERR(m));
return m;
}
/**
* unmap_mft_record_page - unmap the page in which a specific mft record resides
* @ni: ntfs inode whose mft record page to unmap
*
* This unmaps the page in which the mft record of the ntfs inode @ni is
* situated and returns. This is a NOOP if highmem is not configured.
*
* The unmap happens via ntfs_unmap_page() which in turn decrements the use
* count on the page thus releasing it from the pinned state.
*
* We do not actually unmap the page from memory of course, as that will be
* done by the page cache code itself when memory pressure increases or
* whatever.
*/
static inline void unmap_mft_record_page(ntfs_inode *ni)
{
BUG_ON(!ni->page);
// TODO: If dirty, blah...
ntfs_unmap_page(ni->page);
ni->page = NULL;
ni->page_ofs = 0;
return;
}
/**
* unmap_mft_record - release a mapped mft record
* @ni: ntfs inode whose MFT record to unmap
*
* We release the page mapping and the mrec_lock mutex which unmaps the mft
* record and releases it for others to get hold of. We also release the ntfs
* inode by decrementing the ntfs inode reference count.
*
* NOTE: If caller has modified the mft record, it is imperative to set the mft
* record dirty BEFORE calling unmap_mft_record().
*/
void unmap_mft_record(ntfs_inode *ni)
{
struct page *page = ni->page;
BUG_ON(!page);
ntfs_debug("Entering for mft_no 0x%lx.", ni->mft_no);
unmap_mft_record_page(ni);
mutex_unlock(&ni->mrec_lock);
atomic_dec(&ni->count);
/*
* If pure ntfs_inode, i.e. no vfs inode attached, we leave it to
* ntfs_clear_extent_inode() in the extent inode case, and to the
* caller in the non-extent, yet pure ntfs inode case, to do the actual
* tear down of all structures and freeing of all allocated memory.
*/
return;
}
/**
* map_extent_mft_record - load an extent inode and attach it to its base
* @base_ni: base ntfs inode
* @mref: mft reference of the extent inode to load
* @ntfs_ino: on successful return, pointer to the ntfs_inode structure
*
* Load the extent mft record @mref and attach it to its base inode @base_ni.
* Return the mapped extent mft record if IS_ERR(result) is false. Otherwise
* PTR_ERR(result) gives the negative error code.
*
* On successful return, @ntfs_ino contains a pointer to the ntfs_inode
* structure of the mapped extent inode.
*/
MFT_RECORD *map_extent_mft_record(ntfs_inode *base_ni, MFT_REF mref,
ntfs_inode **ntfs_ino)
{
MFT_RECORD *m;
ntfs_inode *ni = NULL;
ntfs_inode **extent_nis = NULL;
int i;
unsigned long mft_no = MREF(mref);
u16 seq_no = MSEQNO(mref);
bool destroy_ni = false;
ntfs_debug("Mapping extent mft record 0x%lx (base mft record 0x%lx).",
mft_no, base_ni->mft_no);
/* Make sure the base ntfs inode doesn't go away. */
atomic_inc(&base_ni->count);
/*
* Check if this extent inode has already been added to the base inode,
* in which case just return it. If not found, add it to the base
* inode before returning it.
*/
mutex_lock(&base_ni->extent_lock);
if (base_ni->nr_extents > 0) {
extent_nis = base_ni->ext.extent_ntfs_inos;
for (i = 0; i < base_ni->nr_extents; i++) {
if (mft_no != extent_nis[i]->mft_no)
continue;
ni = extent_nis[i];
/* Make sure the ntfs inode doesn't go away. */
atomic_inc(&ni->count);
break;
}
}
if (likely(ni != NULL)) {
mutex_unlock(&base_ni->extent_lock);
atomic_dec(&base_ni->count);
/* We found the record; just have to map and return it. */
m = map_mft_record(ni);
/* map_mft_record() has incremented this on success. */
atomic_dec(&ni->count);
if (likely(!IS_ERR(m))) {
/* Verify the sequence number. */
if (likely(le16_to_cpu(m->sequence_number) == seq_no)) {
ntfs_debug("Done 1.");
*ntfs_ino = ni;
return m;
}
unmap_mft_record(ni);
ntfs_error(base_ni->vol->sb, "Found stale extent mft "
"reference! Corrupt filesystem. "
"Run chkdsk.");
return ERR_PTR(-EIO);
}
map_err_out:
ntfs_error(base_ni->vol->sb, "Failed to map extent "
"mft record, error code %ld.", -PTR_ERR(m));
return m;
}
/* Record wasn't there. Get a new ntfs inode and initialize it. */
ni = ntfs_new_extent_inode(base_ni->vol->sb, mft_no);
if (unlikely(!ni)) {
mutex_unlock(&base_ni->extent_lock);
atomic_dec(&base_ni->count);
return ERR_PTR(-ENOMEM);
}
ni->vol = base_ni->vol;
ni->seq_no = seq_no;
ni->nr_extents = -1;
ni->ext.base_ntfs_ino = base_ni;
/* Now map the record. */
m = map_mft_record(ni);
if (IS_ERR(m)) {
mutex_unlock(&base_ni->extent_lock);
atomic_dec(&base_ni->count);
ntfs_clear_extent_inode(ni);
goto map_err_out;
}
/* Verify the sequence number if it is present. */
if (seq_no && (le16_to_cpu(m->sequence_number) != seq_no)) {
ntfs_error(base_ni->vol->sb, "Found stale extent mft "
"reference! Corrupt filesystem. Run chkdsk.");
destroy_ni = true;
m = ERR_PTR(-EIO);
goto unm_err_out;
}
/* Attach extent inode to base inode, reallocating memory if needed. */
if (!(base_ni->nr_extents & 3)) {
ntfs_inode **tmp;
int new_size = (base_ni->nr_extents + 4) * sizeof(ntfs_inode *);
tmp = kmalloc(new_size, GFP_NOFS);
if (unlikely(!tmp)) {
ntfs_error(base_ni->vol->sb, "Failed to allocate "
"internal buffer.");
destroy_ni = true;
m = ERR_PTR(-ENOMEM);
goto unm_err_out;
}
if (base_ni->nr_extents) {
BUG_ON(!base_ni->ext.extent_ntfs_inos);
memcpy(tmp, base_ni->ext.extent_ntfs_inos, new_size -
4 * sizeof(ntfs_inode *));
kfree(base_ni->ext.extent_ntfs_inos);
}
base_ni->ext.extent_ntfs_inos = tmp;
}
base_ni->ext.extent_ntfs_inos[base_ni->nr_extents++] = ni;
mutex_unlock(&base_ni->extent_lock);
atomic_dec(&base_ni->count);
ntfs_debug("Done 2.");
*ntfs_ino = ni;
return m;
unm_err_out:
unmap_mft_record(ni);
mutex_unlock(&base_ni->extent_lock);
atomic_dec(&base_ni->count);
/*
* If the extent inode was not attached to the base inode we need to
* release it or we will leak memory.
*/
if (destroy_ni)
ntfs_clear_extent_inode(ni);
return m;
}
#ifdef NTFS_RW
/**
* __mark_mft_record_dirty - set the mft record and the page containing it dirty
* @ni: ntfs inode describing the mapped mft record
*
* Internal function. Users should call mark_mft_record_dirty() instead.
*
* Set the mapped (extent) mft record of the (base or extent) ntfs inode @ni,
* as well as the page containing the mft record, dirty. Also, mark the base
* vfs inode dirty. This ensures that any changes to the mft record are
* written out to disk.
*
* NOTE: We only set I_DIRTY_SYNC and I_DIRTY_DATASYNC (and not I_DIRTY_PAGES)
* on the base vfs inode, because even though file data may have been modified,
* it is dirty in the inode meta data rather than the data page cache of the
* inode, and thus there are no data pages that need writing out. Therefore, a
* full mark_inode_dirty() is overkill. A mark_inode_dirty_sync(), on the
* other hand, is not sufficient, because I_DIRTY_DATASYNC needs to be set to
* ensure ->write_inode is called from generic_osync_inode() and this needs to
* happen or the file data would not necessarily hit the device synchronously,
* even though the vfs inode has the O_SYNC flag set. Also, I_DIRTY_DATASYNC
* simply "feels" better than just I_DIRTY_SYNC, since the file data has not
* actually hit the block device yet, which is not what I_DIRTY_SYNC on its own
* would suggest.
*/
void __mark_mft_record_dirty(ntfs_inode *ni)
{
ntfs_inode *base_ni;
ntfs_debug("Entering for inode 0x%lx.", ni->mft_no);
BUG_ON(NInoAttr(ni));
mark_ntfs_record_dirty(ni->page, ni->page_ofs);
/* Determine the base vfs inode and mark it dirty, too. */
mutex_lock(&ni->extent_lock);
if (likely(ni->nr_extents >= 0))
base_ni = ni;
else
base_ni = ni->ext.base_ntfs_ino;
mutex_unlock(&ni->extent_lock);
__mark_inode_dirty(VFS_I(base_ni), I_DIRTY_SYNC | I_DIRTY_DATASYNC);
}
static const char *ntfs_please_email = "Please email "
"[email protected] and say that you saw "
"this message. Thank you.";
/**
* ntfs_sync_mft_mirror_umount - synchronise an mft record to the mft mirror
* @vol: ntfs volume on which the mft record to synchronize resides
* @mft_no: mft record number of mft record to synchronize
* @m: mapped, mst protected (extent) mft record to synchronize
*
* Write the mapped, mst protected (extent) mft record @m with mft record
* number @mft_no to the mft mirror ($MFTMirr) of the ntfs volume @vol,
* bypassing the page cache and the $MFTMirr inode itself.
*
* This function is only for use at umount time when the mft mirror inode has
* already been disposed off. We BUG() if we are called while the mft mirror
* inode is still attached to the volume.
*
* On success return 0. On error return -errno.
*
* NOTE: This function is not implemented yet as I am not convinced it can
* actually be triggered considering the sequence of commits we do in super.c::
* ntfs_put_super(). But just in case we provide this place holder as the
* alternative would be either to BUG() or to get a NULL pointer dereference
* and Oops.
*/
static int ntfs_sync_mft_mirror_umount(ntfs_volume *vol,
const unsigned long mft_no, MFT_RECORD *m)
{
BUG_ON(vol->mftmirr_ino);
ntfs_error(vol->sb, "Umount time mft mirror syncing is not "
"implemented yet. %s", ntfs_please_email);
return -EOPNOTSUPP;
}
/**
* ntfs_sync_mft_mirror - synchronize an mft record to the mft mirror
* @vol: ntfs volume on which the mft record to synchronize resides
* @mft_no: mft record number of mft record to synchronize
* @m: mapped, mst protected (extent) mft record to synchronize
* @sync: if true, wait for i/o completion
*
* Write the mapped, mst protected (extent) mft record @m with mft record
* number @mft_no to the mft mirror ($MFTMirr) of the ntfs volume @vol.
*
* On success return 0. On error return -errno and set the volume errors flag
* in the ntfs volume @vol.
*
* NOTE: We always perform synchronous i/o and ignore the @sync parameter.
*
* TODO: If @sync is false, want to do truly asynchronous i/o, i.e. just
* schedule i/o via ->writepage or do it via kntfsd or whatever.
*/
int ntfs_sync_mft_mirror(ntfs_volume *vol, const unsigned long mft_no,
MFT_RECORD *m, int sync)
{
struct page *page;
unsigned int blocksize = vol->sb->s_blocksize;
int max_bhs = vol->mft_record_size / blocksize;
struct buffer_head *bhs[max_bhs];
struct buffer_head *bh, *head;
u8 *kmirr;
runlist_element *rl;
unsigned int block_start, block_end, m_start, m_end, page_ofs;
int i_bhs, nr_bhs, err = 0;
unsigned char blocksize_bits = vol->sb->s_blocksize_bits;
ntfs_debug("Entering for inode 0x%lx.", mft_no);
BUG_ON(!max_bhs);
if (unlikely(!vol->mftmirr_ino)) {
/* This could happen during umount... */
err = ntfs_sync_mft_mirror_umount(vol, mft_no, m);
if (likely(!err))
return err;
goto err_out;
}
/* Get the page containing the mirror copy of the mft record @m. */
page = ntfs_map_page(vol->mftmirr_ino->i_mapping, mft_no >>
(PAGE_CACHE_SHIFT - vol->mft_record_size_bits));
if (IS_ERR(page)) {
ntfs_error(vol->sb, "Failed to map mft mirror page.");
err = PTR_ERR(page);
goto err_out;
}
lock_page(page);
BUG_ON(!PageUptodate(page));
ClearPageUptodate(page);
/* Offset of the mft mirror record inside the page. */
page_ofs = (mft_no << vol->mft_record_size_bits) & ~PAGE_CACHE_MASK;
/* The address in the page of the mirror copy of the mft record @m. */
kmirr = page_address(page) + page_ofs;
/* Copy the mst protected mft record to the mirror. */
memcpy(kmirr, m, vol->mft_record_size);
/* Create uptodate buffers if not present. */
if (unlikely(!page_has_buffers(page))) {
struct buffer_head *tail;
bh = head = alloc_page_buffers(page, blocksize, 1);
do {
set_buffer_uptodate(bh);
tail = bh;
bh = bh->b_this_page;
} while (bh);
tail->b_this_page = head;
attach_page_buffers(page, head);
}
bh = head = page_buffers(page);
BUG_ON(!bh);
rl = NULL;
nr_bhs = 0;
block_start = 0;
m_start = kmirr - (u8*)page_address(page);
m_end = m_start + vol->mft_record_size;
do {
block_end = block_start + blocksize;
/* If the buffer is outside the mft record, skip it. */
if (block_end <= m_start)
continue;
if (unlikely(block_start >= m_end))
break;
/* Need to map the buffer if it is not mapped already. */
if (unlikely(!buffer_mapped(bh))) {
VCN vcn;
LCN lcn;
unsigned int vcn_ofs;
bh->b_bdev = vol->sb->s_bdev;
/* Obtain the vcn and offset of the current block. */
vcn = ((VCN)mft_no << vol->mft_record_size_bits) +
(block_start - m_start);
vcn_ofs = vcn & vol->cluster_size_mask;
vcn >>= vol->cluster_size_bits;
if (!rl) {
down_read(&NTFS_I(vol->mftmirr_ino)->
runlist.lock);
rl = NTFS_I(vol->mftmirr_ino)->runlist.rl;
/*
* $MFTMirr always has the whole of its runlist
* in memory.
*/
BUG_ON(!rl);
}
/* Seek to element containing target vcn. */
while (rl->length && rl[1].vcn <= vcn)
rl++;
lcn = ntfs_rl_vcn_to_lcn(rl, vcn);
/* For $MFTMirr, only lcn >= 0 is a successful remap. */
if (likely(lcn >= 0)) {
/* Setup buffer head to correct block. */
bh->b_blocknr = ((lcn <<
vol->cluster_size_bits) +
vcn_ofs) >> blocksize_bits;
set_buffer_mapped(bh);
} else {
bh->b_blocknr = -1;
ntfs_error(vol->sb, "Cannot write mft mirror "
"record 0x%lx because its "
"location on disk could not "
"be determined (error code "
"%lli).", mft_no,
(long long)lcn);
err = -EIO;
}
}
BUG_ON(!buffer_uptodate(bh));
BUG_ON(!nr_bhs && (m_start != block_start));
BUG_ON(nr_bhs >= max_bhs);
bhs[nr_bhs++] = bh;
BUG_ON((nr_bhs >= max_bhs) && (m_end != block_end));
} while (block_start = block_end, (bh = bh->b_this_page) != head);
if (unlikely(rl))
up_read(&NTFS_I(vol->mftmirr_ino)->runlist.lock);
if (likely(!err)) {
/* Lock buffers and start synchronous write i/o on them. */
for (i_bhs = 0; i_bhs < nr_bhs; i_bhs++) {
struct buffer_head *tbh = bhs[i_bhs];
if (!trylock_buffer(tbh))
BUG();
BUG_ON(!buffer_uptodate(tbh));
clear_buffer_dirty(tbh);
get_bh(tbh);
tbh->b_end_io = end_buffer_write_sync;
submit_bh(WRITE, tbh);
}
/* Wait on i/o completion of buffers. */
for (i_bhs = 0; i_bhs < nr_bhs; i_bhs++) {
struct buffer_head *tbh = bhs[i_bhs];
wait_on_buffer(tbh);
if (unlikely(!buffer_uptodate(tbh))) {
err = -EIO;
/*
* Set the buffer uptodate so the page and
* buffer states do not become out of sync.
*/
set_buffer_uptodate(tbh);
}
}
} else /* if (unlikely(err)) */ {
/* Clean the buffers. */
for (i_bhs = 0; i_bhs < nr_bhs; i_bhs++)
clear_buffer_dirty(bhs[i_bhs]);
}
/* Current state: all buffers are clean, unlocked, and uptodate. */
/* Remove the mst protection fixups again. */
post_write_mst_fixup((NTFS_RECORD*)kmirr);
flush_dcache_page(page);
SetPageUptodate(page);
unlock_page(page);
ntfs_unmap_page(page);
if (likely(!err)) {
ntfs_debug("Done.");
} else {
ntfs_error(vol->sb, "I/O error while writing mft mirror "
"record 0x%lx!", mft_no);
err_out:
ntfs_error(vol->sb, "Failed to synchronize $MFTMirr (error "
"code %i). Volume will be left marked dirty "
"on umount. Run ntfsfix on the partition "
"after umounting to correct this.", -err);
NVolSetErrors(vol);
}
return err;
}
/**
* write_mft_record_nolock - write out a mapped (extent) mft record
* @ni: ntfs inode describing the mapped (extent) mft record
* @m: mapped (extent) mft record to write
* @sync: if true, wait for i/o completion
*
* Write the mapped (extent) mft record @m described by the (regular or extent)
* ntfs inode @ni to backing store. If the mft record @m has a counterpart in
* the mft mirror, that is also updated.
*
* We only write the mft record if the ntfs inode @ni is dirty and the first
* buffer belonging to its mft record is dirty, too. We ignore the dirty state
* of subsequent buffers because we could have raced with
* fs/ntfs/aops.c::mark_ntfs_record_dirty().
*
* On success, clean the mft record and return 0. On error, leave the mft
* record dirty and return -errno.
*
* NOTE: We always perform synchronous i/o and ignore the @sync parameter.
* However, if the mft record has a counterpart in the mft mirror and @sync is
* true, we write the mft record, wait for i/o completion, and only then write
* the mft mirror copy. This ensures that if the system crashes either the mft
* or the mft mirror will contain a self-consistent mft record @m. If @sync is
* false on the other hand, we start i/o on both and then wait for completion
* on them. This provides a speedup but no longer guarantees that you will end
* up with a self-consistent mft record in the case of a crash but if you asked
* for asynchronous writing you probably do not care about that anyway.
*
* TODO: If @sync is false, want to do truly asynchronous i/o, i.e. just
* schedule i/o via ->writepage or do it via kntfsd or whatever.
*/
int write_mft_record_nolock(ntfs_inode *ni, MFT_RECORD *m, int sync)
{
ntfs_volume *vol = ni->vol;
struct page *page = ni->page;
unsigned int blocksize = vol->sb->s_blocksize;
unsigned char blocksize_bits = vol->sb->s_blocksize_bits;
int max_bhs = vol->mft_record_size / blocksize;
struct buffer_head *bhs[max_bhs];
struct buffer_head *bh, *head;
runlist_element *rl;
unsigned int block_start, block_end, m_start, m_end;
int i_bhs, nr_bhs, err = 0;
ntfs_debug("Entering for inode 0x%lx.", ni->mft_no);
BUG_ON(NInoAttr(ni));
BUG_ON(!max_bhs);
BUG_ON(!PageLocked(page));
/*
* If the ntfs_inode is clean no need to do anything. If it is dirty,
* mark it as clean now so that it can be redirtied later on if needed.
* There is no danger of races since the caller is holding the locks
* for the mft record @m and the page it is in.
*/
if (!NInoTestClearDirty(ni))
goto done;
bh = head = page_buffers(page);
BUG_ON(!bh);
rl = NULL;
nr_bhs = 0;
block_start = 0;
m_start = ni->page_ofs;
m_end = m_start + vol->mft_record_size;
do {
block_end = block_start + blocksize;
/* If the buffer is outside the mft record, skip it. */
if (block_end <= m_start)
continue;
if (unlikely(block_start >= m_end))
break;
/*
* If this block is not the first one in the record, we ignore
* the buffer's dirty state because we could have raced with a
* parallel mark_ntfs_record_dirty().
*/
if (block_start == m_start) {
/* This block is the first one in the record. */
if (!buffer_dirty(bh)) {
BUG_ON(nr_bhs);
/* Clean records are not written out. */
break;
}
}
/* Need to map the buffer if it is not mapped already. */
if (unlikely(!buffer_mapped(bh))) {
VCN vcn;
LCN lcn;
unsigned int vcn_ofs;
bh->b_bdev = vol->sb->s_bdev;
/* Obtain the vcn and offset of the current block. */
vcn = ((VCN)ni->mft_no << vol->mft_record_size_bits) +
(block_start - m_start);
vcn_ofs = vcn & vol->cluster_size_mask;
vcn >>= vol->cluster_size_bits;
if (!rl) {
down_read(&NTFS_I(vol->mft_ino)->runlist.lock);
rl = NTFS_I(vol->mft_ino)->runlist.rl;
BUG_ON(!rl);
}
/* Seek to element containing target vcn. */
while (rl->length && rl[1].vcn <= vcn)
rl++;
lcn = ntfs_rl_vcn_to_lcn(rl, vcn);
/* For $MFT, only lcn >= 0 is a successful remap. */
if (likely(lcn >= 0)) {
/* Setup buffer head to correct block. */
bh->b_blocknr = ((lcn <<
vol->cluster_size_bits) +
vcn_ofs) >> blocksize_bits;
set_buffer_mapped(bh);
} else {
bh->b_blocknr = -1;
ntfs_error(vol->sb, "Cannot write mft record "
"0x%lx because its location "
"on disk could not be "
"determined (error code %lli).",
ni->mft_no, (long long)lcn);
err = -EIO;
}
}
BUG_ON(!buffer_uptodate(bh));
BUG_ON(!nr_bhs && (m_start != block_start));
BUG_ON(nr_bhs >= max_bhs);
bhs[nr_bhs++] = bh;
BUG_ON((nr_bhs >= max_bhs) && (m_end != block_end));
} while (block_start = block_end, (bh = bh->b_this_page) != head);
if (unlikely(rl))
up_read(&NTFS_I(vol->mft_ino)->runlist.lock);
if (!nr_bhs)
goto done;
if (unlikely(err))
goto cleanup_out;
/* Apply the mst protection fixups. */
err = pre_write_mst_fixup((NTFS_RECORD*)m, vol->mft_record_size);
if (err) {
ntfs_error(vol->sb, "Failed to apply mst fixups!");
goto cleanup_out;
}
flush_dcache_mft_record_page(ni);
/* Lock buffers and start synchronous write i/o on them. */
for (i_bhs = 0; i_bhs < nr_bhs; i_bhs++) {
struct buffer_head *tbh = bhs[i_bhs];
if (!trylock_buffer(tbh))
BUG();
BUG_ON(!buffer_uptodate(tbh));
clear_buffer_dirty(tbh);
get_bh(tbh);
tbh->b_end_io = end_buffer_write_sync;
submit_bh(WRITE, tbh);
}
/* Synchronize the mft mirror now if not @sync. */
if (!sync && ni->mft_no < vol->mftmirr_size)
ntfs_sync_mft_mirror(vol, ni->mft_no, m, sync);
/* Wait on i/o completion of buffers. */
for (i_bhs = 0; i_bhs < nr_bhs; i_bhs++) {
struct buffer_head *tbh = bhs[i_bhs];
wait_on_buffer(tbh);
if (unlikely(!buffer_uptodate(tbh))) {
err = -EIO;
/*
* Set the buffer uptodate so the page and buffer
* states do not become out of sync.
*/
if (PageUptodate(page))
set_buffer_uptodate(tbh);
}
}
/* If @sync, now synchronize the mft mirror. */
if (sync && ni->mft_no < vol->mftmirr_size)
ntfs_sync_mft_mirror(vol, ni->mft_no, m, sync);
/* Remove the mst protection fixups again. */
post_write_mst_fixup((NTFS_RECORD*)m);
flush_dcache_mft_record_page(ni);
if (unlikely(err)) {
/* I/O error during writing. This is really bad! */
ntfs_error(vol->sb, "I/O error while writing mft record "
"0x%lx! Marking base inode as bad. You "
"should unmount the volume and run chkdsk.",
ni->mft_no);
goto err_out;
}
done:
ntfs_debug("Done.");
return 0;
cleanup_out:
/* Clean the buffers. */
for (i_bhs = 0; i_bhs < nr_bhs; i_bhs++)
clear_buffer_dirty(bhs[i_bhs]);
err_out:
/*
* Current state: all buffers are clean, unlocked, and uptodate.
* The caller should mark the base inode as bad so that no more i/o
* happens. ->clear_inode() will still be invoked so all extent inodes
* and other allocated memory will be freed.
*/
if (err == -ENOMEM) {
ntfs_error(vol->sb, "Not enough memory to write mft record. "
"Redirtying so the write is retried later.");
mark_mft_record_dirty(ni);
err = 0;
} else
NVolSetErrors(vol);
return err;
}
/**
* ntfs_may_write_mft_record - check if an mft record may be written out
* @vol: [IN] ntfs volume on which the mft record to check resides
* @mft_no: [IN] mft record number of the mft record to check
* @m: [IN] mapped mft record to check
* @locked_ni: [OUT] caller has to unlock this ntfs inode if one is returned
*
* Check if the mapped (base or extent) mft record @m with mft record number
* @mft_no belonging to the ntfs volume @vol may be written out. If necessary
* and possible the ntfs inode of the mft record is locked and the base vfs
* inode is pinned. The locked ntfs inode is then returned in @locked_ni. The
* caller is responsible for unlocking the ntfs inode and unpinning the base
* vfs inode.
*
* Return 'true' if the mft record may be written out and 'false' if not.
*
* The caller has locked the page and cleared the uptodate flag on it which
* means that we can safely write out any dirty mft records that do not have
* their inodes in icache as determined by ilookup5() as anyone
* opening/creating such an inode would block when attempting to map the mft
* record in read_cache_page() until we are finished with the write out.
*
* Here is a description of the tests we perform:
*
* If the inode is found in icache we know the mft record must be a base mft
* record. If it is dirty, we do not write it and return 'false' as the vfs
* inode write paths will result in the access times being updated which would
* cause the base mft record to be redirtied and written out again. (We know
* the access time update will modify the base mft record because Windows
* chkdsk complains if the standard information attribute is not in the base
* mft record.)
*
* If the inode is in icache and not dirty, we attempt to lock the mft record
* and if we find the lock was already taken, it is not safe to write the mft
* record and we return 'false'.
*
* If we manage to obtain the lock we have exclusive access to the mft record,
* which also allows us safe writeout of the mft record. We then set
* @locked_ni to the locked ntfs inode and return 'true'.
*
* Note we cannot just lock the mft record and sleep while waiting for the lock
* because this would deadlock due to lock reversal (normally the mft record is
* locked before the page is locked but we already have the page locked here
* when we try to lock the mft record).
*
* If the inode is not in icache we need to perform further checks.
*
* If the mft record is not a FILE record or it is a base mft record, we can
* safely write it and return 'true'.
*
* We now know the mft record is an extent mft record. We check if the inode
* corresponding to its base mft record is in icache and obtain a reference to
* it if it is. If it is not, we can safely write it and return 'true'.
*
* We now have the base inode for the extent mft record. We check if it has an
* ntfs inode for the extent mft record attached and if not it is safe to write
* the extent mft record and we return 'true'.
*
* The ntfs inode for the extent mft record is attached to the base inode so we
* attempt to lock the extent mft record and if we find the lock was already
* taken, it is not safe to write the extent mft record and we return 'false'.
*
* If we manage to obtain the lock we have exclusive access to the extent mft
* record, which also allows us safe writeout of the extent mft record. We
* set the ntfs inode of the extent mft record clean and then set @locked_ni to
* the now locked ntfs inode and return 'true'.
*
* Note, the reason for actually writing dirty mft records here and not just
* relying on the vfs inode dirty code paths is that we can have mft records
* modified without them ever having actual inodes in memory. Also we can have
* dirty mft records with clean ntfs inodes in memory. None of the described
* cases would result in the dirty mft records being written out if we only
* relied on the vfs inode dirty code paths. And these cases can really occur
* during allocation of new mft records and in particular when the
* initialized_size of the $MFT/$DATA attribute is extended and the new space
* is initialized using ntfs_mft_record_format(). The clean inode can then
* appear if the mft record is reused for a new inode before it got written
* out.
*/
bool ntfs_may_write_mft_record(ntfs_volume *vol, const unsigned long mft_no,
const MFT_RECORD *m, ntfs_inode **locked_ni)
{
struct super_block *sb = vol->sb;
struct inode *mft_vi = vol->mft_ino;
struct inode *vi;
ntfs_inode *ni, *eni, **extent_nis;
int i;
ntfs_attr na;
ntfs_debug("Entering for inode 0x%lx.", mft_no);
/*
* Normally we do not return a locked inode so set @locked_ni to NULL.
*/
BUG_ON(!locked_ni);
*locked_ni = NULL;
/*
* Check if the inode corresponding to this mft record is in the VFS
* inode cache and obtain a reference to it if it is.
*/
ntfs_debug("Looking for inode 0x%lx in icache.", mft_no);
na.mft_no = mft_no;
na.name = NULL;
na.name_len = 0;
na.type = AT_UNUSED;
/*
* Optimize inode 0, i.e. $MFT itself, since we have it in memory and
* we get here for it rather often.
*/
if (!mft_no) {
/* Balance the below iput(). */
vi = igrab(mft_vi);
BUG_ON(vi != mft_vi);
} else {
/*
* Have to use ilookup5_nowait() since ilookup5() waits for the
* inode lock which causes ntfs to deadlock when a concurrent
* inode write via the inode dirty code paths and the page
* dirty code path of the inode dirty code path when writing
* $MFT occurs.
*/
vi = ilookup5_nowait(sb, mft_no, (test_t)ntfs_test_inode, &na);
}
if (vi) {
ntfs_debug("Base inode 0x%lx is in icache.", mft_no);
/* The inode is in icache. */
ni = NTFS_I(vi);
/* Take a reference to the ntfs inode. */
atomic_inc(&ni->count);
/* If the inode is dirty, do not write this record. */
if (NInoDirty(ni)) {
ntfs_debug("Inode 0x%lx is dirty, do not write it.",
mft_no);
atomic_dec(&ni->count);
iput(vi);
return false;
}
ntfs_debug("Inode 0x%lx is not dirty.", mft_no);
/* The inode is not dirty, try to take the mft record lock. */
if (unlikely(!mutex_trylock(&ni->mrec_lock))) {
ntfs_debug("Mft record 0x%lx is already locked, do "
"not write it.", mft_no);
atomic_dec(&ni->count);
iput(vi);
return false;
}
ntfs_debug("Managed to lock mft record 0x%lx, write it.",
mft_no);
/*
* The write has to occur while we hold the mft record lock so
* return the locked ntfs inode.
*/
*locked_ni = ni;
return true;
}
ntfs_debug("Inode 0x%lx is not in icache.", mft_no);